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CALIFORNIA FORESTRY 'PAMPHLETS

VOL. I

Chico Forestry Substation, 1897-8. Univ. of Cali-
fornia Experiment Station. v *

Santa Monica Forestry Substation 1899-1901. Univ.
of California Experiment Station.

'-••*v CA^^V*.^ _^"-/v£ £ • 'S^*.. . i) M 2 — / f •?

The Value of Oak Leaves for Forage. Bull. 150.
Univ. of California Agri. Experiment Station.

Walnut Culture in California Walnut Blight. Cali-
fornia Agri. Experiment otation. By Ralph E.
Smith. >! <°

C. T. P-3

!*•' <r/^u*£vu. r,

A/^v/T/V

SOUTHERN CALIFORNIA CULTURE SUBSTATION. 327

Many-flowered millet-grass makes a very thick, rank growth the second
year. Schrader's brome grass does not make nearly the growth on the
damp land as it does on the home tract, where, along the water ditch, it
made a dense mat of fine feed before it headed out. As an annual grass
crop, on semi-arid lands, I think that Schrader's brome will be a good
acquisition, and will subdue, to a certain extent, the troublesome grass
that goes under the name of 'Wild Rye' in the Sacramento Valley.'7

Kales. — Dwarf Purple, Dwarf Scotch, Tall Scotch, White Vienna, and
Tall Jersey kales were planted on the ten-acre tract January 28, 1898.
All the varieties made a very poor growth during the summer until fall,
when Tall Scotch and Tall Jersey suddenly made a rank growth until
they came into bloom. By December 15th they had attained a height
of about eight feet. White Vienna grew to be five feet high. The
dwarf varieties, with the exception of Dwarf Purple, succumbed to the
green aphis and never bloomed. All the dwarf varieties were a failure
in the dry season of 1898.

Sugar Beets. — Eight new varieties of sugar beets were tested in 1898,
but the seed had arrived too late to obtain the best results. The beets
did not attain a sufficient size to warrant an analysis. On April 9th
four acres were planted to k'G. W. I." improved seed obtained from the
Chino Valley Beet Sugar Co., and one acre to Vilmorin Improved seed
obtained from Berkeley. A total stand of four acres was obtained, and
the sugar percentage was 15.2. Four seasons previously, in 1894, when
field tests were made with leading varieties of sugar beets, the highest
percentage obtained was 14.3 upon a brand known as "O. D.," imported
by the Chino Valley Sugar Co. The average, however, was below 13
per cent. A considerable improvement in the sugar percentage has
therefore taken place.

V

328 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

E. CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY.

(One mile east of Chico, and one and a half miles from the foothills of the Sierras.

Elevation, 230 feet.

The Chico forestry station was originally a part of the famous Rancho
Chico (26,000 acres ), belonging to the late General John Bidwell. This
great estate contains some of the finest oak groves known to exist in
California. Portions of it still remain as wild as when the Sacramento
Valley was discovered, and have been the delight of such botanists as
the late Dr. C. C. Parry, the late Professor Asa Gray, and Sir Joseph
Hooker.

TREE GROWTH ON RANCHO CHICO.

General Bidwell began to plant native California trees as early as
1856, and added to his arboretum many of the finer exotics, until his
collection is in some important particulars one of the finest on the
Pacific Coast. The most of his tree-planting was done in 1868, but
has been continued at intervals ever since. Many specimens of Pinyx
sabiniana and Pinus ponderosa planted in 1856 now have trunks of frop:
8 feet 10 inches to 11 feet in circumference, and are more than 100 f< ;
high. Of Sequoia gigantea and S. sempervirens there are many spe-
mens 80 and 90 feet high and girthing from 4 to 5-| feet. A native cot-
ton wood (Populus Fremontii), which has grown to its present size since
1856, measures 16 feet in circumference of trunk, and is 100 feet high.
Among trees planted about 1868 are the following: Quercus robur, 50
feet high, girth 25 inches; Quercus cerris, 45 feet high, girth 22 inches;
Juglans Calif ornica, 80 feet high, girth 13 feet; Salisburia adianti folia,
40 feet high, girth 3 feet 3 inches: Camphora officinalis, height 70 feet,
girth 6 feet 4 inches. Another camphor girths 9 feet, but is of more
spreading habit. The growth of many American oaks, of pecans and
hickories, of the Liriodendron, the European linden, elms, and other
deciduous trees, has been surprisingly rapid. At the same time the
finer spruces, firs, cryptomerias, and other conifers have done quite as
well as the deciduous trees. There is as yet no complete catalogue of
the native and exotic trees on Rancho Chico, but the station is accumu-
lating data for such a publication at some future period.

Native Oak Groves. — One of the most remarkable features of Rancho
Chico and the surrounding district, from a forestry standpoint, consists
of very fine and large groves of second-growth white oak (Q. lobata).
These have grown since the valley was occupied by .white men and are
undoubtedly the best young oak groves in California. Several of them,
covering areas of from twenty to forty acres, were recently photographed
for the Division of Forestry, at Washington, and the station is collecting
statistics regarding the rate of growth, yield per acre, and value of the
crop. .,, ,

FOKJESTRY FINtfca& ^ND HISTORY.

Several important ;clja^gfiS', ty&ye ;takerri 'place at the Forestry Station
since the date of 'the compilation- <>f'^the" last report (see volume for
1896-7, pages 406-412). Considering the very small sum now spent on

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY. 329

the station, it has been creditably maintained, and continues to furnish
new and valuable information respecting the forestry resources of
Northern California.

The State Legislature in the winter of 1896-7, fully recognizing the
usefulness of the two forestry stations (one at Chico, the other at Santa
Monica, both under the charge of the University of California), made
an appropriation of $8,000 to carry on these stations for the two fiscal
years 1897-8 and 1898-9. This amount was based upon a very careful
Estimate made by the Agricultural Department of the University,
which itemized every proposed expenditure, and showed that with
$2,000 per annum for each of the two stations, they could be greatly
developed, upon extremely useful lines. The former appropriation of
$5,000, or $1,250 per annum for each of the two stations, was shown to
be inadequate to the full and proper growth of these important forestry
stations. This item was unexpectedly vetoed by the Governor. By
this veto, the Regents of the University were compelled to either seek
for some legal means for abandoning these two stations, or to make the
smallest possible appropriation necessary to keep them going until their
permanent status could be determined. The Agricultural Department
was, therefore, ordered to cut down all expenditures, and reduce the rank
-. I the stations. The appropriation made to sustain them both was $1,500
lor the fiscal year 1897-8. The appropriation for the fiscal year 1898-9
x* increased to $1,630. The appropriation for 1899-1900 was $1,230.

To sum up this brief history: The two forestry stations, when receiving
$2,500 per annum from the State, were, in point of proportionate develop-
ment, not very far behind the four farm stations, on each of which the
University spends from $2,000 to $2,200 per annum (from the United
States Agricultural Experiment Station Fund). The appropriation
made by the Legislature of 1896-7 would have raised the forestry
stations to practically the same level as the farm stations, and so would
have greatly increased their permanent efficiency.

The meager allowance for the station at Chico necessarily forced a
change in the method of managing the place. It was put under a
workman, instead of a foreman, and though always run economically,
a multitude of new, hard-time economies were put into practice. Mr.
A. B. Boland, long the active and efficient foreman here, was sent to
the Sierra Foothills substation for a short time, and was thence trans-
ferred to a vacancy at the Central Station. Mr. H. B. Allen, of Chico,
who had been for a year under Mr. Boland, was promoted in July, 1897,
to be "workman in charge," and was left, without assistance, to carry
on the station.

A floor was laid in the wagonshed, and rooms made of rough mountain
lumber for Mr. Allen and his wife. They gradually improved the
surroundings of the building, and made a pleasant home out of this
frontier-like combination of barn, wagonshed, stable, and cottage.

In July, 1897, Mr. Pennell resigned as Patron, being about to leave
Chico, and Mr. V. C. Richards, editor of the "Chico Record," was
appointed. He has taken much interest in the station, visiting it
often, helping and advising, so that its success under trying circum-
stances is largely due to his efficiency.

The Lath House. — A small lath-house, 12 feet by 40 feet, was built in
the spring of 1897, and has been extremely useful, enabling seedling
conifers to withstand the summer heat. It has been occupied ever since,

330

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

and among the species grown there and in lath-covered frames were
upward of. forty species of conifers, which were mostly removed to
nursery or to plantations, in the winter of 1899. Many of these species
are new to California.

CLIMATIC CONDITIONS.

As shown in the foregoing pages, the climate of this portion of the
Sacramento Valley must be exceedingly favorable to the growth of a
great variety of trees. The rainfall is usually abundant and the sum-
mers, though hot, are tempered by sea breezes. The most serious diffi-
culties are caused by late and often severe frosts. Still the lists of
species of trees and shrubs represented at the station and published in
previous reports, show that there are gains as well as losses. Many oaks
and other hardwood trees grow especially well here. The limitations of
the district are more distinctly marked in the case of the eucalypts and
acacias than in that of any other class of trees.

Rainfall. — The following table, chiefly compiled from observations
made by A. L. Nichols, of Chico, covers fifteen successive seasons:

RAINFALL AT CHICO — SEPTEMBER, 1885, TO JUNE, 1SOO.

Season.

Rain Began.

Rain Ended.

TotHl Rainfall
in Inches.

1885-6

Sept. 24, 1885

May 6, 1886

31.13

1886-7

Oct. 15, 1886

June 12, 1887

17.16

1887-8

Nov. 29, 1887

June 17, 1888

14.49

1888-9

Sept. 15, 1888

June 27, 1889

21.56

1889-90 . . - -

Oct. 7, 1889

May 11, 1890

52.71

1890-1

Sept. 29, 1890

July 8, 1891

23.46

1891-2

Oct. 28, 1891

June 10, 1892

22.40

1892-3

Oct. 8, 1892

May 18, 1893

33.56

1893-4

Sept. 7, 1893

July 11, 1894

23.32

1894-5

Sept. 29, 1894

May 27, 1895

34.56

1895-6

Sept. 10, 1895

May 11, 1896

25.54

1896-7

Aug. 30, 1896

June 20, 1897

22.44

1897-8 _

Sept. 28, 1897

Apr. 30, 1898

12.81

1898-9

Sept. 25, 1898

Apr. 1, 1899

18.45

1899-00 ....

Oct. 13, 1899

May 12, 1900

24.89

The average annual rainfall, on the basis of this table, is 26.06 inches.
In the fifteen years the rainfall twice fell below 15 inches, and four times
below 20 inches. Four times, however, it was above 30 inches.

The total rainfall of the dry season of 1897-8 was distributed as fol-
lows: September, .09; October, 3.24; November, 1.27; December, 1.98;
January, .73; February, 2.69; March, .13; April, .46.

The rainfall for December, 1889, which was 12.64 inches, was more
than the entire rainfall of the season of 1897-8; and the total of
December and January, 1889, was 22.18 inches, which surpasses the
rainfall for four of the twelve seasons herein tabulated.

Temperature. — The following temperature statistics are compiled from
fifteen years' observations, ending with 1898, and made by the railroad
agent at Chico and by various Weather Bureau agents:

Average winter temperature - 46.9°

Average spring temperature 62.4°

Average summer temperature . 81.1°

Average autumn temperature ^ 64.1°

Average annual temperature 63.6°

Highest temperature 115.0°

Lowest temperature _ - --- 18.0°

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY.

331

The lowest point of 18° was reached April 17, 1883, when the spring
growth of many grapevines was killed. It was again reached in the
spring of IScSS. The minimum of 20° has been reached on many occa-
sions. March 17, 1898, the minimum was 22°, and this destroyed a
good deal of the fruit crop. Large trees of Eucalyptus globulus, a foot
or more in diameter, were killed to the ground in 1883, and others have
been injured on several occasions since. The species of eucalyptus
described as hardy here have withstood 20° at the station. The extreme
maximum of 115° has not yet been recorded at the station (since 1894).
The summer heat, while great, is not a moist heat, and is easily endured.

Climatic Vicissitudes of the Past. — The late GeneralJohn Bid well, whose
invaluable and characteristic pioneer recollections have been drawn upon
by every historian of California, furnished us a very interesting synop-
sis of the seasons before 1852, in the Sacramento Valley. The following
notes were taken from his conversation on the subject in May, 1898:

Season.

Character.

General Bidwell's Comments.

10-1 ...

Very dry indeed

Livestock suffered much

n -2

Verv wet and warm

Great floods. Cattle drowned

I 12-3

A dry season

1843-4

Another dry season

Time of Fremont's first expedition So little snow

1844-5

Medium wet

in the Sierras that he was able to cross without
much difficulty.

W^ould have been a very good agricultural season

1845-6
1846-7 -.

Wet, but not cold ....
Medium wet

Fremont's second expedition.
Time of Mexican ^Var

1847-8

Dry and cold

Discovery of gold.

1848-9
1849-50

Wet and snowy; a
remarkable year.

Very wet

Snow in December, 1848, one foot deep over valley;
in January much more snow. Hard drifts three
feet deep in valley, near where Chico now stands.
Snow lay for a month before melting.

Much suffering in mining camps

1850-1

Dry

1851-2

Dry to very dry

Much complaint from cattlemen, even on the Coast.

Additions to Arboretum, Etc. — In the spring of 1898 many specimen
trees, in some cases from ten to one hundred of a sort, were planted in
the arboretum or in forest form. The additions include the following
oaks: Quercus alba, Q. bicolor, Q. cerris, Q. coccinea, Q. densiflora, Q.
Dovglasii, Q. dumnsa, Q. ilex, Q. imbricatia, Q. macrocarpa, Q. nigra, Q.
phellos, Q. robur, Q. rubrn, Q. Wixlizeni.

The other additions were chiefly deciduous, and included Aphanantha
aspera, two species of Celtis, three species of Colutea, two of Fraxinus,
several of Robinias and Gleditschias, two species of Rhus, economically
valuable, and a number of species from the southern Alleghanies, the trees
of which region seem to thrive better here than at any other California
substation. A dozen fine trees of Arbutus Menziesii (the Madrono) were
set in the arboretum.

332

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

A large number of selected trees were shipped in the spring of 1897 to
various points north of Chico, also to a number of points in the San Joa-
quin Valley and in Southern California, so as to afford comparative
tests of species on different soils and at different 'elevations.

Nursery in 1898—9. — So many shipments have been made, and so
many trees planted out, that the nursery stock is greatly reduced, but it
contains some fine conifers such as Cupressus Corneyana and C. Lusi-
tanica, also some broad-leaved evergreens, principally from Chile, the
Southern States, and Japan; also, some new willows, many useful
deciduous trees, and ten or twelve species of economic and flowering
shrubs, for which a separate place has been selected near the west
entrance. Magnolia glauca is doing very well. Persea Lingue and Boldea
fragrans also seem well adapted to the place.

Self-sown Seedlings. — An interesting feature of the station is the
extent to which forest trees and other seedlings are now growing in
various parts of the grounds. In May, 1898, the following species were
observed, in great numbers, from self-sown seed of the previous autumn:
Juglans Californica, Catalpa speciosa, Paulownia imperialis, Negundo
California, Fraxinus Oregana, Cercis Texensis, and Vitis Calif ornicaj
besides sycamores, cottonwoods, and willows. A few Cupressus semper-
virens and Pinus Austriaca have grown from self-sown seeds in the groves
of these species.

STUDIES OF TREE DEVELOPMENT.

The especial fitness of the soil and climate of the region to the pro-
duction of timber and to the growth of a very great number of species
of trees, is shown by the following notes of measurements made at the
forestry station. In each case, typical trees have been chosen for the
measurement, and marked. Where wide variations occur, several trees
are measured. The blocks are remarkably uniform in size of trees,
and now so cover the ground that cultivation has properly ceased.
Except in the case of the Araucaria, the trees represent close-planted

groups :

TABLE I. STATISTICS OF LARGE CONIFERS.

Name.

No. of Tree.*
Observed .

Measured
Octpber, 1897.

Increase Since
1894.

Soil.

Height.

Girth.

Height.

Girth.

Araucaria Bidwelli

1
35
460
75
10
225
400
10
100
20

Feet.
12
18
26
18
25
22
16
11
27
22

Inches.

18
16

28
17
14
8 .
36
16

Feet.

11
13
14
15
9
7
14
16

Inches.
2
10
10
10
19
10
5
5
20
8

Gravelly ; hard.

Chamsecyparis Lawsoniana
Cupressus sempervirens _-_.
Pinus Austriaca

...Red loam.
Gravelly; red.
Dark, sandy loam.
. _. .Red loam.

Pinus insignis

Pinus resinosa

Gravelly; red.
Gravelly; red.
...Red loam.

Pinus sylvestris

Pseudot -uga taxifolia.

Sequoia gigantea ..

Dark, heavy loam.
Light, sandy.

•

Sequoia sempervirens

The age of all these trees is about the same. They were planted in
1888 or 1889, but no record was kept by the persons at the station
before the forestry work was given to the State University. Cultivation

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY.

333

began in 1894, and by 1896 the trees were beginning to grow rapidly.
Some of the Pinus resinosa in July, 1899, were 30 feet high, with girth
of 21 inches. The ones measured give a fair average, and the grove
surpasses in general appearance the other pines. Pinus insignis (Mon-
terey pine) makes better single specimens.

The Italian cypress (Cupressus sempervirens) is in two closely planted
groves. The best upright or columnar specimens are from 25 to 30 feet
high, with a trunk circumference of 12 to 14 inches and a shaft circum-
ference of 9 or 10 feet. The spreading specimens are usually about 20

334

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

feet high, with larger trunks. While much less attractive than the
columnar specimens, they are equally valuable for timber.

The trees of a small block of Thuya gigantea (Port Orford cedar), not
tabulated, are about fifteen feet high, with branches that cover a circle
of 12 feet across, and, like those of the other conifers, are beginning to
interlock. All the older conifers showed in June, 1898, a spring and
early summer growth of 12 to 24 inches.

The large deciduous trees on the station are growing quite as well as
the conifers. The following table shows some of the principal groups
and several specimens of especial usefulness:

TABLE II. STATISTICS OF LARGE DECIDUOUS TREES.

Name.

No.
Observed.

Measured Oct.,
1897.

Increase Since
1894.

Notes.

Height.

Girth.

Height.

Girth.

Betula alba (European
White Birch)
Catalpa speciosa (Catal-
pa)

75
50
10
54
60
20
3
1
2

Feet.
20

30
20
28
25
28
60
50
21

Inches.
6

26
13
27
19
34
36
30
16

Feet.

14
10
15*
10
9

22

Inches.

10
3
13
8
15

12

Planted in 1895.

A few are much
larger.
Some girth 16 inches

Some are 33 feet tall.

Un gainly and
crooked.
Some are 40 ft. high.

}Very beautiful
specimens about
10 years old.

Planted in 1894.

F rax in us Americana
(American Ash). -
Juglans Ualifornica (Cal-
ifornia Walnut)

N e g u n d o Californica
(California Box Elder)
Paulownia imperialis
(Paulonia) .

Populus fastigiata ( Lom-
bard y Poplar)

Populus Fremontii (Cot-
tonwood).. ._-
Ulmuscampestris (Hunt-
ingdon var. )

The birches noted in above table were received by mail in 1894, when
a few inches high, and placed in nursery. In January, 1895, they were
set out in a group adjoining the block of Sequoia. Their growth has
been marvelous, and justifies all that previous reports have said about
the value of Betida alba as a street tree.

The Huntingdon elm has grown faster than the American and other
species tested here, and it also is a more shapely tree.

The box elder grows rapidly, but it has little value and is less
attractive than the soft maples. Where much better trees will thrive,
it is a pity to plant box elder. The catalpa, with its showy flowers, is
far more attractive. The paulownia has little economic value here,
though its soft lumber has ornamental uses in Japan.

Considering the quality of its product, the rapid growth of the ash
here is very suggestive. It thrives well on the various soils of the
station. Several species of ash are being tested, all giving promise of
usefulness.

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY. 335

TABLE III. STATISTICS OF RECENTLY PLANTED DECIDUOUS TREES.

Species.

Where an«1 When
Planted.

Size as
Planted.

Size hi
ISM.

Si /e in

1897.

Size in
June, 1898

Acer dasycarpum (Silver
Maple)

Mixed forest, Jan.,

Feet.

Feet.

Feet.

Feet.

Acer campestris (Euro-
pean Maple).. .-.
Acer platanoides (Syca-

1895
Mixed forest, Jan.,
1895

3^
4

6
5

10

7

12

g

more Maple)

Arboretum, Jan.,

1895.

3

4

7

8

Alnus glutinosa (Elder) ..

Arboretum, Jan.,
1894 ...

3

8

14

16

Betula lenta (Birch)

Hardwood forest,

Catalpa speciosa (Catalpa)
Celtis occidentalis (Nettle

Jan., 1896
Mixed forest, Jan.,
1895

1
3

Itf

6

IX
8

1%
10

tree ) - -

Mixed forest, Jan.,

Cerasus serotina (\Vild

1895

4

8

13

15

Cherry) - ... .

Arboretum, Jan.,

Cladas<ris tinctoria (Yel-

1895

VA

4

7

8

low Wood)

Arboretum, 1894

5

6*4

71A

8

Diospyrus Americana
(Am. Persimmon).

Arboretum, 1896

3

8

9V<

Fraxinus Americana
(White Ash)

Arboretum, 1894

2

4

6

7

Fraxinus dimorpha (Al-
gerian Ash)

Hardwood forest,

Fraxinus Oregana (West-

Jan., 1896...

1

2

4>£

61A

ern Ash)..

Fraxinus viridis (Green

Hardwood forest,
Jan., 1896

4

7

9

Ash) . . .

Arboretum, 1895

4

6

9

10

Juglans Californica (Cali-
fornia Walnut)
Morus alba (White Mul-

Mixed forest, Jan.,
1895

4

5

8K

9/4

berry)

Mixed forest, Jan.

Morus "Lhoo" (Jap.?

1895

4

61^

9

11

Mulberry)

Rownearash.es Jan

Neerundo Californica (Box

1897 .

4

8

10

Elder) .

Mixed forest, Jan.,

Paulownia imperialis

1895

4

6

10

12

(Paulonia) .

Mixed forest, Jan.,

Ptelea trifoliata (Wafer
Ash)

1895. ...
Arboretum, 1895

4
3

10

5

15

6V<

18
8

Pyrus Americana (Wild
Apple)

Arboretum 1895

1

4

7

11A

Quercus robur No. 1 (Eng-
lish Oak)

On avenue 1894

2

5

8

9V<

Quercus robur No. 2 (Eng-
lish Oak)

On avenue, 1894

2

9

14

15

Quercus robur No. 3 (Eng-
lish Oak)

Mixed forest, Jan.,

Tilia Americana (Bass-

1895

2

6

8

9

wood)

Arboretum, 1896

5

7

9

The number of trees of the above species planted varies from two or
three in the arboretum to a hundred or more in forest form. All receive
cultivation to keep the weeds down and the surface mellow. The catal-
pas and tilias planted in 1895 were in blossom in May, 1898. The
white mulberries planted at the same time were bearing fruit.

The English oaks (Q. peduncnlata) vary greatly in size and nature
of growth. Some are shrubby, branching near the ground, and
requiring free use of pruning knife to form a good trunk; others need
no assistance. The average height of the oaks planted in 1895 in mixed
forest is now 7 feet, well branched, and with trunks of 3 to 4 inches in
circumference. One oak planted in 1894, when 3 feet high, is now 13
feet high, with branches covering a circle 10 feet in diameter, and a
trunk circumference of 4^ inches. The spring growth of 1898 of such
a tree is from 6 to 12 inches on every branch. One tree planted in 1894

336

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

bore acorns in 1897, and several are bearing in the present season
(1898). Deciduous oaks are easily moved when not more than 4 feet
high if well trimmed, and after a year or two of small growth make
new leading roots and grow fast. The tap-roots should be cut in the
nursery the year before removal.

Many species of oaks thrive in the central Sacramento Valley dis-
trict, and here, perhaps sooner than in other parts of California, it would
seem that the planting of oaks for timber might be profitable. The
species indicated are (1) Q. pedunculata, Q. suber, Q. cerris, and other
oaks of Europe and Asia Minor; (2) some of the East American species
which have heretofore failed in many parts of California. The Japanese
oaks suffer from the sun. Our native species grow rapidly, but are of
inferior value for timber. In all, the station has tested or is testing
some forty species of oaks, and every year is obtaining others new to
the district.

Next to the oaks, the ashes promise results in the hardwood forest.
The growth of our native species under cultivation is exceedingly rapid.
The ash is worthy of wider dissemination. Several new species of ash
were only planted out in the spring of 1898, and, therefore, need more
time to develop their characteristics. Fraxinus dimorpha, of Algeria,
proves, upon further acquaintance, to be a tree of slow growth, but of
especial beauty. It is often shrubby, like some specimens of the Eng-
lish oak, and needs pruning to give it a start. Other specimens are
beautifully pyramidal in shape, and would make attractive lawn
trees. The wood seems exceedingly tough. Nine species of ash are now
growing on the station grounds.

Among other hardwood trees recently planted in considerable num-
bers are Celtis orientalis and C. Australis, also ZelJcova Jceaki. The
latter forms quite a grove, as well as being represented in the arboretum.

Like Fraxinus dimorpha, some specimens are shrubby in growth,
while others grow tall and quite rapidly.

The growth of Diospyrus Americana (persimmon) here is much better
than elsewhere in California, as far as noted. The growth of Cerasus sero-
tina is less satisfactory here than at the Southern California substation.

Betula alba, forming a small grove, is listed in the table of larger decid-
uous trees. Smaller trees of later planting show the same adaptation to
the district. The three largest birches at the station are nearly 30 feet
high, with trunk circumference of 18 inches. These are in the aboretum.

The largest Gymnocladus Canadensis in the arboretum stands 15 feet
high, with a girth of 7 inches.

Rapidity of Growth. — The following brief table compares several of
the best specimens of rapidly growing deciduous trees at the Chico
substation:

Species.

Planted.

Height
when
Planted.

Height
Oct., 1897.

Girth
Oct., 1897.

Height.
Oct.J 899.

Girth
Oct., 1899.

Acer dasycarpum (Silver
Maple)

Jan. 1896

Feet.
6

Feet.
12

Inches.
10

Feet.
16

Feet.
1J4

Paulo wnia imperialis

" 1895

6

20

13

36

3K

Platanus racemosa (Nutt)
(California Sycamore)
Salix salmoni (Asia Minor
Willow) -

" 1896
" 1896

6
4

22
32

14

22

38
49

2^

2&

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY.

THE COLLECTION OF WILLOWS.

337

A good deal of correspondence has resulted from the establishment of
the willow grove at the station. About 4,0;)0 cuttings were distributed
to various points in California in the spring of 1898, and another dis-
tribution was made in the spring of 1899. All the plants grew from
cuttings planted in 1895, and were moved to the arboretum in February,
1896. The soil is a rich, sandy loam, eminently suitable for willows!
When planted the willows were cut to a uniform height of 4 feet.
Three species and varieties, it will be noted, have not increased in
height since being planted, but have spread out, forming bushes. In
the table, the different sorts are arranged in order of present height.

STATISTICS OF WILLOW PLANTATION.
(Fifteen of the best species ; from cuttings ; 10 months in nursery ; 21 months in grove.)

Species or Variety.

Height,

Circumfer-
enceof
Trunk.

Spread of
Branches.

Notes.

Salix salmoni (or S. alba
salmonii)

Feet.
32

19
16
12
12
11
10
10
10

10
9

8

8
6

Inches.
22

16
12
9
8
10
6
9
9

7
8
7

5
5

Feet,
12

12
8
6
5
6
8
10
8

5
9
6

4
5

Grew 12 feet in nursery ;
was cut to 4 feet ; grew
15 feet in 1896.

Very strong grower;
coarse basket willow.

Resembles type form of
alba.

Little difference except
in amount of growth.

Light green bark; slen-
der leaves.

A very ornamental spe-
cies.

A very fine basket wil-
low.

Very large, glossy leaves ;
highly ornamental
species.

Purplish bark.

A showy, dark-leaved
species.

A noble English species,
with large, glossy
leaves.

Whitish and green bark ;
ornamental.

Salix viminalis (a variety
from Meehan)..

Salix alba vittelina
Salix regalis

Salix alba (type).

Salix Sieboldii

Salix dasyclades

Salix viminalis (golden). .
Salix Madenii

Salix daphnoides

Salix Japonica

Salix Britzensis

Salix pentandra.

Salix cordata _ -

22 -uc

338

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

EUCALYPTS AND ACACIAS.

The tests of Eucalypts and Acacias at Chico substation have now
been continued for several years, and supplemented by observations on
trees in General Bidwell's collection and elsewhere. The district is
evidently unsuited to a wide range of species in these two important
classes of trees.

Eucalypts (old trees).— The Third State Forestry Report (for 1889-90)
states that Eucalyptus viminalis was the most successful species tested;
E. obliqua grew but poorly; E. rostrata did not thrive as well as E.
viminalis. Many species were planted, possibly most of those tried at
Santa Monica, but no records were kept. At the present time, large
trees are on the Chico substation, of the following varieties: viminalis,
rostrata, globulus, obliqua, eugenoides.

E. viminalis grows very fast here, and forms a noble tree, perfectly
hardy, but not always able to sustain itself against the winds. Trees

PLATE 43. GROUP OP EUCALYPTUS TREES (E. viminalis).

80 feet in height and 12 inches in diameter, planted since 1888, are on
the station grounds. Trees thirty years old are on Rancho Chico.

A very curious and interesting group of E. viminalis stands on the
station grounds. The trees were evidently heeled-in, in a short trench,
when taken from a nursery, and grew there. At the present time, from
a small base 30 feet long and 3 feet wide, spring twenty-two large and
some thirty small trees. The twenty-two largest are from 50 to 75 feet
high, and from 12 to 35 inches in circumference of trunks. The thirty
small trees have merely existed for years past. The trunks touch at
the base (90 square feet), and widening in search of light and air, fill,
at the height of fifty feet, a quadrilateral of about 1,000 square feet.
This remarkable illustration of extremely compact tree growth on good
soil is shown in the accompanying reproduction from a photograph
(plate 43).

CHICO FORESTRY SUBSTATION, SACRAMENTO VALLEY. 339

The only living specimens of E. globulus stand in a much sheltered posi-
tion among large white oaks. They have several times suffered from frost,
and large branches have been killed. Under these circumstances, the
total growth of this species is considerably less than that of E. viminalis.

One of the most sturdy species on the station grounds is E. eugenoides, a
fine, strong, upright tree, as hardy as viminalis, but of less rapid growth.

In point of attractiveness, no eucalypt at either Chico or Santa
Monica surpasses E. viminalis, var. minima, a beautiful weeping tree,
which adds to an upright stem the charm of long, graceful, trailing
branches, as slender as those of the weeping willow; and has proved
entirely hardy here. This species should become a very popular shade
and ornamental eucalypt for Northern California. The small, white
flowers, abundant in March and April, fairly cover the tree.

New Tests of Eucalypts. — Since 1894, seeds have been sown and plants
raised of some thirty species obtained from the Melbourne Botanic
Gardens, from Vilmorin, Paris, and from the Santa Monica substation.
The following notes show results to date:

Eucalyptus alpina was planted in forest in the spring of 1896. The
tallest tree is now 6 feet, with spread of 2-J feet. It grows much better
than at Santa Monica. The growth of 1897 was 14 inches. The new
growth of 1898 was 6 inches, when measured in May. Hardy here.

Eucalyptus acerbula (quite rare and new to California). Planted in
1896. Tree a beautiful one, with remarkably fine, delicate leaves and
red bark. Height 2 feet in October, 1897. Spring growth of 1898,
1 foot. Hardy here.

Eucalyptus gunni. Planted in 1896. Trees of 7 feet in height badly
frozen. The growth of 1897 was 4 feet. This species will probably be
somewhat hardier when large, but is of doubtful value here.

Eucalytus llFoeld Bay." Planted in 1896. The best tree so far tested
in the forest. Largest specimen, 9 feet, with 6 feet spread of bough. In
appearance it resembles the blue gum, but the young growth is very red,
and more attractive. Hardy here.

Eucalyptus leucoxylon. Planted in 1896, when very small. Height,
October, 1897, 3 feet. Trees healthy and hardy here. A great acquisi-
tion to the district, but a grower and chiefly ornamental.

Eucalyptus resinifera, and others. E. resinifera is very tender here;
only one tree is left, and shows no tendency to sprout from the base.
Eucalyptus rudis is also very tender here, and unfit for the district.
One tree of 18 inches is still struggling to recover ground. E. tereticornis
is another species that is too tender here, though of somewhat better
growth. The following species have been frozen to the ground, and did
not again start: E. cosmophylla, E. cinerea, E. Lehmanii, E. acmenioides,
E. andreana, E. botryoides, E. decipiens, E. floribunda. Adding to this
list E. maculata var. citriodora, E. ficifolia, and E. calophylla, which
have proven too tender here, either in nursery or after being planted in
the grove, we have fifteen species that it seems necessary to discard.

Large Acacias. — The most hardy acacias planted here some years ago
are A. melanoxylon and A. pycnantha. A. decurrens, the black wattle,
in all its varieties, while semi-hardy, and eventually making a large
tree, is liable to have large branches killed back. This is particularly
noticeable with A. mollissima, the popular street tree. A. melanoxylon
has not suffered seriously in twenty years of trial in the Chico region.
Acacia cyanophylla is only semi-hardy here.

340 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

F. SANTA MONICA FORESTRY SUBSTATION.

(In Santa Monica Canon, two miles west of Santa Monica.)

The situation of the Santa Monica Forestry Substation has been
described in previous reports. It is easily accessible from Los Angeles by
frequent trains passing at the mouth of the canon, and has many visitors,
at all seasons of the year. Its progress, like that of the Chico substation,
has been slow, by reason of the small appropriation, which has pre-
vented many and much needed improvements. Mr. Roy Jones still
serves as patron. Mr. John H. Barber, who was appointed foreman in
1896, was promoted to the Paso Robles foremanship in September of
1898. His successor at Santa Monica was Mr. Charles A. Colmore,
a graduate -of the Agricultural Department, University of California.
Mr. Barber did excellent work at Santa Monica, and the following
chapter, though edited, condensed, and brought down to date, is largely
from his reports:

Water Supply. — During the past two years the inadequacy of the
water system has been increasingly felt. In the winter of 1897-8 a
small windmill was erected, with tower and pump, which saves the
waste of the hydraulic ram, and raises more water to the middle mesa,
where it is most needed.

Distribution of Seeds and Plants. — The mature trees on the station
increase in number, and furnish more seed each year, and the collection
of seeds for public distribution and for exchange has become an impor-
tant feature of the work. By means of this annual distribution, various
species of eucalypts and acacias, and other trees tested and found of
value here, have been introduced throughout the State to be more
widely tested under different conditions. In addition, the station is
enabled to obtain by exchange rare seeds from abroad for trial here.
It may be as well to repeat in this connection, that the distribution of
seeds collected at this and other substations is made as a part of the
regular annual seed distribution from the Central Station at Berkeley.

Station Herbarium. — Botanical specimens of a large number of the
trees on the station have been prepared. A set of these forms the
nucleus of an herbarium, which will be invaluable for reference in the
determination of species, especially in the case of the eucalypts. As is
well known, the nomenclature of the species of eucalypts introduced
into the State by nurserymen and others has become much confused.
Specimens of eucalypts grown in various sections are often sent to the
station for identification.

A second set of these specimens has been placed in the Herbarium of
the Botanical Department at Berkeley. Collections of eucalyptus speci-
mens have also been sent, by request, to the Arnold Arboretum of
Harvard University, and to the United States National Museum (Smith-
sonian Institution) at Washington, D. C. These will be added to as
time permits. Another collection has been made for the Missouri
Botanical Garden, St. Louis.

SANTA MONICA FORESTRY SUBSTATION.

341

Botany of the District. — Some attention has been given to the study of
the local flora, and several hundred specimens have been collected for
the Herbarium of the Botanical Department at Berkeley.

In this connection acknowledgment should be made of the kindness
of Professor A. J. McClatchie, of the University of Arizona, and of Dr.
H. E. Hasse, Surgeon of the Soldiers' Home, near Santa Monica. The
latter gentleman has placed freely at the disposal of the Forestry Sta-
tion not only his botanical library, but also his invaluable knowledge
of the flora of Southern California.

CLIMATE.

Rainfall. — The season of 1897-8 was exceedingly hard on tree growth.
The lack of late spring rains in 1897, and the exceptional dry ness of
the following winter, made up a combination of circumstances peculiarly
trying to vegetation. The rainfall at the station for 1897-8 was only
5/24 inches, and the full benefit of this was not received, because it came
in small quantities at long intervals, and was followed by strong, dryin
winds. As shown by the accompanying table, there was no rain at al
at Santa Monica during the months of November and December, 1897.
The spring rains were very scant, and cereal crops in the district were
practically a failure. Light showers at the end of April and middle of
May enabled some little hay to be made, but were not sufficient to be
of much benefit to trees. Every possible effort was made to keep the
station plantations in good growing condition by thorough cultivation
of the soil. In addition, the tops of many of the large trees were heavily
thinned to reduce their draught on the soil-moisture.

The following table shows the rainfall by months, as compared with
that of the previous season:

STATISTICS OF RAINFALL, IN INCHES.

Aug.

Sept.

Oct.

Nov.

Dec.

Jan.

Feb.

Mar.

Apr.

May

Total.

1896-7

31

00

86

196

199

605

342

1.54

.00

.00

16.13

1897-8

.00

.32

1.17

.00

.00

1.37

.32

1.10

.36

.60

5.24

District Comparisons of Rainfall. — It is interesting to note that the
annual rainfall at Los Angeles, twenty miles inland, though larger,
differs little from that at Santa Monica; but, as might be expected, pro-
ceeding farther eastward along the base of the Sierra San Gabriel toward
the loftier peaks of the San Bernardino Mountains, one finds the rainfall
to increase materially. This will be seen at once in the following state-
ment, giving the annual rainfall at Santa Monica, Los Angeles, and
Pomona for five consecutive years:

COMPARATIVE RAINFALL STATEMENT, IN INCHES.

1893-4.

1894-5.

1895-6.

1896-7.

1897-8.

Total for
Five Years.

Average per
Year.

Santa Monica

7.83

14.01

8.40

16.13

5.24

51.61

10.32

Los Angeles

6.73

16.11

8.51

16.86

7.06

55.27

11.05

Pomona

10.90

23.00

8.78

17.89

9.37

69.96

13.99

342

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

Temperature. — The spring of 1898 was also unusually trying in the
matter of temperature. Complaints of the unusual coldness of the
season were general in the neighborhood. Truck- farms on the low
lands south of Santa Monica suffered heavily. Even those in the so-
called frostless belt of the foothills did not escape unscathed. Heliotropes,
cannas, the choicer roses, and other tender garden plants, which ordi-
narily winter perfectly at Santa Monica, were this year cut down by the
frost in many cases, and the leaves of Eucalyptus robusta and E. globulus
(blue gum) were quite badly frosted in the town.

The accompanying table gives the temperature at the Forestry Station
for the fiscal year ending June 30, 1898, compiled monthly from the
continuous, automatic record of a thermograph kept on the middle
mesa of the station tract, where the main plantations are located:

MONTHLY SUMMARY OF TEMPERATURE.

Maximum.

Minimum.

Mean
Maximum.

Mean
Minimum.

Mean Tem-
perature.

1897— July

80°

51°

73°

57°

65°

August

88

52

76

58

67

September

90

51

76

57

67

October .

81

45

70

50

60

November

89

39

70

47

59

December

88

33

67

43

55

1898 — January .

82

31

60

41

51

February

78

40

65

44

55

March

78

35

65

43

54

April .-.

98

40

70

49

59

May

72

45

66

49

58

June

93

48

72

55

00

64

For the vear

98°

31°

69°

49°

60°

Effects of Frost. — It will be noticed that only once did the ther-
mometer fall below the freezing point. In fact, this middle mesa, where
the observations were made, enjoys an exceptional immunity from
frosts, due evidently to its intermediate position in the canon or bar-
ranca, midway between the higher mesa level of the surrounding plains
and the lower level of the canon bottom. Even here, however, this
year the tender young growth of the scarlet passion-flower ( Tacsonia
manicata) was touched by frost. New shoots of Phytolacca dioica also
were frosted, but no other damage was done to trees and shrubs.

On the colder creek level, where the nursery is located for convenience
to water, the young shoots and in many cases the swelling buds of
mulberry cuttings were killed. Japanese willows (Salix Japonica and
S. Sieboldii) were slightly damaged ; native and Eastern willows
remained uninjured. Foliage of the rubber tree (Ficus elastica) was
frosted. A large Jacaranda mimosssfolia lost two years' growth of wood ;
the new growth of a young umbrella tree (Melia Azedarach) was killed
back; while a fine hedge of Pittosporum undulatum looked for a time as
though flames had swept over it.

Comparison of Temperatures. — As with the rainfall, so in the matter
of temperature a comparison has been drawn between Santa Monica,

SANTA MONICA FORESTRY SUBSTATION.

343

Los Angeles, and Pomona, as shown in the following condensed table
giving the main- points of the temperature record at each:

Santa Monica.

Los Angeles.

Pomona.

Maximum temperature for year ...

98°

99°

104°

Minimum temperature for year

31

30

26

Mean maximum temperature for year
Mean minimum temperature for year . __
Mean temperature for year

69
49
60

73
51
62

77
46
62

THE YOUNG EUCALYPTUS GROVE.

This plantation, set out in the spring of 1897, on the upper mesa, as
noted in the last annual report (page 418), has thriven better than
might have been expected, considering the character of the past season.
A few trees have died from drought, but on the other hand the growth
of the majority has been gratifying, and some species have done exceed-
ingly well under difficulties.

Eucalyptus globulus, the well-known " blue gum/' used in this planta-
tion for shelter purposes, maintains its reputation for rapid growth.
It may be taken as a standard in estimating roughly the relative
rapidity of growth of other species, though we must always bear in
mind that different species are naturally adapted to different conditions,
and each species will, of course, grow best under the conditions best
suited to it.

E. goniocalyx, a tall-growing species, made a growth even surpassing
that of the " blue gum," the best specimen being of the same height, 14
feet, when two years old from seed, while the general average is higher.
This species was especially recommended for new plantations by the
late Baron F. von Mueller. The inferior growth of the single specimen
in the older grove on the middle mesa has not borne out this recom-
mendation, but these young trees so far appear to justify it.

E. rostrata and E. tereticornis, closely allied species, and E. Stuartiana
follow closely with a growth of 12 feet each for the best individual tree,
when two years old from seed, and an average of 7 to 8 feet; while E.
acmenioides, E. Andreana, E. angulosa, E. cinerea, E* Foeld-Bay, E.
Muelleriana, and E. urnigera, all new introductions, are not far behind.

• Growth at Different Ages Compared. — As some of the species in the new
plantation are also represented in the old grove on the middle mesa,
some instructive comparisons can be drawn. At seven years from
planting E. rostrata measured 45 feet in height and 10 inches in
diameter of trunk, E. tereticornis 55 feet in height and 9 inches in
diameter, while the height of E. Stuartiana at the same age was only
28 feet, though its trunk diameter was 9 inches, equal to that of the
much taller E. tereticornis. These marked differences emphasize a point
which must be kept in mind when considering the relative growth of
young eucalyptus trees, that the rate of growth often varies with the age
of the trees, so that trees of different species which make an equal
growth during the first year or two, may, nevertheless, differ widely in
size some years later.

344 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

New Eucalypts. — The new eucalypts include the following species:

E. acervula E. cornuta E. jugalis E. paniculata

E. acmenioides E. cornuta E. maculata E. polyanthema

E. Andreana var. Lehmannii E. maculata E. Kisdonii

E. angulosa E. cosmophylla var. citriodora E. resinifera

E. botryoides E. decipiens E. megacarpa E. rostrata

E. calophylla E. dumosa E. microcorys E. Stuartiana

E. cinerea E. Foeld-Bay E. Muelleriana E. tereticornis

E. coccifera E. goniocalyx E. obcordata E. urnigera

Of many of the above-named species little is known, except from
meager foreign repots; but the information at hand, viewed in conjunc-
tion with their growth so far, indicates that some of them will be of
notable value for this State. E. coccifera and E. urnigera are reported as
especially hardy. The latter is also rated by Baron von Mueller as the
most antiseptic of all the eucalypts, and therefore of especial value for
planting in malarial districts. The wood of E. botryoides, E. microcorys,
E. Muelleriana, and E. paniculata is said to be very durable underground,
and thus excellently adapted for fence posts, railroad ties, etc.

Experiments on a Large Scale Needed. — Tests on a small scale are apt
to be misleading, on account of the difficulty of eliminating merely
accidental factors. Therefore, it is probable that the average rate of
growth of individual species, as well as the relative rate of growth of
different species, under certain conditions in California, could only be
determined with exactness by the continued observation for a series of
years of several hundred trees of each of the species under trial, planted
in solid blocks. Experiments on this scale, however desirable, the
station has not at present the means of undertaking. A large area of
more uniform soil would be necessary for such experiments.

RECENT ADDITIONS TO THE ARBORETUM.

New species of trees and shrubs are continually being added to the per-
manent collections on the station. Many of these are raised from seed or
cuttings in the station nursery; others are obtained from outside sources.

Pseudotsuga taxifolia, the Douglas spruce, proved a failure on the
middle mesa. It needs more moisture, and will be tried again on the
creek level.

OTHER TREES AND SHRUBS.

Acacia Koa is a beautiful and rare species from the Sandwich Islands.

Casuarina glauca, from Australia, there called the Desert Sheoak,
grows rapidly and endures considerable drought. All the casuarinas
are valuable trees for dry localities and barren places. They grow
rapidly and furnish excellent firewood. Young trees of C. glauca
grown from seed on the station in 1896 and planted out in the spring of
1897, when about one foot in height, grew in one year to a height
of 5 to 7 feet, and in 1899 were 12 feet high.

Cytisus scoparius and Genista juncea, natives of Europe, are showy,
free-blooming shrubs, well suited to dry situations. The former furnishes
a yellow dye, can be used for tanning, and has been highly recom-
mended for arresting the drifting of loose sands.

Ligustrum Japonicum, the Japanese privet, is a useful hedge plant.

Myoporum laetum, from New Zealand, is an excellent shade tree. It
makes a fairly rapid growth, bears exposure well and withstands
drought. It grows well on this station and also at Berkeley.

SANTA MONICA FORESTRY SUBSTATION. 345

Schinus terebinthifolius, a new " pepper tree " introduced from Brazil,
shows great promise. A near relative of the common pepper tree, Schi-
nus molle, it is rated a much more desirable tree. In habit it is more
upright and symmetrical than Schinus molle, and its foliage is heavier,
with shorter, broader, thicker leaflets of a rich dark green color, glossy
and shining. A number of seedling trees were planted at the station in
1897 on a well-drained gravelly slope. At time of planting they were
about one 'foot high. No rain fell after they were set out, but they
received a bucket of water each several times during the summer. A
year from planting, the best ones measured 6 feet in height, while the
average was about 4 feet of stout growth. At first the young trees
branched freely, from the ground up, and they expended considerable
energy in this way before the tendency was finally checked by pruning
and pinching back the shoots. These trees bore some seeds in 1899, and
will soon yield sufficient for distribution.

Cedrela odorata, a native of Central America and the West Indies,
furnishes a valuable wood much used for cigar-boxes.

Cercidiphyllum Japonicum is an important timber tree of Japan, and
ranks high also as an ornamental.

Eriodendron anfractuosum, the Kappa, or Silk Cotton tree of the West
Indies, has failed to grow here. It seems to require a moister climate.

Phytolacca dioica, or Pircunia dioica, the Ombu of the South American
pampas, is a quick-growing shade tree with heavy, deep green foliage,
suitable for sidewalks and roadsides. The new shoots are liable to be
killed b}^ spring frosts, but the tree seems fairly hardy, and is worthy of
extended trial. At this station in two years from the seed it has attained
7 feet in height, with a girth of 11 inches at one foot from the ground.

EFFECT OF DROUGHT ON TREES.

The shortness of the rainfall of 1897-8 and 1898-9 necessitated extra
precautions against the loss of rare trees by drought. Besides keeping
down weeds and conserving the moisture in the soil to the utmost extent
by frequent and thorough stirrings of. the surface with the cultivator,
it was deemed advisable also to take measures, as far as means per-
mitted, to lessen the demand of the larger trees on the soil-moisture.
To this end, all limbs which could reasonably be spared were removed
from many of the large eucalypts, thus reducing the area of their
foliage and consequently decreasing materially the amount of water
transpired by them. The effect of this thinning of the crowns of the
trees has so far been satisfactory.

Drought Resistance of Eucalypts. — In the main eucalyptus grove
during 1898 no trees succumbed to drought, though several showed
signs of distress. On the whole, the results here were conclusive,
except as regards the inferior drought-resistance of E. obliqua, which is
confirmed by other observations.

The smaller grove at the north end of the middle mesa, on the west
side of the main road, contains trees of Eucalyptus calophylla, E. cornuta,
E. corynocalyx, E. globulus, E. leucoxylon (smooth-bark form), E. rostrnta,
and E. viminalis. Of these a single E. globulus, a spindling tree, died
from drought; the balance of the grove is in perfect health.

East of the road, on the sloping ground at the base of the steep bluff
rising to the upper mesa, the grove consists of E. cornuta, E. coryno-
calyx, E. globulus, E. leucoxylon, E. obliqua, E. paniculata, E. rostrata,

346

UNIVERSITY OP CALIFORNIA — EXPERIMENT STATION.

and E. viminalis. Here, of E. obliqua four out of twelve trees died from
drought, a loss of 33 per cent. Of E. viminalis, ten out of twenty-three
perished, a loss of about 43 per cent. E. viminalis suffered, also, on the
heavier soil of the upper mesa. Its losses here amount to about 25 pel-
cent. No other large trees failed on this level. Evidently, judging
from observations during several seasons on different soils and levels,
this species is deficient in drought-resisting qualities. This is to be
regretted, as its rapidity of growth and moderate toleration of alkali
make it otherwise a desirable tree for windbreaks and firewood on the
alkaline plains. Trees of E. polyanthema on the upper mesa, planted
along the edge of the steep bluff, stopped growing, but held out well
and pulled through.

Miscellaneous Trees. — Of the acacias, several small specimens of Acacia
melanoxylon died, but the older trees stood the drought well. The same
was true of A. decurrens and A. mollisima. A. pycnantha showed more
resistance to drought than the other two principal tan-bark wattles; no
trees of this species died, and only one or two showed signs of distress.
A few camphors (Cinnamomum camphora) have succumbed on the mid-
dle mesa. All other trees withstood the drought of 1897-8 excellently.

EUCALYPTS IN CULTIVATION IN 1899.

The following list shows the species of eucalypts represented by trees
in the station plantations July 1, 1899. It does not include plants
still in the nursery:

EUCALYPTS IN CULTIVATION AT SANTA MONICA, IN 1899.

E. megacarpa E. Risdonii

E. melliodora E. robusta

E. microcorys E. rostrata

E. Muelleriana E. rudis

E. obliqua E. .saligna

E. occidentalis E. siderophloia

E. occidentalis E. sideroxylon

var. macrandra var. pallens

E. paniculata E. sideroxylon
E. Planchoniana var. rosea

E. platypus E. Stuartiana

E. pipenta E. tereticornis

E. polyanthema E. tereticornis
E. pulverulenta var. latifolia

var. cinerea E. tetraptera

E. punctata E. urnigera

E. resinifera E. viminalis

.DESCRIPTIVE NOTES ON A FEW SPECIES.

Eucalyptus corynocalyx, the sugar gum, is well enough known to
render detailed description of the tree unnecessary here. It grows
rapidly, and when given plenty of room usually branches freely and
forms an immense, spreading, leafy crown. It blooms profusely in
summer, and is very attractive to bees. Its habit of seeding freely often
causes the heavy masses of seed-pods to overweight the branches so that
they break easily in a high wind. It may be reckoned, nevertheless, a
useful tree for roadside planting, and, also, singly or in groups, for
diversifying the landscape on treeless plains. It affords plenty of shade,
and its spreading habit and dark, glossy foliage render it a conspicuous
and pleasing object in the landscape. The wood is useful and said to
be very durable in the ground.

E. acmenioides
E. alpina
E. amygdalina
E. amygdalina
var. angustifolia
E. amygdalina
var. regnans
E. botryoides
E. buprestium
E. calophylla
E. coccifera
E. coriacea
E. cornuta
E. corymbosa
E. corynocalyx
E. cosmophylla
E. crebra
E. decipiens

E. diversicolor
E. dumosa
E. eugenioides
E. ficifolia
E. globulus
E. gomphocephala
E. goniocalyx
E. Gunnii
E. Gunnii
var. undulata
E. hsemastoma
E. Lehmanni
E. leptophleba
E. leucoxylon
E. macrorrhyncha
E. maculata
E. maculata
var. citriodora

SANTA MONICA FORESTRY SUBSTATION.

347

Eucalyptus cornuta, the
"Yate" of Southwest Aus-
tralia, is another eucalypt
of spreading habit. The
foliage is somewhat thin,
however, and does not af-
ford a heavy shade. The
leaves are small, narrow,
dull green in color, but
shining with a metallic lus-
tre in sunlight. The flower
buds resemble close clusters
of small horns, whence the
specific name cornuta
( horned ) . These horn-like
calyxes fall away, leaving
the blossoms in globular,
pompon-like heads of yel-
low filaments. Later the
filaments also fall, and the
fruit develops in close, spiny
clusters. The wood of E.
cornuta is hard, tough, and
elastic, and is highly es-
teemed in Australia, being
there considered equal to
ash. (Plate 44.)

I

PLATE 45. BRANCH OF EUCALYPTUS CALOPHYLLA.

PLATE 44. BRANCH OF E. CORNUTA VAR. LEHMANNI.

Eucalyptus calophylla is
one of the handsomest spe-
cies of the genus. It makes a
straight, symmetrical, stur-
dy, leafy tree,with cinnamon-
colored bark, and oval, point-
ed, bright green leaves. The
large, creamy white flowers
are borne in heavy clusters
during August, September,
and October. The fruits are
large and remarkable. They
are rudely goblet-shaped,
some two inches or more in
length and an inch in diame-
ter. These pods or capsules
make excellent pipe bowls,
and can be utilized also for
umbrella handles and the
like. The tree endures some
frost, makes a fairly rapid
growth, and may be ranked
as a fine ornamental and a
useful shade tree. Its wood
is hard, close-grained, and
finely veined. The illustra-
tion (plate 45) shows a
cluster of leaves, flowers, and

348

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

PLATE 47. BRANCH OF EUCALYPTUS OBCORDATA

They are followed by
heavy and pendent
clusters of large pods,
almost as large as those
of E. calophylla, which
are well shown in the
illustration. The bark
is cinnamon -colored
and persistent. E. fid-
folia is of much slower
growth than many of
the eucalypts, and nev-
er attains a large size,
the maximum height
being about fifty feet,
but as a showy orna-
mental of striking
beauty and a hand-
some avenue tree is not
surpassed.

Eucalyptus obcordata
is a curious small tree of
some ornamental value.
Its dull, red flowers are
borne more or less the
whole year round. The
leaves are small, thick,
and of a dull green

fruits, as photographed
at the station.

Euca lyptus ficifolia,
the scarlet-flowered euca-
lyptus, is closely related
to E. calophylla, but is
even a handsomer tree in
habit and foliage, not to
mention its magnificent
blossoms. It makes a
symmetrical, pyramidal
tree, as shown in plate 46.
The leaves are large, oval,
and pointed, thick in tex-
ture and dark green in
color, paler beneath. The
flowers, as in E. calophyl-
la, are borne in heavy
trusses on the ends of the
branches, in August and
September. They are
brilliant red in color,
varying on different trees
from scarlet to crimson,
always very showy.

PLATE 47. BRANCH OF EUCALYPTUS OBCORDATA.

SANTA MONICA FORESTRY SUBSTATION.

349

color. The broad, flattened, recurved flower stalks are well shown in
the illustration (plate 47).

Eucalyptus maculata var. citriodora, the lemon-scented gum, is a rather
slender, straight-stemmed tree, with long, slender, drooping branchlets,
and long, narrow, sickle-shaped, bright green leaves. It is a summer-
bloomer, bearing its cream-colored flowers in good quantity, principally
in June and July. The bark is very striking— smooth and beautifully
colored in pale gray and lavender tints, and the leaves are exquisitely
lemon-scented. The habit of the tree is graceful. Here it shows a
marked tendency to branch out on the windward side, toward the sea
breeze, like the apricot. It will stand some frost, being hardy at Oak-
land, Cal. It furnishes a useful timber, and deserves a place in any
collection of ornamental trees.

PLATE 48. EUCALYPTUS ROSTRATA, OR "RED GUM."
A very hardy and valuable timber tree.

Eucalyptus rostrata, the red gum, has been very generally confused
in this State with E. viminalis, a much inferior tree. E. rostrata is a
fast-growing tree of erect habit, with persistent, smooth, gray bark, and
drooping foliage of a grayish-green color. The blossoms are creamy
white, small and in small clusters, produced freely in early summer.
The tree endures extreme heat, resists frost better than many eucalypts,
and stands considerable drought without suffering. Its timber is hard,
strong, and durable. It has been alleged that the blossoms of this

350 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

species are fatal to bees. Such is certainly not the case at this station.
Here the bees seek them eagerly, but repeated careful observations have
failed to discover a single dead bee in the neighborhood of the trees.
Few trees can be better recommended for general planting than this the
true " red gum." It is one of the species that should be much more
freely grown in California. The illustration (plate 48) shows the small
seed-pods and drooping stems so characteristic of E. rostrata.

Eucalyptus corymbosa is a handsome, symmetrical tree of pyramidal
habit. Its leaves are narrowly oval, slightly sickle-shaped, a rich dark-
green in color, paler beneath, with a conspicuous white midrib. The
new leaves are light- yellowish green, with dark-green veining, very
attractive. The creamy-white flowers are borne profusely in large, showy,
rather loose clusters on the ends of the branches, giving the tree a most
ornate appearance when in bloom. The bark is reddish brown, smooth
and finely fissured, persistent. As an ornamental tree E. corymbosa ranks
with the best of the eucalypts. Its blossoming season has extended here
from August through into December, affording good bee forage. Its
timber is said to be very hard and very durable for underground pur-
poses, but inferior for use in the arts on account of the amount of kino
or gum it contains, whence the popular name of "Blood wood." It
should, however, make good fuel.

ACACIAS AND OTHER TREES.

Acacia cyanophylla, blue-leaved acacia, is a low-growing, spread-
ing tree, branching near the ground, its radiating branches and long,
drooping branchlets forming a perfect leafy canopy. Its leaves, or
more properly phyllodes, are long and narrow and of a bluish cast. The
globular flower-heads, borne profusely along the branchlets and twigs, are
larger than those of many acacias, and are of a rich orange color. When
in bloom, in spring, the tree is very showy. It is admirably adapted for
parks and lawns, where it can have room to display its beauties. It is
also a useful tree for the home yard.

Acacia melanoxylon, the blackwood acacia, is a neat, straight-stemmed,
symmetrical tree, of regular, pyramidal outline. Foliage very dense,
dull green. Flowers pale yellow, in the usual small globular heads. A
desirable tree for sidewalk and roadside planting where compact growth
and formal effect are desired. The timber is highly valued for many
purposes. It is hard, finely grained, and takes a good polish. Even in
the young state it makes excellent firewood, about equal to live oak.

Casuarina stricta. An erect, branching tree, with the typical slim,
jointed, horsetail-ash-like branchlets in lieu of foliage. In this species
the branchlets are short and rigid, resembling pine needles, and are
arranged in tufts. The bark is smooth, dark brown. This is a unique
tree for avenue planting, and for producing certain ornamental effects in
grouping.

Angophora lanceolata. The Angophoras belong to the same order as
the eucalypts and are very similar trees, differing only in minor botanical
characteristics. A. lanceolata yields a strong, heavy timber. It has dark
green, sickle-shaped leaves, and large white flowers produced in heavy
trusses on the ends of the branches in summer, when the top of the
tree is one immense cluster of blossoms. The bark is smooth, bronze-
colored, and deciduous.

SANTA MONICA FORESTRY SUBSTATION. 351

Fraxinus velutina, the common ash-tree of the arid Southwest, has
proved here a valuable tree for dry localities in California. It grows
rapidly, and in a few years makes a beautiful umbrageous tree, on dry
soil without irrigation. It leafs out early in the spring, and holds its
foliage until quite late in the autumn. It can be recommended as a
valuable deciduous shade tree for hot and dry localities, but while doing
well on dry soils, it will amply repay irrigation. Seedlings of this species
obtained by Mr. R. E. Houghton from this station in 1893, when only
a few inches tall, and planted by him on his Kern County ranch, in 1896
measured 20 feet in height and 12 feet in spread of branches. These
received some irrigation. Seedlings of the same age planted on the
station, and not irrigated, attained in the same time 14 to 15 feet in
height and 10 to 14 feet spread of limbs. The best of the latter now
measures about 17 feet in height and the same in spread.

Quercus robur, var. pedunculata, the pedunculated English oak, with
typical foliage and fruit. This tree furnishes most of the oak timber
used in Great Britain; from it were built the *' wooden walls'7 which
antedated the modern ironclad, and it still plays an important part in
shipbuilding as well as in other industries. Though naturally at home
on heavy, moist soils, this oak has grown well here on light, gravelly
soil without irrigation, and seems well adapted to our drier climate. Its
rapidity of growth as compared with our native oaks is remarkable,
and it is undoubtedly a tree which should be largely planted, where the
object sought is a supply of most excellent timber in a comparatively
short period of time.

The Bamboos. — The Japanese bamboos have held their own in the
main, in spite of the dry season, demonstrating their ability to succeed
without irrigation even on light soils, in ordinary years. For orna-
mental purposes, where a close screen, a dense thicket, or highly effective
clumps of a light color are required, nothing could be better than the
golden bamboo (Phyllostachys aurea). The canes of this handsome
bamboo also have some economic value. Though small and slender
(10 to 15 feet in height, and three quarters of an inch in diameter at
the base), they are tough, strong, and elastic; would make excellent
trout poles, and could be used in the manufacture of light articles of
furniture. The light, graceful foliage is very effective in floral decora-
tions. Phyllostachys aurea has grown well here, increasing rapidly,
without any care whatever.

352 UNIVERSITY OK CALIFORNIA — EXPERIMENT STATION.

DONATIONS MADE TO THE EXPERIMENT STATION
SINCE JULY, 1897.

Since the last repprt was issued, gifts of seeds, plants, and scions have
been received from the following persons, firms, and institutions:
The U. S. Department of Agriculture, Washington, D. C.
The Royal Gardens, Kew, England.
The Royal Botanic Gardens, Calcutta, India.
The Agri-Horticultural Society, Madras, India.
The Saharanpur Botanic Gardens, Saharanpur, India.
The Botanic Garden, Georgetown, British Guiana.
The Forestry Department, Cape Town, South Africa.
The Botanic Gardens, Rio Janeiro, Brazil.
The Botanic Gardens, Buenos Ayres, Argentine Republic.
The Botanic Gardens, Sydney, New South Wales.
The Botanic Department, Brisbane, Queensland.
The National Herbarium, Melbourne, Victoria.
The Botanical Department, University of California.
The Minister of Agriculture, Mexico.

T. W. Adams, Esq., Greendale, Canterbury, New Zealand.
Vilmorin & Co., Paris.
Barr & Son, Convent Garden, London.
William Thompson, Ipswich.
Golden Gate Park, San Francisco, California.
Luther Burbank, Santa Rosa, California.
N. S. Berg, Dos Palos, Fresno County, California.
Dr. Franceschi, Santa Barbara, California.
Mrs. Theodosia B. Shepherd, Ventura, California.
George Roeding, Fresno, California.
John Rock, Niles, California.
Joseph C. Shinn, Niles, California.
W. A. Burppe, Philadelphia, Penn.
Morse Seed Co., Gilroy, California.
Dr. Lorenzo Yates, Santa Barbara, California.
Carl Purdy, Ukiah, California.
Abbot Kinney, Lamanda Park, California.
Los Angeles Park Commissioners, Los Angeles, California.
Superintendent of Riverside Park, Riverside, California.
Mr. C. Tharsing, Reform School, lone, California.
T. V. Munson, Denison, Texas.

EXCHANGES RECEIVED AT STATION READING-ROOM. 353

EXCHANGES RECEIVED AT STATION
READING-ROOM.

CALIFORNIA.

Berkeley Daily Gazette, Berkeley, Alameda County.
Amador Ledger, Jackson, Amador County.
Amador Dispatch, Jackson, Amador County.
Oroville Register, Oroville, Butte County.
Chico Enterprise, Chico, Butte County.
Colusa Sun, Colusa, Cplusa County.
Pinole Weekly Times,' Pinole, Contra Costa County.
Fresno Weekly Republican, Fresno, Fresno County.
Willows Journal, Willows, Glenn County.
Inyo Register, Bishop, Inyo County.
Inyo Independent, Independence, Inyo County.
Lake County Bee, Lakeport, Lake County.
California Cultivator, Los Angeles, Los Angeles County.
Pacific Fruit World, Los Angeles, Los Angeles County.
Rural Californian, Los Angeles, Los Angeles County.
L'Union Nouvelle, Los Angeles, Los Angeles County.
The News, San Pedro, Los Angeles County.
Pomona Weekly Times, Pomona, Los Angeles County.
Pomona Progress, Pomona, Los Angeles County.
Pasadena Weekly Star, Pasadena, Los Angeles County.
Madera Mercury, Madera, Madera County.
Marin Journal, San Rafael, Marin County.
Dispatch-Democrat, Ukiah, Mendocino County.
Mendocino Beacon, Mendocino, Mendocino County.
Merced Express, Merced, Merced County.
Salinas Index, Salinas, Monterey County.
Gonzales Tribune, Gonzales, Monterey County.
St. Helena Star, St. Helena, Napa County.
Napa Register, Napa, Napa County.
Weekly Index-Telegraph, Grass Valley, Nevada County.
Press and Horticulturist, Riverside, Riverside County.
Citrograph, Redlands, San Bernardino County.
Chino Valley Champion, Chino, San Bernardino County.
Weekly Times-Index, San Bernardino, San Bernardino County.
Ontario Record, Ontario, San Bernardino County.
Colton Chronicle, Colton, San Bernardino County.
Colton News, Colton, San Bernardino County.
Escondido Times, Escondido, San Diego County.
Weekly Post, San Francisco.
Weekly Chronicle, San Francisco.
Weekly Call, San Francisco.
Weekly Examiner, San Francisco.
23— uc •

354 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

California Demokrat (German), San Francisco.

California Fruit-Grower, San Francisco.

United States Weather Report, San Francisco.

Wood and Iron, San Francisco.

Pacific Rural Press, San Francisco.

Deutsche Vereins-Zeitung (German), San Francisco.

Western Creamery, San Francisco.

San Miguel Messenger, San Miguel, San Luis Obispo County.

San Luis Obispo Breeze, San Luis Obispo, San Luis Obispo County.

Paso Robles Record, Paso Robles, San Luis Obispo County.

Times-Gazette, Redwood City, San Mateo County.

Weekly Press, Santa Barbara, Santa Barbara County.

Gilroy Gazette, Gilroy, Santa Clara County.

Pacific Tree and Vine, San Jose, Santa Clara County.

Pajaronian, Watsonville, Santa Cruz County.

Dixon Tribune, Dixon, Solano County.

Vacaville Reporter, Vacaville, Solano County.

Santa Rosa Republican, Santa Rosa, Sonoma County.

Healdsburg Tribune, Healdsburg, Sonoma County.

Oakdale Graphic, Oakdale, Stanislaus County.

Yreka Journal, Yreka, Siskiyou County.

Sutter County Farmer, Yuba City, Sutter County.

Corning Observer, Corning, Tehama County.

The New Era, Corning, Tehama County.

Weekly Tulare Register, Tulare, Tulare County.

Tulare County Times, Visalia, Tulare County.

Porterville Enterprise, Porterville, Tulare County.

Visalia Delta, Visalia, Tulare County.

Santa Paula Chronicle, Santa Paula, Ventura County.

Ventura Free Press, Ventura, Ventura County.

OTHER STATES.

Florida Times-Union and Citizen, Jacksonville, Florida.

Monthly Bulletin, Tallahassee, Florida.

American Farm and Vegetable Journal, Chicago, Illinois.

The Chicago Daily Drover, Chicago, Illinois.

Dairy and Creamery, Chicago, Illinois.

Elgin Dairy Report, Elgin, Illinois.

Farmers' Magazine, Springfield, Illinois.

Farm, Field, and Fireside, Chicago, Illinois.

Farm and Home, Chicago, Illinois.

Farmers' Voice, Chicago, Illinois.

Farm and Fireside, Chicago, Illinois.

Garden and Farm, Chicago, Illinois.

Hospodarske Listy (Russian), Chicago, Illinois.

National Farmer and Stockgrower, Chicago, Illinois.

Orange Judd Farmer, Chicago, Illinois.

Prairie Farmer, Chicago, Illinois.

Sugar Beet Gazette, Chicago, Illinois.

Agricultural Epitomist, Indianapolis, Indiana.

Farmers' Guide, Huntington, Indiana.

Indiana Farmer, Indianapolis, Indiana.

EXCHANGES RECEIVED AT STATION READING-ROOM. 355

The Jersey Bulletin, Indianapolis, Indiana.

Dubuque Trade Journal, Dubuque, Iowa.

Farmers' Tribune, Des Moines, Iowa.

Homestead, Des Moines, Iowa.

Wallace's Farmer, Des Moines, Iowa.

Topeka Daily Capital, Topeka, Kansas.

The Southwestern Farmer, Kansas.

Louisiana Planter, .New Orleans, Louisiana.

Turf, Farm, and Home, Waterville, Maine.

Baltimore Weekly Sun, Baltimore, Maryland.

The Ruralist, Gluckheim, Maryland.

Southern Farm Magazine, Baltimore, Maryland.

Farm Poultry, Boston, Massachusetts.

American Cultivator, Boston, Massachusetts.

New England Farmer, Boston, Massachusetts.

North American Horticulturist, Monroe, Michigan.

The Michigan Sugar Beet, Bay City, Michigan.

Market Garden, Minneapolis, Minnesota.

The Golden Egg, St. Louis, Missouri.

Western Fruit Grower, St. Louis, Missouri.

Edwards' Fruit Grower and Farmer, Missoula, Montana.

Weekly Union, Manchester, New Hampshire.

Mirror and Farmer, Manchester, New Hampshire.

New Mexico Review, Santa Fe, New Mexico.

Vick's Magazine, Rochester, New York.

American Agriculturist, New York City, New York.

Bonfort's Vine and Spirit Circular, New York City, New York.

The Strawberry Specialist, Kittrell. North Carolina.

American Grange Bulletin, Cincinnati, Ohio.

Gleanings in Bee Culture, Melina, Ohio.

Woman's Home Companion, Springfield, Ohio.

Northwest Pacific Farmer, Portland, Oregon.

Oregon Agriculturist, Portland, Oregon.

Germantown Telegraph, Germantown, Pennsylvania.

Public Ledger, Philadelphia, Pennsylvania.

Practical Farmer, Philadelphia, Pennsylvania.

Sugar Beet, Philadelphia, Pennsylvania.

Successful Farmer, Sioux Falls, South Dakota.

Texas Farm and Ranch, Dallas, Texas.

Texas Stockman and Farmer, San Antonio, Texas.

The Southern Planter, Richmond, Virginia.

Holstein-Friesian Register, Brattleboro, Vermont.

Northwest Horticulturist, Tacoma and Seattle, Washington.

West Virginia Farm Review, Charleston, West Virginia.

Mind and Body, Milwaukee, Wisconsin.

Hoard's Dairyman, Fort Atkinson, Wisconsin.

Farmers' Magazine, Madison, Wisconsin.

The Farm Magazine, Milwaukee, Wisconsin.

356 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

FOREIGN.

The Agricultural Journal and Mining Record, Maritzburg, South
Africa.

The Agricultural Journal, Natal, South Africa.

Bulletin de la Direction de 1'Agriculture et du Commerce, Tunis,
Algiers.

Bulletin Agricole de L'Algerie et de la Tunisie, Mustapha, Algiers.

The Agricultural Gazette of New South Wales, Adelaide, Australia.

The Hawkesbury Agricultural College Magazine, Richmond, N. S. W.,
Australia.

Queensland Agricultural Journal, Australia.

Journal of Agriculture and Industry, Adelaide, South Australia.

Tiroler Landwirtschaftliche Blatter, S. Michele, Austria.

Field and Garden, Australia.

The World, Vancouver, B. C., Canada.

The Cooperative Farmer, Sussex, N. B.

The Canadian Horticulturist, Grimsby, Ontario.

Mark Lane Express, London, England.

Bulletin de la Societe Nationale d'Acclimatation de France, Paris,
France.

Bulletin du Ministere de 1'Agriculture, Paris, France.

Revue des Cultures Coloniales, Paris, France.

Deutsche Landwirtschaftliche Presse, Berlin, Germany.

Agriculturist, Japan.

The Popular Agriculturist, Tokyo, Japan.

Bolletin Mensual del Observatorio Meteorologico Central de Mexico.

The Agricultural Gazette, Hobart's, Tasmania.

Planting Opinion, Madras, India.

INDEX.

PAGE.

Abel, U. G., Escondido, reports from.. 240

Acacias, at Chico Forestry substation . 339

at Foothill substation _.. 266

at Santa Monica substation 344, 350

moisture in soil of -.'. 74,94

Adams, Ira W., Calistoga, reports from

_ 237,249, 250

Adams, J. W., Calistoga 98

Agricultural colleges, preparatory
teachingin 21

Alameda County 41, 63, 83, 85, 89, 90

apples from 143

fruit from 157

moisture in soils of ..66, 69, 71, 75, 83, 85, 90
sugar beets from 140

Alfalfa, at Foothill substation 267

on alkali 115,117

use of, with vine-hopper 180

Alkali and alkali soils 99

effect of , on citrus trees. ._ 99

from leaky ditches Ill

in Sisquoc Valley 33

in unirrigated soils 107

Alkali land, culture tests on 128

reclamation, Tulare 292,301

small cultures on 326

Alkali soils, analysis of, from —

Bakersfield; D. E. Josephi 117

Chino; J. W. Mills —

Clearwater; C. P. Eldridge 115

Colusa; F. J. Snow 113

Corona; R. H. Loughridge 107, 111

Escondido; H. W. Coute 117

King City; William Winterhalter... 115

Mendota; S. P. R. R .... 116

San Jacinto; J. A. Cook _. 117

Traver; J. P. McCarthy 115

Traver; Mrs. Dora Brown 117

Tulare; J. Ferrer... ._ 114

Tulare Lake Bed ; W. E. Dennison.. 116

Alkali soil, moisture in _ 67

near Traver 115

Tulare Lake 116

Alkali water, Tulare substation _ 114

use of , in irrigation 126, 130

Allen, H. B., foreman of substation... 329

Allen, M. C., Pomona 97

Almonds, analysis of 135

ash ingredients of _ 148

at Foothill substation... 268

at San Joaquin Valley substation 296

at Southern California substation 314

at Southern Coast Range substation. 286

moisture in soils of 77, 78, 94

on hardpan 291

Amador County ..84, 86, 88

apples from 143

moisture in soils of 67, 75, 83, 86, 88

Ames, Mrs. Mary P., Auburn 254

Anlauf, H., Santa Paula 120

Antiseptics, comparison and tests of . 170, 172

PAGE.

Apples, ash ingredients of 148

at Foothill substation 268

at San Joaquin Valley substation ... 296
at Southern California substation ... 310
at Southern Coast Range substation. 283
dwarf and ornamental at Southern

California substation 311

irrigation of 309

moisture in soils of 80, 94

of California, analyses of 143

on hardpan ._ 291

Apricots, ash ingredients of 148

at Foothill substation 269

at San Joaquin Valley substation ... 296
at Southern Coast Range substation. 286

moisture in soils of 81, 82, 94

on hardpan _ 291

sugar of 145

Arboretum of Chico substation 331

of Foothill substation 266

Arid region, endurance of drought in

lands of _ 40

Arroyo Grande Valley, moisture in

soils of 80, 81

Analyses of —

alkali soils 107-113

apples _ 143-148

canned fruits and products .158-164

cattle foods 132

desiccated vegetables 154-156

fruits 135, 145-148

grasses 132

purifine 170

salad oils 165

soils 31-38

sugar beets 137-142

tobacco 149-154

waters _ 118-126

wattle bark 228

Artichokes, Jerusalem, reports on 245

Ash, at Chico forestry substation ..334, 336
at Santa Monica substation, descrip-
tion of 351

ingredients in California fruit 146, 148

Ashley, E, H., Rivera, report from .... 239
Asparagus, canned, souring of fruit ... 159

Atkinson, Mrs., Berkeley _ 254

Ayers, Wm., Eureka 98

B

Bachus, P. F., reports from 239

Bacteria, multiplication of, in water... 174
Bagnall, S. B., Simi, reports from. .239, 251
Bagwell, 0. N., Campbell Station ....89, 90

Bailey, J. C., Willits 98

Ballard, G. W., Travers, reports from.

238, 242

Bamber, J. J., Skyland, reports from ._

I. 238,250

Bamboos at Santa Monica station 350

Bananas, ash ingredients of 148

Bancroft, H. P., San Francisco 254

358

INDEX.

PAGE.

Bangs, Vital, Modesto 69

Barber, J. H., foreman of substation ._

_ 98, 278, 340

report on saltbush _ 289

wattle bark for tanning _. 227

Barley, analysis of 132

at Southern Coast Range substation. 288

distribution of seed of 234

moisture in soils of 69, 70, 95

tolerance of alkali 129

Barnes, Mrs. H. W., Los Gatos .. 254

Bartholomew, E., Rockport, Kansas .. 254

Basore, E., Pasadena •__. 98

Beans, distribution of seed of 234

Bean-meal, for poultry 135

Bean, Veitch's French climbing 252

Bedrock lands of Sacramento County . 44

Beet-sugar industry 16

Behr, Dr. H. H., San Francisco 254

Bender, J., Morgan Hill... 183, 200

Berg, N. S., Dos Palos 352

Bermuda grass, extermination of 201

Berries at Southern California sub-
station. _ 323

Bidwell, General John, oaks on the

ranch of 328

remarks on climate of Chico region.. 331

Birch at Chico forestry substation 334

Birds, poison for 310

Bioletti, F. T., effect of different de-
grees of light on multiplication of

water-bacteria _ 174 |

note on olives 173, 178 ]

notes on specimens received. _. 183

seeds from _. 254

tests of various antiseptics 170

vine pruning 185

Bishop, A. D., Orange 122, 125

Bishop, R. K., analyses by 38, 118

orange plants from _ 256

Bitter melilot, experiments with 217

Blackberries at Southern California

substation 323

Blake, W. R., Escondido 98

Blasdale, W. C., examination of olive

oils by 165

seeds and plants from 254

Blight in pear orchards 314

Blood, dried, food for poultry 135

Blowers, R. B., Woodland 87

Boardman, G. C., San Francisco 97

Boland, A. B., foreman of substation. 329

Bolton, Arthur L., Peralta Park 254

Bolton, Miss Alice, Peralta Park 254

Bonta, Peter, Miller, reports from

245,249,251, 252

Botanic Garden of University 253

Bordeaux mixture, formula for... 182

Bourne, D., Auburn, plants from 256

Bowbeer, B. F., Penn Grove 98

Box elder at Chico forestry substation. 334

Boyes, Mrs. A. C., Sonoma _. 98

Bradford, W. C., Arbuckle 256

reports from 237,244, 246

Brannon, R. W. O., Hollister 120

Braunton, F., Los Angeles 256

Bristol, W. M., Highlands 36, 97

Brome grasses for dry land 248

Brown, H. E., St. Helena, reports from.

X 246, 251

Brown, Mrs. Dora, Traver 117

Brubaker, B. H., Corning, reports from. 237
Bruck, B., St. Helena, vines from._184, 200
Buckel, Dr. C. A., Angwin 97

PAGE.

Buffalo grass for dryland 248

Bundschu, C. E., San Francisco 200

Bunnell, Mrs., Berkeley 254

Burbank, Luther, Santa Rosa 352

Bur clover for green-manuring 204, 240

Burpee, W. A., Philadelphia. 352

Butter, A. J., Colusa, reports from 244

Butter, for export 131

Butternuts at Foothill substation 276

Butterworth, W. A., South Pasadena,

reports from 240

Buysman, M., Middleburg, Holland... 254

Calcareous land, growth of lupins on.. 225
Canadian field pea for green-manuring 240
Canaigre at Southern California sub-
station 325

distribution of 234

Cannahan, F. M., Metz, reports from..

238, 246

Canned fruit, examination of 157

Canned products, investigations of ... 159

Canning peaches, test of _.. 315

Carpenter, B. S., North Carolina Station 149

Carob, moisture in soil of.. 83

Carrot, new-short-white, reports on ... 251

on alkali 326

Caruthers, J. H., Rialto 98

Casalegno, Thomas, Evergreen, reports

from 252

Castle Bros., San Francisco 98

Catalpa at Chico forestry substation... 334

Cattle foods, investigation of 131

Central Experiment Station, experi-
ment with lupins 207, 211

report on work of 233

table of lupin culture 220

Cereal grasses, root-penetration of 48

Cereals at Southern Coast Range sub-
station .__, 288

distribution of 233

Chad, G. H., Scotia, reports from

246, 248, 250

Chambers, E. L., Riverside, reports

from 250

Chapman, C. M., Brentwood 256

Chappell, W. W., Nashville 256

Cheese, analysis of _.. 135

Cherries, ash ingredients of 148

at Foothill substation 271

at Southern California substation ... 314
at Southern Coast Range substation. 287

moisture in soils of 84, 94

on hardpan _ 291

Chestnuts, ash ingredients of _. 148

Chico Forestry substation, report on ._ 328

Childs, F. G., Davisville 77, 78

Citrus trees, at Foothill substation 276

effect of alkali on 99

moisture in soils of 83, 84, 94

tolerance of alkali 129

Clark, L. C., San Francisco 256

Clarke, Capt. F. L., Veterans' Home,

Yountville 256

Clarke, J. J.,Tehama 254, 256

Clarke, W. T., California vine-hopper . 179
Clift, Mr., Paso Robles, note on climate. 280
Climatic conditions at Chico substation 330

of Chino Valley ...- - 307

of Foothill substation 267

of San Joaquin Valley substation ... 294
of Southern California substation ... 307
of Southern Coast Range substation. 2?8

INDEX.

359

PAGE.

Climate of Santa Monica substation ... 341
Clinton, H. G., Gertrude, reports from. 245
Clovers at San Joaquin Valley sub-
station 298, 299

tolerance of alkali 129

Cockrill, W. C., Latrobe, reports from. 244

Colby, George E 17

analysis of purifine _ 170

analyses by 118,155, 228

examination of California apples 143

examination of canned fruit 157

investigations of canned products ... 159

nicotine in California tobacco 149

note on olives ._ 173

physical, chemical properties of salad

oil 165

Colmore, Charles, foreman __ 340

Colusa County, alkali soils x>f 113

analysis of soil from 32

Conifers at Chico substation . . 332

Conklin, L. E., Montecito, reports from

239, 249

Contra Costa County, fruit from 157

Cook, A. J., conductor of Farmers' In-
stitutes _ 26

Cook, H., Gridley 122

Cook, James, Los Angeles, tanning

tests by 229

Cook, J. A., San Jacinto 97, 98, 117

Cooper, Chas., Campbell Station 89, 90

Cooper, Wm. A., San Jos6 - 97

Coop, John, Winters 96

Copeland, H., Chula Vista 97

Corn, distribution of seed of 234

Cornmeal, analysis of... 132

Corn, moisture in soils of _.69, 70, 94

on alkali _ 326

root development of 49

Washington Market, reports on ... .. 250
Corona, moisture and alkali in orchards

of 83, 84, 99

Corson, Mary A., Redmoon, Oklahoma,

reports from. _._ 240, 245

Cotton at Southern California substa-
tion 323

Cottomvood at Chico forestry substa-
tion.. 334

Coute, H. W., Escondido 117

Cowpeas for green-manuring 240

Crabb, H. W., Oakville 98

Crimson clover for green-manuring 240

Crops, amount of water required by... 40

deep-rooting of 41

Crump, J. A., Elizabeth Lake, reports

from _ 251

Cultivation of soil to various depths,

effect of 63

Currants at Southern California sub-
station _. 323

Cushman,W.H.,Millsaps, reports from 244

Custer, W. Q., Covina 256

Cypress at Chico forestry substation.. 333

Bail, Wm., Jamul, reports from. 247, 250, 251

Dairy school, need of 16

Date palms, at San Joaquin Valley sub-
station 297

at Southern California substation 319

Davidson, Dr. A., Los Angeles -:. 254

Davisville, soils from region of_. 77, 78, 80

Davy, J. B., Berkeley 46, 122, 125, 254

lupins for green-manuring _. _. _ 203

University Botanic Garden 253

PAGE.

Day, Miss Edith M., Ventura 254

Day, Mrs. Clinton, Berkeley... 254

De Seille, J. F. C., Texas.... _.__'_ 98

Denicke, E. A., San Francisco _. 98

Dennison, W. E., San Francisco 116

Depps, J. W., Pasadena 98

Dickenson, S., Bakersfield 123

Dillon, W. H., Los Angeles 98

Dimmick, D. M., Carpinteria, reports

from ..239, 251

Distribution of plants, seeds, etc 233

of seeds and plants from substa-
tions 292, 340

Dobbins, J.H.,Colfax, reports from.243, 244

Dodd, Geo., Caruthers 125

Donations to the Experiment Station.. 352
Donkin, G. F., Grayson, reports from..

...238, 245

Dowd, T. E., Lakeville 98

Downs, F. H., Otay 97, 123

Drew, Elmer R., Piedmont... 254

Dresser, Mrs. C. A., Fresno Flats 254

Drought, effect of, on trees at Santa

Monica substation 345

in soils of arid region, endurance of.. 40

resistance of eucalypts 345

Drury, J. S., Bakersfield 98

Dry-land grasses, reports on _ 248

Dye, H.E.,Tulare 254,257

Dye, Sperry, Walnut Grove ._. 96

Dudley, B. W., Ventura 81, 82, 91, 92

Duffy, J. B.,Galt 96, 139

Duncan, F. E., Campbell 97

Dunninger, Dr. P. G., Pacific Grove... 97

Dutard, H., San Francisco 134, 254, 257

Duvall, Mr., Datura, reports from 244

E

Earlcliff, H., Santa Barbara 98

East Highlands, soils from ...36, 38

East Riverside, lands of. 37

Eastwood, Miss Alice, San Francisco.. 254

Ecker, Geo. C., Alameda .123, 125

Edible-pod pea, distribution of seed of. 234

reports on__ 249

Edmonds, W. O., Upper Lake 257

Edwards, E. A., Hollister, reports from

238,247

Edwards, J. T., Napa 87

Eels, A. B.,WestPalmdale--_ 254

Egbert, R. S., Rio Vista

237,246, 249, 250, 251, 252

Eggers, H. C., Fresno 96

Ehrenfeld, C., Redding 96

Eisen, Dr. Gustav, San Francisco 254

Eisenhart, F. M., Elsinore, report from. 252
Eitel, J. G. F., Mountain Ranch, reports

from 247, 250

Eldridge, C. P., Clearwater 97, 115

Elliott, Wm., Riverside 125

Elms at Chico forestry substation 334

English oaks, at Chico forestry substa-
tion 335

at Santa Monica, description... 351

Endurance of drought in soils of arid

region __ 40

Epsom salts, efflorescence in Sisquoc

Valley 33

Ercanbrack, C. K., Pajaro 123

Eriogonumparvifolium, analysis of... 132

Eshleman, J. S., Fresno 254, 258

Eucalyptus, at Chico Forestry sub-
station 338

at Foothill substation _. ..266

360

INDEX.

PAGE.
Eucalyptus, descriptive notes of trees

and flowers 346

grove, Santa Monica substation 343

moisture in soils of _ 74, 95

resistance of drought of 345

Evans, J. F., San Francisco ... 98

Evaporation of soil-moisture, preven-
tion of 57

Exchanges received in reading-room ._ 353
Exline, Levy, Paso Robles, note on

climate _ 280

report from 290

Expenditures in seed distribution 235

Experiment Stations, need for 15

Extermination of weeds ._ .. 201

Fairfield, C. P., Campbell, reports

from.. .__ 238,249,251

Farmers' Institutes, comparative cost

of..... 1 28

held in the State ...14, 26, 278

report on __ 24

Farwell, Wm., Los Gatos .. 97

Feathers, Orlinda, Long Beach .._ 122

Fenugreek, description of 241

distribution of seed of 235

for green-manuring 241

reports on _ 241

Fermentation, control of temperature

in, note on ... 185

Fertilizers, use of on Highland soils... 39

Fiber plants, distribution of 233

Figs, ash ingredients of 148

at Foothill substation 273

at San Joaquin Valley substation 297

at Southern California substation ... 217
at Southern Coast Range substation. 287

distribution of 233

irrigation of 309

moisture in soils of .84, 85, 94

on hardpan 291

sugar of. 145

Filcher, J. A., San Francisco 98

Finances of Chico forestry substation. . 328

Firth, R., Cucamonga 97, 125

Flax at Southern California substa-
tion _ 326

on alkali soil. 326

Flint, R., Berkeley, waters from 122,125

Food, use of lupin seed for 219

Foothill substation, experiments with

lupins __1 213

rainfall of 65, 84, 88

report on 264

Forage,. use of lupins for 223

Forage plants, distribution of 233

reports on _ ...211, 243

Foremen of substations, duties of 2b3

Forestry, instruction in 17

Forestry substations 16

at Chico _ 328

at Santa Monica 340

Forest trees at Southern California sub-
station __ 321

Forrer, Julius, foreman of station 292

Fowler, D. T., conductor in Farmers'

Institutes _. 26, 96

Franceschi, Dr. F., Santa Barbara. .254, 352

Fresno County 116

fruit from 157

Frost, G. T., Exeter 96

Frosts, at Foothill substation 267

at Paso Robles... .. 280

PAGE.

Frosts, at San Joaquin Valley substa-
tion 295

at Santa Monica Station, effects of .. 342

Fruits, analyses of 143

ash ingredients of 148

canned, examination of 157

moisture in soils of .. 77

Fruit trees, at Foothill substation 268

tolerance of alkali. ._• i29

Fulton, A. W., Saticoy, waters from... ISO

Fungi, sprays and washes for _. 181

Gage, L. C., Lincoln, reports from 242

Garden and field seeds, reports on 249

Gerst, M., Paso Robles, note on climate 279

Gibson, H. W., Ventura 80, 81, 82, 91, 92

Gier, Theodore, Livermore .. 120

Gird, H. H., Bonsall, reports from. 245, 246

Gladden, W. N., Healdsburg 139

Glaser, Mrs., San Francisco 98

Gleghorn, S. W., Sunny Side 123

Glenn County, analysis of soil from... 31
Glenn, John N., Valle Vista, reports

from __ 240, 247

Gober, R. P., Los Gatos 122

Goodyear, E. F., San Francisco 98

Gooseberries at Southern California

substation 323

Gossman, August, Philo, reports from. 250

Gould, R. A., Montecito... _ 83

Graham, A. S., Redwood City 97

Graham, L., Fresno 200

Graham, S. F., SanJose"... 98

Grapes, ash ingredients of 148

distribution of 233

moisture 94

sugar of.._ -. 145

Grasses, at San Joaquin Valley sub-
station _ 298

at Southern California substation... 326

distribution of seeds of.. 234

dry-land, reports on 248

foxtail hay, etc., analysis of. I _ 133

on alkali soil.. 326

tolerance of alkali 129

Grapevines, root-penetration of 52

Green, A. H., Castle Crag ..96,98

Greenlaw, John A., Parkneld._ 120

Green-manuring, bitter melilot for 217

crops for 203, 240

crops, time of sowing.. 225

hairy vetch for 242

inoculation of soil 219

lupins recommended for 218

plants, distribution of 233, 235

Green, Prof. Edw. L., Washington, D. C. 254

Griffin, Henry, Jackson _ 143

Gugenhieme, Mr., San Francisco 98

Guilford, C. D., Creston, reports from

238, 242, 243, 245, 249, 252

Guill Bros., Chico, reports from 237, 248

Gunnison, A. W., San Francisco 254

Gurr, A. R., Merced 200

Gury, R. C., Hollister 123

Guss, L. L., Brentwood, reports from..

._ 237,245, 254

Gypsum, in irrigation water 130

used in alkali reclamation at Tulare
substation " 301

Hagenbuck, Mrs. 1 254

Hagerand Tuttle, Colusa 113

INDEX.

361

PAGE.
Hairy vetch for green-manuring ...240, 242

moisture in soils of _ 95

yield of 242

Hall, A. W., East Highland, reports

from _ 239

Hall, H. M., Riverside .. 254

Hall, G. P., San Diego.. „ 98

Hall, J. H., Mendota 96

Hall, James, Los Angeles 98

Hall, P., Riverside 97

Hall, W. L., Nordhoff 200

Hamilton, Dr., Corona ._ 97

Hammond, W. H., Tulare 120

Hansen, J. C., Campbell, reports from. 247
Hardpan, investigations at Paso Robles 290

plowsole 44

tree roots on _ 45

Hare, G. A., Fresno 96

Hardt, Louis, Grass Valley, reports

from 243, 250

Harger, E. B., San Francisco _. 254

Harshberger, Dr. J. W., Philadelphia,

Pa 254

Hasse, Dr. H. E., Soldiers' Home 341

Hastie, Robert, Clayton, reports from. 245

Hathaway, F. B., Colton 125

Hawkins, C. N., Hollister 118

Hayes, James C., Porterville, reports

from 248

Hayne, A. P., note on control of tem-
perature in fermentation 185

Herbarium of Santa Monica substation. 340

Herron, Mr., Modesto 96

Hickman, J. B., Monterey .. 254

High, A. G., Parkfield 98

Hilburn, L. A., Suisun ._ 200

Hilgard, E. W., endurance of drought

in soils of arid region 40

examination of canned fruit 159

green-manure crops 203

growth of lupins on calcareous land. 225

investigation of canned products 159

soils of East Highlands 36

the extermination of weeds. 201

use of alkali waters in irrigation 126

Hillman, Prof., Reno, Nevada 254

History of Chico forestry substation .. 328

Hodgkins, W. H., Fresno 122

Hollmg, H. H., San Pablo 97

Rolling, W. W., Mendota 96

Holzinger, J. M., Winona, Wis. 254

Honey, E. A., Orange.. .'_ 98

Hooper, F. W., Little Shasta 254, 258

Hoover, S. F., Tulare 122

Hopkins, H. P., Big Sur River 254

Hopper, J. J., Los Angeles, reports

from 239

Hornbeck, J., San Jacinto 98

Howe, H. L., Oakdale, reports from ...

238, 246, 247, 248

Hoyt, Mrs. J. B., Bird's Landing, re-

portsfrom _. 247

Huetenberger, H. H., Oakland, reports

from _ _ 252, 253

Huston, E. W., Newman _ 98

Hutchinson, A. J., Lindsay 258

Indian mesa, lands of 37

Insects, sprays and washes for 181

Investigations of canned products 159

Irgens, J. S., Jamul, reports from 245

Irrigation, at Southern California sub-
station .. 309

PAGE.

Irrigation, basin method 52

of vineyard at station _ . 322

percolation of water of 57

proper system of__. 104

winter 55-308

with alkali waters . . _ 126

Jacobs, J., Visalia _• 140

Jaeger. Rudolph, Berkeley 254

Jaehne, S. A. R., Bakersfield 258

Jaffa, M. E., analyses by 118

analyses of sugar beets 136

investigation of cattle foods 131

nutritive value of desiccated vegeta-
bles _. 154

Jameson, M., Corona, reports from 242

Jamieson, H. E., Downey 254

Jamison, J. D., San Diego 97

Janks, Mr., Los Gatos 254

Jared,L.,Estrella 254

Jepson, Dr. W- L., Berkeley.. 254

Jersey kale, distribution of seed of 234

for poultry, reports on 246

Jerusalem artichokes, for forage crop.. 245

on alkali 326

Jessen, Hans, Half-Moon Bay 97

Jobes, J. W., Escondido, reports from. 251

Johnson grass, extermination of 201

Johnson, Mrs. I. E., Los Gatos 254

Jones, Miss K., Berkeley 254

Jordan, P. H., Saratoga 97

Josephi, D. E., Bakersfield .96, 117, 122, 254

K

Kaiser, L. M., San Luis Obispo 81, 82

Kales at Southern California substa-
tion... 327

Kelly, W. W., Morgan Hill.... 97

Kelsey, H., Montalvo ... 98

Kennedy, F. F., Elk Grove, reports

from 237, 247

Kern County Land Company 118

Kern County 117

sugar beets from.. 139

Kerosene emulsion, formula for 182

Ketchem, R.W., Jackson ... 184

Keyes, W. S., San Francisco 200

King, Miss M. A., Berkeley 254

Kinney, Abbot, Lamanda Park 352

Kirkendall, T. L., Natividad 200

Kleman, Gus, Los Angeles .. 118

Klinberg, Dr. C., Redding 96

Knock, Thomas L., Willows 120

Koch, F. W., Merced 254

Kochler, D., Paso Robles 122

Keener, Charles, Willits, reports from. 245
Kolpien, Jasper, Grimes, reports from. 244

Kramp, A. L., Diamond Springs 122

Kuhirt, H., Atlas, reports from 244

Lake Elsinore, waters of 83, 99, 118, 129

Lamb, Mrs. D. 0., Fallbrook, reports

from ...240, 251

Land and Irrigation Co., Riverside,

waters from... 125

Lane, B. E., Morgan Hill 97

Le Boyd, Paul, Elk Grove, reports

from _ 242,247,252

Leckenby, A. B., Tacoma, Wash. ..254, 258

Lecureuil, Isador, Santa Cruz 238, 254

Lemmon, J. G., North Temescal 254

362

INDEX.

PAGE.

Lemon, ash ingredients of 148

at Foothill substation 276

at Southern California substation ... 319
Lester, Edward, Pasadena, seeds from

_ _ ..239, 242, 243, 249

Lewers, Ross, Franktown, Nevada,

apples from. _ _ 143

Light, effect of, on water-bacteria 174

Lima beans, report on 237

Lime, effect of, on growth of lupins... 225

Loco poisoning with lupins 223

Loganberry at Southern California sub-
station 323

Loop, Rev. C. F., patron ... 307

Los Angeles Chamoer of Commerce.254, 259

Los Angeles County. .83, 85, 89, 90, 115

fruit from _ _ _ 157

moisture in soils of 70, 74, 84, 85, 90

rainfall of 65

Loughridge, R. H 17, 118, 119

alkali on citrus trees _.. 99

description of Santa Maria and Sis-

quoc valleys and Nipomo mesa 33

endurance of drought in soils of arid

region _ ._ _.. 40

moisture in California soils 65

Lucan, E. A., Cloverdale, reports from. 248

Lucas, E. W., Rosamond 254

Liidemann, F., Pacific Nurseries 254

Lumsden, W. H., Santa Rosa 122

Lupins, description of varieties 206

for green-manuring 203

inoculation of soil from 219

rotting of, in soil 219

uses of 211, 215

seeds, for human food 219

soils for _ 207-211

use for forage 223

Lupinose poisoning 223

Luther, M., Hollister, waters from 125

Lyman, E. R., analyses by.. 31, 35

Lyons Nurseries, Los Angeles 254

Lyons, Wm., Los Angeles 97

Macaroni flour, for feed 135

Machado, E. S., Morgan Hill 98

Mack, G. W., Westminster, reports

from 240

Maclver, D. B., San Diego 98

Macleod, George B., Matilija 259

MacVine, John, Sunland 259

Maiden, J. H., analyses of wattle bark. 228
Manson, Dr. Marsden, San Francisco.. 255

Mapel, E. T., Stockton 98

Mapel, E. T., Craftonville 98

Maples at Chico forestry substation ... 335

Marson, Paul, San Jose" 120

Martel, Mrs. Kate, Vacaville 98

Martin, Mrs. S. J., La Costa, reports

from.. 240,251

Maslin, P., Sacramento .254, 259

Matheson, M., Victor 98

Mathews, Wright, Lakeport 259

Mathison, C. P., Guadalupe, reports

from __ 239

Matts, F. J., Gardena, reports from

240, 247, 250, 251

Mauerham, Mrs., Fruitvale ..122, 125

Maynard, Mrs. T. J., Walnut Creek. 254, 259

McAdams, T. D., San Jos6 97

McCarthy, J. P., Traver.. 96, 115

McCarthy, Mr., San Leandro 97

McCart, Peter, Goodwin 123

PAGE.

McClatchie, A. J., Tucson 217, 254, 341

McClung, J. A., Selma 98

McDonald, E. C., Aptos 98

McEuen, D. N., Winchester 259

McFarland, D., Los Angeles 98

McFarland, J. H., Porterville 98

Mcllrath, Mr., Yolo County 96

Mclniosh, W. P., Redlands 98

McNulty,W. J., Fresno 122

McOwan, P., Capetown, South Africa.. 254
Mechanical analysis, Santa Maria soil. 36

Meeker, F. L., San Diego 255

Megason, J. F., Corona 112

Mel, John, Glenwood 255

Melde, Henry, Eureka 255

Meldon, R. E.. Winters, reports from.. 237

Messer, N., Wildomar _ 118

Meyer, E. E., Wright... 200

Milks, J., Davisville- 77, 78

Milkweed, extermination of 201

Miller, D. W., San Jose", reports from..

...246, 250

Miller, L. H., Berkeley 255

Miller,-Mrs. L., Elk Grove, reports from. 237

Millet on alkali soil 326

Millikan, Kate, Santa Clara, reports

from.. 238

Mills, J. W., foreman.. 104, 105, 207, 225, 307

notes on roselle 236

Mills, W. H., Rumsey 96

Minerals received for examination 97

Mining and Investment Co., Los An-
geles 98

Modiola, distribution of seed of _.. 234

Moisture, amount necessary for citrus

trees 106

demand for, by cultures 92

hygroscopic, definition ._ _. 66

in California soils in 1898 65

in soil, conservation of 55

in soils of Paso Robles substation. .. 291

in soils of irrigated orange groves 105

supply in Corona soils 104

Monterey County 86, 115

analysis of soil from _ 32

moisture in soil of ...66, 86

Montgomery, W., Davisville 77, 78

Moody, James C., Alma, reports from

238, 249

Moody, Dr. J. D., Los Angeles 97, 122

Moore, George A., San Francisco 98

More, James, Campbell, reports from. 246
Morgan, Wallace, Miramonti, reports

from 245

Morning-glory, extermination of. 201

Morrison, J. S., Los Angeles 97

Morse Seed Co., Gilroy 352

Mueller, Baron F. von... 255

Muirson, G. A., LosGatos 97

Mulberries, at Chico forestry substation 335
at Southern Coast Range substation 287

at Foothill substation 266

distribution of 233

moisture in soil... 83

on hardpan . 291

Mumma, W. R., Grand Island 259

Munson, T. V., Dennison, Texas 352

Murdock, S. J., Westminster 97

Muth-Rasmussen,Wm., Independence,
reports from -238, 251

Napa County, moisture in soils of

69, 70, 76, 87

INDEX.

363

PAGE.

Nash, G. S., New Idria, waters from... 123
Neal, J. W., foreman of Foothill sub-
station ..143, 264

Nectarines, analysis of 146

at Foothill substation 270

at San Joaquin Valley substation ... 296
at Southern Coast Range substation. 286

Nelles, H. E., Jamacha... 125

Neustadt, A., San Francisco, roselle

from 236

Nevada, apples from _. 143

Nipomo Mesa, description of 35

Nicotine, in California tobacco _. 149

Nisley, P. W. 255

Nisson, C., Petaluma 184, 200

Nixon, A. L., Anderson _ _. 98

Noack, Harry R., Berkeley _. 259

Nolan, S., Oakland 255

Nougaret, R. L., Oakland .184, 200

Noyes, A. C., Sonoma, reports from.237, 250
Nutritive value of desiccated vege-
tables .. . 154

Oaks, at Chico forestry station 335

on hardpan 291

on Rancho Chico. _. 328

Oat grasses for dry land 248

Oat hay 133

Oat, root development of 50

Oester, J. H., O'Neals _.184, 200

Oils, physical, chemical properties of.. 166
used for salad or adulterants, list of.. 169

Olive oils, adulterants for 169

properties of _ 167

Olive-knot, note on... 178

Olives, ash ingredients of 148

at Foothill substation 273

at Southern California substation... 317
at Southern Coast Range substation. 287

distributi9n of 233

moisture in soils of 85,94

note on 173

self-pollenization of... 317

statistics of blooming and ripening. . 318
Oneto, Mr., donation to the Foothill

substation __. 267

Oranges, ash ingredients of _ 148

at Foothill substation 276

at Southern California substation... 319

sugar of. -. 145

Orange trees, irrigation of 54

root-penetration of _ 43

Orchard, at Foothill substation 268

at San Joaquin Valley substation 295

at Southern California substation 310

at Southern Coast Range substation. 283

fumigation, note on 181

reclamation of alkali 112

soils, moisture in 77

Osen, Adolph, Corning ._ 98

Osterhout, W. J. V., Berkeley 255

Otis, H., Cazadero 97

Overhiser, J. C., Stockton. 69

Owen, Frank, Monticello, reports from. 247

Owens, J. A., Claremont 97

Oxnard, moisture in soil of 71, 74

Oxnard, R., San Francisco 97

Pacific Mfg. Co., Corona. 122

Paige, Cutler, San Francisco... _. 259

Palmer, Sutton, Lindsay. 96

Palmer, W. S., Mendota 116

PAGE.

Paris green, formula for 181

Parish, S. B., San Bernardino 255

Parsnips on alkali _. 326

Paull, J., Artesia 97

Paulonia at Chico forestry substation. 334

Paxton, B. W., Healdsburg 184, 200

Pecans, at Foothill substation 276

Peaches, ash ingredients of 148

at Foothill substation .'_. 270

at San Joaquin Valley substation 297

at Southern California substation 314

at Southern Coast Range substation . . 286

caution regarding varieties 316

moisture in soil of 86, 94

on hardpan 291

spring and winter pruning. 314

sugar of ., 145

test for canning, report of 315

Peanuts, analysis of 135

Pearce, G. E., Paradise, reports from..

237, 247, 251, 252

Pears, ash ingredients of 148

at Foothill substation 268

at San Joaquin Valley substation ... 296
at Southern California substation ... 311

irrigation of 309

moisture in soil of ._ ..87, 94

sugar of.. 145

Pearson, A. R., Clifton, reports from.. 238

Peck, R. E., Long Beach 123

Peckinpah, Mrs.L. A. R 255

Pepper trees at Santa Monica 345

Persimmons, at Chico Forestry sub-
station 335, 336

at Foothill substation 277

Persian sheep _ 278

Peterson, C. J. A., Selma 200

Phillips, A., Arroyo Grande 81, 82

Phelps, M. D., San Jos6... 120

Pine nuts, analysis of for candy 135

Pischet, W. A., Santa Monica 183, 200

Plants, amount of water demanded by. 65

deep-rooting of 41

distribution from substations 292

distribution of from Central Station .. 340

for green-manuring.. 240

received for examination 97

reports on, from correspondents 236

root-penetration of 46

seeds, etc., amount distributed .. 233

Platt, R. H., Vacaville 255

Plowsole hardpan 44

Plums, ash ingredients of 148

at Foothill substation 271

at San Joaquin Valley substation... 297
at Southern California substation ... 316
at Southern Coast Range substation. 287

moisture in soil of__ 88, 94

on hardpan 291

sugar of. 145

Poison for birds 310

Pollock, J. M., Gilroy, reports from.245, 249

Poplar at Chico forestry substation 334

Poultry, Jersey kale for 246

Preparatory teaching in agricultural

colleges 21

Preston, F. H., San Luis Obispo, re-
ports from 247, 251

Prunes, ash ingredients of .- 148

at Foothill substation 271

at San Joaquin Valley substation 297

at Southern California substation ... 216
at Southern Coast Range substation. 287
moisture in soils of 88, 89, 94

364

INDEX.

PAGE.
Prunes, sugar 145

Pruning of grapevines, systems of _185, 191
Pruning, spring and winter, of peaches 314

Purdy, Carl, Ukiah 255,352

Purinne, examination of 170

Pumpkins on alkali 326

Q

Quinces, at San Joaquin Valley sub-
station 296

at Southern Coast Range substation. 285

Rainfall, at Chico substation 330

at Foothill substation 267

. at San Joaquin Valley substation 294

at Santa Monica substation 341

at Southern California substation 309

at Southern Coast Range substation 278

in the State for 1896-8 65

of winter, utilization of _ 55

utilization of _-, 280

Raspberries, at Southern California

substation _.. 323

Raymond, George A., San Francisco ._ 259
Redington, Mrs. A. P., Santa Barbara. 123

Reed, C. H., Gary, soil from 35

Regulations for substations 263

Reports on seeds and plant distribution 236

Reynolds, Miss Mary J., Pomona 255

Rey, W. J. A., San Francisco 260

Rhagodia at San Joaquin Valley sub-
station 301

Rice and hulls, analysis of _ 132

distribution of seed of 234

Rice, T. E., Livermore, reports from...

237, 242,245, 248

Richards, V. C., Patron of Chico sub-
station 329

Richards, T. J., Bishop 98

Righter, F. M., Campbell Station 89, 90

Rising, W. B., examination of oils by.. 166

Riverside County 83, 99, 117

moisture in soils of 67, 83

Rivers. J. J.. Santa Monica ___

...98, 239, 249, 251, 252, 255, 260

Rixford, George P., San Francisco. 253, 255

Robertson, George, Mentone 260

Robertson, J. C., Cloverdale 122

Robertson, R., Yountville, reports from 242

Roberts, V., Alcalde, reports from

238,246,249,250

Robinson, J. G., Santa Clara 260

Rock, John, Mies 352

Rocks received for examination 97

Roeding, George, Fresno 352

Rood, H. J., San Diego 97

Root-penetration of apricot trees 42

of cereal grasses 48

of Eastern trees _ 44

of grapevines 52

of native annuals _ 51

of orange trees 43

of peach trees 42

of plants _ 46

of weeds 51

Root-rot in lupins 224

Rose, J. N., Smithsonian Institute,

Washington, D. C., seeds from 255

Roselle, nature of _ 236

distribution of seed of 234

reports from correspondents on 236

Rowell, George B., San Bernardino 125

Rowley, B. IL, San Francisco 98

PAGE.

Royce, Mrs. L. D., Emeryville 260

Rupert, E. E., West Side 98

Rust, Judge R. C., Patron of Foothill

substation 264

Rutherford, J. E., Wyandotte, reports

from 250

Rutter, James, Florin, Paris-green from 200

Sacramento County, sugar beets from. 136

Sacramento Fruit Co., Sacramento 98

Sacramento, rainfall of 65

Salad oils, report on 159, 165

Salinas Valley, analysis of soil of 32

Salsify on alkali 326

Saltbush, at San Joaquin Valley sub-
station 292, 299

at Southern California substation... 326
at Southern Coast Range substation. 288

distribution of seed of 234

moisture in soils of 71, 74, 94

reports on.... 243, 262

San Bernardino County 86, 87

analyses of soils from 38

moisture in soils of _ 76,86,87

Sanborn, F. G., Santa Clara 120

Sandercock, W. C., Winlaw, Assiniboia. 255
Sander, F. & Co., St. Albans, England. 255

San Diego County 117

San Francisco, rainfall of 65

San Joaquin County, moisture in soils

of 69, 70

San Joaquin Valley substation, rain-
fall of 65,84,85

report on 292

San Luis Obispo County 86

analysis of soil from 35

fruit from _ 157

moisture in soil of 67, 74, 86

Santa Barbara County

83, 84,85, 89,90, 91, 131

analyses of soils from 35

moisture in soil of 63, 67, 83, 85, 90, 92

Santa Clara County ..89, 90

apples from 143

moisture in soil of 89, 90

Santa Cruz County, moisture in soils

of ....71,74

sugar beets from 13&

Santa Maria Valley, description of. ..33, 85

moisture in soils of 63

rainfall of 65

Santa Monica Forestry substation, re-
port on 340

moisture in soils of . 69, 70, 74

Saticoy Plain, moisture in soils of 63, 80

Sayre, A. I., Madera... 123

Sawyer, E. P., Los Angeles '123

Scale insects, spravs and washes for-._ 182

Scanland, G. A., Etiwanda ....97, 125

Schaeberle, Prof., Mount Hamilton 125

Schaffer, J. S., Tuttletown 255, 260

Scharff, Adolph, South Pasadena, re-
ports from _. -.. 250

Schein, Miss Louise E., Bridgeport,

Conn., reports from 240

Schlesinger & Bender, San Francisco.. 98

Schmidt, P. R., Calistoga^ 200

Schwagerl, E. O.,Puget Sound Univer-
sity 255

Scripps, W. A., Miramar._ 97

Seamans, Karl H., lone, reports from . 247

Sears, F. H., Corona 97, 118

Sea water, antiseptic value of ..._ 171

INDEX.

365

PAGE, j

Seerneth, Mrs. S., Santa Clara 97 j

Seed distribution from station.233, 292, 340 !

Seeds, garden and field, reports on 249 !

plants, etc., amount distributed 233

reports from correspondents 236

Sell, Mrs., Berkeley ..... 255 |

Segsworth, F., Ben Lomond, reports

from-.. -_ .—243, 250,251, 253!

Sedgwick, T. F., foreman of substation 278

Setchell, Dr. W. A., Berkeley 255

Setterly, R., ISpenceville, reports from. 244 j
Skellman, Theo., Petaluma, soils from. 97 j

Sharp, R. V., Hanford 184, 200 I

8haw,H. C., Stockton....: 96 j

Shaw, O. B., San Jose" 97

Shelley, W. S. H., Berryessa 122 i

Shepherd, Mrs. Theodosia B 255, 352 !

Shinn, C. H 16, 255

report on substations 262 j

Shinn, J. C., Niles, apples from 143, 352

Shipman, D. L., Rosamond 98

Shorteng, Agnes, South Pasadena, re-
ports from 239,251, 252

Sierra Madre, lands of 37

Silo _ ... . 134 i

Sisquoc Valley _ 89, 91

description of _ 33

moisture in soils of 81, 82 i

Slinson, Lewis, Napa, reports from. 242, 248

Smalley, F. N., analysis by 32

Smith, Alex., Corning 260

Smith, C. A., Hollywood, reports from

240, 247

Smith, F. G., Skaggs, reports from

_ ..237, 251, 252

Snail clover, for green-manuring. ..204, 240

Snider, E., Davisville 82

Snow, F. J., analyses by

..35, 38,113,118, 131, 136

Snow, Prof., Santa Barbara 83, 84

Snow, Wm., Palo Alto. 125

Sodium 'chlorid, injurious effect of 111

Soil, inoculation _ 219

map of the State 14

Soil-moisture, conservation of 55

effect of summer-fallow 64 !

effect of weeds 64

evaporation of, prevented 57

in California soils 65 j

Soils, alkali .'.. .99, 107-117 '

Soils, analyses of. 31 j

Colusa; "S. V. West 31

East Highlands ; W. M. Bristol 38

Fort Romie 32

Nipomo; C. H. Reed ._..'__ 35

Santa Maria 35

Willows 31

Soils, conditions for productiveness. .. 103
cultivation to various depths, effect of 63
difference in humid and arid regions 41
of arid region, endurance of drought

in ._ 40

received for examination 96

Sonoma County, sugar beets from 139

Southern California substation

....57, 84, 104, 129

experiments with lupins. .206, 207, 212, 214

moisture in soil of -68, 74, 76, 84, 87

roselle from 236

report on .' 307

Southern Coast Range substation

.._ ...65, 86, 283, 284

experiments with lupins. 210

hardpan of 45

PAGE.
Southern Coast Range substation,

moisture in soils of 68, 74, 80, 86

report on _ 278

Sorghum on alkali.. _ 326

moisture in soils of— _ 71, 74, 95

Soya bean, at Southern California sub-
station 324

distribution of seed of 234

moisture in soil of 71, 74, 95

Spear, C. C., Waddington 241, 260

Spinach, distribution of seed of 234

Sprague, A. R., Fairmont 260

Sprays and washes.. 181

Spreckels, A., San Francisco 97

Squashes on alkali 326

Stamper, E., San Francisco.. 98

Stanislaus County, moisture in soils of _

- 69, 70,92

Starrell, S. E., San Francisco .. 255

Stearns, Elmer E., Bakersfield 255

Stetson, E.J3K, San Francisco 260

Stewart, C. K., Nestor 97

Stewart Fruit Co., Famosa _ 139

Still, A. A., Annette 98, 255

Stillman, E. A., Mendota, reports from 238

Stivers, H. F., Hunters •_ 261

Stix, John, Napa, reports from

244,246, 247, 249

Stockton, J. T., Ventura 120

Stone, E. B., San Leandro 97

Street, C. F., San Mateo, reports from..

246, 247, 249, 250

Strehlow, Charles, Healdsburg, reports

from _ 242, 252

Strong, J. C., Los Gatos..- 123

Stubenrauch, A. V., Napa 120

Stucky, J. A.,Rosemond 96

Subsoil, knowledge of, important 56

Substations, organizations of _. 263

report on 262

Sucksdorf, W. N.,Bingen, Wash 255

Sugar beets, analyses of, from —

Berkeley; Experiment Station 140

Dry Creek; Sacramento Chamber

of Commerce... 136

Fresno; Stewart Fruit Co 139

Gait; J. B. Duffy 139

Healdsburg; W. N. Gladden 139

Hoptown ; Sacramento Chamber of

Commerce 136

Merritt Island ; Sacramento Cham-
ber of Commerce 139

Pierson Reclamation Tract; Sacra-
mento Chamber of Commerce ... 137
Pierson Reclamation Tract; T. G.

Van der Bosch... 137

Pomona; Experiment Station 140

Sacramento Chamber of Commerce 136"

Tyler Island; H. Voorman 138

Visalia; J. Jacobs & Bro 140

Walnut Grove; P. J. Van Loben

Sels.... 138

Watsonville; T. Therwatcher 139

at Southern California substation 327

from various soils 140

moisture in soils of 71, 74, 94

on alkali 326

sent from experiment stations 140

Kern, Santa Cruz, Sonoma, Yolo

Counties 139

Sacramento County _ 136

Tulare County 140

tolerance of alkali _ 129

tops as a cattle food 131

366

INDEX.

PAGE.

Suhren, Geo. H., Collinsville, reports
from 245

Summer-fallow, effect of, on soil mois-
ture _- - 64

Summer pruning _-_ 197

Sunflowers on alkali 326

Sutter, A. J., Colusa, report from 245

Swan, J. B., Hollister, reports from ...

_. 238, 247, 249

Sweat, A. D., Visalia ... 96

Sweat, J. W., Ventura, waters from ... 123
Swett, Frank, Martinez, specimen from 200

Talcoa Vineyard, soils of 69, 70, 76

Tanning, tests of wattle bark 229

wattle bark for 227

Tarr, Henry, Gubserville 98

Taylor, Edwin, Parkfleld. 249, 251

Taylor, J. T., New Mexico 118

Taylor, Joe, Purissima 123

Taylor, J. W., Los Gatos 98

Taylor, Mrs. V. H. B., Manton, reports

from.. 244, 249

Temperature, at Central Station 233

at Chico substation ._ 330

at Foothill substation 268

at San Joaquin Valley substation .._ 295

at Santa Monica station _. 342

at Southern California substation ... 307
at Southern Coast Range substation. 280

Texas blue grass for dry land 248

Tharsing, C., lone, donations from 352

Therwatcher, T., Watsonville 139

Thompson, Mrs. Harry, Peralta Park . 255
Thorndike, Joseph, South Pasadena,

reports from 239

Thorn, S. F., Glenwood, reports from..

...246,250

Tidestrom, Ivan, Berkeley 255

Timm, W. D., Rio Vista 261

Tobacco, analyses of. 143

Todd, G. G., Parkfield , 255, 260

Tolman, L. M., analyses by 147

Trask, Mrs., Avalon .__ 255

Tree development studies at Chico sub-
station - 332

Trees at forestry substations 332, 344

distribution of, from stations 233, 266

Tribble, C. D., Lotus, reports from

237, 245, 249

True, T. J., Forestville, reports from .. 245

Trumbull, R. J., Orland . 96

Tucker, M. A., Los Angeles — 97

Tulare County 84, 85, 87, 115, 117

alkali in soils of... — ..114, 292, 301

experiment station (see San Joaquin
Valley.)

foxtail hay from — _ 133

moisture in soils of _

67, 68, 70, 71, 74, 76, 85, 87, 92

rainfall at points in 294

sugar beets from _. 140

Tulare Lake, alkali soil of 116

water of..-. - 129

Tuohy, John, Tulare 255, 292

Tule soil, analysis of 32

Turner, T. J., Lower Lake, reports from 249
Tyrrell, Mrs.,Lorin _ 255

Van der Bosch, T. G., Alametos . ..122, 137
Van Loben Sels, P. J., Walnut Grove.96, 138
Van Kirk, George, Corona... 118

PAGE.

Veale, R. R., Martinez 97

Vegetables, analysis of 143

desiccated, nutritive value of 155

distribution of 233, 234

tolerance of alkali .-_ ...129, 326

Ventura County _ 65, 91

moisture in soils of _. 63

Veitch's Climbing French Bean, re-

portson... 252

Veifinger, Jacob, Jamul, reports from. 242

Vetch, for green-manuring 240

growth at the station _ 224

moisture in soils of 71, 74

Veterinarian needed 17

Vineyard at Southern California sub-
station _ _ 321

Vineyard land, moisture in 75, 76

Vine-hopper, California, note on 179

Violet leaves, disease of 183

Vogt, Dr., Palmdale 255, 261

Voorman, H., San Francisco 122, 138

Wahrhaftig, M. S., Sacramento 98

Waite, 'F. D., San Diego, reports from. 247
Walker, E. H., Hanford, reports from.. 246

Wall, Peter, Elsinore 118

Walnuts, analysis of 135

ash ingredients of 148

at Chico forestry station 334

at Foothill substation 275

moisture in soil .of •„ ..91, 92, 94

Walter, Mrs. C. Stevens, Mountain

View 97

Wambold, M., Lakeport, reports from. 237
Washington market corn, reports on ._ 250

Water, amount required by crops 40

Waters, alkali, use of in irrigation 126

Waters, analyses of artesian, from —

Colton; F/B. Hathaway 125

Hollister; M.Luther 125

Riverside; Wm. Elliott .... 125

San Bernardino; G. B. Rowell 125

Westminster; A. D. Bishop 125

Waters of Common Wells, from —

Alameda; Geo. C. Ecker 123, 126

Alametos; T. G. Van der Bosch 122

Bakersfield; S. Dickenson 123

Bakersfield; D. E. Josephi 122

Berkeley; J. B. Davy 122, 126

Berkeley; R.Flint 122, 126

Berryessa; W. S. H. Shelly 122

Cloverdale; J. C. Robertson. 122

Corona ; Pacific Manufacturing Co. _ 122

Diamond Springs; A. L. Kramp 122

Fresno; W. J. McNulty 122

Fresno; W. H. Hodgkms 122

Fruitvale; Mrs. Mauerham 122, 126

Goodwin; Peter McCart 123

Gridley; H. Cook _ 122

Hollister; R. C. Gury _ 123

King City; Wm. Winterhalter 123

Long Beach; J. D. Moody... 122

Long Beach; Orlinda Feathers 122

Long Beach; R. E. Peck 123

Los Angeles; E. P. Sawyer 123

Los Gatos; J. C. Strong 123

Los Gatos; R. P. Gober 122, 126

Madera; A. I. Sayre 123

Napa; A.F.Allen 122

Newldria; G. S. Nash 123

Orange; A. D. Bishop '. 122

Otay; F. H. Downs 123

Pajaro; C. K. Ercanbrack 123

INDEX.

367

PAGE.
Waters of Common Wells, from—

PasoRobles; D. Kochler 122

Purissima; J.Taylor 123

Santa Barbara; Mrs. Reddington ... 123

Santa Rosa; W. H. Lumsden 122

Sunny Side; S. W. Gleghorn 123

Taylor Island ; H. Voorman 122

Tulare: S. F. Hoover 122

Ventura; J. W. Sweat 123

Waters of Reservoirs, from —

. Caruthers; Geo. Dodd 125

Cucamonga; E. Firth 125

Etiwanda; C. A. Scanland... 125

Jamaeha; H. E. Nelles 125

Palo Alto; Wm. Snow 125, 126

Riverside; Land and Irr. Co. 125

Westminster; A. D. Bishop 125

Waters of Springs, from —

Clarks Valley; T. L. Knock 120

Hollister; R. W. O. Brannon 120

Laurel Glen Farm; A. V. Stuben-

rauch 120,126

Livermore; Theo. Gier 120

Mineral King; W. H. Hammond .... 120

Monte Vista; M. D. Phelps 120

Parkfield; J. A. Greenlaw 120

San Jose"; Paul Marson 120

Santa Clara; F. G. Sanborn 120

Santa Paula; H. Anlauf 120

Saticoy; A. W. Fulton 120

Ventura; J. F. Stockton 120

Willows; T. L. Knock 120

Waters, Stream and Lake, from —

Hollister; C. N. Hawkins. 118

Lake Elsinore —102, 119

Los Angeles; Gus Kleman 118

Pecos River, N. Mexico; J. T. Taylor 118

Plato Creek, Kern County 118

Mt. Hamilton; Prof. Schaeberle 126

Water-sprouts, removal of 198

Wattle bark for tanning ..227, 228

Weber, A. H., San Francisco 97

Weeds, extermination of 201

injury from _ 64

root-penetration of 51

Weeks, Mrs., Pacific Grove 255

Wente, C. H., Livermore 184, 200

West, S. V., Colusa 31, 96

Wheat, at Southern Coast Range sub-
station.. .. 288

PAGE.
Wheat, bran, middlings, and shorts,

analyses of 132

distribution of _. 234

moisture in soils of _. 68, 70, 94

of reclaimed alkali land, Tulare 303

tolerance of alkali 129

Whitehead, D. Radcliffe, Santa Barbara 261
Whitemore,Wm.E., Whitemore, report

from 237, 241

Whiting, E. H., Warthan, reports

from 238, 250, 255, 261

Whitmore, F. M., Amador County.143, 144

Wickson, E. J. 17, 255

distribution of seeds, plants, etc 233

report on Farmers' Institutes 24

reports on seeds and plants dis-
tributed 236

Wilkendorf, Fred, Woodland, reports
from .. .. 244

Wilks, Mrs. F. M., San Jose" 255

Williamson, C. L., Auburn _ 200

Williams, B. T., Ventura 81, 82

Williams, W. T., Grass Valley, reports

from _ . 248

Willows, at Chico forestry station 337

distribution of 234

Wilson, N". G 255

Wind storms in Chino valley 308

Winterhalter, Wm., Kings City.. ..115, 123

Winter irrigation at substation 308

Wohlford, A. W., Escondido 97

Woodworth, C. W 1 17

California vine-hopper 179

note on orchard fumigation 181

sprays and washes 181

Wright, W. G., San Bernardino 255

Yates, Dr. Lorenzo, Santa Barbara,

donations from 352

Yelland, R. D., East Oakland 255

Yolo County 87, 88, 90

moisture in soils of

75, 76, 77, 78, 80, 87,90,92

sugar beets from 139

Yolo orchard, moisture in soils of 77, 78

Yost, Thomas, Kings River 98

Young, Dr. N. A., Los Angeles.. 98

SANTA MONICA FORESTRY SUBSTATION HISTORY. 89

SANTA MONICA FORESTRY SUBSTATION.

(Near the mouth of Santa Monica Canon, two miles west of Santa Monica.)

This forestry substation was established in the winter of 1887-8 by
the State Board of Forestry, and was transferred by the State to the
University of California, July 1, 1893. The forestry plantation of 29
acres near Chico came under the control of the University in the same
way. The State Board of Forestry was abolished by the same Act
which made the transfer.

For the first two years the sum of $2,000 per annum was granted by
the State for forestry purposes, and this was raised to $2,500 per
annum in 1895-6, but all direct State aid ceased at the close of 1896-7,
since which time the University has made small annual appropriations,
at no time equal to those formerly made by the State. The progress of
the substation has therefore been slow, as lack of means prevents many
needed improvements. The policy has been to spend the larger share
of the appropriation at Santa Monica, and to keep a foreman there.

While the Santa Monica substation is in some respects the most
attractive of all the substations, as it possesses a practically frostless
climate, it is better suited for a botanical garden than for pure forestry,
for which, indeed, the area is too limited. It affords an excellent loca-
tion for tests, on a small scale, of acacias, eucalypts, pines, and a few
other classes of trees, and now that the water-supply is ample, its unique
value, possessed by few places in the United States, lies in the direction
of a botanic garden, in which a great variety of plants from all parts of
the world could be grown.

Changes and Improvements. — The substation has had four foremen
since 1893— Mr. W. J. Strachan, Mr. John H. Barber, Mr. Charles A.
Colmore, and Mr. William Shutt. The latter took charge on September
1, 1900. Mr. Roy Jones, son of Senator J. P. Jones of Nevada, continues
to serve as Patron.

The most important improvement since the issuance of the report of
1*897-8 consists of an unexpected development of the water-supply, made
by Mr. Shutt, as foreman, in the winter of 1900-1901. The daily flow
from the new springs, cut by drifting farther into the bank, is about
16,000 gallons, and this enables more land to be irrigated on the lower
flat. The hydraulic ram is again used to lift water to the house, and
the windmill is no longer needed, except when repairs are being made
to the other systems.

Some desirable changes in the roads and grades have been lately
made, and about three acres of brush-covered land has been cleared. A
good deal of this has been planted with acacias and eucalypts. This is
excellent soil, although so steep as to be unfit for anything but trees.

90 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

CLIMATE.

The climate of Santa Monica and its vicinity is justly famous for its
evenness, and a very great variety of native and exotic plant life is
found here, as at Ventura and Santa Barbara. Thorough cultivation is
absolutely necessary, however, with the light rainfall, and irrigation is
practiced wherever possible. The forest trees grown at the substation,
however, have received no irrigation excepting as noted in the following
pages. Small trees, when first set out from the nursery, often require a
little water. As a rule, this "irrigation" consists of a quart or two of
water given to each tree from a barrel on a sled. A hole is made beside
the tree and the water poured slowly in. When it settles, the hole is
filled up with dry earth. One such watering in April has enabled
eucalypts and acacias to take root and grow well thereafter; without it,
losses would probably amount to half the stock.

Rainfall. — Since the University took charge of the place, the annual
rainfall has been as follows:

Year. Rainfall. Comment.

1893-4. . . 7.83 in. An extremely trying year.

1894-5 14.01 " Fairly good crops.

1895-6 _... 8.40" North winds; crop poor.

1896-7 16.13" An excellent year.

1897-8 ._. 5.24 " Crops failed; some large trees died.

1898-9 .- 7.11 " Crops scanty; some trees died.

1899-1900... _ 8.48 " Crops scanty; some trees died.

1900-1901 11.54 " Fairly good crops.

1901-1902 11.65 " Good crops.

The average rainfall for the above nine years has therefore been a
trifle over 10 inches. It would seem to persons unacquainted with
California conditions as if this low rainfall would make tree-growth
impossible, but the statistics elsewhere given show plainly that such is
not the case. In fact, one especial value of this substation is its trial,
for a long term of years, of a great number of species of trees under an
average rainfall of 10 inches.

The monthly rainfall varies greatly from season to season, as shown
by the following table of the precipitation during the past four seasons:

Month. 1898-99. 1899-1900. 1900-01. 1901-02.

October 0.34 1.11 0.25 2.41

November.. none 1.25 5.66 none

December .10 1.59 none none

January 4.56 2.45 none 1.75

February .01 none 4.35 3.90

March 1.69 .55 .20 3.27

April _. .05 .17 .50 none

May.. _ __.. none .36 .58 none

June _ .36 none none none

In practice, a rainfall of less than half an inch in any given month
is of little value. The desirable thing is to have "enough rain to start
plows" in November or December; then to have heavier rains in Janu-
ary or February, followed by spring showers. The favorable distribu-
tion of the rainfall doubles its usefulness. This year (1902, May 1st)
some barley on the upper mesa stands 3^ feet high and cuts 4 tons
of hay to the acre. Young eucalyptus trees, also on the upper mesa,
have made from 3 to 6 feet of growth this season. The above table,

SANTA MONICA FORESTRY SUBSTATION — CLIMATE.

91

however, shows that trees and hay received 2.71 inches of rain before
January, and after January nearly 9 inches, all well distributed. The
crops are better than in 1894-5, with 14 inches badly distributed
through the winter.

Temperature. — Only once during the nine years has the frost injured
heliotropes, nasturtiums, cannas, and other tender garden plants in
this district, but not then on the middle mesa of the substation, where
no serious injury has ever been done to even the most tender eucalypts.
The lowest flat, by the creek, has proved too cold and shady for Ficus
elastica and many other plants. On the middle mesa, where the most
valuable plantations exist, the immunity from frost is exceptional.
Here are growing Hibiscuses, Bauhinias, the Jacaranda mimossefolia,
Tacsonia manicata, Eucalyptus ficifolia, and many other tender plants.
The following table, continuing the record in the annual report for
1897-8, gives the temperature at the substation from June 30, 1898, to
April 1, 1902:

MONTHLY SUMMARY OF TEMPERATURE.

1898— July

August

September.

October

November .
December .

1899— January.-
February . .

March

April

May.

June

July..

August

September.

October

November .
December .

1900— January...
February..

March

April

May

June

July

August

September-
October

November .
December .

1901— January...
February..

March

April

May

June

July

August

September.

October

November .
December .

1902— January...
February..
March ..

Max.
79°
84
98
79

77
77

77
82
83

83
77
78
86
83
77
73
76
95
96
96
86
92
86
71
87
87
71
66
80
81
84
82
92
82
80
82
69
73

Mill. Mean Max. Mean Min. Mean Temp.

52°

54

50

42

42

41

38

33

37

42

43

48

49

51

51

42

42

41

42

42

40

39

44

50

51

52

48

46

47

39

37

33

39

38

43

44

50

48

44

62

43

33

33

35

35

74°

78

76

71

69

68

66

59

64

66

66

68

73

73

73

71

69

66

67

65
66
62
65
68
63
68
73
64
60
64
68
62
64
66
71
73
69
65
66
66
62
59
63

57°

58

56

49

47

47

45

41

48

47

49

55

55

55

56

51

51

46

45

46

49

46

47

70

75

77

70

50

54

47

43

48

48

47

50

55

55

56

51

52

47

43

42

42

42

65°

58
57
55
50
56
54
57
61
64
64
64
61
60
56
56
57
57
55
56
55
58
60
56
63
64
57
52
56
58
54
57
59
63
65

57
55
52
50
53

In January, 1898, the thermometer fell to 31°, but 33° is the next
lowest winter minimum, and the average minimum of nine years was

92 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

35°. The maximum has in nine years but once reached 100°, but every
year has gone to 90° or above for a few days. The maximum of 1898
was 98°, and the next highest temperatures of that year were 93° and
89°; in 1899 the two highest temperatures were 99° and 89°; in 1900
they were 95° and 92°, and in 1901 they were 92° and 87°.

THE EUCALYPTUS GROVES.

The plantations of eucalyptus trees at this substation have deservedly
attracted much attention for some years past. They have been visited
by many persons and reported upon in many forms. Mr. Abbot Kin-
ney's work on Eucalypts contains photographs of single trees here,
together with notes upon their growth, etc. Professor McClatchie has
also taken many notes and photographs here. Former station reports
contain much historical and descriptive material on these eucalypts.
(See Report of 1892-4, pp. 428-432; Report of 1894-5, pp. 450-455;
Report of 1895-7, pp. 412-426; and Report of 1897-8, pp. 340-351.)

A few of the large trees in the main group have died or have been
blown down. These losses seem to have been due in every case to poor
root systems, pot-bound or too large trees having been originally used.
The younger plantations show no such defects. Others of the older trees
will soon have to be removed, but specimens of all the species repre-
sented in this grove are now established elsewhere.

The following table shows some of the measurements taken in this,
the oldest grove of eucalypts in June, 1902:

Height. Girth.

E. amygdalina 23ft. 21 in.

E. calophylla 38" 47

E. citriodora 61" 35

E.corymbosa 36 " 32

E. corynocalyx 61" 47"

E. diversicolor .... 68" 42

E. viminalis 53 " 44

E.callosa _ 32" 15

E. sideroxylon 53" 52

Eucalypts on the Upper Mesa. — The original planting of eucalypts, done
on the upper mesa nearly one hundred feet above the middle flat, was
in the form of a narrow strip, chiefly on the western side, with a few
rows across the south and north. This mesa is a long and very narrow
tongue of land nearly level on the top, sloping south toward the ocean.
On the east it descends almost perpendicularly to the canon bottom; on
the west the descent, less abrupt, is to the cottage mesa, or middle bench
of the substation. The light, gravelly soil, and the height and exposure
of this plateau, make the growth of trees difficult. Success here argues
similar success on plateaus even farther inland.

The eucalypts planted here in 1889, thinned out in 1893 and 1894, and
since then uncultivated, have made in many cases noble trees, with
trunks that girth from 25 to 40 inches. Their growth has been lessened
in recent years by light rainfall, as most of them stand within sixty
feet of the edge of the mesa. In point of drought-resistance E. coryno-
calyx, E. rostrata, E. paniculata, and E. globulus are among the best.

The younger grove on the upper mesa was begun in the spring of 1897,
when about eight hundred trees were set out, representing thirty-one
species. Other trees have been added since. The soil is light and poor,

SANTA MONICA FORESTRY SUBSTATION — EUCALYPTUS GROVES.

93

96

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

California. It is evident that crosses of the best eucalypts are likely to
produce valuable results, giving possibly (a) finer and more free blos-
soming, and hence greater value for ornament and as honey-yielders;
(b) better growth, more hardiness, or other economic advantages.

Among all the newer species, however, none are more striking in
appearance than E. ficifolia, by far the most brilliant, medium-sized tree
of the family. In some respects even more graceful and ornamental is
the famous E. sideroxylon var. rosea, a superb, quite hardy, drought- resist-
ing species of much larger growth than E. ficifolia. Its dark, red-brown
bark, bluish foliage, and elegant, half-weeping branches, give it a dis-
tinguished appearance in any collection, and the largest specimen at the
substation, a plate of which, made in 1896, is herewith shown, has
increased in size steadily since that date. Younger trees make good
growth and bloom early. There is no more promising species for general
ornamental planting in southern California. E. calophylla, which has
been widely planted, is a very showy species, but if E. sideroxylon var.
rosea were more generally known it would probably take the lead.

The following periods of the eucalypts range over the entire year, and
those who plant collections of these valuable trees never need be without
blossoms. The following notes apply not only to Santa Monica, but
also to the whole seacoast region south of Santa Barbara:

Months. Species Usually Blooming.

January and February Amygdalina, globulus, leucoxylon, occidentalis, polyan-

thema, robusta.
March and April Amygdalina, diversicolor, eugenoides, leucoxylon var.

rosea, marginata, meliodora, obliqua.
May and June.... ..Citriodora, corynocalyx, diversicolor, eugenoides, gunni,

obliqua, paniculata, rostrata, stuartiana.
July and August Buprestium, calophylla, ficifolia, corynocalyx, "Sewell's

Red," macrorhynchus, etc.
September and October . -..Alpina, calophylla, ficifolia, corymbosa, cornuta, leh-

manni, etc.
November and December Alpina, corymbosa, diversicolor, globulus, occidentalis,

robusta, polyanthema, saligna, etc.

The New Grove of 1901. — There were some three hundred trees planted
in January, 1901, at the northern end of the middle mesa. Their growth
has been excellent, as shown by the following table. In a few cases
measurements were again taken in May, 1902, to show the excellent
spring growth, and these notes follow the table. These trees have received
no irrigation since planting. Those from Department of Agriculture
seed are indicated by the numbers in the second column of figures:

Name.

E rudis X rostrata

128

E. botryoides X rostrata

130

E rostrata X resinif era

127

E maculata

119

E. sp. .-

115

E. stellulata

120

E longiflorus .

105

E pilularis - -

E macrocarpa - - ..

118

E raveretiana

125

E obtusiflora

122

E sp - --

114

E pauciflora

108

E macrandra

117

E sp

* - 116

E. eximia ..

160

U. C. No. Govt. No.

1652
1672
1678
1670
1646
1635
1651
1609
1657
1644
1663
1654
1633
1617
1643
1639
1625

Size When
Planted.

15 in.

16 "
15 "
18 "
10 "
16

8
10

8

12
10
10
12

Size in Jan., 1902.

Height. Girth.

10 ft. 7

in.

8 " 8

"

5

5

u

8

8

u

8

7

"

6

5

"

6

7

1

4

10/-£

1

5

7

(

6

5

1

7

8

1

5

5

M

6

5

"

2

' IK

"

1

K

"

6 ' 3

"

6 " 3X

"

SANTA MONICA FORESTRY SUBSTATION — EUCALYPTUS GROVES.

97

Name.

E. punctata var

E. salmonophloia

E. sieberiana

E. stricta

E. McArthurii _.

E. robusta

E. corynocalyx

E. rubida

E. stuartiana

E. pulverulenta _.

E. globulus _

E. rostrata ... •__

E. resinifera var.grandiflora..

E. siderpxylon

E. tereticornis _.

E. redunca

E. obcordata ._

C. No. Govt. No.

164

168

170 1675

171

161

1668
1620

167
36
163

1676

20

27

9

29

165

162

Size When

Planted.

12 in.

8 "

8

12
18
15
12
16

S

15
15
18
18
12

6

6

Size in Jan., 1902.

Height. Girth!

9 ft. 8

in.

3

2^

8

5

3

4

M

10%

8

«(

7

6

»

9

7

•«

11

11A

12%

8

5

«

13

9

«'

9%

7

M

10

6

"

7

5

"

8

5

"

12

fc

2

3

<(

Notes on Eucalypts from the Department of Agriculture. — No. 1652,
E. incrassata, the "Mallee" gum, increased 2 feet in height between
January and May, 1902. This species stands up fairly well against the
wind, but some specimens are crooked and poor.

No. 1672, E. rudis X E. rostrata, is more stocky than the preceding
and promises good results. The permanent leaves show considerable
variation in different plants, as if the type were not yet fixed.

No. 1678, E. botryoides X E. rostrata, known in France as E. Trabuti,
is a very interesting tree. While slower in growth than many species,
it is now gaining (growth from January to May, 1902, was 3 feet).
The trees are remarkably uniform in appearance and incline to spread.

No. 1670, E. rostrata X E. resinifera, has also shown rapid spring
growth, average plants girthing 1 inch more in May than in January
and standing 2 feet higher. The rostrata blood shows very plainly in
this cross. It is worthy of extended trials.

No. 1646, E. maculata, the "Morrel Gum"; No. 1617, E. pauciflora,
the "White Gum"; No. 1616, E. globulus, the well-known " Blue Gum";
No. 1622, E. crebra, the "White Ironbark," and some others are
already represented by large trees, as well as in the new planta-
tions. The best young specimen of E. globulus measured May 1st was
17 feet high and girthed 12 inches.

No. 1635, received as "a species," is otherwise noted in the Inventory
as E. gracilipes, which is said to resemble E. leucoxylon. It is a slow
grower here, and does not as yet seem superior to leucoxylon.

No. 1633, also unnamed when received, is E. gomphocornuta. Its
growth is practically identical with that of No. 1643 (E. macrantha),
which is extremely poor. It evidently requires more rainfall and a
heavier soil.

No. 1639, which came unnamed, but was inventoried as E.jugalis,
a " small tree 25 to 30 feet high," is a very beautiful species, much
resembling in tint, odor, and appearance a half-dwarf E. globulus.
The plant is more graceful, and the first leaves somewhat more pointed.
Its growth averages 6 feet, as against 15 feet for E. globulus. This
species should have value for ornamental planting.

No. 1609, E. largiflorens, the "bastard box," a valuable timber tree,
grows very slowly compared with other species. E. pilularis, the Black-
butt (No. 1657), does somewhat better, and E. stellulata, the "Green
Gum" (No. 1651), exceeds by a trifle such species as E. macrocarpa and

7

98 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

E. eximia of the same age and under similar conditions. E. raveretiana,
the "Gray Gum" (No. 1663), is considerably better in point of growth
than any of these.

One of the most striking of the new eucalypts is E. stuartiana (No.
1676), also received from other sources. Trees of this, on May 1st, were
14 feet high and girthed 11 inches. E. corynocalyx, the noted "Sugar
Gum'* (No. 1620), grew 3 feet between January and May, and is also
one of the best in appearance among the species in this plantation.

Other New Eucalypts. — Several species or sub-species, not heretofore
named, have done very well. One of the very best of these is E. punc-
tata var. grandiflora, of excellent upright and rapid growth. E. resinifera
var. grandiflora is another of striking appearance. Both the above have
made trees 12 feet high in fifteen months after planting out, and both,
like E. rostrata and E. corynocalyx, are worth the serious consideration
of planters. E. rubida has done nearly as well, and is also a desirable
species. E. McArthurii yields badly to tlie sea winds. E. stricta has
grown slowly and very poorly. E. obcordata, while very slow in growth,
is a handsome shrub.

Distributions of Seed and Trees. — Eucalyptus seeds gathered at this
substation were to some extent distributed locally. Trees of new and
rare species to the number of 4,000 were distributed to such applicants
as agree to make future reports. Among those receiving trees were the
American Beet Sugar Company at Oxnard, the Hollywood Cemetery
Association, the Imperial Land Company, Senator Thomas R. Bard,
Mr. T. P. Lukens, Mr. Theodore Payne, and Mr. W. L. Clay berg. These
trees were sent to widely scattered points, from Indio and Imperial to
Santa Barbara and Antelope Valley. Many small lots of a dozen
named trees were sent out. The number of species distributed was
twenty-five, including E. ficifolia and other ornamental sorts, E. corym-
bosa, E. polyanthema, and other honey eucalypts, and E. corynocalyx, E.
rostrata, and other timber and drought-resisting species.

Hillside Planting. — In 1901 and 1902 a number of eucalypts were
planted on the newly-cleared hillslopes. In places these were too steep
to plow and the trees were "pocketed in." The results have been very
satisfactory, not one out of four hundred trees having been lost. Most
of the species represented in the new plantation on the middle mesa
were used here also, together with a few represented only on the upper
mesa. In all, nearly thirty species were set on this slope. On similar
slopes, pines (P. insignis and P. austriaca) and six species of acacias
were planted at the same time and have made a good start. Each of
these trees received a quart of water when planted out.

ACACIAS.

In previous reports attention has been called to the value of the
tanbark acacias for otherwise waste lands wherever the winter tempera-
ture does not fall below 22° Fahr. A full account of the yield of eight-
year-old trees of Acacia decurrens, A. mollissima, and A. pycnantha,
together with analyses, appears on pages 227-230 of the Report for
1897-8. The remaining portion of the acacia grove therein reported
upon suffered much from drought in 1898-1900, but the past two winters-

SANTA MONICA FORESTRY SUBSTATION ACACIAS.

99

100 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

have greatly aided it. Young trees planted out in the winter of 1901
and the present season have also done very well indeed.

Drought- Resistance. — All observations at the substation confirm the
view that on the light, gravelly wash of the mesa, the large tanbark
acacias stand the drought somewhat better than do the eucalypts. Seed-
ling trees also frequently spring up in the grove. With good' cultivation,
a grove of A. decurrens or A. mollissima can be established in such soil
without any irrigation and with an annual rainfall of only 10 inches.

The largest specimen of A. decurrens, now twelve years old, girths
3 feet 9 inches, measured breast-high; this surpasses both A. mollissima
(largest tree, 2 feet 10 inches) and A. dealbata (largest tree, 2 feet 4
inches). A. cyanophylla, a low, shrub-like, much-branched tree, quite
unlike the two preceding species, which rise to 40 and 50 feet, has in
the case of the largest specimen a trunk girthing 3 feet 1 inch. All these
stand on soil similar to that of the older eucalypts and have suffered
less in times of drought.

Acacia melanoxylon,, whose beautiful rosewood-like timber only needs
to be better known to be demanded among cabinet-makers, has now,
in 1902, fully recovered from its severe suffering in the years of
drought, when one half of the large trees of this species ceased growth
and some died. This recovery when the annual rainfall rose from
about 6 inches to nearly 12 inches is interesting, but the profitable
growth of this riverine species for timber is evidently limited to regions
of more rainfall and better soil. Nevertheless, the largest standing tree
of A. melanoxylon, aged twelve years, girths 3 feet 8 inches.

The rapidity of growth of A. melanoxylon is hardly surpassed by any
other species, and it reproduces itself freely from root-cuttings or suck-
ers as well as from seeds. One large tree removed in 1899, because it
died in the ground, threw up a multitude of suckers scattered over a
large area. Nine of these have been left at spaces of from 10 to 20 feet
apart; they average a height of 18 feet and a girth of 15 inches.
Fed, of course, by the old roots, this growth far surpasses that from
seeds. In suitable locations, however, a wood-lot of A. melanoxylon
could be trusted to reproduce itself from the roots. The fuel value of
the wood is high.

Other Acacias. — A new collection of acacias was planted out in the
spring of 1901, and with previous plantings and a few set in the spring
of 1902, the total representation of acacias is now nearly thirty species.
One of the most striking of these is A. Baileyana, a very ornamental
tree. A. verticillata and A. linifolia} both species of small growth, have
attracted much attention.

OAKS AND OTHER HARDWOOD TREES.

English Oak (Quercus robur). — The English oak has now received a
thorough test here on all the levels. Many trees promised well until about
1897. The largest, twelve years planted, now girth from 14 inches to
21 inches, a foot from the ground, and this would be excellent if the
trees were healthy. But four out of five of the trees this age are dead
or dying at the top. A few are 16 feet high; the tallest healthy tree is
but 13 feet. The growth is seriously affected, as elsewhere on the coast,

SANTA MONICA FORESTRY SUBSTATION — ACACIAS. 101

by the little "oak wasp" (Andricus sp.), and the whole tendency of
the tree is to grow shrubby and crooked. It has taken much pruning
and suckering to keep them in shape. The tree is therefore practically
useless here for timber purposes, as are all the oaks tested at this sub-
station.

The Japanese species need better soil and more water; the Eastern
oaks grow very slowly indeed. In the canon the native coast live oak
(Quercus agrifolia) grows very well, and there are some good trees of
this species on the substation tract. Its growth is checked by caterpillars.

Black Locust. — This well-known tree remains the leading small hard-
wood adapted to this climate. It thrives on the middle mesa without
irrigation, and reproduces readily from self-sown seed. Few trees have
stood the severe droughts better. Trees can be grown here with trunks
of 8 or 10 inches in diameter in twelve years. This tree in recent years
has been much neglected; its value for fuel and fence-posts, as well as
for various hardwood uses, justifies more general planting.

The Casuarinas. — No species of hardwood trees have proved more
drought-resistant here than the larger casuarinas. C. suberosa is one of
the best. C. glauca has done well. The largest trees of C. suberosa, now
twelve years old, show trunks 6 feet to lowest branches and girthing from
2 feet 2 inches to 2 feet 10 inches. Such growth gives evidence of the
great value of casuarinas to tree-planters.

Zelkova keaki.— This Japanese hardwood tree needs more rain; other-
wise, the climate is well adapted to its growth. It develops, however,
too slowly in California to be of value anywhere when compared with
other species of hardwoods.

Ashes. — After long trial of five species, including the European White,
American White, etc., the Arizona ash (Fraxinus velutina) proves by far
the best for this locality. So well does it grow from seed that a planta-
tion, if rainfall or irrigation up to an average of 15 inches per annum
can be obtained, should be profitable. Here, with an average of only 10
inches, the tree, though making a good start, does not equal the common
black locust, the casuarina or the best acacias ; but it is exceedingly
drought-resistant.

Maytenus boaria. — This little Chilian hardwood tree has taken hold
remarkably here, growing fast without irrigation. Its value for orna-
mental purposes is undoubted, but its hardwood value depends on rate
of growth, which is greater here than at Berkeley, with greater rainfall.

Other Hardwood Trees. — There are many interesting and valuable
trees in the arboretum here which have proven their adaptation to the
locality, and some of these deserve especial mention.

Seed of the Schinus terebinthifolius, a new and large-leaved pepper
tree, was locally distributed last season. The demand is great and
increasing. It is a much more bright-leaved, healthy, and attractive
tree than the common pepper tree (Schinus molle)j and should in great
degree supersede it. As in the case of the common species, the berries
are red and handsome; the leaves and general growth are superior. It
was planted on a dry hillside and has received no irrigation.

102 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

CHLCO FORESTRY SUBSTATION.

(Situated one mile east of Chico, near the Sierra foothills; elevation, 230 feet.)

In previous reports the history of this substation has been given, and
need not be repeated. Three years' further experience with the location
only makes more evident its great value as regards soil, climate, and
facilities for the cheap and rapid production of fine forest trees, or for
any agricultural experiments.

Five acres as yet unplanted remain at the western end of the tract,
and the soil there is extremely rich. The vacant land at the upper or
eastern end of the tract is more sandy, though still excellent for tree
growth.

Since 1898 the substation has been carried on at a reduced expense,
using the Rancho Chico teams and labor and paying merely the actual
cost. A workman has occupied the small house on the grounds and has
kept the place in order, working elsewhere when not needed at the sub-
station. In 1901, Mr. T. L. Bohlender, formerly in charge of the Chico
nursery and later the ranch foreman, made an agreement by which he
gives a portion of his time to supervision of the work at the substation,
and this arrangement continues.

The substation, however, needs the entire time of some competent
person, as at Santa Monica, or it might with advantage be developed
hereafter into a substation fully equal in importance to that near
Pomona, for not less than five acres of its area can be devoted to agri-
cultural experiments without seriously infringing upon its forestal
value. Besides, it is probable that a larger area can be secured when
needed for strictly forestry work. At all events, the foundation for a
most useful Sacramento Valley substation exists at Chico, where also
sufficient trees can be easily and cheaply grown to cover the entire
eastern or hill portion of the University tract at Berkeley.

There have been no other changes in local management. Mr. V. C.
Richards, editor of the Chico " Record/' appointed Patron in 1897,
still holds that office. Colonel C. C. Royce, manager of Rancho Chico,
and Mrs. Bidwell, the owner of that famous place, have continued their
interest -in the station.

Eucalyptus Planting. — The most important extension planned for is
that of the eucalypts at the eastern end of the tract. About four
thousand trees of E. rostrata and other hardy species are being grown
for planting here in the autumn of 1902. They are now in seed-boxes
and will be set out with the first rains.

CLIMATIC CONDITIONS.

There is very little difference in climate between the town of Chico
and the substation. Some seasons the cold is less at the latter place,
but severe frosts are about the same everywhere along the creek. In

CHICO FORESTRY SUBSTATION — CLIMATE. 103

fact, some of the orchards which have suffered most are several miles
east of Chico, and at a considerable elevation. Only a few species of
acacias do well here, and the eucalypts are also limited in their adapta-
tion to this region. The growth of the conifers is enormous, and that
of many oaks and ashes is also unusually great. The rainfall is excel-
lent; the summer heats are modified by the trade winds.

Rainfall. — The average rainfall of the Chico district, based on observa-
tions since 1870, is somewhat over 25 inches. It has fallen as low as 12
inches, and has risen to more than 50 inches, but these extremes very
rarely occur. The following table shows the rainfall for the past seven-
teen years, the average of which, disregarding 1901-2, which is not quite
complete at this date, is 26.64 inches:

RAINFALL FROM SEPTEMBER, 1885, TO APRIL, 1902.

cpn(8mi Total Period in which

Rainfall. Some Rain Fell.

1885-6 31.13 in. 7 months 12 days.

1886-7 17.16 " 7 ' 28 "

1887-8 14.49 " 7

1888-9 _ 21.50 " 9

1889-90 52.71 " 7

1890-1 _ 23.46 " 9

1891-2. 22.40 " 7

1892-3 _ 33.50 " 7

1893-4 _ 23.32 " 10

1894-5 34.56 " 7

1895-6 25.54 " 7

1896-7 _ 22.44 " 9

1897-8... 12.81 " 7

12
11
5

10
12
10
4
28
1

20
2

1898-9 18.45 6 ' 5

1899-1900 24.89 " 7 " 1

1900-1 27.22 " 7 " 22

1901-2.... 1996 " 7 " 22 "

There is a good deal of early summer rain in this region, lengthening
the season. The rains have commenced as early as August 30th, but
the usual time is in late September or early October. They have con-
tinued until July llth, in showers after April, excellent for many crops,
but injuring cherries, hay, etc. The rainless period is comparatively
short here, and the growth of all kinds of trees suitable to the climate
is therefore stimulated. No other portion of California with which I am
acquainted has shown such rapid growth of the native white oak ( Quer-
cus lobata), nor such large groves of second-growth trees springing up
since the American occupation, and this must be attributed in great
measure to the favorable rainfall.

Temperature. — The observations of the past twenty years give an aver-
age winter temperature of 46.6° Fahr., an average summer temperature
of 81.3°, and an average annual temperature of 63.8°. The lowest
temperature of the period was 18°, and the highest was 115°.

The following table shows the temperature day by day during 1899,
1900, and 1901, as furnished by Colonel C. C. Royce, and kept on Rancho
Chico. These temperatures were taken from a point fifteen feet above
the ground, and the minimums therefore show from 5° to 8° lower than
would be the case if .taken in the town, on the plan of the Weather
Bureau, from the top of a high building. They were taken for agricul-
tural purposes, and show the actual conditions to which vegetation at
the forestry station and the adjacent district is subjected:

102 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

CHICO FORESTRY SUBSTATION.

(Situated one mile east of Chico, near the Sierra foothills; elevation, 230 feet.)

In previous reports the history of this substation has been given, and
need not be repeated. Three years' further experience with the location
only makes more evident its great value as regards soil, climate, and
facilities for the cheap and rapid production of fine forest trees, or for
any agricultural experiments.

Five acres as yet unplanted remain at the western end of the tract,
and the soil there is extremely rich. The vacant land at the upper or
eastern end of the tract is more sandy, though still excellent for tree
growth.

Since 1898 the substation has been carried on at a reduced expense,
using the Rancho Chico teams and labor and paying merely the actual
cost. A workman has occupied the small house on the grounds and has
kept the place in order, working elsewhere when not needed at the sub-
station. In 1901, Mr. T. L. Bohlender, formerly in charge of the Chico
nursery and later the ranch foreman, made an agreement by which he
gives a portion of his time to supervision of the work at the substation,
and this arrangement continues.

The substation, however, needs the entire time of some competent
person, as at Santa Monica, or it might with advantage be developed
hereafter into a substation fully equal in importance to that near
Pomona, for not less than five acres of its area can be devoted to agri-
cultural experiments without seriously infringing upon its forestal
value. Besides, it is probable that a larger area can be secured when
needed for strictly forestry work. At all events, the foundation for a
most useful Sacramento Valley substation exists at Chico, where also
sufficient trees can be easily and cheaply grown to cover the entire
eastern or hill portion of the University tract at Berkeley.

There have been no other changes in local management. Mr. V. C.
Richards, editor of the Chico " Record/' appointed Patron in 1897,
still holds that office. Colonel C. C. Royce, manager of Rancho Chico,
and Mrs. Bid well, the owner of that famous place, have continued their
interest -in the station.

Eucalyptus Planting. — The most important extension planned for is
that of the eucalypts at the eastern end of the tract. About four
thousand trees of E. rostrata and other hardy species are being grown
for planting here in the autumn of 1902. They are now in seed-boxes
and will be set out with the first rains.

CLIMATIC CONDITIONS.

There is very little difference in climate between the town of Chico
and the substation. Some seasons the cold is less at the latter place,
but severe frosts are about the same everywhere along the creek. In

CHICO FORESTRY SUBSTATION — CLIMATE.

103

fact, some of the orchards which have suffered most are several miles
east of Chico, and at a considerable elevation. Only a few species of
acacias do well here, and the eucalypts are also limited in their adapta-
tion to this region. The growth of the conifers is enormous, and that
of many oaks and ashes is also unusually great. The rainfall is excel-
lent; the summer heats are modified by the trade winds.

Rainfall. — The average rainfall of the Chico district, based on observa-
tions since 1870, is somewhat over 25 inches. It has fallen as low as 12
inches, and has risen to more than 50 inches, but these extremes very
rarely occur. The following table shows the rainfall for the past seven-
teen years, the average of which, disregarding 1901-2, which is not quite
complete at this date, is 26.64 inches:

RAINFALL FROM SEPTEMBER, 1885, TO APRIL, 1902.

Season.

1885-6 ....
1886-7--..
1887-8....
1888-9.-.
1889-90...
1890-1....
1891-2....
1892-3... .
1893-4-...
1894-5....
1895-6....
1896-7— .
1897-8....
1898-9....
1899-1900.
1900-1 .-
1901-2...

Total
Rainfall.

31.13 in.

17.16

14.49

21.50

52.71

23.46

22.40

33.50

23.32

34.56

25.54

22.44

12.81

18.45

24.89

27.22

1996

Period in which
Some Rain Fell.

7 months 12 days.

7

28

«

7

12

«

9

11

«f

7

5

"

9

10

«

7

12

' 1C

7

10

M

10

4

1C

7

28

((

7

1

((

9 .

20

•«

7

2

M

6 " 5

"

7 " 1

((

7 " 22

II

7 " 22

«

There is a good deal of early summer rain in this region, lengthening
the season. The rains have commenced as early as August 30th, but
the usual time is in late September or early October. They have con-
tinued until July llth, in showers after April, excellent for many crops,
but injuring cherries, hay, etc. The rainless period is comparatively
short here, and the growth of all kinds of trees suitable to the climate
is therefore stimulated. No other portion of California with which I am
acquainted has shown such rapid growth of the native white oak ( Quer-
cus lobaia), nor such large groves of second-growth trees springing up
since the American occupation, and this must be attributed in great
measure to the favorable rainfall.

Temperature. — The observations of the past twenty years give an aver-
age winter temperature of 46.6° Fahr., an average summer temperature
of 81.3°, and an average annual temperature of 63.8°. The lowest
temperature of the period was 18°, and the highest was 115°.

The following table shows the temperature day by day during 1899,
1900, and 1901, as furnished by Colonel C. C. Royce, and kept on Rancho
Chico. These temperatures were taken from a point fifteen feet above
the ground, and the minimums therefore show from 5° to 8° lower than
would be the case if .taken in the town, on the plan of the Weather
Bureau, from the top of a high building. They were taken for agricul-
tural purposes, and show the actual conditions to which vegetation at
the forestry station and the adjacent district is subjected:

104

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.
TEMPERATURE RECORDS AT RANCHO CHICO.

1899.

1900.

1901.

January.
Temperature —
Mean for month (Pahr.)

53°

. . 48°

44.9°

Warmest day. . . __ .

27th 75

6th, 17th . 62

16th 62

Coldest day

4th 29.5

24th . 30

1st 23

Range

455

32

39

Greatest daily variation

24th 31

9th 23

19th 29

Least daily variation

18th 5

28th 3

2d 6

Mean daily range

17 5

11.4

172

Mean lowest

46

42

36

Mean highest _

. .. 59

54

. 53.9

Frost on

8th 12th 23d 24th

9th 10th llth

7th 15th 16th 23d

Rain on

6th 7th 9th llth

25th.
lst-5th 12th 15th

26th, 28th.
3d 4th 6th 8th

Fog on

13th-15th.
17th 18th.

18th, 28th.
12th-15th, 18th-

10th-14th, '20th,'
21st, 24th, 31st.
13th 14th 29th

Ice on

22d, 29th-31st.
24th.

30th.
1st 9th 10th 17th

February.
Temperature —
Mean for month .

51

50.3

19th, 29th.

48.5

Warmest day

19th 79

24th . 70

28th 77

Coldest day

6th 24

7th, 9th 33

10th 26

Range

55

37

51

Greatest daily variation

18th 31

23d 31

lUth 32

Least daily variation ..

28th . . 7

7th 2

5th, 13th 8

Mean daily range _

23.7

19.3

18.9

Mean lowest

39.1

39.8

39.1

Mean highest ,

63

60.7

58

Frost on

10th, llth 25th.

5th-7th, 9th, llth,

Rain on

28th.

12th, 23d, 27th,
28th.
1st, 2d, 17th-20th.

2d-5th, 7th, 13th,

Fog on ...

25th.
2d, 3d.

16th, 18th-20th.

Ice on .

4th, 5th, 6th.

Hailstorm, 18th.

1st, 6th, 10th, llth.

March.
Temperature —
Mean for month

538

57.3

Snow on 7th, 8th.
54.9

\Varmest day

6th 74

13th 8L

5th 78

Coldestday

10th 30

28th. 33

31st . 34

Range

44

... 48

.... 44

Greatest daily variation

6th 35

28th 36

19th . ..33

Least daily variation

15th . 3

7th . 4

4th . .3

M can daily range

204

23.4

23.4

Mean lowest

43.6

45.5

42.2

Mean highest

64

691

67.5

Frost on

10th, 13th, 30th.

28th.

8th, 13th-15th,

Rain on . . _ ...

7th, 8th, 12th, 14th,

3d, 4th, 6th-8th,

28th-31st.
9th, 10th, 22d, 25th,

Ice on

15th, 17th, 19th-
20th, 22d-24th,
31st.
13th.

19th.
Hail, 4th.

27th, 28th.

April.

Temperature—
Mean for month

59.9

57.3

. 55.9

Warmest day

21st 87

17th, 18th 8L

13th 81

Coldest day

29th 36

9th 35

4th 30

Range

51

46

51

Greatest daily variation

29th 39

17th » 36

10th . . .1 40

Least daily variation

23d 14

llth 3

5th 3

Mean dailv ranse

28.2

23.7

25.2

Mean lowest

45.8

45.2

41.7

Mean highest ..

.. 74

.. 69.3

.. 70.1

CHICO FORESTRY SUBSTATION — CLIMATE.
TEMPERATURE RECORDS AT RANCHO CHICO — Continued.

105

1899.

1900.

1901.

April — Continued.
Frost on

24th, 25th,

28th,

9th.

3d, 4th, 6th-10th,

Rain on

29th.
24th, 30th.

1st, 2d, 6th, llth,

22d.
2d, 5th, 28th, 29th.

May.
Temperature —
Mean for month

62°

12th, 19th-21st,
30th.

64.8°

63.7°

Warmest day

10th

96

31st 92

31st 92

Coldest day

1st

38

llth, 27th... 44

19th 41

Range

58

48

51

Greatest daily variation

12th

39

20th, 30th 26

8th .. 38

.Least daily variation

31st

14

4th 16

24th . 13

Mean daily range

275

283

. 27.2

Mean lowest

479

51.8

50

Mean highest

75

77.7

77.4

Frost on

1st 2d 15th

Rain on

23d-25th,

28th,

1st, 3d-5th, 9th-

1st, 24th, 25th, 27th.

June.
Temperature —
Mean for month

31st.

745

12th.
70.4

Fog on 29th.
.. 71.2

\Varmest day

16th

104

6th llth 102

28th 103

Coldest day

2d

46

16th 48

12th 44

Range

54

54

59

Greatest daily variation

16th

44

5th .. . 43

13th, 27th... 38

Least daily variation

1st 24th

15

21st 16

4th . .... 21

Mean daily range

301

30

30.5

Mean lowest

598

58

55.2

Mean highest

89.3

... 82.8

87.1

Rain on

1st, 18th, 24t

h.

15th, 21st.

July.
Temperature-
Mean for month

777

78.7

78.6

\Varniest day

18th 19th

105

7th 8th 104

6th,27th,31st.l01

Coldest dav

6th

52

2d 54

2d, 13th 52

Range

53

50

49

Greatest daily variation

8th

41

7th 44

19th, 20th ... 41

Least daily variation

29th

18

22d . 22

llth 12

Mean daily range

335

30.5

32

Mean lowest

608

-. 62.6

.... 62.7

945

94.9

94.4

August.
Temperature —
Mean for month

72.2

72.2

.. 75.1

\Varmest day

1st 30th

92

1st 3d 99

2d 104

Coldest day

27th 28th

49

21st 51

22d 49

Range

43

48

55

Greatest daily variation

1st

38

1st 42

llth 39

Least daily variation

17th

17

6th 20

17th 8

29.2

29.6

29

56

. 56.4

59.4

883

. 88

90.8

Rain on

3d 4th 6th.

September.
Temperature —

72.7

. . 64.5

. 66.7

Warmest day

24th

99

1st 94

14th, 15th,

Coldest day

6th, 7th

. 47

27th, 30th ... 44

16th, 17th. 92
24th 42

Range

. 52

50

50

Greatest daily variation

23d

44

1st, 29th, 30th 36

8th .... 37

Least daily variation

28th

25

8th 8

23d .. 10

Mean daily range

352

26.3

..27

Mean lowest

55

52

53.4

Mean highest

903

79

.. . 80

Rain on ._

llth, 12th.

22d, 23d, 25th.

106 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

TEMPERATURE RECORDS AT RANCHO CHICO — Continued.

1899.

1900.

1901.

October.
Temperature —
Mean for month

58.8°

583°

652°

Warmest day

8th 96

8th 82

12th 89

Coldest day

15th 24th 37

30th 35

29th 41

Range __.

.. 59

47

- - 48

Greatest daily variation .

6th 41

8th 36

llth, 12th 36

Least daily variation .. .

20th . 5

4th . 7

26th 12

Mean daily range - _

23.9

23

25.4

Mean lowest

46.8

... 468

532

Mean highest

70.8

69.7

771

Frost on

24th 27th.

25th.

Rain on

10th 12th 13th

2d, 3d 4th llth

17th 23d 25th 28th

November.
Temperature —
Mean for month

19th-22d, 29th,
30th.

53.9

18th, 19th, 27th,
30th, 31st.

52.9

544

Warmest day

13th, 14th 69

12th 74

3d 74

Coldest day

22d 36

28th, 29th 35

12th 36

Range

33

39

38

Greatest daily variation

2d 31

llth 31

4th. ... 31

Least daily variation . _

llth 9

24th 5

19th, 23d 5

Mean daily range

. 18.5

193

19

Mean lowest

. . 44.6

42.5

44.9

Mean highest

63.1

63.3

638

Frost on

23d.

28th.

llth 12th

Rain on

3d 8th 9th llth

7th 15th, 16th

9th 15th 16th 19th

Fog on .

12th, 15th, 16th,
18th, 21st, 23d,
25th-29th.

17th, 19th, 20th,
21st, 24th, 25th,
30th.
1st, 23d, 27th, 29th.

20th, 23d, 28th.

December.
Temperature-
Mean for month

48.1

457

468

Warmest day

2d, 3d 64

21st .. 66

2d .. 68

Coldest day

20th 28

31st 23

16th 26

Range

36

. . 43

42

Greatest daily variation

1st . . 24

27th, 28th 25

20th, 3Ist 30

Least daily variation

llth 6

10th 3

3d . 1

Mean daily range

15

12.7

19.5

Mean lowest

44

39.1

37

Mean highest

522

522

565

Frost on

1st, 6th, 17th, 18th.

1st, 23d, 27th.

7th, 22d, 26th, 28th.

Rain on

4th, 7th-llth,

12th, 14th, 16th-

2d, 3d, 5th, 9th.

Fog on

14th-16th, 29th-
31st
3d, 4th, 20th-29th.

20th.
2d 13th, 25th,

Ice on

13th 19th 20th.

26th, 29th.
28th, 30th, 31st.

llth 21st, 29th.

STUDIES OF TREE GROWTH.

The fitness of this district to rapid growth of trees is illustrated by
almost every measurement taken since the establishment of the station.
Cultivation has been given to all the trees when small. The larger
conifers now cover the ground so completely that cultivation is no longer
necessary or practicable.

THE CONIFERS.

The most striking feature of the substation consists of large pines,
cypresses, sequoias, and other conifers planted in blocks. The following
table shows the comparative growth of a few species:

CHICO FORESTRY SUBSTATION — STUDIES OF TREE GROWTH.

107

TABLE I. REPRESENTATIVE CONIFERS.

Name.

Araucaria Bidwelli

Chamsecyparis Lawsoniana ..

Cupressus sempervirens

Pinus austriaca

Pinus insignis

Pinus resinosa

Pinus sylvestris

Pseudotsuga taxifolia .._

Sequoia gigantea

Sequoia sempervirens

No. of Trees
Measured.

1
5
5
5
5
5
5
5
5
5

Av. Size, Oct., 1897.

Size, Oct., 1901.

Height.
12ft.
18
26
18
25
22
16
11
27
22

Girth.

6 in.
22
18
16
2*
17
14

8

36
16

Height.
20ft.
21
42
22
32
38
21
16
42
43

Girth
Sin
30

36
21
42
36
24
15
48
46

These trees are in age fourteen or fifteen years from seed, but no record
was kept at the station by those in charge before the University assumed
control. There is but one Araucaria, and it stands too close to large
oaks to have a fair chance. The numbers of the other species range
from 10 (Pseudotsuga) to 400 and 500 (Pinus sylvestris and Cupressus
sempervirens). The trees chosen stand on the outside of the blocks
which are now being thinned.

The only difficulty in regard to the continued development of these
blocks of conifers and the maturing of as large a timber-crop as this
soil can possibly carry, lies in the nature of some of the root systems in
transplanted trees. When a block of 225 trees of Pinus resinosa was
partially thinned in the spring of 1902, a violent gale from the north
blew down several of the standing trees, and showed conclusively that
the roots of conifers planted in sacks, as these were in 1889, are
more or less prevented from properly descending. There is no reason
why much smaller conifers should not be used, or seeds sown under
temporary shelter plants. In all cases where deep-rooted, healthy trees
are desired, pines and other conifers can be transplanted from boxes
when only a foot high, in small " puddled " balls of earth, without the
use of sacks. Certainly the sacks should always be removed, not merely
slashed across.

Self-sown seedlings already show in the groves, and the reproductive
powers of any natural forest in this district, if properly protected, are
evidently great. Allusion has been made to the rise of large oak groves,
but no less interesting is the extent to which young Pinus sabiniana
thickets abound on Rancho Chico. This forestry station shows on
every hand satisfactory natural increase of many species, coniferous
and deciduous.

Further Notes on Conifers. — There were two cedars, Cedrus deodara
and Cedrus Libani, planted in 1895 at the eastern end of the substation.
The former has far outgrown the latter, and is 23 feet high, with
branches touching the ground; the latter is but 13^ feet high.

The Italian cypresses (C. sempervirens) are in some cases nearly 50
feet high, and are superb trees. Many are heavily branched, and the
lower branches in these blocks begin to fall, but the columnar specimens
still receive light on all sides.

The best block of Pinus austriaca averages over 25 feet high, with
girths that often equal or exceed 20 inches, but the specimens tabu-
lated were from a block of somewhat smaller size.

The growth of conifers in the mixed forest planted in January, 1895,
affords the best illustration the substation can give of the ease and

108 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

rapidity of tree-growth here. The conifers are rapidly taking posses-
sion of the entire ground, and the larger maples, walnuts, catalpas,
paulownias, and mulberries scattered through this two-acre plantation
have been removed, leaving, however, many deciduous trees. All the
conifers here were planted out when small by Mr. Boland, then fore-
man, and have deep root-systems.

The most remarkable growths made in the mixed forest were of
Pinus sabiniana, many of which now stand more than 18 feet high.
Three measured girths of 20, 22, and 23 inches. From seed these are
but eight years old. It is a pity that the timber from this tree is not
more valuable, but its usefulness in the foothills has hardly received
sufficient attention, for it grows under very adverse conditions. The
following brief table shows comparative growths of some of the mixed-
forest conifers:

TABLE II. MEASUREMENTS OF CONIFERS IN MIXED FOREST.

Height. Girth.
18 ft. 21 in.

Name.
Pirius sabiniana

No.

Measured.
5

Age.

8 to 9

8 " 9
8 " 9
8 " 9

8 " 9
9

Pinus ponderosa

5

Pinus austriaca

5

Pinus lambertiana

5

Thuya gigantea

4

Larix eurooea ..

2

10 "

9 "
8 "
7 "
3 "

Conifers of Especial Value. — The experience of the substation leads us
to recommend several species of conifers for more general planting in
the Sacramento Valley and on the foothills. Among our native trees,
Pinus ponderosa, the great yellow pine of the Sierra takes a prominent
place. The redwood (Sequoia sempervirens) does much better than was
expected, but on drier situations will not thrive so well. The growth
and health of the Big Tree (Sequoia gigantea) shows that it may be
extensively planted for ornament and shelter. The Monterey pine,
though growing quite well, is best adapted to the coast; but the so-called
Oregon pine (Pseudotsuga) is entirely at home here. The best exotic
conifers tested are the Deodar cedar and Pinus austriaca. The latter
is not as rapid in growth as some other species, but it makes a fine tree.
There should be more attention paid by land-owners to the establish-
ment of small groves of our native conifers, especially as windbreaks.

DECIDUOUS TREES.

The largest European White Birch among several of the same age,
girths 30 inches and is 45 feet high. Its age is about fifteen years. A
group of about seventy-five younger specimens of this birch (Betula
alba), planted in 1895, small trees received by mail, are now (1902)
from 35 to 40 feet high, and four girthed, respectively, 12, 14, 15, and 16
inches. Birches generally do well in this region, and any one who
wishes may have a grove of this beautiful white-stem tree, the fastest-
growing species of birch yet tested here.

Previous reports have described the two Catalpa (C. speciosa) groves.
Small trees from self-sown seeds are frequently to be found here. The
late General Bidwell planted many catalpas and distributed trees
widely at various times from his nurseries. The average height of the
catalpas at the substation in 1897 was 30 feet, with trunks 26 inches in

CHICO FORESTRY SUBSTATION — STUDIES OF TREE GROWTH. 109

girth, breast-high. In 1902, three girthed 36, 40, and 46 inches.
Young catalpas planted in 1895, when 3 feet high, are now (1902) 18
feet high and girth 12 inches. The catalpa seems to produce on a given
area in a given time about twice the amount of wood as does the well-
known Western box-elder (Negundo Calif arnica), which is often planted
for its rapid growth. Neither species, however, begins to yield as much
wood as the paulownia.

The Paulownia imperialis of Japan is very little known, but it grows
with such rapidity here that its more frequent growing can be recom-
mended. Some remarkable measurements of this tree have been given
in previous reports. This year (1902) one was measured which in two
years had grown from an old stump to a height of 25 feet with a girth
of 15 inches and was well-branched about 15 feet from the ground.
Numbers of the older paulownia planted in 1889 are over 40 inches in
girth; three, measured "as they came,'7 were 45, 48, and 49 inches.
One of the largest, near the grove of sequoias, girths 5-J feet. The com-
mercial value of paulownia wood in California has not yet been deter-
mined, but many small articles of Japanese manufacture, such as toys,
boxes, and furniture, are made of this light-brownish timber.

Several species of Celtis (nettle-tree) have grown very fast here. The
best is Celtis australis, which, planted in 1896, now girth 12 and 14
inches and are 16 to 18 feet high. C. occidentalis, somewhat older, has
also made very fine growth. C. orientalis is much behind the others.
These are all trees of easy cultivation.

One of the disappointments here is the growth of Zelkova keaki, which
ranks as the best hardwood of Japan. A lot of trees were obtained in
1895 and several thousand trees grown. These were widely distributed,
and a block was planted here. The trees have never straightened up or
made much growth. The increase of wood is only about one quarter
that of American ash and half that of English oak. The tree does no
better anywhere else, so far as tested in California.

The Ashes ha.ve deservedly attracted attention here, and no other
hardwood better justifies planting for timber in this region, if the best
species be used. Fraxinus dimorpha is small and slow of growth, but
a beautiful ornamental. It comes from Algeria. Trees planted in 1896
are now (1902) 10 and 12 feet high, girthing 7 and 8 inches. Fraxinus
kabyla, also from Algeria, is a much more striking species. Four meas-
ured (eight years from seed) girthed 16, 18, 19, and 20 inches, and they
are 18 to 20 feet high, with fine trunks. Fraxinus oregona, of the same
age, are only two thirds as large. Fraxinus viridis is also much poorer
than F. kabyla. Fraxinus alba, however, the well-known American white
ash, ranks in point of growth somewhat nearly with F. kabyla. Trees
grown from seed in 1892 are now, ten years later, about as large as F.
kabyla trees of eight years of age, and a few are even larger. The differ-
ence so far is perhaps ten per cent in favor of the foreigners. The older
white ashes, in some cases, fourteen years of age, are very fine trees.
One is 40 feet high and 3 feet in girth, and all are nearly as large as this.
The best single ash upon the substation, considering age, is a white ash
eleven years old, planted on the main avenue. It is 30 feet high, 10
feet to the lowest branch, and girths 28 inches. The growth of ash
timber on such land as this should attract attention, as evidently in
twenty or twenty-five years some cutting could be done. The growth
of the white and the Kabyla ashes here has been about equal to that of

110

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

the strong-growing Japanese mulberry known as "Lhoo," and much
surpasses that of the white or red mulberries.

Elms are often planted in this region. Two Huntingdon elms at the
west gate, planted from the nursery in 1892, now girth 31 and 35 inches,

and have a very large spread of branches. They were in full bloom
March 29, 1902.

English Oaks are well represented here, as well as many other species
of Quercus. All have been planted since 1894, and many now bear
acorns. Those left untrimmed are " bushy," branch near the ground,

CHICO FORESTRY SUBSTATION — STUDIES OF TREE GROWTH. Ill

and are far behind those that were pruned. The latter, now from seven
to nine years old from the acorn, stand from 14 to 15 feet high, with
trunks that girth from 8 to 15 inches. One tree, which was several
years old when sent to the station, and is therefore about twelve years
from the acorn, stands 22 feet high, with a trunk circumference of 21
inches. This region is one of the best oak districts in the State, and
English oaks (Q. robur), or cork oaks (Q. suber), or any other desirable
American or European species, can be grown here.

Quercus lobata has an excellent representative in the celebrated
Hooker oak, which stands in the center of a large open glade, about a
mile from the substation. This very shapely and beautiful tree, shown
in the accompanying illustration (taken by Dr. Loughridge in 1900),
was greatly admired by Sir Joseph Hooker when in California. The
following are the dimensions as measured in July, 1894, by Mr. Boland,
the foreman of the station:

Circumference of trunk 20 feet.

Circumference of largest branch ___ 15£ "

Spread of limbs from trunk, on south 73 "

Spread of limbs from trunk, on north 63 "

Spread of limbs from east to west _ . 112 "

Approximate height _ 100 "

The largest willow trees, S. salmoni, or S. alba salmoni, grown from
cuttings planted in .1895, are over 60 feet high, and girth more than 30
inches. One of these trees is 68 feet in height, and its trunk is 38 inches
around, measuring breast-high. Cuttings of this willow have now been
widely distributed; it grows considerably faster than the common Salix
alba form.

THE EUCALYPTS AND ACACIAS.

Previous reports have described the work done with many sorts of
eucalyptus here. Their rapidity of growth is astonishing, and it would
seem that profitable plantations of certain species could be planted in
the Sacramento Valley.

The station recommends E. rostrata and E. viminalis as highly desir-
able species, whose timber is much more useful than that of E. globulus.
Few large trees of E. rostrata exist here, the earlier plantings having
been mainly of E. viminalis, but a few are scattered in the earlier plan-
tation (established in 1889), and there is no appreciable difference in
the growth of the two species. Both are desirable; the wood of E. ros-
trata is considered the more useful.

The following measurements of the older trees, now thirteen or four-
teen years from seed, will show how the red gums have increased in this
kindly soil and climate. In the old grove, five trees out of twenty- one
of E. viminalis were measured, and girthed, respectively, 46, 48, 51, 57,
and 61 inches. One girthed almost exactly 6 feet. These trees are 20,
30, and 40 feet to a branch. Trees of E. rostrata, of the same age, girthed
50, 52, 54, and 64 inches, and one was a little more than 6 feet around.

A superb grove of mixed species, rostrata, viminalis, amygdalina, and
others, averages trees of 50 to 60 inches in girth and something over 100
feet high. The largest tree here is 6 feet 6 inches in girth. Many of
these stand 8x8 feet apart, but the grove is long and narrow, receiving
light on all sides.

112 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

The hardy species of eucalyptus of the newer sorts are E. alpina,
E. acerbula, E. leucoxylon, and the superb E. Foeld-Bay, seed of which
was received from Vilmorin in 1895. This last named is by far the
best of all the new eucalypts. Planted out in 1896, when quite small,
it girths 31 inches in 1902, and bids fair to outgrow both E. rostrata and
E. viminalis.

Acacias. — The well-known A. decurrens, which suffered much from
frost here while small, has made large trees at last, several being now
53 feet high, with trunks that girth nearly 5 feet. A. melanoxylon has
never suffered seriously from frost.

CENTRAL STATION — TREE-PLANTING ON A HILLTOP. 113

CENTRAL EXPERIMENT STATION.

Berkeley, Alameda County.

TREE-PLANTING ON A BERKELEY HILLTOP.

BY C. H. SH1NN.

A significant experiment in tree-planting has been carried on for a
number of years on a high hill-top in the northeastern part of the Uni-
versity tract at Berkeley. This tract comprises 249 acres (outside of
the Hillegass tract) and rises, at first gradually, then more abruptly,
from its western frontage on Oxford street to an elevation of 950 feet
near the extreme northeastern corner. Its general appearance is famil-
iar to the public, as a contour map has been printed on many occasions.
It is sufficient to say here that the mountainous portion east of the
building site contains about 125 acres, used as pasture land.

The soil is for the most part adobe; the native vegetation, confined to
the canons, consists of coast live-oaks, laurels, willows, and lesser shrubs.
One stray madrono stands on the creek near the agricultural building.

Eucctlypts. — Considerable planting of eucalypts (chiefly E. globulus),
pines (chiefly Monterey), and other conifers was done soon after the
University was established here, but nearly all on a level below 400
feet, where the soil was deep and could be easily plowed.! The growth
of these trees has been rapid, and, in many respects, surprising. One
large block of almost two thirds of an acre, situated west of the cftider
track at the union of the two creeks, has long been recognized as one of
the most instructive eucalyptus groves of its size in this part of Cali-
fornia (see .Plate 17). There are about two hundred and fifty trees here,
the largest of which now girths 7i feet, breast-high.

The trees on the outer edge of this grove range from 40 to 90 inches
in girth, stand 8 to 10 feet apart, and often rise 40 feet without a branch;
in the middle of the grove the trees are from 18 to 30 inches in circum-
ference, but with even taller shafts. It is estimated that this grove, if
cut for fuel, would yield about 400 cords of firewood, or at the rate of
about 600 cords per acre.

One eucalyptus tree cut on the Hillegass tract in 1901 was measured
by the writer. Its age was twenty-four years and its diameters were 26
inches and 31 inches after the bark had been stripped off. Yields of
800 cords to the acre have been reported from trees of twenty years of
age. Ten-year-old red gums grown by Mr. J. C. McCubbin, of Reed ley,
yielded at the rate of 235 cords of wood per acre, and it was by him
reported to have from 85 to 90 per cent of the fuel value of mountain
live-oak. ( Whether this was E. rostrata or E. viminalis was not reported. )

On the hills, where the soil is scantier, the rainfall of less amount, and

trees more exposed to winds, the growth is necessarily very much less

than it is on the flat. Such hill land as this, however, has only a pasture

value, as it is not suitable for early vegetables, and is too steep for grain.

8

114

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

In 1887 the Director of the Experiment Station had several hundred
trees planted near the top of a knoll at an elevation of 800 feet. The
slope here is west and northwest and is fully exposed to the winds. It

PLATE 17. EUCALYPTUS GROVE (E. globulus), NEAR ECONOMIC GARDEN.

was therefore, as a site, hardly equal to the average. The trees planted
were English oaks, cork oaks, Monterey pines, and Monterey cypresses.

CENTRAL STATION — TREE-PLANTING ON A HILLTOP.

115

In 1888 some Acacia decurrens were added to the plantation, and a few
miscellaneous trees, most of which died. In 1892 a row of Eucalyptus
corynocalyx, or sugar gum, and in 1892 some Eucalyptus globulus were
planted here. The latter were set at a considerably higher point, or at
nearly 900 feet elevation. All these trees have been subject to pasture
conditions, have received no care nor cultivation, and hence can not be
said to give an exaggerated idea of the growth that might be expected
on such Coast Range slopes as these.

PLATE 18. E. GLOBULUS IN ADOBE SOIL OF HILLTOP.

The growth of the common blue gum, Eucalyptus globuluSj now ten
years planted, is greater than that of any other trees tested. Four trees
standing near the crest of the hill, at an elevation of nearly 900 feet
above the sea (or 785 feet above the Oxford street entrance to the Uni-
versity grounds), now show an average girth of 28 inches. The largest
girths 33 inches. They are from 40 to 45 feet high and were planted 8

116 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

feet apart. They are now growing very fast. (Plate 18 shows three of
these trees.) .

The sugar gums (Eucalyptus corynocalyx) , which are two years older
than the blue gums, are planted on the eastern side of the main grove,
which consists largely of oaks. These trees, now twelve years old, range
in girth from 20 to 30 inches, and are 20 to 25 feet high. The trunks
are short, not exceeding 5 feet, and many branch near the ground. The
tops spread widely; cattle have eaten the leaves and smaller limbs
within reach.

PLATE 19. ACACIA DECURRENS, ON HILLTOP.

Acacias. — The plantings of acacia originally made included melanoxy-
lon and decurrens. The former have died; the latter are so large and
healthy as amply to justify large plantations on such soils.

One of two Acacia decurrens near the north line, close to the fence and
isolated from the main grove, is shown in Plate 19. This tree stands

CENTRAL STATION — TREE-PLANTING ON A HILLTOP. 117

on a northern slope, on heavy adobe soil, with native vegetation of
clover, wild oats, foxtail, etc. It girths 42 inches near the ground.
The main stems girth 27 and 30 inches. The height of the tree is
30 feet. Cattle have destroyed all the lower branches. Trees of Acacia
decurrens in the main grove, surrounded by eucalypti and oaks, girth
from 38 to 40 inches (single stems).

The amount of firewood per acre furnished under these conditions by
Acacia decurrens is greater than that from E. corynocalyx, but is less
than that from E. globulus. In fuel value the acacia wood is estimated
to rank higher than that of either eucalyptus. But the chief value of
Acacia decurrens, its yield of tan bark, deserves especial consideration.
Planted in a grove on such land as this, the yield of bark in, say, eight
years, would be considerable. It should be fully twice as much per

PLATE 20. ENGLISH OAKS ON HILLTOP.

acre as from the lighter and more arid Santa Monica grove (see report
for 1897-8, pp. 227-230). Wattle barks, as therein reported by an
expert tanner after practical tests, are "as good value at $28 a ton as
oak bark at $18 a ton."

Acacia pycnantha has not been tested on this hill-top. A. mollissima,
as well as A. decurrens and some of the ornamental species, were planted
in the southeastern portion of the tract, on a slope near Strawberry
Creek, at an elevation of about 427 feet. Here the growth of the wattle
acacias was very rapid, girths of from 4 to 5 feet being reached in fifteen
years from planting. In this location the acacias showed considerable
power of reproduction from sprouts when trees were cut and from self-
sown seeds.

Oaks.— The oaks, planted in 1887 on the hilltop, elevation 800 feet,
consisted of about one hundred and twenty English ( Quercus pedunculata)
and twenty cork oaks (Q. suber). At the present time, ninety-eight

118

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

English oaks and fifteen cork oaks remain. Many of these are branched,
shrubby, and spreading, and have suffered from being browsed upon;
but forty-nine of the English oaks are of good size, with trunks girthing
over 15 inches, and twenty of these exceed 18 inches. The average

height, of the English oaks, however, is only 10 or 12 feet. Eight or nine
trees are much taller than this, and are conquering the unfortunate
tendency toward a shrubby growth. (See central oak in Plate 20.)
The best cork oaks are rather larger in girth of trunks than are the

CENTRAL STATION — TREE-PLANTING ON A HILLTOP. 119

English oaks; three are 16, 20, and 23 inches, respectively, above the
ground. Of the fifteen trees, six will average fully 10 feet in height,
while the others are more or less scrubby. Both cork and English oaks
are very healthy, and seem as well established here as any native tree in
the adjacent gulches. The oaks are on a dry western slope, where the
pasturage was turning brown May 24th.

The only profit possible from oak plantations in such soil as this
must come from trees constantly side-pruned and cultivated for several
years. If a shrubby growth can be avoided, both the English and the
cork oaks will thrive here. A plantation of twenty or more acres of cork
oaks would give the matter a thorough practical test.

Other Trees. — Pines of several species planted here made good growth,
reaching in some cases a girth of 15 inches, but were broken down by
cattle. Monterey cypresses, though still alive, are now mere clumps
with dozens of scattered stems. Cork-bark elms failed. Two California
poplars (Populus Fremonti) are growing well, but have no economic
value as compared with the eucalypts, acacias, and oaks.

Conclusions. — The poorest part of the grove is at the extreme west,
exposed to the full sweep of the wind. Gophers and cattle, not drought
or native vegetation, destroyed most of the trees which died. Fenced
from cattle and given some cultivation the first few years, the growth
would have been much greater than it is. In a larger plantation, too,
the mutual shelter afforded by the young trees would be considerable.

But in spite of all drawbacks, Acacia decurrens, eucalypts, and oaks
are well established here. Land as steep as this is rented at from fifty
cents to a dollar an acre per annum, and is only used for pasturage.
There are thousands of acres of such land in the Coast Range within
fifty miles of San Francisco that will pay interest on a much higher
valuation, if used for growing firewood, not to say a better quality of
timber. As the general illustration (Plate 21) shows, the grove of oaks,
eucalypts, and acacias, though small, covers the ground well, is healthy,
and gives good evidence of the value of these hilltops for tree growth.
On even steeper slopes and on the very crest of the Coast Range,
numerous groves of blue gums exist which are now yielding profitable
returns. Larger forests should therefore be planted, and other species
of eucalyptus, also the wattle acacias, as well as oaks, should be given
consideration.

NOTE* ON THE COMPOSITION OF THE ADOBE SOIL OF THE HILLTOP.

BY E. W. HILGARD.

The soil of the hilltop where the grove is situated is a very hard and
black adobe clay, cracking open when dry, breaking up in lumps, and
very difficult to remove, even with a pick. Samples were taken to a
depth of three feet in a representative part of the grove, and those of
the first and third feet subjected to a mechanical and chemical analysis
by Prof. Loughridge and Mr. Triebel in the station laboratory, with the
results given below.

There was in each sample from 12 to 15 per cent of coarse grits and
rock fragments, which was sifted out and the analysis made of the fine
earth having a diameter of one half millimeter and less.

120

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

Nos. 2430, 2432. MECHANICAL COMPOSITION OF HILLTOP ADOBE : BERKELEY.

Hydraulic
Value.
Velocity per
Second.

Diameter of
Grains.

Physical Characteristics.

First Foot.
No. 2430.

Third Foot.
No. 2432.

Ab've 64 mm.

Above % mm.

Grits

Per cent.
12-15

Per cent.
12 15

64

.50 -.30

Very coarse sand

421

18

64-32

.30 -.16

... Coarse sand

7.21

.28

32-16

16-12

Medium sand

389

2 11

16- 8

.12 -.072

__ Fine sand ._

5.48

3.18

8- 4

.072 -.047

. Coarsest silt

5.16

283

4 2

047 036

Coarse silt

4 13

2 75

2- 1

.036 .025

Medium silt

430

282

1- 0.5

.025 -.016

Fine silt

180

410

0. 5- 0.25

.016 -.0023

; Finest silt

42.62

51.02

0.25- ?

.0023- ?

Colloid clay

20.18

30.45

98.98

99.72

The soil mass is of rather extreme physical composition, in the great
predominance of very fine materials, amounting in the subsoil to over
80 per cent; and such land must always be difficult to handle in culti-
vation, and be uncertain on account of its dependence upon favorable
rainfall. Unless very deeply cultivated it will crack open in summer,
tearing the roots and drying the soil into a mass of rocky hardness. As
it is not intrinsically very rich, it would be desirable to utilize it for
suitable timber growth, provided sufficient root-penetration can be
secured. The lack of this is probably one cause of the low growth of the
English oak.

CHEMICAL ANALYSIS OF ADOBE SOIL OF BERKELEY HILLS, No. 2430.

Per cent.

Insoluble matter „ ..72.19) 7R^n

Soluble silica 6.5lf 78</u

Potash (K2O) 33

Soda(Na20) — - -- .29

Lime(CaO) - .76

Magnesia (MgO) 76

Br. ox. of manganese (Mn3O4) _ ._ .08

Peroxidof iron(Fe203) .- 6.02

Alumina (ALO,) 4.58

Phosphoric acid (Po05) ._ 07

Sulfuric acid (S03) .02

Water and organic matter. ._ 8.93

Total - - 99.72

Humus. .- - 1.85

Nitrogen, per cent in humus 8.70

Nitrogen, per cent in soil 16

Hygroscopic moisture (absorbed at 15° C)__ . 9.09

In its chemical composition this soil, as might be expected, does not
differ widely from that of the lower slopes and the yellow ridge soil
of the University grounds (No. 4, in Report of 1884). It is poor in
potash for a California soil; and for so heavy a material the lime con-
tent, although relatively high from a general point of view, is too low
to insure ready tillage. The content of phosphoric acid is an average
one, its humus content is good for the arid region, and the nitrogen per-
centage of the humus sufficiently high. The fact that in years of abund-
ant rainfall this land bears a very heavy growth of grasses and certain
classes of weeds, shows that if improved in texture it might be highly
productive for a time.

UNIVERSITY OF CALIFORNIA PUBLICATIONS.

COLLEGE OF AGRICULTURE.

AGRICULTURAL EXPERIMENT STATION.

THE VALUE OF OAK LEAVES FOR FORAGE.

BY W. W. MACK1E.

SIGNAL PEAK, IN EASTERN MENDOCIKO COUNTY.

Slopes covered with low-growing Quercus garryana, and open places where covering has been
killed by sheep. In the foreground is False Hellebore ( Veratrum), an indication of
moist ground.

BULLETIN No. 150.

(Berkeley, April, 1903,)

SACRAMENTO:
w. w. SHANNON, : i : : SUPERINTENDENT STATE PRINTING.

1903.

BENJAMIN IDE WHEELER, Ph.D., LL.D., President oj the University.

EXPERIMENT STATION STAFF.

E. W. HILGARD, Ph.D., LL.D., Director and Chemist.

E. J. WICKSON, M.A., Horticulturist, and Superintendent of Central Station Grounds.

W. A. SETCHELL, Ph.D., Botanist.

ELWOOD MEAD, M.S., C.E., Irrigation Engineer.

R. H. LOUGHRIDGE, Ph.D., Agricultural, Geologist and Soil Physicist. (Soils and Alkali.)

C. W. WOODWORTH, M.S., Entomologist.

M. E. JAFFA, M.S., Assistant Chemist. (Foods, Fertilizers.)

G. W. SHAW, M.A., Ph.D., Assistant Chemist. (Soils, Beet-Sugar.)

GEORGE E. COLBY, M.S., Assistant Chemist. (Fruits, Waters, Insecticides.)

RALPH E. SMITH, B.S., Plant Pathologist.

A. R. WARD, B.S.A., D.V.M., Veterinarian, Bacteriologist.

E. H. TWIGHT, B.SC., Diplom6 E.A.M., Viticulturist.

E. W. MAJOR, B.Agr., Dairy Husbandry.

A. V. STLTBENRAUCH, M.S., Assistant Horticulturist and Superintendent of Substations.

WARREN T. CLARKE, Assistant Field Entomologist.

H. M. HALL, M.S., Assistant Botanist.

C. A. TRIE BEL, Ph.G., Student Assistant in Agricultural Laboratory.

C. A. COLMORE, B.S., Clerk to the Director.

,}

EMIL KELLNER, Foreman of Central Station Grounds.

JOHN TUOHY, Patron, }

JULIUS FORRER, Forenan,] ™«e Substation, Tulare.

R. C. RUST, Patron,

JOHN H. BARBER, Foreman

8. D. MERK, Patron,

J. H. OOLEY, Workman in charge

S. N. ANDROUS, Patron, ) ( Pomona.

J- Southern California Substation, •<
J. W. MILLS, Foreman, J ( Ontario.

V. C. RICHARDS, Patron, )

V Forestry Station, Chico.
T. L. BOHLENDERjincfeargre, J

ROY JONES, Patron,
WM. SHUTT, Foreman,

V Coast Range Substation, Paso Robles.

>• Forestry Station, Santa Monica.

The Station publications (REPORTS AND BULLETINS) will be sent to any
citizen of the State on application, so long as available.

THE VALUE OF OAK LEAVES FOR FORAGE.

The exploration in the course of which the data and samples forming the basis of
this bulletin were gathered, was originated by the Bureau of Forestry of the Depart-
ment of Agriculture, with a view to a study of the forest resources of the region in
question. At my request, Mr. Mackie paid some attention to the pasture conditions
existing there, to serve as a complement to the previous exploration of Mr. Joseph
Burtt Davy in northwestern California, the results of which were published in Bulletin
No. 12, of the Bureau of Plant Industry of the Department. Mr. Mackie found some-
what unexpectedly that a large part of the actual nourishment of stock in the region
was obtained by browsing on the various oaks, and on his return I suggested to him,
as an interesting subject for his graduating thesis, an examination of the chemical
composition and nutritive value of the several kinds of oak leaves usually eaten by
stock. The results of this work, carried out in the Station laboratory, together with
the general information obtained regarding the importance of browsing forage as
against the rapidly deteriorating grass range, form the subject of this paper.

E. W. HILGARD.

During the summer and fall of 1902, while exporting a forest reserve
in the northern Coast Ranges, the writer noticed with surprise and
interest the eagerness with which leaves of certain oaks were eaten by
live stock. Having this fact in mind, many observations were made in
regard to the forage value of each species of oak occurring in the Coast
Ranges. These observations, while confined more especially to the
extent to which each species was eaten by stock, included also the
range or distribution, altitude, and mode of occurrence.

Later in the year, in order to ascertain, if possible, whether these
observations indicated fully the real value and significance of these
oaks for forage, a chemical analysis was undertaken covering six species
of oaks and one of poison oak. Only those species were chosen which
occur on hills, ridges, and mountains where tillage is impossible; and
the object kept continually in mind was the forage value of the leaves
of the different species.

It is the purpose of this paper to give in full the results of both
observation and analysis, and to discuss the harmony or lack of
harmony between the two.

The ranges covered by the investigation are those situated in Lake
County, in eastern Mendocino north of Ukiah to Humboldt County, in
the western parts of Colusa and Glenn counties, and in southwestern

4 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

Teharaa County. These northern Coast Ranges are broken up into many
ridges, all running northwest and southeast. Between them are small,
narrow, gravelly valleys, with very little cultivable soil. The moun-
tains and slopes are composed of shales or loose soft rocks, often volcanic
in formation. The soil formed by decomposition of these rocks on ridges
is very shallow and poor— seldom as deep as four feet and commonly
two or less. The decomposition of these whales is hastened by the growth
of chaparral, herbs, and grasses, and on these poor, shallow, rocky soils
the browsing oaks are found. In the sedimentary or alluvial, or even
the colluvial soils washed from these mountains, none of the browsing
o.aks are found. These oaks, therefore, are good indicators of poor, shal-
low, and .rocky soils.

This area is typical of all the northern Coast Ranges, and, in regard
to oaks, may be taken also as a type of the southern Coast Ranges.
Thus the browsing areas of the Coast Ranges alone cover about one third
of the State. Adding to these those areas of the lower foothills of the
Sierra Nevada, which are occupied in part by many of these same
species of oaks, we have, as the entire region enriched in many places
by browsing oaks, about one half the State area.

Of the six species of oaks chosen from this browsing area for investi-
gation and here discussed, three are peculiar to California. The remain-
ing three species (Quercus garryana, Q. californica, and Q. chrysolepis)
range north into Oregon, as also does the Poison Oak, a species ol
sumach. Each of these oaks varies in range according to temperature,
altitude, and humidity; and the value of each species as a "browse"
increases almost directly with the altitude, except when modified by
exposure to the direct rays of the sun. Beginning on the lower hills.
the six species succeed one another upward in nearly distinct zones or
ranges, as follows: Blue Oak (Quercus douglasii), Scrub Oak and Curl-
leaf Scrub Oak (Q. dumosa and its variety, bullata), Canon Live Oak
(Q. widizeni), Maul Oak (Q. chrysolepis), Black Oak (Q.. calif ornica) <
and White Mountain Oak (Q. garryana). In addition to these, the
Poison Oak (Rhus diversiloba) is found commonly everywhere, on hills,
slopes, and by streams.

In the following description we will attempt to characterize each indi-
vidual species in the above order, as regards form, mode of occurrence,
range, and the forage value as indicated by the stock feeding upon it.

BLUE OAK (Quercus douglasii).

The Blue or Rock Oak reaches, in favored localities, a height of 20
feet, but is commonly found as a small tree about 12 feet high, or as a
shrub from 4 to 6 feet in height. It is oval or round in appearance,
and is covered densely with dark bluish leaves. The leaves are obovate
to oblong, with lobes commonly increasing in size toward the apex. In

VALUE OF OAK LEAVES FOR FORAGE. 5

young trees and shrubs the leaves are inclined to become spinescent.
The acorns, borne in shallow cups, are oval to ovate- acute, and are
about 1 to 1^ inches long.

In altitude, this oak is limited to the low foothills and dry valleys
where the soil is hard and rocky, and never ranges upward to the higher
slopes and valleys. It is found most abundantly in the dry foothills of

PLATE I. QUERCUS DOUGLAS1I. (BLUE OAK.)

the inner Coast Ranges, but extends from Mendocino County and the
upper Sacramento Valley through the Coast Ranges and Sierra Nevada
to Tejon Pass, in Kern County, from whence stunted individuals extend
to the margin of the Mojave Desert. In the southern Coast Ranges it
reaches its maximum height of fully 30 feet.

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

On account of the dry ness of its leaf, only goats and sheep browse on
the Blue Oak; but the acorn mast, which is plentiful and quite certain,
is excellent feed for hogs, cattle, sheep, goats, and often for horses.

It

S o

Of O

SCRUB OAK (Quercus dumosa).

This oak is a round-topped shrub 5 or 6 feet high, consisting of
numerous closely tangled branches starting from near the ground. The
twigs are usually tomentose, with leaves bunched at the ends. The

VALUE OF OAK LEAVES FOR FORAGE.

leaves are oblong to obovate and entire on the older trees?, but are often
sinuate-toothed and spinescent in young shrubs. They are pale green
in color and pubescent on the lower side. The acorns are oval and

:

PLATE III. QlJERCUS DUMOSA. (SCRUB OAK.)

pointed, from \ to l\ inches long, and are contained in shallow cups.
The crop is light and very uncertain.

The Scrub Oak is commonly found associated with many other shrubs
in the chaparral of the mountains and upper foothill slopes in dry

8

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

localities. It ranges from Mendocino County southward through the
Coast Ranges to Lower California, and is also found in the foothills of
the Sierra Nevada.

This shrub, on account of its low habit of growth, is particularly
adapted to browsing, and is one of the best for sheep and goats. Cattle,
however, dislike it on account of its harsh, spinescent leaves, but feed on
it during the winter when snow has covered the ground, or when from
any cause other food is not available.

PLATE IV. QUERCUS DUMOSA, VAR. BULLATA. (CURL-LEAF SCRUB OAK.)

CURL-LEAP SCRUB OAK (Quercus dumosa, var. bullata).

The Curl-leaf Scrub Oak is a variety with the same habit of growth
as the typical species. The leaves differ, however, in having the mar-
gins strongly revolute, thus presenting a curled appearance. The under
side of the leaf is densely tomentose, and the whole leaf is thicker and
rounder than that of the type. The acorns of the variety are similar in
size and shape to those of the other, but are contained in even shallower
cups.

VALUE OF OAK LEAVES FOR FORAGE. 9

This oak is seldom found south of San Francisco Bay, and reaches its
greatest abundance north of Clear Lake, on the dry eastern slopes of the
Coast Ranges bordering on the Sacramento Valley, and extending to
Mount Shasta.

The forage value of the variety is apparently the same as that of the
type of the species.

PLATE V. QUEKCUS WISLIZENI. (CAJJON LIVE OAK.)

CAftON LIVE OAK (Quercus wislizeni).

The Canon Live Oak when found in the canons is a tree usually 20
to 40 feet high, but when it passes into the chaparral it is never higher
than 8 feet. Here it is an intricately branched shrub with a rounded
top. The bark on old trees is rough and thick, but on shrubs it is
smooth. The leaves are usually oblong-lanceolate, entire, serrate or
dentate, and are lustrous and dark green in color. They are about 1^
inches long and f of an inch wide. The nuts ripen in the second season,

10

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

and are long, sessile, slender oblong-oval, set in deep scaly cups. The
mast is usually scanty.

The shrub is common in the chaparral with Quercus dumosa, and
ranges with it in altitude. It is well distributed in the Coast Ranges
from Mount Shasta to San Diego County, usually at quite a distance

PLATE VI. QUERCUS CHRYSOLEPIS. (MAUL OAK.)
Showing two distinct leaf forms.

from the sea. It also exists, but not commonly, from Mount Shasta
through the lower foothills of the Sierra to Tejon Pass.

The leaves of this shrub are sought in preference to those of the
Scrub Oak by sheep, goats, and cattle, and it is thus often found
stripped of its leaves.

VALUE OF OAK LEAVES FOR FORAGE.

11

MAUL OAK (Quercus chrysolepis).

The Maul Oak (Q. chrysolepis), when found growing on well-watered
and protected slopes, is a tree 40 to 60 feet in height, with large sweeping
branches. On exposed slopes, however, and on the upper ridges and
peaks, it becomes a gregarious shrub with Q. garryana. The leaves are
oblong, acute or cuspidate, entire on old trees but spinose-dentate on
young ones and on shoots. They are pale and glaucous above, with

PLATE VII. QUERCUS CALIFORN1CA. (BLACK OAK.)

golden tomentum below. The acorn is usually solitary, ovate or oval,
\ to 2 inches long, and borne in a shallow cup. The crop of mast is
uncertain and is often ruined by the larvae of moths.

The range of this oak extends from southern Oregon through the
Coast Ranges and Sierra Nevada, and on through the San Bernardino
Mountains to Lower California. It often reaches an elevation of 9,000 feet.

Maul Oak is used as a "browse" by sheep and goats, and sparingly
by cattle.

12

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.
BLACK OAK (Quercus calif or nica).

The Black Oak is a tree 18 to 30 feet high, usually with several large erect
branches. It is generally found near coniferous trees, and apparently
occupying the same belt. Young trees often occur in dense growth, and,
when in this condition or when overshadowed by other trees, grow slowly,
thus enabling stock to browse on them. The leaves of young trees are
covered with a dense gray tomentum below, and are pubescent above.
On older trees the leaves are glabrous with little tomentum. They vary

PLATE VIII. QUERCUS GABRYANA. (MOUNTAIN WHITE OAK.)

from oblong to broadly ovate in outline, and each is parted into about
seven broad lobes. The nut is broadly ovate, one inch in length, and
ripens in the second season. The crop is scanty and unreliable.

The range of the Black Oak extends from the Mackenzie River in
Oregon through the Coast Ranges and Sierra, and through the San
Bernardino Mountains to Lower California. This oak often reaches
elevations of 7,000 to 8,000 feet. It is scarce near the coast.

The flexible texture of the leaves of this oak allows it to be easily
eaten by cattle and horses as well as by sheep and goats.

VALUE OP OAK LEAVES FOR FORAGE.

13

WHITE MOUNTAIN OAK (Quercus garryana).

Two forms of this species, differing only in range and height of indi-
viduals, may be distinguished. The typical form is a tree from 80 to 70

q

O ;a
K O,

3 a
1 fi

£ a

*; «

I I

feet in height, with erect rigid branches. Its leaves are oblong to
obovate, 4 to 6 inches long, with coarse lobes. The acorns are sessile or

14 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

shortly peduncled, oval to slightly obovate, about 1 to 1^ inches in
length, contained in a shallow cup.

It ranges from Vancouver Island southwestward through western Wash-
ington, Oregon, and, the Coast Ranges of California, to Santa Cruz. It
is the only oak used for lumber on the Pacific Coast, and furnishes the
oak lumber for the furniture factories of West Berkeley.

The other form of this species is a mere shrub from 2 to 6 feet high,
but identical with the larger form in every other particular.

Its range begins in an exposed portion of western Washington, where
apparently it is stunted by the severe sea-breezes. Passing along the
western slopes of the Cascades in Washington and Oregon, its elevation
continually increases until in California it is found only on the highest
ridges and peaks. Its southernmost range is Snow Mountain in Lake
County.

The entire range of this oak is swept by cold driving north winds,
which apparently serve to keep the temperature and other conditions
uniform throughout.

It is to this form of Q. garryana that stockmen turn when seeking
"browse" in their mountain pasture. It is gregarious over hundreds of
acres on the ridges, peaks, and higher slopes in the most exposed places
of the northern Coast Ranges. It forms thickets to the exclusion
of everything else except the Maul Oak (Quercus chrysolepis) , and
occasionally Wild Cherry (Cerasus demissa).

This species, almost unaided, supplies pasture for thousands of sheep
and goats as well as cattle and horses, and not only keeps them up, but
actually fattens them. The stock keep whole ranges of it eaten down
often to within less than two feet of the ground. Aside from the value
of the leaves, the acorn, which is quite sweet, forms a rich diet for stock.
The mast is usually sure and abundant.

POISON OAK (Rhus diversiloba).

The Poison Oak (Rhus diversiloba) is usually a small shrub from 2 to
5 feet high, but occasionally it ascends the trunks of trees as a vine, to a
height of 15 or 20 feet. The leaflets are orbicular to ovate, glaucous,
with distinct venation. They contain an irritating and poisonous vola-
tile oil, which poisons many persons by simple contact or even by diffu-
sion in the air. The fruit is pale, about three lines thick, and quite
abundant.

Rhus diversiloba is everywhere common through the hilly portions of
California.

On the ranges the leaves and berries are readily eaten by sheep, goats,
and horses, but not by cattle, as far as could be ascertained by observa-
tion and numerous inquiries. Many of the bushes are stripped entirely
of leaves long before they would naturally drop them.

VALUE OF OAK LEAVES FOR FORAGE.

15

VALUE OF CALIFORNIA OAKS FOR BROWSING PURPOSES.

In summing up the value of these California oaks, the common classi-
fication into "live," or evergreen, and deciduous will be made. The
former class includes Scrub Oak and Curl-leaf Scrub Oak (Quercus
dumosa and variety bullata), Canon Live Oak (Q. wislizeni), and Maul

"

PLATE X. RHUS DIVERSILOBA. (POISON OAK.)

Oak (Q. chrysolepis). The deciduous oaks consist of Blue, or Rock Oak
(Q. douglasii), Black Oak (Q. calif ornica) , and Mountain White Oak
(Q. garryana). The Poison Oak (Rhus diversiloba) is also deciduous.

The live oaks, as seen in the previous descriptions, occupy the brush
areas on the slopes and ridges, and, except for a few isolated specimens

16 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

of Quercus chrysolepis, never grow within the timbered, or coniferous,
belt. These live oaks, therefore, occupy a continuous belt of country
which is free from snow except for occasional short periods. This belt,
for this reason, is used as a winter range for holding-over stock when
feed is scarce in the valleys and deep snows cover the mountains.
Sheep and goats are kept in good condition on these live oaks, but
cattle and horses do not eat them to any extent until other food can
not be obtained. Then this "browse" keeps them in feed until other
kinds are available.

The deciduous oaks, not taking into account the Quercus douglasii,
which is of little forage value, are found in the timber belt or above it.
The leaves of the deciduous oaks, in contrast to the harsh spinescent
ones of the live oaks, are larger, lobed, and soft. This enables cattle and
horses to eat them with ease, as is also true of sheep and goats. They
actually fatten on the leaves of the Black Oak and White Mountain
Oak of these upper ridges and peaks.

Nutritive Value of the Leaves. — From the observations just recorded
concerning these several species of oaks, it would seem that the nutritive
value increases with the altitude. To verify this, and to ascertain if
possible their relative food values, a chemical analysis of each species
was made.

For the purpose of this analysis the leaves were gathered during the
month of September, when they were fully mature. Only those which
were green and vigorous were taken. These were dried in a room of
ordinary temperature, and were then ground to a fine powder.

It would seem that the irritating and poisonous oil of Poison Oak
(Rhus diversiloba) is volatile at a comparatively low temperature. In
gathering the specimen the writer was badly poisoned, even though
gloves were worn; yet after drying at ordinary room temperature, and
the leaves pressed into the mill with bare hands, no poisoning effects
followed.

In the analyses of these oak leaves, the methods for foods, as set forth
in Bulletin No. 46, Bureau of Chemistry, U. S. Department of Agri-
culture, were followed. In this work, however, some errors appeared in
the ether extract and in the nitrogen-free extract. These errors were
due to certain peculiarities of composition of the oaks.

In the determination of fat, or ether extract, quantities of chlorophyll,
the green coloring matter in the leaves, remained in the extract. No
quantitative method being known for the extraction of chlorophyll, this,
together with the gums and resins which are contained within the leaves
or on the tomentum and pubescence of the outside, increased the ether
extract beyond its true percentage. After determining the nitrogen-free
extract, which consists of sugar, starch, pentosans, etc., the percentage

VALUE OF OAK LEAVES FOR FORAGE.

17

appeared inexplicably high. The only possible explanation seemed to
be that the tannin content, which, by the method of difference, falls
in this group, had not been accounted for. It was necessary, then, to
make determinations of tannin.

In determining the tannin, the method of Giinther was followed ; that
is, two grams of the substance to be analyzed was taken and the tannin
extracted with hot water, in which it is easily soluble, until a dilution
of 1 to 400 parts was obtained. This dilution is necessary in order that
potassium permanganate may completely oxidize tannin in the presence
of indigo-carmine. The oxidizing power of the indigo-carmine was
determined by extracting all the tannin by means of animal charcoal
and titrating with potassium permanganate. The difference between the
two titrations was the tannin oxidized by the potassium permanganate.

With these exceptions in the ether extract and the nitrogen-free
extract, the regular official method was followed; and the /table below
gives the results of the analyses of the different species of pak in an air-
dry condition. As a means of exact comparison, these results were cal-
culated first to a water-free basis, and finally, to an alfalfa hay basis.
The analyses were all carried out in duplicate and the averages found

as follows:

ANALYSES OF OAK LEAVBS.

Samples Air Dry.

Species.

Water.

Ash.

Protein.

Fiber.

Tannin.

Nitr'gen
Free
Extract.

Ether
Extract.

Blue Oak

Percent.
5.21

Percent
932

Percent.
8.32

Per cent.
33 35

Per cent.
500

Per cent.
34 55

Per cent.
425

Scrub Oak. .

3.90

9.42

9.16

26.79

14.06

31.41

5.26

Canon Live Oak .

3.51

9.66

10.95

29.48

9.62

30.89

5.86

Maul Oak ..

6 53

962

8.32

30.35

10.16

31.52

3.50

Black Oak

5.10

9.35

8.15

19.22

10.62

40.50

7.06

Mountain White Oak

4.59

9.44

15.05

16.26

9.01

40.18

5.47

Poison Oak

5 39

8 66

6 85

25 13

6 42

41 05

6 50

Water-Free.

Blue Oak.

9.83
9.80
10.02
10.29
9.85
9.90
9.15

8.78
9.53
11.35
8.90
8.59
15.77
7.24

35.18
27.88
30.56
32.47"
20.25
17.04
26.56

5.28
14.63
9.97
" 10.89
11.19
9.44
6.79

36.45
32.69
32.02
33.73
42.68
42.11
43.39

4.48
5.47
6.07
3.74
7.44
5.73
6.87

Scrub Oak

Canon Live Oak

Maul Oak

Black Oak

Mountain White Oak

Poison Oak

Water on Alfalfa Basis.

Blue Oak

10.95
10.95
10.95
10.95
10.95
10.95
10.95
10.95

8.75
8.72
8.92
9.16
8.77
8.82
8.15
6.43

7.83
8.48
10.11
7.92
7.65
14.04
6.44
17.60

31.32
24.83
27.21
28.91
18.03
15.18
23.65
22.63

4.70
13.03
8.88
9.70
9.96
8.41
6.04

32.46
29.11
28.52
30.03
38.01
37.50
38.64
39.31

3.99
4.87
5.41
3.33
6.63
5.10
6.13
3.08

Scrub Oak ._ __

Cafion Live Oak

Maul Oak

Black Oak

Mountain White Oak

Poison Oak. .

Alfalfa

18 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION

In the discussion of the chemical analysis of these species, alfalfa hay
is selected for comparison because alfalfa seems to be the best and
commonest forage plant in California. A comparison with this plant,
then, naturally sets forth the value of oak leaves for forage to better
advantage than a comparison with any other stock food.

Ash Content. — In comparing the ash content of oak leaves and alfalfa,
it is noted that the ash of oaks varies but little in various species. This
variation is not more than four-tenths of one per cent, while the average
ash for all the species is somewhat greater than 8.75 per cent. This
percentage is 2£ per cent greater than in alfalfa hay.

As all the mineral, and hence the bone-forming, materials of the
plant are in the ash, oak leaves have thus a greater value for growing
stock than has alfalfa.

Protein Content. — Proceeding to the protein, or muscle-forming content,
greater variations are encountered. The comparison shows alfalfa to
contain more than twice as much protein as any of the oaks, with the
exception of two species, Quercus wislizeni and Q. garryana. The former
averages 10.11 and the latter 14.04 per cent. Quercus garryana, there-
fore, approaches alfalfa closely. The other species, though falling far
below alfalfa, are not poor in protein. The average is nearly 8 per cent,
which is one-half of one per cent higher than oat hay — the best of
cereal hays.

These analyses indicate that oak leaves are superior in muscle-forming
ingredients to non-leguminous hay; that one species (Quercus wislizeni)
is equal to bur-clover hay; and the best species (Quercus garryana)
almost equal to alfalfa hay.

Crude Fiber. — In oak leaves the crude fiber is as variable as the pro-
tein, ranging from over 30 per cent in Quercus douglasii to 15 per cent
in Q. garryana. With the exception of two of the deciduous oaks,
Quercus californica and Q. garryana, the oak leaves are considerably
higher in crude fiber than alfalfa. This crude fiber, or roughage, in oaks
tends to produce a wide nutritive ration.

Ether Extract.— The fat, or more correctly speaking, the ether extract,
is considerably higher than in alfalfa in all the species, and increases to
twice as much in Quercus wislizeni and Q. californica. This ether
extract does not represent pure fat, but includes the chlorophyll, waxes,
and resins, which can not be separated from the true fat. These waxes
and resins serve to protect the leaves from drying winds and inclement
weather, and usually occur in the tomentum or pubescence which cover
some leaves. In some cases, as in Quercus californica, the waxes and
resins are distasteful to stock, thus decreasing their forage value.

VALUE OF OAK LEAVES FOR FORAGE. 19

Nitrogen-Free Extract. — In oaks the nitrogen-free extract, consisting
of starch, sugars, pentosans, etc., does not equal alfalfa in any species,
and in Scrub Oak falls as far below as 10 per cent. This fact indicates
a lower fattening and heat-producing power than in alfalfa.

Tannin. — Tannin is an astringent principle found in many plants.
Aside from its astringent properties, it is acrid, and therefore offensive
to the palates of animals. In the stomach, it precipitates the pepsin
and peptones, thus preventing the formation of dextrose and hindering
digestion. Great thirst and constriction in the digestive tract usually
follow an overdose of it. These effects are not so marked in some tan-
nins as in others, for some do not have so great a precipitating power as
do others.

In determining the tannins in the oaks, it was found to vary greatly
in the different species, but did not serve as an infallible indication of
the value of the leaves for forage. For example, Quercus douglasii, which
is the poorest forage oak analyzed, is lowest in tannin, while Q. dumosa,
a species preferred by sheep and goats, contains 13 per cent, the largest
amount of tannin determined in any one species.

The average of tannin for all the oaks is a little over 10 per cent. In
tasting the powdered specimens of the various species, the intensity of
acridity perceived coincides with the tannin percentages. In comparison
with oak leaves, alfalfa contains an inappreciable amount of tannin.

Water. — Although the water-content of the oak leaves was placed on
an alfalfa hay basis, this does not indicate their true comparison when
both are green. Green alfalfa contains 80 per cent of water, ^which is
from 10 to 20 per cent higher than that in the various species of oaks.
This shows the oak leaves to be a somewhat more concentrated feed in
regard to protein, ash, and nitrogen-free extract, than appears in the
comparison on an alfalfa hay basis.

Injurious Constituents. — Judging from the results of the chemical
analyses of these oak leaves, they would seem to occupy a high place
among forage plants. This would be the case were it not for excessive
amount of three of the chemical constituents; namely, crude fiber, resins
and waxes, and tannin.

The high percentage of crude fiber taken together with the low per-
centage of nitrogen-free extract produces a coarser and less nutritious
feed than leguminous crops.

The resins have pungent and disagreeable flavors, which render them
distasteful to stock. A good example of this is seen in the Quercus
californica, before cited. The leaves of the young trees and shrubs of
this species contain no more tannin than those of most of the other
species, are only 1-J per cent below alfalfa in nitrogen-free extract, have
a fair amount of protein, are low in crude fiber, and are large and soft.

20 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

These qualities should produce a feed superior to oat hay. This is not
the case, however, for stock avoid it to a great extent on account of the
resins and waxes in the dense tomentum covering the leaves. Those
waxes and resins serve as a protection against drying winds and severe
weather, and all the oaks have more or less of them.

As compared with the crude fiber and resins, tannin of oak leaves, as
before stated, is not only bitter and astringent, but interferes with
digestion.

Conclusion. — In summing up the value of the forage oaks, from chemi-
cal analyses and observations in the field, the conclusion is reached that
the facts observed in the field coincide in most cases with those deter-
mined by analysis. For instance, the deciduous oaks possess a higher
nutritive value than the live oaks and are, as would be expected, more
readily eaten by houses, cattle, sheep, and goats. In some cases, how-
ever, certain physical conditions modify these relations. This is true
in the case of the live oaks. These contain a sufficiently high proportion
of nutrients, and yet only sheep and goats thrive upon them. This is
due to the thick, harsh leaves with their spinescent teeth, which prevent
horses and cattle from relishing them.

Pasturing Oaks. — Although all stock prefer the deciduous oaks of the
higher altitudes, yet indiscriminate pasturing causes much damage to
the forests and ground-cover. When sheep and goats are allowed to
browse on the deciduous oaks of the timbered area, they kill the seedling
conifers by nibbling and trampling, kill the shrubs by over-browsing,
and cut up the slopes in trails which become deep gullies during the
rainy season. This could be avoided by pasturing the sheep and goats
on the " live oaks" of the lower chaparral or brush areas, the only neces-
sary precaution being to prevent too many congregating in one place,
thus avoiding too much trampling and gullying.

Since cattle and horses are unable to thrive on the live oaks, and
since they do not browse close enough to kill shrubs, never browse on
young conifers, nor cut up slopes by trails, they may profitably be pas-
tured on the timbered areas and on the higher altitudes.

Thus, this oak area, comprising half the whole State, can, by a con-
servative and well-regulated system of browsing, be made to pasture
sheep and goats throughout the year, and all stock during the summer
months; and also during seasons of drought or when winter conditions
make other feed inaccessible.

VALUE OF OAK LEAVES FOR FORAGE. 21

BIBLIOGRAPHY.

1. Flora of Western Middle California. Jepson.

2. Silva of North America, Sargent.

3. Check List of the Forest Trees of the United States, their Names

and Ranges. Bulletin No. 17, Bureau of Forestry. Sudworth.

4. Stock Ranges of Northwestern California. Bulletin No. 12, Bureau

of Plant Industry. Davy.

5. Feeding of Farm Animals. Bulletin No. 132, College of Agricul-

ture, University of California. Jaffa and Anderson.

6. Feeds and Feeding. Henry.

7. Official Methods of Analysis adopted by the United States Asso-

ciation of Chemistry. Bulletin No. 46, Bureau of Chemistry,
U. S. Department of Agriculture.

8. Plant Analysis. Dragendorff.

9. Chemie der Nahrungs- und Genussmittel. Konig.

UNIVERSITY OF CALIFORNIA PUBLICATIONS

COLLEGE OF AGRICULTURE

AGRICULTURAL EXPERIMENT STATION

BERKELEY, CALIFORNIA

WALNUT CULTURE IN CALIFORNIA
WALNUT BLIGNT

BY

RALPH E. SMITH

ASSISTED BY

CLAYTON O. SMITH AND HENRY J. RAMSEY

BULLETIN No. 231

(BERKELEY, CALIFORNIA, AUGUST, 1912)

FRIEND WM. RICHARDSON, SUPERINTENDENT OF STATE PRINTING

SACRAMENTO, CALIFORNIA

1912

BENJAMIN IDE WHEELER, President of the University.

EXPERIMENT STATION STAFF.

E. J. WICKSON, M.A., Director and Horticulturist.

E. W. HILGARD, Ph.D., LL.D., Chemist (Emeritus).
W. A. SETCHELL, Ph.D., Botanist.

LEROY ANDERSON, Ph.D., Dairy Industry.
M. E. JAFFA, M.S., Nutrition Expert.

R. H. LOUGHRIDGE, Ph.D., Soil Chemist and Physicist (Emeritus).
C. W. WOODWORTH, M.S., Entomologist.

RALPH E. SMITH, B.S., Plant Pathologist and Superintendent of Southern California
Pathological Laboratory and Experiment Station.

F. R. MARSHALL, B.S.A., Animal Industry.

G. W. SHAW, M.A., Ph.D., Experimental Agronomist and Agricultural Technologist, in

charge of Cereal Stations.

B. A. ETCHEVERRT, B.S., Irrigation Expert.
F. T. BIOLETTI, M.S., Viticulturist.

W. T. CLARKE, B.S., Assistant Horticulturist and Superintendent of University Exten-
sion in Agriculture.

JOHN S. BURD, B.S., Chemist, in charge of Fertilizer Control.
J. E. COIT, Ph.D., Pomologist, Riverside.

C. B. LIPMAN, Ph.D., Soil Chemist and Bacteriologist.

GEORGE E. COLBY, M.S., Chemist (Fruits, Waters, and Insecticides), in charge of

Chemical Laboratory.

H. J. QUAYLE, M.S., Assistant Entomologist.
H. M. HALL, Ph.D., Assistant Botanist.
C. M. HARING, D.V.M., Veterinarian and Bacteriologist.
E. B. BABCOCK, B.S., Agricultural Education.
W. B. HERMS, M.A., Assistant Entomologist.
W. T. HORNE, B.S., Assistant Plant Pathologist.
L. M. DAVIS, B.S., Assistant Dairy Industry.
W W. BONNS, M.S., Assistant Pomologist.

A. J. GAUMNITZ, Assistant Agronomist, University Farm, Davis.
T. FRANCIS HUNT, B.S., Assistant Plant Pathologist.

P. L. MCCREARY, B.S., Chemist in Fertilizer Control.

E. H. HAGEMANN, Assistant in Dairying, Davis.

R. M. ROBERTS, Farm Manager, University Farm, Davis.
J. I. THOMPSON, B.S., Assistant Animal Industry, Davis.
J. C. BRIDWELL, B.S., Assistant Entomologist.
L. BONNET, LA., Assistant Viticulturist.

F. C. H. FLOSSFEDER, Assistant in Viticulture, University Farm, Davis.
P. L. HIBBARD, B.S., Assistant Fertilizer Control Laboratory.

C. H. McCHARLES, M.S., Assistant Agricultural Chemical Laboratory.

B. A. MADSON, B.S.A., Assistant Experimental Agronomist.

WALTER E. PACKARD, M.S., Field Assistant Imperial Valley Investigation, El Centre.
S. S. ROGERS, B.S., Assistant Plant Pathologist, Plant Disease Laboratory, Whittier.

C. O. SMITH, M.S., Assistant Plant Pathologist, Plant Disease Laboratory, Whittier.

E. H. SMITH, M.S., Assistant Plant Pathologist.

C. L. ROADHOUSE, D.V.M., Assistant in Veterinary Science.

F. M. HAYES, D. V. M., Assistant Veterinarian.
P. S. BURGESS, M. S., Assistant Soil Chemist.
W. F. GERICKE, B.S., Assistant Soil Chemist.

M. E. STOVER, B.S., Assistant in Agricultural Chemical Laboratory.
W. H. VOLCK, Field Assistant in Entomology, Watsonville.
E. L. MORRIS, Field Assistant in Entomology, San Jose.

E. E. THOMAS, B.S., Assistant Chemist, Plant Disease Laboratory, Whittier.
A. B. SHAW, B.S., Assistant in Entomology.

G. P. GRAY, M.S., Chemist in Insecticides.

H. D. YOUNG, B.S., Assistant in Agricultural Chemistry, Plant Disease Laboratory,

Whittier.

A. R. TYLOR, B.S., Assistant in Plant Pathology, Plant Disease Laboratory, Whittier.
W. V. CRUESS, B. S., Assistant in Zymology.
J. F. MITCHELL, D.V.M., Assistant in Veterinary Laboratory.
W. A. BOYS, B.S., Assistant Cerealist.
M. R. MILLER, B.S., Assistant Chemist in Insecticides.

F. H. WILSON, B.S., Assistant in Soil Chemistry.
W. M. MERTZ, Assistant in Pomology, Riverside.

ANNA M. LUTE, A.B., Scientific Assistant, U. S. Department of Agriculture.
J. C. ROPER, Patron, University Forestry Station, Chico.
E. C. MILLER, Foreman, Forestry Station, Chico.

D. L. BUNNELL, Secretary to Director.

CONTENTS.

PAGE

INTRODUCTION 119

SPECIES OF WALNUT.

THE ENGLISH WALNUT 128

AMERICAN BLACK WALNUT (Juglans nigra) 128

CALIFORNIA BLACK WALNUTS 128

NORTHERN CALIFORNIA BLACK WALNUT 129

SOUTHERN CALIFORNIA TYPE 138

Relationship Between the Southern and Northern California Types of

Black Walnut 141

OTHER NATIVE WALNUTS OF THE SOUTHWEST 146

NATIVE WALNUTS OF ARIZONA 147

NATIVE WALNUTS OF TEXAS 149

NATIVE WALNUTS OF NEW MEXICO 150

THE BUTTERNUT (Juglans cinerea) 151

FOREIGN WALNUT SPECIES 152

Juglans sieboldiana 152

Juglans cordiformis 152

Juglans mandshurica 152

Juglans 'bolimensis 152

Pterocarya caucasica 152

HYBRID WALNUTS 152

PARADOX HYBRIDS 154

Seedlings of Paradox Trees 162

ROYAL HYBRID WALNUTS 163

Seedlings of Royal Trees 167

FREAK WALNUT TREES 168

FOSSIL WALNUT SPECIES 171

WALNUT CULTURE IN CALIFORNIA 171

HISTORY 171

LOCATION FOR WALNUTS 176

Climate 176

Frost 176

Heat 177

Soil __. 178

DISTANCE OF PLANTING 179

Interplanting 179

CULTURE 182

Soil Handling 182

Irrigation 183

Fertilization 185

Pruning 189

CROP HANDLING 192

Picking 193

Washing 193

PACKING-HOUSE OPERATIONS 195

Sampling 195

Bleaching 196

Grading 197

Walnut Grades 198

Selling 199

CONTENTS — Continued.

PAGE
WALNUTS IN CALIFORNIA — Continued.

PROPAGATION OF THE WALNUT '. 200

Rootstocks 200

English Walnut Root 202

Eastern Black Root (Juglans nigra) 202

Northern California Black Root (Juglans hindsii) 202

Southern California Black Root (Juglans californica) 203

Hybrid Roots — __ 204

Paradox Hybrid Roots 205

Royal Hybrid Roots 210

Planting the Nuts in Place 211

Planting Black Walnut Seedlings in Orchard Form 212

Raising the Trees in the Nursery 214

Seed Treatment 214

Grafting 217

Time of Grafting 218

The Scion • 219

Grafting 220

Budding 1 225

Methods of Top-Working 230

Top-Grafting — 230

Top-Working by Budding 242

Digging 245

Planting 253

VARIETIES OF THE ENGLISH WALNUT 254

COMMERCIAL VARIETIES 258

Chase 258

Concord i. 263

Eureka 269

Franquette 277

Placentia (Placentia Perfection) 283

Prolific (Disher's Prolific, Ware's Prolific) 289

San Jose1 (San Jose Mayette, Wilts) 295

OPINION OF AN EXPERT WALNUT BUYER 299

Size and Weight of Principal Walnut Varieties 300

MISCELLANEOUS AND LESS PROMINENT VARIETIES 305

Acme 305

Barthera 305

A. Bijou (Gant) 305

Bishop 307

Chaberte 307

Cluster ; 308

El Monte (El Monte Large) , 308

Eureka No. 2 309

Ford's Improved 309

Ford's Eureka 309

Grenoble 309

Hale 309

Hicks. See Bishop 310

Hildebrand. See Mayette 310

Kaghazi 310

Keesling 313

Klondyke 313

Laciniated 313

Lane 313

Main. See Bishop __._ 313

Mayette 313

CONTENTS — Continued.

PAGE.
MISCELLANEOUS AND LESS PROMINENT VARIETIES— Continued.

Mayette Blanc 336

Mayette Rouge 316

Mesange 316

Meylan 316

Monstreuse 316

Neff (Ncff's Prolific) 316

Paper Shell 317

Parisienne 317

Persian. See Kaghazi 317

Powell. See Mayette 317

Pride of Ventura 317

Proeparturiens 318

Santa Barbara Soft Shell 318

Santa Rosa 318

Seedling. See Santa Barbara Soft Shell — 318

Serotina . 318

Soft Shell. See Santa Barbara Soft Shell 318

Treyve 318

Tribble. See Mayette 319

Vourey 319

Wagner - 319

Willson (Willson's Wonder) 319

DISEASES AFFECTING THE WALNUT — — 320

WALNUT BLIGHT OR BACTERIOSIS 320

Host 320

Popular Name of Disease 321

Geographical Distribution . 321

History of Disease in California 322

Losses from Blight = 323

Earlier Studies 324

Cause of Disease 325

Confusion with Marsonia juglandis 325

Characteristics of Bacteriosis 328

On Branches 328

Bacteriosis is not Die-Back 329

On Nursery Trees — 329

Leaves 329

Catkins 329

Nuts 329

Blossom End Infection 332

Lateral Nut Infection 333

Late Infections - 333

White Deposit on Diseased Tissue 335

Winter Habitat of Germ 335

Secondary Infection 337

Effect of Climate 337

Fogs and Moisture 338

Insects 338

How the Germ Enters the Tissue 339

Two Seasons Compared 339

Non-blighting of Late-Blooming Trees 341

Immunity 342

Isolation 342

A MORE TECHNICAL STUDY OF THE WALNUT ORGANISM 343

Pseudomonas juglandis Pierce 343

Morphology 343

Cultural Characteristics _ 344

CONTENTS — Continued.

DISEASES AFFECTING THE WALNUT— Continued. PAG«

A MORE TECHNICAL STUDY OF THE WALNUT ORGANISM — Continued.

Artificial Inoculations 351

More Detailed Account of Inoculation Experiments 355

Inoculations on Other Species of Juglans 357

Action of Germicides on Walnut Organism 361

Control of Walnut Blight 363

Spraying 363

Blight Control by Means of Applications to the Soil 367

Resistant Varieties 367

Working Over Seedling Groves to Better Varieties 369

DIE-BACK 372

SUNBURN — BACK SAP 373

PERFORATION 376

CROWN GALL 377

ROOT ROT — OAK FUNGUS — TOADSTOOL DISEASE 378

SEEDLING ROOT ROT — WILT 379

LITTLE LEAF — "YELLOWS" 379

SHRIVELED MEAT 382

APHIS 383

Aphis Control 384

Mixtures for Spraying 385

BLISTER MITE— ERINOSE 385

RED SPIDER _ 385

ACKNOWLEDGMENT _ 398

WALNUT CULTURE IN CALIFORNIA.

WALNUT BLIGHT.

By RALPH E. SMITH.
Assisted by CLAYTON O. SMITH and HENRY J. RAMSEY.

The present bulletin represents the results of the most extensive, and,
perhaps, the most important investigation undertaken by the depart-
ment of plant pathology since its foundation. When the writer first
came to California in 1903, one of the most conspicuous and most seri-
ous plant diseases then prevalent in the State was the so-called walnut
blight. The disease, while comparatively a new one at that time, had
reached all the important walnut-growing districts and was reputed to
have been the cause of a diminution of at least one half in the walnut
crop of the State. The trouble had been under investigation for some
little time by Professor Newton B. Pierce, then of the United States
Department of Agriculture, who had succeeded in definitely establish-
ing its cause and had undertaken considerable work along the line of
treatment for its suppression, and also that of developing varieties of
the walnut which might be immune to this disease. Professor Pierce,
however, was burdened with much other work, which prevented his giv-
ing to walnut blight the amount of attention which the walnut grow-
ers felt that the subject justified ; indeed, the importance of the matter,
owing to the extensive ravages of the disease, seemed to justify every
possible effort toward finding means for reducing the great losses
occasioned by this trouble. The walnut growers' associations had,
therefore, offered a standing reward of twenty thousand dollars for
a feasible remedy for the blight, and were eager to demand all possible
assistance in solving this problem. The legislature of 1905 made an
appropriation of four thousand dollars to the Regents of the University
of California, directing them to cause to be prosecuted investigations
looking for a remedy for the walnut blight, and under this appropria-
tion the present work was started.

In the spring of 1905 a laboratory was established in the city of
Whittier. Los Angeles County, primarily for the study of walnut
blight. This laboratory was placed in charge of Mr. Albert M. West,
an experienced bacteriologist, who, under the direction of the writer,
commenced the investigations which are reported in this bulletin. The
work was largely contributed to in later years by Messrs. Clayton 0.
Smith and Henry J. Ramsey, the latter working particularly upon the
pomological side of the investigation, while Mr. Smith's work has been

120 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

largely confined to the study of the bacterial organism which is the cause
of the disease.

It was found early in the work that the problem was much broader
than one simply of bacteriology or plant pathology proper, and as the
investigation developed, it became necessary to study the whole sub-
ject of walnut culture from a horticultural or pomological standpoint.
The establishment of the Southern California Plant Disease Laboratory
at Whittier as a permanent institution made such work possible. Soon
after the location of this laboratory, space was obtained on the grounds
of the Whittier State School for orchard planting of walnuts. Upon
this ground there was commenced, in the spring of 1907, an experi-
mental walnut orchard, in which may now be seen representative trees
of all the important varieties. Upon the same grounds, and also those
of the laboratory proper, a large amount of nursery work was also
commenced in connection with the study of methods of propagation
of the walnut, testing of different roots and other similar subjects.
In 1909 this portion of the work was mostly transferred to the Pasa-
dena City Farm near Alhambra, where it could be carried out on a
much larger scale. In addition to nursery experiments, considerable
work has also been done in the vicinity of Whittier and in other places
in top-grafting walnut trees in the orchard with the idea of determin-
ing the feasibility of working over undesirable trees to better varieties.
Much work has been done in searching for desirable walnut trees all
over the State, and such trees when found have been tested out quite
extensively by propagation, both in the nursery and upon old trees, as
mentioned above. A large amount of top-working of this sort has been
done upon the Pasadena City Farm, where a large seedling walnut
orchard already existed, and also in conjunction with several growers
in various parts of the State. Scions and nursery trees of promising
varieties have also been distributed quite extensively during the past
three or four years. In this way many new varieties will be tested in
various parts of the State much more quickly than would otherwise
have been the case. Considerable testing of root stocks has also been
brought about by the same means. A line of work similar to that at
Whittier has also been inaugurated on the University Farm at Davis,
and it is hoped that this work may be continued and extended there
on account of the growing importance of the walnut industry in the
northern part of the State. As now presented, the results of this inves-
tigation cover practically all phases of the subject of walnut culture in
California, both north and south.

The English or Persian walnut, Juglans regia, constitutes one of the
most important and one of the most attractive tree crops of California.
In southern California, to which portion of the State the crop on a

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 121

commercial basis has thus far been largely confined, the walnut is sec-
ond only to the orange in prominence. Under favorable and normal
conditions walnut growing is one of the most attractive horticultural
pursuits which can be imagined. The trees require comparatively little
care compared with citrus fruits, and they are subject to comparatively
few pests or diseases. The price of the crop has been almost invariably
good, and first-class walnuts have always sold readily at excellent prices.
The product is not subject to decay, freezing, or other dangers which
are common to most fruit crops. No unusual skill is required to con-
duct a well-established walnut grove, and all in all this crop is, as said
above, perhaps the most attractive and the best adapted to the average
settler coming to California when favorable conditions for its produc-
tion obtain.

Unfortunately, this bright picture of the walnut industry has been
seriously marred during recent years by the disease above referred
to, and various evils which have been more or less attendant upon it.
Fortunately, however, the prospects of the industry are at present very
much brighter than they have been in the recent past, and there is now
every reason to believe that walnut growing is again coming into its
own upon a new and better basis, as one of our- best horticultural pur-
suits. The walnut has been grown in California to a greater or less
extent since the early days of white settlement, but it is only within
about the last twenty-five years that the crop has assumed the rank of
an important horticultural product. Up to about 1900 the production
of walnuts in the State rapidly increased, reaching an amount in that
year which was nof exceeded until 1911, and which fell off nearly one
half during the intervening period. Until very recently about the
whole commercial crop was produced in southern California, and almost
exclusively in the counties of Santa Barbara, Ventura, Los Angeles,
and Orange. In these counties, which still contain by far the bulk of
our walnut acreage, there is probably at present more than thirty
thousand acres of walnuts, young and old. It was thought at first that
this portion of the State was the only one adapted to this crop, but
later experience has shown this idea to be erroneous; and especially
since land values have become so high in much of the southern Cali-
fornia walnut country, and the citrus industry has extended over much
of the available walnut land of that portion of the State, the walnut
has commenced to go north, so that at present there is a strong indica-
tion that large walnut districts in the future may be found in the cen-
tral portion, probably within a radius of one hundred and fifty miles
from San Francisco, as well as in the southern districts.

122 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

FIG. 1. — Bloom of English walnut, showing catkins (A) coming from the old wood,
and the new growth and leaves with two young nuts or pistillate blooms (B) at
the end.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 123

THE ENGLISH WALNUT.

(Juglans regia.)

"Juglans regia, which is a large and lofty tree with stout, spread-
ing branches, is probably indigenous to the mountains of Greece, in
Armenia, in the region south of the Caucasus and the Caspian Sea, on
the northwestern and northern Himalayas, and in Burmah (A. de Can-
dolle, Origine des Plantes Cultivees, 342). It was cultivated in north-
ern India in very early times, and carried then to China, where it is
still grown on a large scale (Bretschneider, On the Value and Study
of Chinese Botanical Works, 16; Early European Researches into the
Flora of China, 174). It is probably not indigenous, however, to China,
nor is there any evidence that this tree is a native of Japan, as many
authors have believed, although it is occasionally seen in that country
in the neighborhood of human habitations. The Greeks cultivated a
variety of this tree obtained from Persia ; the Romans carried it to
Italy, whence its cultivation as a fruit tree has spread through all the
countries of southern and western Europe, the Pacific states of North
America. Chile, and other temperate regions. The nut of the wild tree
is small, with a thick, hard shell and small kernel, and is scarcely
edible."*

The walnut tree is naturally of rapid and thrifty growth, and forms
an attractive, decidedly ornamental tree, with a clean trunk and tall,
spreading top. The bark of the young growth is usually of a dark
green color with a smooth, glossy appearance, that of the larger limbs
light colored or nearly white and fairly smooth, with a trunk of the
same appearance, the bark remaining smooth until the tree becomes
of considerable age and size. The fruit is a true nut, being borne in
an outer, fibrous, rather fleshy enveloping husk or shuck, which opens
and allows the nut to drop out freely when matured. The walnut in
its best commercial form is one of the best of nuts, being of good size,
attractive appearance, easily cracked, and having a kernel of pleasing
flavor and attractive appearance, which is readily removed from the
shell. It is also healthful and nutritious and a valuable article of food.

The foliage of the tree is composed of large, compound, pinnate
leaves, which are deciduous in the fall. The flowers are of two kinds,
staminate and pistillate (male and female), both born on the same tree.
The staminate blossoms are born on long, pendulous catkins, which
develop in spring from naked buds already formed on the twigs of
the preceding year. These catkins contain an abundance of light, dusty,
yellow pollen, which is carried by the wind to the pistillate or fruiting

* Sargent, Silva of North America.

124 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

blossoms. The latter are produced at the tips of young shoots coming
out in the spring from terminal buds on twigs of the previous year's
growth. These consist of miniature nuts, or ovaries, each bearing at its

FIG. 2.— Mature walnuts, dropping from shucks. (Courtesy Kruckeberg Press.)

extremity a two-branched, feathery stigma, which is designed to catch
the pollen coming in the air from the catkins. After pollination the
stigmas wither away and the pistillate flowers develop into nuts. In

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 125

California most of the blooming takes place in April and May, although
some unusually early or late trees bloom previous to or later than this
period. The nuts commonly mature during September and October.

The English walnut grows readily from seed, if the nuts are not
allowed to become too dry, and are planted with plenty of moisture dur-
ing the spring following their production. The seedlings are of strong
and vigorous growth, but in this species do not usually make very much
growth in height during the first season. A large taproot is formed,
usually longer and thicker than the stem above ground. The latter
remains comparatively short during the first year, but makes very much
more growth the second year. Trees averaging only about one foot in
height at the end of the first year will frequently make a growth of
ten or twelve feet, or even more, the second year. Seedling trees,
though varying widely, are usually vigorous, thrifty and long-lived,
so long as soil and climatic conditions are favorable. The English
walnut on its own root, however, has little adaptability to unfavorable
conditions, and is very easily injured or killed by lack of moisture,
excessive moisture, poor soil, or other unfavorable conditions. While a
long-lived tree in the Old World, growing in regions of abundant nat-
ural rainfall, the seedling walnut has proven itself much shorter-lived in
California, and many of the older groves have largely died out. There
are a few trees in the State close to sixty years of age, but these are
mostly in the northern part, where the rainfall is fairly abundant. In
the south many trees and groves planted less than forty years ago have
almost entirely died out, largely on account of an uncertain or irregu-
lar supply of soil moisture.1

The seedling English walnut is rather slow in coming into bearing,
most trees producing very few nuts until the fifth or sixth year after
planting or even later. Different trees, however, vary widely in this
respect. The production per tree also varies greatly. The average
product per year for the older seedling groves of the State is scarcely
more than 50 pounds per tree, although many individual trees far
exceed this. One hundred pounds per tree at an age of fifteen to
twenty years may be considered quite satisfactory, according to pres-
ent production, while some individual trees of particularly large size
and heavy bearing qualities, run up to 300 pounds or a little more.
There are a few very large old seedling trees in the State, standing in
good soil with no other trees close about them, which have produced as
high as 400 or even 500 pounds of nuts per year, but this is very excep-
tional and cannot be considered on the same basis with trees planted in

Belong (Rep. Cal. Bd. Hort. 1895-96) quotes accounts of Old World walnut trees
of ten, fifteen or even more feet in diameter and bearing as much as 2,000 pounds of
nuts per year. One of these trees is estimated to be at least 1,000 years old. See
Gardners' Chronicle, London, 1852, p. 568; 1857, p. 694; 1877, p. 310.

126 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

orchard form.1 If walnut trees could be obtained which would average
200 pounds of good nuts per tree in the orchard, the profits from such
a planting would probably equal the average returns from citrus groves,
while 300 pound trees would be even better than the latter in the long
run. Since such trees already exist in individual cases, there is no
reason to doubt that it may ultimately be possible to produce commer-
cial orchards of this sort.

During the many years during which the walnut has been under
domestication, both in the old world and the new, it has, like all other
cultivated plants, come to vary to a large extent in individual trees
in regard to the characteristics of the tree, and particularly in regard
to the size, form, flavor and other qualities of its fruit. Likewise, as
with other crops, certain individuals of superior merit of one sort or
another have been noted from time to time, and many such individ-
uals have been given definite names as special varieties and the
peculiar properties of these varieties have been perpetuated by bud-
ding or grafting. In this way we have many definite varieties of the
walnut, just as with the apple, peach and other fruits. In a broader
way, the walnut has also become broken up into certain more or less
well-defined types, which come true to a certain extent from seed.

OTHER SPECIES OF WALNUT.

A considerable number of walnut species is found in various portions
of the world, in addition to the cultivated form, Juglans regia. "Jug-
lans is now confined to the temperate and southern parts of North
America, the Antilles, South America from Venezuela to Peru, the
Caucasus, Persia and northwestern India, Manchuria, northern China,
and Japan. About ten species are known; two are widely distributed
in the forests of eastern North America; one inhabits western Texas,
New Mexico, and Arizona, ranging far south into Mexico, where one
and perhaps two other species occur; and one inhabits the valleys of
western California. The flora of the Antilles contains a single species
of Juglans, while two or perhaps three others occur in the northern
and western countries of South America. In the old world the genus
is represented by Juglans regia, an inhabitant of southeastern Europe
and western Asia and now cultivated in all temperate countries, by
Juglans mandshurica of the Amur valley and northern China, and
by Juglans sieboldiana of Japan."*

JThe famous Payne tree, near San Jos6, has produced over 700 pounds of nuts in
one year, but this is a large black walnut tree, topworked in the branches.
* Sargent, Silva of North America.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

127

FIG. 3.— Black walnuts. 1, Southern California (calif ornica) ; 2, Arizona (major) ;
3, five different types of rupestris from Texas and New Mexico; 4, Northern
California (Tiindsii) ; 5, Eastern (nigra).

128 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

AMERICAN BLACK WALNUT.

(Juglans nigra.)

This is the native walnut of the Middle West, occurring in river
bottoms and valleys from western Massachusetts to Minnesota, south-
ward to Georgia, Florida, Mississippi, and Texas, and forming one of
the finest trees of Ohio, Illinois, Nebraska, Kansas, Kentucky, western
Pennsylvania and other portions of the Middle West. It is a tall,
erect-growing tree with a large, straight trunk covered with deeply-
furrowed, narrow-ridged bark. The fruit is large, with a thick husk,
containing a nut which is of brown or, when dry, nearly black color,
with a hard, thick shell marked on the surface with deep, narrow fur-
rows and prominent, irregular ridges. This tree is not native to Cali-
fornia, but was brought here by the first settlers from the East, and
has been planted quite abundantly since the early fifties. In California
the true eastern species is of very slow growth during its early years,
and is distinguished from all others by its very rough nuts. Other
conspicuous characteristics are the fact that it is extremely late in
coming out in the spring, the trees remaining bare and dormant long
after other walnuts are in full leaf, while at the same time, it is one
of the first to drop its foliage in the fall. Typical trees of the true
Juglans nigra, grown from seed introduced from various Middle West
States, may be found growing about almost all of the older towns of
the State, particularly in the central and northern portions.

CALIFORNIA BLACK WALNUT.

The first American explorers of California found growing here native
walnut trees which have been variously classified by botanists. Sereno
Watson1 in 1875 described Juglans calif ornica as "A large shrub or
tree in the vicinity of San Francisco, growing 40 to 60 feet high and
2 to 4 feet in diameter, and ranging southward to Santa Barbara,
southern Arizona and Sonora." He includes in this species what
Torrey had previously described as Juglans rupestris, var. major,
stating that "The more eastern Juglans rupestris is but 6 to 20 feet
high, with more numerous and usually more acuminate leaflets," etc.
To the latter species he also ascribes a smaller, thicker walled nut than
that of calif ornica. Most of the standard works, such as those of Sar-
gent and Britton, follow this arrangement, giving the one species Jug-
lans calif ornica for this State, with a range extending over most of
the State. Britton2 states, for instance, page 220, that "This walnut

:Proc. Am. Acad. Arts and Sc. Vol. 10 :349, 1875.
2North American Trees.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 129

occurs in river bottoms and stream banks in western California, extend-
ing from Los Angeles County northward to Napa County. It is a very
beautiful tree, attaining a height of 60 feet, with a trunk diameter of
20 inches. Sometimes, however, it is reduced to a shrub."

Locally it has long been noted that there are in California two more
or less distinct species of native walnut, that of the north and that of
the south. Some have classed the southern form as Juglans rupestris,
but very little observation is necessary to show that the native walnut
of southern California is not that which is included under this name.
Jepson,1 in the Bulletin of the Southern California Academy of Sci-
ences, discusses this matter, concluding that Watson undoubtedly had
in mind the southern California form, and that, therefore, this must
be taken as the type of Juglans calif ornica. For the northern form he
proposes the name Juglans calif ornica, var. hindsii, naming it in honor
of Richard Brinsley Hinds, botanist of the Sulphur Expedition, who
first discovered the California walnut on the lower Sacramento River
in 1837. In a later work Jepson2 again classes all the California native
walnuts under the species calif ornica, stating that "The northern form,
named var. Hindsii — Jepson, is characterized by its distinctly arbore-
ous form, tall trunks and larger fruits (1J to 2 inches in diameter).
Such differences may be readily attributable to the climatic and soil
conditions of the northern habitat."

The study of the native California black walnut having become of
considerable importance in this work in connection with the subject
of rootstocks for the English walnut, we have given no little attention
to an effort to determine the true relationships of the black walnuts
found growing in various portions of the State. As Jepson and others
have noted, there is a marked segregation of these trees into the north-
ern or central and the southern portions of the State, with a broad ter-
ritory between, in which it is evident that at the present time at least
no native walnuts occur.

NORTHERN CALIFORNIA BLACK WALNUTS.

In the upper portion of the State no tree is more conspicuous as a
shade and street tree, especially about the older towns, than that which
is called the California black walnut. Among these may be found many
specimens of the eastern walnut, Juglans nigra, which may be easily
identified by their rough nuts, late development in spring and early
shedding of the leaves in the fall. Excluding these, there remain
very numerous specimens of the so-called true California walnut, a

'Vol. VII, No. 1, p. 23, 1908.
2The Silva of California.

2—231

130

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

tall, erect-growing tree, having somewhat smaller leaves and nuts and
smoother bark than the eastern species, with nuts the surface of which
is almost perfectly smooth. This type is popularly supposed to be
native to, and commonly distributed in, the northern half of the State.
Inquiry soon develops, however, that the majority of these trees have
been planted where they now stand within the memory of people still
living.

FIG. 4. — Northern California black walnuts, south of Gilroy.

In this way, the history of numerous very fine, large, old trees can
be ascertained, the oldest of which are invariably found to have been
planted between 1850 and 1860. Such, for instance, are the two very
large trees standing by the roadside just south of Gilroy, and numer-
ous specimens about San Jose, Hayward, Stockton, Vacaville, Win-
ters, Suisun, Santa Rosa, Napa, Colusa, Marysville, Yuba City, Chico,
Tehama, and many of the old mining and commercial towns of the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 131

western slope of the Sierra Nevada, the San Joaquin Valley, and
on both sides of the Sacramento Valley. In each and every case the
history and original planting of these old trees, which represent the
largest California black walnut trees in the State, can be definitely
ascertained. In his investigations on the subject Jepson found two
localities where this tree appeared to have been growing naturally at
the time of the advent of the first white settlers. On this point he
states as follows:* "There are two centers of distribution, one in the
north and one in the south, without connecting localities so far as I
have been able to determine. In the north it occurs in the lower Sac-
ramento region, keeping to the banks of the river islands of Andrus,
Grand, and others, and along streams in the valleys at the western base
of Monte Diablo, specifically on Walnut Creek and Lafayette Creek."
In our investigations conclusions were reached coinciding with Jep-
son's, that these were two of the original homes of the northern Cali-
fornia black walnut, and a third location was added to the list which
appeared to be older than either of the other two. This was a station
known locally as Walnut Grove, situated on the east slope close to the
top of the first divide east of Napa, near Atlas post office. In this
locality there exists along the mountain-side, near the top, a series of
small ponds or marshes, each consisting of a cup-like depression or ter-
race in the hillside, about the edges of which discharge several springs.
Each of these terraces no doubt contained at one time a small body of
water, but in the course of time they have filled up with vegetation
and soil into swamps and mud holes. There are some eight or ten of
these formations scattered along the hillside within a mile or so, the
largest, the northernmost one, having an area of possibly three or four
acres. The whole hillside throughout this locality is covered with a
dense growth of native trees characteristic of the region, particularly
the Oregon maple and black oak, with California laurels and madrones
in the deeper canons. The soil is deep and moist upon this slope, and
all vegetation is very luxuriant. On the largest and northernmost of
the little basins mentioned there stand, near the north end, three large,
black walnut trees, one of which appears to be by far the oldest wal-
nut tree in the State. This consists really of a group of seven good
sized trees, all arising from a common base, which evidently are sprouts
or second-growth from the stump of a still older tree. The individual
stems in this group form very tall, clean trunks, as upright and tree-
like in form as the best type of the eastern walnut. The other two
trees in this group have single trunks at the base, growing up with
clean, erect trunks and lofty, spreading tops. They resemble the first
mentioned tree in most respects, save that one of them has deeply fur-

*Bulletin of the Southern California Academy of Science, Vol. 1, p. 23, 1908.

132 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

rowed bark much resembling that of Juglans nigra. All of these trees
bear medium sized, almost perfectly smooth nuts, similar to those of
the northern California black walnut trees found growing about the
various towns mentioned above. It is evident at first sight that these

FIG. 5. — Old black walnut tree at Walnut Grove, Napa County.

are very old and on the decline. They are gradually dying all over the
tops and large limbs are breaking off and falling to the ground.

Around each of the other basins in the hillside is found a group of
similar trees, some with single trunks, others composed of several stems

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 133

coming from a common base. Other trees are found in considerable
numbers scattered here and there through the forest and about the hill-
side between the springy basins. Quite a number of these scattering
trees have recently been cut for wood. Altogether there are several
hundred of the trees. Evidently they have seeded spontaneously from
the older ones and become distributed over an area of about a square
mile by natural means. The impression gained at present, however^
from all these trees, is that they are no longer reproducing to any
extent, but are gradually dying out. There is hardly a specimen less
than at least twenty years of age, or possibly fifty years might be nearer
the truth. All the older trees are dying back and breaking down and
show very little vigorous, new development. The latter is seen only in
the case of those trees which have been cut down during the last two or
three years. In these cases a very vigorous crop of sprouts has been sent
up from each stump.

Examination of the stumps of some of these cut-off trees shows one
that many of them were more than one hundred years of age when cut,
and this is true even of some of the smaller ones. Some may be found
which are considerably older than this and apparently well up toward
two hundred years old. The broken off stem shown in the picture of
the largest tree was cut off and found to be at least sixty years of age,
and probably considerably older than this at the base. This was much
the smallest of the trunks in this group.

The little glade in which this tree stands was evidently the site of
an Indian village, as evidenced by numerous arrow heads, spear points,
mortars, etc., which have been found there. On investigation these
trees show beyond all possible doubt that many of them must have been
large, old trees even at the time of the Spanish occupation of Cali-
fornia, and that they could not have been planted by any white people.
This grove can be most readily reached by driving from Napa to Wil-
son's Inn, a summer resort, at which is located Atlas post office, and
from which a wood road leads down to the walnut trees at a distance
of about two miles.

A few miles southeast of this grove, on the old Combs ranch in Gor-
don Valley, there stand several black walnut trees, one of which is par-
ticularly large; early settlers state that this tree existed from their
earliest recollection, but that they can remember it as a comparatively
small tree. It is, therefore, probably older than any of the trees planted
about the towns during the past sixty years, but younger than those
upon the mountain-side, from which it presumably descended. One
of the oldest residents of this region, Mr. Joe Gordon, of Gordon Val-
ley, was interviewed in regard to the history of these trees. Mr. Gordon
is of Spanish descent and was born and has always lived in this vicin-

134

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 135

ity, being now a man of advanced age. Mr. Gordon stated that the one
tree just mentioned had existed as long as he could remember, but he
could recollect it as a small tree in his boyhood. In the grove on the
mountain-side, he stated, there were old trees as large as any which
are there now as far back as he could remember in his earliest boyhood.
Several of the earliest American settlers, whose memory goes back for
nearly sixty years, make the same statement in regard to these trees.

The history of the two stations mentioned in the quotation from
Jepson has been quite thoroughly investigated in connection with this
work. In regard to the one mentioned near the base of Mount Diablo,
we may say that in the valleys on the west side of the mountain in
the vicinity of the towns of Walnut Creek, Danville, Lafayette and
Concord, there are a great many California black walnut trees, both
young and old, most of which have been planted within the memory
of people still living in that vicinity. Inquiry shows, however, that
there was one locality in this region where black walnut trees were
growing when the first white people arrived in the country. This is
evidenced by the memory of various old settlers, also by the name
"Walnut Creek," and the fact that the original Spanish grant com-
prising this region bore the name ' ' Kancho Arroyo de las Nueces y Bol-
bones." "This fact," to quote from Mr. Ely Hutchinson, "is con-
firmation strong as proofs of holy writ that the walnut was growing
in the vicinity when the Mexicans sent in their petition for the grant. ' '
The name "Bolbones" appears to be at present quite obscure, but,
according to the investigations of Mr. Hutchinson, it probably refers
to some other kind of tree which grew in that vicinity. The original
trees of this locality were located in the so-called "Moraga Valley" in
the Walnut Creek country east of Oakland. Some of these trees are
still standing, although many of the finest were cut for timber many
years ago. These trees are of an extremely stately, tall-growing, clean-
trunk type, fully as much so as the best types of the eastern walnut,
Juglans nigra. They are all composed of single trunks and have the
appearance of being younger than the oldest trees in the Napa Moun-
tains. The bases of them are larger than any of the trees in the latter
locality, being in good, moist, deep soil in an open valley, free from
the competition of other trees. The nuts and foliage are entirely sim-
ilar to those of the Napa County trees.

The third original locality mentioned is that in the vicinity of the
town of Walnut Grove on the Sacramento River, about thirty miles
south of Sacramento city. Large, old, black walnut trees are very
abundant on the ranches in this locality, and there was until quite
recently a long row of large, fine, old trees along the river bank out-
side the levee from Walnut Grove north. These trees were cut down

136 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

a few years ago in repairing the levee. Although very large, they were
not the original trees of that locality, but were planted there within
comparatively recent times. Inquiry in the vicinity of Walnut Grove
has developed the information that when the first American settlers
came to the lower Sacramento there were a great many black walnut
trees growing in this vicinity. Mr. "William Holtlum, who at the time
of this investigation was thought to be about the oldest living settler
in the vicinity of Walnut Grove, came there about 1850. At that time,
he stated, there was quite a large grove of magnificent black walnut
trees growing at and below the fork of the river just below Walnut
Grove. There were twenty or more trees there over three feet in diam-
eter. Black walnut trees were scattered all along the river from Free-
port to Rio Vista, growing on the higher spots on the river bank rather
than in the more swampy land further back from the river.

On what is now the Hart place, near Isleton, there were some
especially large trees. The row of trees which stood along the river
near Walnut Grove was planted by one H. W. O'Dell. The earliest
planting was probably about 1856, followed by others up to the early
sixties. During the early fifties many people used to come to Wal-
nut Grove from the country about Vacaville, Elmira, and other places,
and carried away walnuts by the bushel and sack. Up and down the
river there was a great growth of live oak, white oak, ash, cotton-
wood and black walnut until 1856, when a great fire from the north
swept over the whole country destroying almost all the native tim-
ber. . . Mrs. Clara Lord, of Walnut Grove, stated that her parents
came to this locality in 1850 and set up a tent under three walnut trees
which stood in front of her present house. There were also many other
large black walnut trees in the locality at that time. . . Mr. Joe Wise
stated that he chopped wood on the river in 1853 and '54, and chopped
down many walnut trees 2-J feet and more in diameter. . . Mr. Robert
Sharp, of Walnut Grove, stated that he came to the vicinity in 1851,
when a boy, but remembers very distinctly that there were many large
walnut trees growing along the river at that time. Also that they had
to cut their way in with axes on account of the luxurious vegeta-
tion. . . Mr. Joe Greene, living two miles above Courtland, stated that
in the early days they cut out black walnut trees two, three and four
feet in diameter. Also that such trees grew among the timber along
the river bank rather than back in the swamps, and that they extended
south as far as Rio Vista. . . Mr. C. V. Talmage came to this region
in 1857, and stated that there were many immense black walnut trees
along the river at that time. He has trees on his place of immense size,
which were planted in 1858. . .

This data is sufficient to show that there was an abundant growth

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 137

of black walnut trees at this point previous to the first white settle-
ment. Apparently, none of the original trees now remain in this local-
ity, although some of the largest black walnut trees in the State may
be found here, having been planted in the fifties. These trees and the
nuts which they bear are of exactly the same type as those at Walnut
Creek and at Walnut Grove in the Napa Mountains.

It is not improbable that other localities of this sort may be found in
the northern part of the State, especialy in northeastern Napa County
where we have a fairly definite report of such original trees.

As to the oldest trees standing in the vicinity of the various towns
mentioned, the history of almost all of them can be ascertained. In
regard to the two large trees south of Gilroy, for instance, which are
some of the largest in the State, Judge S. F. Leib, of San Jose, writes
us as follows: "I was informed by Mr. Zuck (now deceased), who
examined into the matter for me, that the two large native California
black walnut trees about a half mile south of Gilroy fronting on the
public road were planted in 1856 or 1857 by Mr. Eeeve. I measured
them last fall and found each of them to be over four feet in diameter. ' '
About San Jose there are trees still older than these, most or all of
which appear to have been planted from nuts obtained at Walnut
Creek. About Stockton most of the oldest trees seem to have come
from Walnut Grove on the Sacramento River. In Suisun Valley there
are some particularly large, fine old trees on the Matthew Wolfskill
ranch and others, planted in the fifties. The nuts from which these
trees grew came mostly from Walnut Creek. There are some very
large trees on the Dan Berry place in the same vicinity. These are
thought to have been planted in the early fifties from Walnut Creek
nuts. In the vicinity of Vacaville there are numerous old trees ; one on
the W. B. Davis ranch east of Vacaville is said by Mr. Davis to have
been a natural seedling in Gordon Valley, Napa County, which was
moved to Vacaville in 1853. This is the largest tree on the place, stand-
ing just south of the Japanese bunk house. Mr. Davis states that he
grew a nursery in 1860 from nuts obtained at Walnut Grove on the
Sacramento River, and that most of the old trees about Vacaville came
from this planting. When he obtained the nuts there were many trees
at Walnut Grove three to four feet in diameter. On the Thurber place
in Pleasant Valley, between Vacaville and Winters, there are two large
trees in front of the house at the front gate and one north of the house
which were grown by Mr. Hough on the Joe Bassford place. He got
the nuts from Napa County, supposedly from wild trees. The long
rows of black walnuts on both sides of the road near the Fred Buck
place, most of which have been worked over into English walnuts, came
from the Wolfskill place near Winters. On the latter places, that of

138 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

John Wolfskill east of the road and that of his brother on the west
side, there are a great many old California black walnut trees, the old-
est being a row along the creek bank to the northwest of the road.
These trees, according to a statement of Mrs. S. Wolfskill, were planted
about 1855 by a man named McMahan, from nuts obtained in the
mountains east of Napa. (Presumably from the trees which we have
described.) Mrs. Wolfskill states that all the black walnut trees in this
vicinity originated from this planting. According to the recollection
of her sons, Joe and Will, however, John Wolfskill brought walnuts
from the Sacramento River about 1860 and planted them on the ranch.
Mr. W. W. Smith, of Vacaville, recollects that a man by the name of
Percy Wiggins, who formerly lived in Napa, told him that he found
walnuts growing wild in Conn Valley in the northern part of Napa
Valley, and planted a nursery of these about 1858. He sold all these
trees but one and allowed this one to grow where it stood, which was
in Browns Valley west of Napa. Mr. Smith took nuts from this tree
in 1873 and raised the trees which stand along the road on what is now
the Henry Bassford place near Vacaville, which trees were cut off and
worked over to English walnuts after they were a foot or more in
diameter.

We need not occupy our space with further details of this sort, hav-
ing given enough of this historical matter to show that the origin of
most of these old trees can be traced by inquiry among old settlers.

SOUTHERN CALIFORNIA TYPE.

In the southern part of the State black walnut trees, apparently
indigenous, are found growing over a considerable area, and, contrary
to the case in the northern part of the State, very few such trees have
been planted out along roadsides or for ornament. The southernmost
point at which the tree, to our knowledge, is found growing is in the
Santiago Canon east of the city of Orange. From this point north it
occurs sparingly near the mouth of the Santa Ana Canon, abundantly
in Brea Canon along the road between Fullerton and Pomona, and
scattered through various canons in the Puente hills west of this road.
It is quite abundant in the San Jose hills west of Pomona, especially
in the so-called Walnut Wash, which extends down toward Covina.
The species is scattered sparingly along the southern base of the high
mountains from the Cajon Pass above San Bernardino to Garvanza,
near Los Angeles. In the Santa Monica Mountains the tree is abun-
dant, especially on the northern slopes, near Lankershim, near the north
opening of the Cajuenga Pass, and in all canons through this range on

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

139

both sides to its northern extremity near Hueneme. The tree is abund-
ant along both branches of the Southern Pacific Railroad between Bur-
bank and Ventura and in the intervening country. That is to say, it
occurs in the vicinity of Chatsworth, Simi, and Moorpark, in the hills
north of the latter places, in the next valley north near Newhall and
on down the valley through Camulos, Fillmore and Santa Paula, and
in the foothills to the north of this valley (Santa Clara Valley of the

FIG. 7. — Native southern California black walnuts, Brea Canon.

south). Going farther north, the tree is not seen near the railroad,
but is abundant in the foothills up into the Ojai Valley back of Ven-
tura, and scattered along the foothill range back of Ventura and Car-
pinteria, north of which point near Santa Barbara the species begins
to grow scarce. Mr. C. W. Beers states that Mr, Ellwood Cooper has
pointed out to him trees which were undoubtedly growing wild in the
canons back of Mr. Cooper's ranch some twenty miles north of Santa
Barbara. From this point north we know of no well authenticated

140

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

record of native-growing black walnut trees until we reach those at
Walnut Creek near Mount Diablo, a distance of about three hundred
and fifty miles. We have investigated various reports of indigenous
trees in this stretch of country, but thus far have found evidence of all
such having been planted since the American occupation.

The southern California trees are considerably different in aspect
from those of the north, although individual specimens of each may be

FIG. 8. — Large southern California black walnut tree near roadside between Ventura

and Nordhoff.

found which resemble each other quite closely. The southern tree is
much more shrubby, frequently branching directly from the ground,
and tending to break up into a much branched, broad, low-spreading
head even when a single trunk is formed. It is not, as is popularly
supposed, a dwarf or slow-growing tree, except in so far as it is influ-
enced to develop in this way by the fact that it is able to and frequently

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 141

does grow upon dry, exposed hillsides rather than in deep, rich, moist
soil, to which the original groves of the northern California type are
confined. In a similar situation, the southern California tree grows
rapidly and vigorously, forming particularly a very thick trunk, but
with a round, bushy top rather than with a single, erect, continuous,
central axis. Along the road between Ventura and Nordhoff and in
the hills about the latter vicinity, trees of extremely great trunk
diameter may be seen, but the tops are very broad, low and bushy.
Professor Jepson has well characterized this form as "elephantine" in
comparison to the erect, arboreous habit of the northern type. There is
an immense tree of apparently the southern type on the premises of
F. M. Gifford, at No. 18 East Haley street, Santa Barbara. This tree
is of unknown age and over four feet in diameter. There is another
extremely large one a few miles northwest of Covina, forming a well-
known landmark and resting place by the roadside. Many other
instances could be cited to show that the southern California black wal-
nut is not at all a dwarf tree, but is rather one of rapid growth and large
size in diameter when growing under conditions at all favorable.

The nut of the southern type varies considerably in size on different
trees, but in general it is much smaller than that of the northern type.

Relationship Between the Southern and Northern California Types of
Black Walnut. — Assuming that the southern California type of black
walnut is indigenous to the region where it is found, which fact there is
no reason to doubt, the question arises, whence came these three, isolated,
original groups of the northern tree 1 It is most natural to agree with
Dr. Jepson that these northern trees were planted by the Indians many
years ago, either intentionally or by chance, with nuts which they had
brought from the south for food and exchange. Each of the three local-
ities is known to have been the site of an abundant Indian population,
and it is also well known that walnuts and other nuts were carried about
by the Indians for such purposes.

Mr. Joe Gordon, alluded to above, whose memory goes back to about
1846, states that in his youth, when Indians were abundant in Solano and
Nap a counties, they frequently used black walnuts with which to trade
with the white people for various articles which they desired. On being
questioned as to his idea of the origin of the old walnut trees in his
vicinity, Mr. Gordon stated that he had heard that black walnuts grew
wild in the southern part of the State and that his idea had been that the
Indians brought nuts from the south from which these trees originated.
The more erect type of tree and the larger nuts of the northern type are
explained by Professor Jepson as an influence of environment.

In order to obtain further light upon this question, we commenced

142 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 9. — One-year-old black walnut seedlings; southern California on the left (1),
eastern in the center (2), northern California on the right (3).

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 143

several years ago planting both southern and northern California wal-
nuts side by side in nurseries both in the south and in the north. When
so grown the resulting trees have shown very marked and constant differ-
ences from one another and the characteristics of each type as shown in
the nursery have remained constant both in the south and in the north.
Seedlings of the southern type are much more branching and bushy than
those of the northern, sending out large, lateral branches and secondary
stems close to the ground, while the northern seedlings grow erect with
one stem and few large laterals. In this way the southern seedlings are
broad, bushy and covered with foliage clear to the ground, in marked
contrast to the other type. The leaves of the southern tree are some-
what smaller, more finely divided and with more sharply pointed leaflets
than those of the northern. They are also a little lighter in color and
the bark is of a brighter green. One of the most pronounced differences
lies in the fact that the southern seedlings come out much earlier in the
spring and continue to hold their foliage and grow much later in the fall
than the northern, whether they are planted in the south or in the north.
This is a most decided difference and holds true constantly, the rows of
southern seedlings being always in full leaf in the spring while the
northern are still bare, and showing the same condition in the fall for
several weeks after the northern California seedlings have dropped all
their leaves. This characteristic is one upon which environment, in the
first generation at least, has no apparent effect. In the germination of
the nuts the two forms also show a difference. Nuts of the southern
California type are much quicker to germinate in the spring and when
planted in the same conditions invariably sprout much earlier than the
northern nuts, whether they be planted in the north or south.

Another decided difference lies in the relative effect upon trees of the
two forms of various conditions such as dryness, heat, etc. An appar-
ently physiological disease, which we will discuss later, called the "yel-
lows" or "frizzles," affects the northern California type very badly in
some instances, but we have never known a southern California seedling
to show this disease, even though grown in rows adjoining badly-affected
northern California trees. Another disease, nursery root rot, see page
379, invariably picks out the southern California black seedlings, never
affecting those of the northern type in the same nursery.

We know of no trees of the southern California type of any consid-
erable age now growing in the north. There are several of these trees
about four years of age planted by Professor E. B. Babcock on the Uni-
versity grounds west of the new agricultural building, and these trees are
of the characteristic bushy-topped form, coming out early in the spring
and holding their foliage very late in the fall, in marked contrast to
trees of the northern type. We have planted southern nuts in several
nurseries in the northern part of the State and found that the resulting

144 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 10. — Young northern California black walnut tree, State School grounds,

Whittier.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

145

seedlings retained all their usual characteristics in relation to seedlings
from northern California nuts. No effect whatever of environment
could be seen in any of these cases. Of the northern California walnuts
in the southern part of the State, we know of one considerable planting

FIG. 11. — Young southern California black walnut tree, State School grounds, Whittier.

near Pasadena where the trees are now old enough to produce quite large
crops of nuts. These trees retain all the characteristics of the northern
California type in regard to the size of the nuts and the time of foliation
and defoliation.
3—231

146 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

Considering the characteristic and constant difference in the form of
the trees, both in old specimens and in the nursery, the most pronounced
difference in the vegetative period when the trees are grown side by side,
and the same difference under the same circumstances in relation to the
diseases mentioned, we feel, on the whole, extremely doubtful as to the
identity of the northern California type with that of the south. It
seems to us certain that the northern type is at least a distinct variety of
the southern, in which case Jepson's classification of it as Juglans cali-
f arnica var. hindsii would be acceptable. Still it is remarkable that a
variety so uniformly distinct from the original type in the larger size of
the nuts, the upright form of the tree, later foliation and earlier defolia-
tion period, slower sprouting of the nuts and different behavior under
certain climatic conditions should comprise all the northern California
trees without exception. It is also remarkable that so distinct a variety
should have developed in the north without the development of any other
distinct varieties in the south or other portions of the State. Almost
the only way to account for the northern California type as a variety of
the southern is to assume that the northern trees are all descended
originally from one individual tree, which tree happened to be of its
distinct type.

We are considerably inclined toward another solution of the question,
namely, that the northern California trees represent the relics of an
almost extinct species, paralleling the case of several other trees found
in California. In this case the northern California walnut would prob-
ably be called Juglans hindsii Jepson. Even under this supposition, it
is true in all probability that the original trees of the northern type
found in the three localities mentioned were planted by the Indians
rather than representing an original, indigenous growth. What, then,
the history of the tree was previous to these plantings and when the
original planting in these localities took place must still remain a mys-
tery^ ... Present indications are that the Napa County ^station is the oldest
of the three, and it is possible that the tree was originally a 'native of
that portion of the State whence the nuts were carried by Indians to
other localities.

OTHER NATIVE WALNUTS OF THE SOUTHWEST.

In addition to the California species of black walnut, there have been
more or less distinctly recognized by botanists at least two other species,
namely Juglans rupestris and Juglans major, the range of these forms
extending over Arizona, New .Mexico, and Texas. Much uncertainty
has prevailed and still exists as to the identity and, limits of these
species, especially as to the limitations of Juglans rupestris. By some

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 147

the latter species has been held to include, at least as a variety, the
southern California type, while Juglans major has frequently been con-
sidered a variety of rupestris. The general understanding of rupestris
has been that it is a decidedly dwarf, shrubby type with very small
nuts, while major has been considered a larger and more erect form.
According to Britton, Juglans major is the species indigenous to Ari-
zona, particularly the western portion, while the range of rupestris is
found further eastward in New Mexico and Texas. We have not
studied this subject to any extent from a botanical standpoint, but in
connection with our investigations on rootstocks for the English walnut
we have received and planted nuts from all the states just mentioned,
and have also through correspondence gathered considerable informa-
tion concerning the native black walnuts of these states. From such
information, together with a study of the nuts which we have received
and the trees grown therefrom, we are convinced on one point, namely
that Juglans major of western Arizona and Juglans rupestris of New
Mexico and Texas are quite distinct from one another and also distinct
from either of the California types. It is true that all four of these
forms run more or less into one another, and the question as to whether
the differences between them are of varietal or specific rank does not
lie within the province of the present work. It is certain, however,
that in the nursery the four forms are very distinct and decidedly
different from one another. From our observations thus far it would
appear that there is as much similarity between Juglans major of Ari-
zona and Juglans hindsii of northern California as between any other
two of the four types. Our observations in this respect, however, extend
only to the general form and appearance of the old trees, seedlings, and
nuts.

NATIVE WALNUTS OF ARIZONA.

Black walnut trees of an evidently indigenous nature are found
growing in various portions of Arizona. The Arizona species was
formerly classified as Juglans rupestris, with a variety or second species
called Juglans major, the latter being supposedly a more erect and
tree-like type than the true rupestris. Professor J. J. Thornber of the
University of Arizona writes as follows: .

"We had supposed that Juglans rupestris was our common walnut
here and had classified it as such. Last year, however, I came to the
conclusion that our species, at least a considerable amount of' it,' is
Juglans major. This is our common walnut that grows in southern
Arizona, and it may be the only species. Juglans rupestris, as I under-
stand it, grows in Texas, though of course it may get as far as Arizona. ' '
Again, "I am sending you under separate cover two quarts of nuts of

148

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Juglans major, as we call it. The plant may be only a form of Juglans
rupestris." Again, "The tree (Juglans major] is common throughout
southern Arizona, in mountain canons and alluvial soils of flood plains.
It grows at as low an altitude here as 1,500 feet and apparently as high
in the mountains as 8,000 feet, so you see it has a wide range. ' '

FIG. 12. — Arizona black walnut tree, Vacaville.

One old tree which we found growing in California, of supposedly
Arizona origin, is of interest in this connection. This is located on the
home place of Mr. Harbison, near Vacaville, and is a very large, erect
tree said to have been planted about 1854. The story is that Mr. Har-
bison's father crossed the plains in that year and picked up some wal-
nuts in Arizona, from one of which this tree came. The tree is of a
decidedly erect, tree-like type with none of the dwarf or bush form

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 149

which is supposed to belong to Juglans rupestris. It is much like the
northern California black walnut in general appearance, but the nuts
are somewhat smaller and more deeply grooved and the aspect of the
foliage slightly different. Seedlings from this tree, and likewise those
grown from Arizona nuts, are in general appearance very much like
the northern California type, being of a rapid growth, erect, with dark-
colored bark and no large side branches. The tree is decidedly dif-
ferent in the nursery from the supposedly true Juglans rupestris of
Texas and New Mexico and it is therefore our conclusion that Juglans
major is a fairly distinct species as southwestern black walnuts go.

NATIVE WALNUTS OF TEXAS.

From Texas we have received many nuts of what we take to be the
true Juglans rupestris. These nuts, while varying greatly in size, are
smaller even than those of the southern California type, while some of
them are extremely tiny, averaging only about one half inch in diameter.
The nuts are characteristically marked by decidedly deep, branching
grooves, being easily distinguished in this respect from the California
species and from Juglans major of Arizona. As compared with nuts
of Juglans nigra these are much smaller in size, less abundantly grooved
and not ridged like those of the latter species. From such nuts develop
what appears to be true Juglans rupestris, a dwarf, shrub-like tree, of
comparatively slow growth even in good soil. These trees have a light-
grey bark, lighter in color than that of any other black walnuts. In
seedlings the bark toward the base of the tree is of this light-grey color,
prominently striped with still lighter markings, while toward the tops
the bark is of a characteristic, light, yellowish green. The seedlings
which we have raised have usually produced the first year only a single
stem with no side branches, which stem leans decidedly to one side
rather than standing up perpendicular to the ground. Our trees have
become rather bushy in later years but have continued with a single
main stem, slow growth and a leaning position. The foliage is composed
of leaves with rather narrow leaflets and a lighter or more bluish green
than those of other species. The type is decidedly different from any-
thing else which we have grown and its seedlings are entirely distinct
from those of the Arizona Juglans major, which are rapid-growing,
erect, wTith dark-colored, almost black bark.

In various lots of nuts received from Texas great variation has been
found in respect to size and degree of roughness. Some of the nuts
were of the diminutive size and characteristically deep-grooved type
described above, while others were larger and so much grooved as to
be indistinguishable from small nuts of Juglans nigra. So far as we

150 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

have raised trees from any of these nuts, however, they have all been
quite characteristic of the rupestris type described above. The range of
Juglans nigra extends westward into Texas so that it would not be sur-
prising to find hybrids and peculiar forms there, if the various species
hybridize as readily in that locality as they do in California. Mr. G. A.
Schattenberg, of Boerne, Texas, writes as follows:

"While I have not sufficiently investigated the matter, I have seen
enough to convince me that there are more than two very distinct forms
here. As with the pecan, hardly two trees can be found with nuts alike.
We collected over twenty-five bushels of nuts the past season and found
hardly two trees alike."

Mr. F. T. Ramsey, of Austin, Texas, another of our correspondents,
writes as follows :

"I will try to find you some of the small walnuts and mail them.
I do not believe that this particular walnut has been definitely men-
tioned by any botanist. The trees rarely have any top of any conse-
quence, but are inclined to throw up two or more branches near the
ground. They are sometimes nothing better than a big bush. In their
wild state they are usually found along the river banks and gravelly
streams in the limestone country running west from Austin. Lam-
passas is 70 miles from here, yet the nuts up there seem to be five or
six times as large as the nuts here. However, some trees here bear
larger nuts. There is infinite variation in the shape and size of both
nuts and trees, also in the time of ripening, which varies from the
first of August to November. Irrigation and good cultivation makes
them no larger. They are enormous bearers of pollen. There are a
few eastern black walnuts growing through this country. Upon the
steep sides and valleys of our rough rocky cedar mountains we have
a walnut that makes a large tree, but bears a nut in size just between
the rupestris and the black. The intermedia has a light green leaf free
from yellow tinge and grows slower than rupestris."

NATIVE WALNUTS OF NEW MEXICO.

Through correspondence we have obtained some information as to
native walnuts in New Mexico, and also have planted a considerable
number of nuts from that State. Professor E. O. Wooton, of the New
Mexico College of Agriculture, writes as follows: "I am sending you
specimens of two kinds of black walnuts obtained from this region.
Both kinds are obtained from relatively large trees which grow in the
Mogollon mountain region of this territory. Neither is Juglans rupes-
tris ; just what they may be I am unable to say. I have seen Juglans
rupestris growing and know to a certainty that the trees from which
these nuts came are not of that species."

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 151

Mr. James K. Metcalfe, of Silver City, New Mexico, from whom we
obtained large and small types of walnuts, native to his locality, writes :
' l We have always considered that trees which bear the larger nuts^ are
simply those which grow nearer water. ' ' Subsequent to Mr. Metcalf e 's
death, his daughter, Miss Mary Metcalf e, writes: "The trees grow to
fair size and then are invariably hollow. They are beautiful landscape
trees, 30 to 35 feet in height, diameter 2J feet or a little more. Grow
best where they can get down to water."

These New Mexico walnuts vary largely in size and roughness sim-
ilarly to those from Texas. All the trees which we have grown from
them have been of the rupestris type with light-grey bark, but varying
considerably in size and rapidity of growth. Some of them appear at
present as though they might make trees of considerable size, while
others bid fair to remain quite small like typical rupestris: We have
received nothing from either Texas or New Mexico which at all resem-
bles the typical Juglans major received from western Arizona. There
is a tree in the Botanical Gardens at Berkeley, on the east side of the
walk running across the upper end of the garden to the Mechanics '
Building, which was formerly labeled Juglans rupestris, and which
appears to be typical of this species as .we have grown it in the nurs-
ery. This tree has a single trunk and axis, but is of small size and
slow growth, with the typical light-grey bark, light-colored foliage and
leaning position.

OTHER AMERICAN SPECIES.

THE BUTTERNUT.

(Juglans cinerea).

This well known native nut of the Northeastern United States is
not native to California, although a number of specimen trees are to
be found in the State, especially on some of the older ranches. There
are trees in bearing on the John Wolfskill ranch at Winters, Matthew
Wolfskill's in Suisun Valley, George Payne has a tree near San Jose,
and there is one in Berkeley on Allston Way, just across from the
University cottages, on the lot which corners on the west side of Oxford
street. This species is easily identified by its long pointed nuts, the
surface of which is covered with high, rough, sharp ridges. It is a
tree of slow growth and of no economic importance in California.

152 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FOREIGN WALNUT SPECIES.

There is, as stated in our quotation from Professor Sargent's work
on page 171, a considerable number of native walnut species in various
parts of the world. Of these, the following are of some importance in
California :

Juglans sieboldiana Maxim. — This forms a good sized tree, bearing
nuts in long clusters or racemes with sometimes as many as twenty
in a cluster. The nuts are very hard shelled, rather long and pointed,
with a fairly smooth surface. The best and oldest specimen of this
tree in California is one at the Tower House in Shasta County, on the
road between Redding and Weaverville. This tree was planted about
1860, and is now a large, fine specimen, bearing heavy crops of nuts
every year. Another bearing tree may be seen on the grounds of the
old Experiment Station near Pomona, and there are probably others
in the State. The species is a native of the mountains of northern
Japan and is hardy, vigorous and of rapid growth. It is at present
of no economic importance in this State.

Juglans cordiformis Maxim. — A Japanese species considerably like the
last, trees of which are sometimes offered by nurserymen. There appears
to be some doubt whether this is more than a variety of Juglans siebol-
diana, differing in the shape of the nut, which is heart-shaped, flattened
and pointed at one end, with a shallow groove in the middle of the flat
sides.

Juglans mandshurica. — A species sometimes offered by nurserymen,
originating in Manchuria. Said by some to be simply a variety of the
English walnut.

Juglans boliviensis. — A species supposedly native of Bolivia, which is
said to form forests of fine, large, vigorous growing trees in that country.
This form has been secured by Mr. Frank A. Leib, of San Jose, from
whom we have received scions and produced young trees of this species.

Pterocarya caucasica. — We have obtained scions of this species, which
is supposed to be the Caucasian walnut of commerce, from Mr. George
Payne, of San Jose, who raised trees from seed. The seed is very small
and not at all like that of ordinary walnuts.

HYBRID WALNUTS.

The readiness with which different species of Juglans hybridize or
cross with one another is quite remarkable. To such an extent does
crossing of this sort take place in California wherever two species grow
anywhere near each other, that hybrid trees are extremely common in
every part of the State under such conditions. In the vicinity of most
of the northern towns, like San Jose, Stockton, Santa Rosa, Napa. Vaca-

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

153

FIG. 13.— Nuts of hybrid walnuts, each from a different tree. Natural size.
Royal in left-hand row, Paradox in right-hand row. Second nut from
bottom in left-hand row is Burbank Royal.

154 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

ville, Winters, Chico, and almost all the other towns of this portion of
the State, the northern California black walnut and the eastern black,
Juglans nigra, have been very commonly planted during the last sixty
years. The original specimens of nigra came from nuts brought from
the East and Middle West, and such trees are typical in every way of
their species. Among the younger trees, however, of later generations
which grew from nuts obtained from these eastern and California trees
growing more or less near together, numerous hybrids may be found, and
indeed after two or three generations in California it is almost impossible
to find a true type of Juglans nigra.

Another very common cross is that between various species of black
walnut and the English walnut, which cross with great frequency in
California wherever the species grow at all close together. These two
crosses, that of California black on eastern black and California black on
English, received considerable prominence several years ago through the
introduction by Luther Burbank of trees of these two types, to which he
gave the names respectively of Royal and Paradox. These names, in the
absence of any others, have been quite generally taken up in California
to designate trees resulting from crosses of this sort, so that now by the
name Paradox is generally understood any hybrid tree resulting from a
cross between English and black walnuts, while Royal means popularly
any hybrid resulting from a cross between two different species of black
walnut. Trees of both of these crosses, and all sorts of mixtures and
degrees between four or five different species of Juglans, are not uncom-
mon in the State, and the particular strains introduced by Mr. Burbank
are sim'ply two very good examples of hybrids which have likewise
originated spontaneously in various parts of the State.

That these trees are true hybrids and not simply variations due to
environment or other factors is evidenced in many ways, as may be seen
in the following discussion.

PARADOX HYBRIDS.

If the nuts from a black walnut tree of any species which stands near
an English walnut tree or grove be planted, the resulting seedlings are
apt to show a varying percentage of individuals of decidedly different
appearance from those of the black walnut. This difference consists in
a more or less marked resemblance to English walnut seedlings, the
trees having bark and leaves much resembling those of the English wal-
nut, and, in general, a very similar aspect to the latter species. In their
first year these seedlings may or may not differ decidedly in rate of
growth from the straight black walnut seedlings, but after the first year
in almost every case they show a more rapid development and within the
first four or five years they assume a size and rapidity of growth several

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 155

times as great as that of the other seedlings. The rapid growth of some
of these hybrid trees is truly astonishing. To such a tree which he
obtained in Santa Rosa Mr. Burbank gave the name Paradox, and, as
we have said, similar types are of common occurrence in almost every
lot of black seedling's originating from a tree near which an English
walnut stands.

The cross takes place just as freely in the opposite direction, so that if
the nuts from the English walnut tree be planted, hybrids are likewise
present among the seedlings from such nuts. In this case, however, it is
much more difficult to distinguish the hybrids from the true English
seedlings, inasmuch as there is much less difference in their appearance,
particularly during the first year. In after years the hybrids begin to
outstrip the others in rapidity of growth and differ from them in their
general appearance. Such trees are sometimes found in seedling walnut
groves, and become very conspicuous by their great size as compared with
the other, trees of the grove.

There is no noticeable difference in appearance between Paradox trees
grown from black walnuts and those grown from English walnuts.
Such trees are very slow in coming into bearing and in the majority of
instances are always very light producers of nuts. Many of the trees
bear enormous crops of catkins and pollen and many of them also pro-
duce very numerous pistillate blossoms, but for some reason the latter do
not seem to pollenize readily and very few nuts result. The nuts vary
considerably in different trees, but all that we have ever seen are inter-
mediate in form between the black and English walnuts, extremely hard
shelled and of no value whatever for eating purposes. There are a few
Paradox trees in the State which some years bear quite abundant crops
of nuts, but these in every case stand in close proximity to English wal-
nut trees, and it is possible that most of their nuts are pollenized by
pollen from the other trees. In the majority of instances, even though
the hybrid trees stand in the midst of wralnut groves where they were
planted for English walnut trees and bloom at about the same time as the
other trees, they set very few nuts.

The extent to which crossing takes place between the English wralnut
and various black walnut species varies with the nearness of the trees to
one another and also, in a general way, with the degree to which the
blooming time of the trees coincides. The percentage of hybrids from
certain trees, however, varies decidedly in different seasons. Some years
the nuts from a certain black walnut tree which stands near English
walnuts will give almost all hybrids, while in other years the seedlings
from the same tree will be almost all straight blacks. This difference is
presumably accounted for by variation in the blooming time of the tree
from year to year. Many trees give commonly as high as 40 or 50. per

156 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 14. — Paradox hybrid walnut five years old from the seed ; four years in present

location.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 157

cent hybrids, and seedlings from certain trees will some years run above
90 per cent.

We have observed Paradox trees resulting from the following crosses :

English x Northern California Black.

English x Southern California Black.

English x Juglans nigra.

English x Juglans major.

Also English x Paradox and English x Royal.

Trees of the first cross mentioned are found very commonly in certain
nurseries where the northern California species has been planted. Also
many trees grow in the northern part of the State among those which
have been planted for northern California black and also those which
have been planted for English. The so-called Smith tree near Elk Grove
is an example of the latter. This particular tree bears a much larger nut
than most Paradox walnuts. There are few trees of the cross in this
direction in the State, simply from the fact that very few seedling walnut
groves have been planted in the northern part of California.

Paradox trees grown from northern black nuts are very common.
Most notable is that called the Yuba City tree, which stands in the town
of the above name just across the street to the north of the court house.
This tree is undoubtedly the largest walnut tree in California, and, in all
probability, the largest in the world. Its great size is accounted for by
its age, as it appears to have been planted at least forty years ago along
with several neighboring ordinary black walnuts of the northern Cali-
fornia type. Any one interested in walnuts will be well repaid by a visit
to Yuba City for the purpose of seeing this grand tree. It is conspicuous
long before reaching the town, rearing its enormous head above every
other object in the whole vicinity. The tree bears a considerable quan-
tity of nuts every year, but the amount of the crop is insignificant in
proportion to the size of the tree.

Other Paradox trees occur in almost all the northern California towns
and may be distinguished by their great rapidity of growth, very thrifty
and vigorous appearance, foliage and general aspect closely resembling
that of the English walnut, and very light production of inferior, very
hard-shelled nuts.

Paradox trees resulting from the cross between the English and the
southern California black are quite frequent in the south. In this case
almost all the older trees resulted from the planting of the English
walnut, as very few of the southern California black walnuts have ever
been planted except in nurseries. In the latter case hybrids coming
from the nuts of the black walnut are very common. In many of the
seedling walnut orchards of the southern part of the State hybrids of the
English and southern black have occurred. Frequently several trees of

158

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

this sort would develop in one orchard. These trees soon attract atten-
tion by their rapidity of growth, great vigor, and failure to produce nuts.
Many of them have been dug out or grafted over as soon as their true
nature became apparent. The Killian.tr.ee east of El Monte was a
notable example of this type, growing in a seedling grove on somewhat
sandy land, and one which had been considerably neglected during its
earlier years. Under such conditions the trees suffered for water so that
they were small and poorly developed for their age. This one tree, how-

FIG. 15. — Two Paradox hybrid walnuts in English walnut grove south of

El Monte.

ever, was an enormous, thrifty, vigorous tree, several times as large as
any of the •others, but producing only a very few nuts and these of no
value. The tree^ljas now been grafted over to an English walnut variety.
In another orchard southwest of El Monte, on the road from that place
to Whittier, may be seen two very large Paradox trees standing in a
walnut grove upon decidedly wet land, where the regular English walnut
trees are small an.d in poor condition. The Paradox trees are several
times larger than tjife.o,thers and in a very thrifty, healthy condition.
These hybrid .trees, therefore, resist both drouth and excess of water

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

159

much better than does the English walnut, growing vigorously under
extreme conditions of both sorts.

In our experimental orchard on the state school grounds at "Whittier
there is a tree of the southern California species which was planted in
1907 along with the other trees. This tree is the first in the grove to
come out in the spring, and all the English walnut trees immediately
around it are French varieties, which do not come out for at least two
months after this black walnut tree is past its blooming period. In

FIG. 16. — Camulos tree; Paradox. (Photo by Prof. W. T. Clarke.)

the farther end of the orchard to the west, some five or six hundred
feet away, there are, several trees of southern California English walnut
varieties, some of wrhich produce pollen nearly as early as does this
black walnut tree. This tree in the spring of 1910, when four years
old from the nut, set a crop of several hundred nuts, over 90 per cent of
which when .planted the following year produced Paradox hybrids of
an extremely vigorous type. In 1911 the tree produced a much larger
crop of nuts. It would appear in this case that the crossing with
English pollen, probably mostly from the Chase variety, increased the-

160 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

productiveness of the tree to a marked extent as well as producing such
a large proportion of hybrids.

We will present but one other example of this cross, namely, the
Camulos tree on the old Camulos or Del Valle ranch situated close
to Camulos station, in Ventura County, on the Southern Pacific Rail-
road. This tree stands in a grove of old English walnut seedlings, and
evidently resulted from a chance cross with wild black walnut pollen
on the original tree whose nuts were used for growing the trees for
this orchard. This is a very large, spreading tree, and is notable in
producing much larger crops of nuts than any other Paradox tree
which we have found. This tree, for some reason, either on account
of inherent productiveness or crossing with the English walnut trees
about it, seems to produce every year a very large crop of nuts. It is
rather doubtful whether crossing with the other trees does take place
extensively, as these seedlings are very uniform and typical second-
generation Paradox trees rather than showing any indication of cross-
ing. We had at one time great hopes of this stock as a root for the
English walnut, on account of the productiveness of the tree and the
fact that its seedlings are of a very uniform type. Unfortunately,
however, like all other Paradox trees which we have tried, its seedlings
have failed to justify this hope and do not impart any exceptional
vigor to English walnut trees grafted upon them.

The Strong tree, on the ranch of Mrs. H. W. R. Strong, near Whit-
tier, is a notable example of this cross in the opposite direction, the
tree having been planted for a southern California black walnut. This
tree is thought to have been planted somewhere about thirty-five years
ago and was one of several supposed southern California black seed-
lings brought from Orange County. It closely resembles at first sight
the black walnut type, especially in the foliage, but at the same time
the leaf and particularly the bark show the English cross. The nut
is very similar to the southern California black walnut. The tree is
now of immense size, especially in the spread of branches, which extend
far out with the lower ones coming down and resting upon the ground.
The tree is comparatively a very light producer, but it is evident that
some years it is crossed quite freely by the neighboring English walnut
trees, and a large proportion of its seedlings have the appearance of
first cross Paradox trees. The original tree is apparently a Paradox
which partakes much more of the characteristics of the black walnut
(the female parent) than of those of the English.

Paradox trees resulting from a cross of the English on the eastern
black walnut, Juglans nigra, are comparatively uncommon, or at any
rate there are few trees in the State which can be traced positively
to this parentage. On the old Pleasants ranch in Pleasants Vallev.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 161

between Vacaville and "Winters, there is a large Paradox tree in the
dooryard near the corral which is probably of this cross. It is a par-
ticularly thrifty, beautiful tree, bearing fair crops of medium-sized
nuts of the usual Paradox type. In the vicinity of Goleta, in Santa
Barbara County, there is a considerable number of nigra trees planted
along the road on the county road from Santa Barbara to Goleta.
Intermixed with these nigra trees are numerous individuals of the
southern California black species, while on either side of the road are
extensive groves of English walnuts. In this instance a general mix-
ing takes place and among the seedlings of the various trees may be
found all sorts of freaks and hybrids. Nuts from the nigra trees give
a majority of straight nigra seedlings, some of the Royal type (having
crossed with the California black), and a considerable proportion of
strong, lusty individuals of the Paradox type, as shown by their leaves
which closely resemble those of the English walnut. Nigra trees come
out so much later in the spring than most of our English walnut trees
that it is remarkable that any cross takes place between these species.
Apparently, however, the English pollen either retains its vitality for
several weeks or there are some very late catkins which coincide in
development with the bloom of the nigra trees. These nigra Paradox
trees obtained from the Goleta nuts appear to be of an especially
thrifty, vigorous, hardy nature.

The large old Juglans major, or Arizona black walnut tree, which
we have described as standing on the Harbison ranch near Vacaville,
crosses freely with English walnuts in the vicinity, and usually about
40 per cent of the seedlings from this tree are of the Paradox type.
It is reasonable to suppose that the tree also crosses with the northern
California black walnut, many large specimens of which stand close
to this Arizona tree, but the pure seedlings of the northern California
and major are so much alike that we have not been able to distinguish
any hybrids between these two in the nursery.

Our experience, so far as it goes, seems to indicate that the English
walnut and the Paradox do not cross very readily, even though the trees
stand close together in the same orchard. Either this is the case or else
the resulting seedlings are indistinguishable from those of the Paradox
fertilized with its own pollen. Almost all Paradox trees are very light
producers and their seedlings are of a fairly uniform type, with no
individuals among them of exceptional vigor or differing noticeably in
appearance from the majority. Only in the case of the Strong tree
above mentioned have we found undoubted new crossing with the
English walnut among the seedlings, and this tree, as we have said,
resembles its black walnut parent much more than the English. Among
its seedlings there is always a large percentage of undoubted first

4—231

162

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

crosses, showing as very vigorous, characteristic trees entirely different
in appearance from those of the ordinary type. Such individuals have
all the vigor of growth and other characteristics of first-generation
Paradox trees.

"With Royal hybrids the English seems much more free to cross and
when English and Royal trees grow near together the resulting seedlings
are very much mixed. We know of no large trees which can be posi-
tively ascribed to this cross, but have obtained numerous examples of
them in the nursery among the seedlings of Royal trees which stood

FIG. 17. — Young Royal hybrid walnut tree, showing foliage.

close to English walnuts. Such individuals have all the vigor and desir-
able characteristics of the first cross.

Seedlings of Paradox Trees. — Paradox walnut trees of the first gener-
ation, that is, those of the first cross which originated directly from nuts
cross-pollinated by other species, are almost without exception trees of
unusual vigor and exceptional rapidity of growth. It 'would therefore
seem that seedlings from such trees, grown from the nuts which they
produce, would also be exceptionally vigorous trees. Such is not the
case, however, especially as regards the use of such seedlings as root-
stocks for the English walnut. These trees, in every instance which we
have tried or known of, do not show exceptional vigor, and English wal-

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 163

nuts grafted upon them do not grow as well as a rule as those on straight
black walnut roots. This subject will be discussed more fully in con-
nection with root stocks.

ROYAL HYBRID WALNUTS.

The name Royal, as we have explained, was first given by Mr. Bur-
bank to a supposed hybrid between the northern California black and
Juglans nigra, the eastern black. From the first published description
of this variety, however,* it would appear that the staminate parent,
supposedly a northern California black walnut, was in reality itself a
Royal hybrid, as the illustration of the nut of this tree shows a very
rough, small nut which must certainly contain more or less nigra blood.
Such trees are quite common about the streets of Santa Rosa. The Bur-
bank Royal is presumably, therefore, at least three quarters nigra and
one quarter northern California black.

Following Mr. Burbank's naming of this hybrid, the term Royal has
come to be applied in California to all hybrids resulting from crossing
between different black walnut species. There are many of these trees
in the State, particularly about the older towns like Santa Rosa, San
Jose, Vacaville, Winters, Chico, Red Bluff and other points in the Sac-
ramento Valley, Stockton, Santa Barbara and other places. It is indeed
difficult to find in the State a straight Juglans nigra, except those
grown from nuts brought directly from the East. It is rather remark-
able that the California species should hybridize so freely with nigra,
inasmuch as their blooming periods are quite distinct, the true nigra
coming out much later than any other black walnut. Such great varia-
tion exists indeed in these seedlings of California nigra trees that in
some cases it seems difficult to account for all this variation on the
basis of hybridization. For example, there are some nigra trees in the
State planted from nuts which came from the East, which have all the
charactertistics of the species. They are of slow growth, very late in
coming out in the spring, early in shedding their foliage in the fall and
bear the typical deep-grooved, sharp-ridged nigra nuts. When nuts
from these trees are planted it often happens that almost none of the
resulting seedlings are of the true nigra type, but they are hybrids,
freaks, variations, mutants, or whatever we may call them. We were
at one time inclined to the opinion that such variation was the effect
of environment, causing a breaking up of the original species, but
further study has brought us to believe that these are really hybrids.
We are led to this opinion from the fact that the percentage of these
unusual trees varies from year to year and that among the seedlings

* Supplement to New Creations in Fruits and Flowers, Burbank, 1898. See Pacific
Rural Press, Feb. 5, 1898.

164 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 18. — Burbank Royal hybrid walnut tree.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 165

of these California nigra trees there are always some typical of the
species, and some years a great many. Moreover, the progeny of certain
trees are almost all straight nigra and the proportion of such normal
seedlings is in inverse ratio to the opportunities for crossing with other
walnut species.

Juglans nigra was planted quite commonly with eastern nuts in Cali-
fornia in the very earliest years of the American occupation. Thus
there are many large trees of the species now growing in the State.
The trees are in almost every instance closely associated with specimens
of both California species and also more or less with the English walnut.
Many nuts from these original trees have been planted, and again those
from the next generation, down to three or four or perhaps more gener-
ations. The result has been that about the older towns in the central
and northern part of the State, trees may be found which present every
degree of gradation between nigra and the California species and also
many trees which have only slight resemblance to either, but might
easily be classed as entirely new species if their origin was not known.
It is hardly worth while to describe the individual trees of this sort,
so numerous are they in the State. In some cases it is difficult or impos-
sible to distinguish between hybrids and true nigra, as the nuts and
foliage are very similar. Most of them, however, can be pretty certainly
picked out on account of their unusual vigor of growth, the fact that
they come out earlier and hold their foliage later than true nigra,
a different aspect of the tree and foliage which cannot be definitely
described, and the fact that the nuts are somewhat smoother and vary
in other ways from those of true nigra, although various trees of the
latter species have nuts of very different form and size.

The Royal hybrid is very different from the Paradox in regard to
productiveness, being in almost every instance very precocious and an
unusually heavy bearer of nuts. The most productive nut trees which
we have ever seen are some of these Royal hybrid walnuts. In favor-
able seasons the ground beneath them will be covered several deep with
nuts, while there are still so many on the tree that it is difficult to see
where there could have been room for those which are upon the ground.

The cross between nigra and the northern California species is com-
monly illustrated in all the towns above mentioned. The Burbank Royal
is an unusually fine tree, being of tall, erect growth, with a clean, uni-
form trunk, and of exceptionally vigorous and rapid development. It
is a heavy bearer of very large nuts of a type more closely resembling
those of nigra than those of the California species. The 'nuts, in fact,
would pass for a fine large type of nigra, but are smoother than those of
the usual type. They are deeply and much grooved, but not ridged to
any extent.

166 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

There are other hybrid trees of spontaneous origin in the central and
northern part of the State which are fully equal in every way to the
Burbank type. These are too numerous for individual description. A
particularly fine one is the Pleasants tree which stands close to the
bridge on the county road near the old Pleasants ranch, between Vaca-
ville and Winters. This is one of the most beautiful walnut trees in
the State.

Juglans nigra crosses just as freely with the southern California black
walnut or perhaps even to a greater extent than it does with the north-
ern type, although this seems unusual since the blooming periods of the
two species are several months apart. The most notable examples of
southern California Royals are the El Molino or Oak Knoll trees, situ-
ated on the old Kewen or Mayberry ranch, now the property of Mr.
H. E. Huntington and his son Howard Huntington, situated southeast
of Pasadena in the Oak Knoll district. This place is well known on
account of having upon it a picturesque old Spanish mill built by the
Mission Fathers, from which the name El Molino is derived. In its
original condition this place had two double rows of large black walnut
trees, one extending on either side of a drive from the home site toward
the south, to what is now Huntington Drive, and the other extending
east and west to the west of the home site and the old mill, near the
present residence of Mr. Howard Huntington. In going to Pasadena
on the El Molino electric car line the first mentioned group of trees is
situated a few rods to the east of the point where the El Molino line
leaves Huntington Drive and turns in toward Oak Knoll and the Went-
worth Hotel. The second group is found just to the east of the car
line at the point where it starts up the hill below the Wentworth Hotel.
Quite a number of other trees of apparently the same origin and gen-
eration as these may be found scattered here and there in dooryards
and by roadsides through Pasadena, Alhambra, San Gabriel, El Monte,
Covina and other neighboring localities. These trees are all of the same
general type, being large, erect, with clean trunks and rather rough bark
and having a general resemblance to Juglans nigra. It is evident, how-
ever, that none of them are entirely typical of that species. The nuts
are all much smaller and smoother and quite different from the nigra
type, all the trees come out much earlier in the spring and hold their
foliage much later in the fall than typical nigra and they are all of
much more rapid growth than nigra.

There stands on the Graves place, near the El Molino trees, a group of
real nigra, planted from eastern nuts, and the difference is most pro-
nounced between the trees in the two places. Mr. H. H. Mayberry,
whose father was one of the early owners of the El Molino ranch, writes
as follows concerning these trees : "There formerly stood in front of the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 167

old mill building on the ranch a very large eastern black walnut tree
that was cut down about 1883 or '84 and had a diameter of about four
feet. This tree was, I believe, bearing when Colonel Kewen bought the
property from a Mrs. Holt. The other black walnut trees were raised
from seed from this original tree. ' '

In the canons back of this ranch, and at no great distance from the
mill, there is still to be found a considerable number of native trees of
the southern California type, so that presumably such trees were orig-
inally quite abundant here. It is, therefore, most reasonable to suppose
that the various trees of this El Molino type are Royal hybrids, resulting
from a cross between the old nigra tree by the mill and these wild
southern California trees. It is remarkable, however2 that all the seed-
lings grown from the nuts of this tree should have been hybrids, which
appears to be the case. There are probably at least fifty of these seed-
lings represented by the present large trees on the ranch and a consid-
erable number more scattered about the surrounding country, and not
one of these trees can in any possibility be considered a true nigra. It
may be that in planting these trees the largest specimens in the nursery
were picked out and in this way nothing but hybrids were chosen. Such
a case is indeed quite probable, as the straight nigra seedlings grow only
a few inches the first year, while the hybrid trees among them may be
several feet in height. Naturally these largest trees would be chosen for
permanent planting.

Seedlings of Royal Hybrids. — The seedlings originating from first-
generation Royal trees, of either the northern or southern California
type, are in general much more vigorous and retain the qualities of their
parents to a much greater extent than in the case with seedlings of
Paradox trees. In the second generation, however, that is, trees twice
removed from the original cross, the exceptional vigor is mostly lost and
the seedlings become no better than or even inferior to those of the
original species. In other words, the Royal hybrid seems on the average
to retain its quality of exceptional vigor of growth one generation longer
than does the Paradox. Various individual Royal trees, however, vary
greatly in their ability to impart their characteristics to their progeny.
Only a very few of them give seedlings which show uniformly a large
percentage of trees as good as the parent. In the majority of cases the
seedlings vary greatly and are not at all uniform. Almost always,
however, the rule above stated is maintained that the seedlings of first-
generation trees are more vigorous than those of the second generation,
even though the parent trees may appear equally vigorous. This is an
important fact in obtaining seed for nursery planting as a rootstock for
the English walnut. In fact, it should be clearly understood that while
Royal and Paradox hybrid walnut trees are quite common in the State,

168 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

these trees represent all sorts of relationships and degrees, a few being
first crosses, but many more being of the second, third or even later gen-
erations. Of the trees tested by ourselves and by a few of the most
progressive nurserymen who have taken the trouble to plant the nuts
from various trees separately, only an extremely small proportion have
shown themselves worthy of being used for producing rootstocks for the
English walnut. To test such a tree thoroughly requires several years,
inasmuch as the nuts must first be planted and the seedlings raised to
grafting age, the trees then grafted and kept in the nursery for at least
another year, after which they must be planted out in various types of
soil and their growth observed for some time in comparison with that of
trees on other roots. The majority of hybrid trees which produce seed-
lings of exceptional vigor among their progeny do this in an extremely
irregular manner, the seedlings being of all sorts of sizes and char-
acteristics. English walnuts grafted on such seedlings will vary corre-
spondingly. As we have previously said, no Paradox trees have been
found whose seedlings are desirable as rootstocks, and of all the Royal
trees which have been tested there are less than half a dozen in the State
at present ^whose seedlings are known to be of sufficient uniformity in
good qualities to be desirable for propagation. Seedlings of most Royal
hybrids are really inferior to those of the straight California black
walnut of either species for nursery purposes on account of their lack of
uniformity. At least one nurseryman in the State is taking the trouble
to hybridize certain black walnut trees by hand in order to obtain a
walnut cross which he considers especially desirable for the nursery.

One fact is to be remembered in connection with the progeny of any
California walnut tree, namely, that in almost every instance walnut
trees of some sort stand near to each other, and cross-pollination is there-
fore always possible and probably always goes on in every instance to a
greater or less extent. The tree therefore which gives an unusually good
lot of seedlings might not do the same at all if it stood elsewhere, removed
from certain other trees which stand near it and which cross-pollinate its
blossoms. It is therefore also true that it may or may not always be
possible to perpetuate a desirable tree of this sort even by grafting, since
when planted in some other place the combination of cross-pollination
which resulted in the production of exceptionally good seedlings may be
entirely lost.

FREAK WALNUT TREES.

Walnut trees are quite frequently met with in California which, while
it is probable that they are mostly hybrids, present very peculiar char-
acteristics and have little resemblance to any known species. It is pos-
sible that these may be partly the effect of environment as well as that
of hybridization. About the city of Berkeley there are a number of

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 169

black walnut trees which do not coincide with any species known to the
writer. There is a tree, for instance, on the University grounds just
north of the creek in the rear of the old athletic field, which is of a
peculiar type. This is a tall, clean-trunked, vigorous tree, having much
of the appearance of a Eoyal hybrid and bearing a small smooth nut.
The origin of this tree could not be ascertained. On the south side of
Bancroft Way, just east of St. Mark's Episcopal Church, there is a row
of black walnut trees which seem peculiar to themselves in regard to
specific characteristics. There is another row of larger trees on the west
side of College avenue, about midway between Oakland and Berkeley,
in the Claremont district. All these street trees have a general resem-
blance to one another and look as though they might possibly be Royal
hybrids. The writer has never been able to obtain any nuts from them.
It is possible that they are all seedlings from some one tree.

On the El Molino ranch, above mentioned, there may be found in the
canon above the ranch in the Oak Knoll property several most peculiar
trees. These vary in foliage and general appearance all the way from
that of the English walnut to that of nigra and calif ornica and bear
all sorts of peculiar nuts. Some are quite large, some extremely small
like those of rupestris, some rough, some smooth, some round, some
elongated and some almost square. Mr. Fred Gray, now superintend-
ent of the Leffingwell ranch near Whittier, who was formerly super-
intendent of the El Molino ranch, stated that he planted many of these
canon trees by taking nuts from the large Royal trees which we have
described and throwing them about broadcast among the bushes and
brush in the canon. There are also growing in this canon several trees
of Juglans calif ornica. There is a considerable number of old English
walnut trees on the ranch in the immediate vicinity of the black wal-
nuts and these peculiar trees therefore represent, presumably, a gen-
eral mixture of the three species, nigra, regia and calif ornica.

One tree in this canon is especially peculiar. This has been called
the pecan-walnut tree, under the assumption that it might possibly be
a cross of the pecan with nigra, or the Royal hybrid. There are sev-
eral pecan trees growing close to the black walnut trees on the ranch,
so that opportunity exists for such a cross, if it were possible. The
tree mentioned stands on the east side of the canon near its opening,
and in its general characteristics might easily pass for such a cross.
The foliage resembles that of the pecan to a considerable extent; the
bark is fibrous, striated and very close-fitting and smooth like that of
the pecan; the wood has something of a pecan appearance, and the
nut is exactly intermediate in character between those of the pecan
and the eastern black walnut. The nuts are of an elongated oval form,
pointed on both ends and deeply grooved. The seedlings of this tree,.

170 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

however, give no reason to suppose that they contain any pecan blood.
They resemble those of a good type of Royal hybrid walnut, and are
very uniform in appearance. It is, therefore, safe to assume that this
tree is a hybrid between nigra and calif ornica, but one which has
retained more of the characteristics of the latter species, as the foliage
of this tree has considerable resemblance to that of the pecan. We
have also found one or two other Royal hybrid trees in the State which
bear nuts of an oval form, pointed at one or both ends very much like
pecans.

Another peculiar freak is the so-called walnut-oak hybrid, which has
been described and discussed by Babcock.* These peculiar trees orig-
inated in Orange County among a lot of seedlings of Juglans cali-
f 'ornica. Of the original trees there were about twenty among two
thousand seedlings. The foliage of these trees is quite different from
that of the walnut and resembles very closely that of a small-leaved
oak. The fruit is peculiar, being similar externally in appearance to
that of Juglans calif ornica, but peculiar in the structure of the nut.
The appearance and general characteristics of the tree are sufficiently
characteristic to suggest very strongly that it might be a hybrid between
the walnut and live oak tree, which grow in very close association in
southern California. Efforts by Professor Babcock have thus far failed,
however, to produce such a cross by artificial pollination, and he has
come to doubt whether this is the true explanation of the origin of
this peculiar form. Since the first lot of trees of this kind was noticed
a few other similar individuals have appeared among seedlings of
Juglans calif ornica. It should have been said that nuts of some of
these trees are fertile and produce seedlings, some of which have foliage
like the parent, while others appear to have reverted to the walnut type
of leaf.

The native American species of walnut when grown in California
certainly present a unique example of freedom in hybridization and
variation. It has not been possible in the present work to go into this
matter from a technical standpoint, and we have perhaps already given
more space to the subject than it deserves in a publication upon wal-
nut culture. We desire, however, to record the status of the matter
and call the attention of plant breeders and those interested in similar
work to a most promising field of investigation.

*E. B. Babcock, The Plant World, Vol. 13, No. 2, Teratology in Juglans Cali-
f ornica — Watson. Silva of California — Jepson, p. 50, The Walnut Oak Hybrids.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 171

FOSSIL WALNUT SPECIES.

Many species of walnut seem to have existed in this and other coun-
tries in prehistoric times. We quote as follows from Sargent: "The
type is an ancient one in Europe, from which later it entirely disap-
peared, existing in the cretaceous flora and abounding with many
species during the tertiary epoch ; in North America traces of Juglans
appear in the eocene rocks of the northern Rocky Mountain region
and of the northwest coast from Vancouver Island to Alaska, regions
where no representative of the walnut family now exists, and in the
auriferous gravel deposit of the California Sierra Nevada."*

WALNUT CULTURE IN CALIFORNIA.

HISTORY.

The first English walnuts in California were probably brought by the
Mission Fathers, although this crop does not seem to have been especially
prominent in the earlier Mission plantings ; it was only after the coming
of the first Americans and the discovery of gold that English walnuts
began to be extensively planted in the State, t The first trees were of the
so-called hard-shell type, bearing rather small, roundish nuts, with a
very hard shell. There are still a few trees in the State of these early
plantings, but most of them have been removed. Such trees were
planted in orchard form to a limited extent by some of the pioneers, but
in its present form the walnut industry is of comparatively recent origin.
Laying aside the sometimes discussed question as to whose was the first
walnut orchard in California, or who introduced or developed certain
types of nuts: it can fairly be said that the present California walnut
industry owes its origin preeminently and fundamentally to the efforts
of two men : Joseph Sexton of Santa Barbara and the late Felix Gillet
of Nevada City. The former was the originator and first propagator
of the Santa Barbara Soft Shell type of nut, of which practically all
the producing groves of southern California are at present composed,
and the latter was the first introducer and life-long promoter of the
various French varieties which form the basis of the northern California
walnut industry as it exists to-day. A great many others have done
much to promote the walnut industry both in the south and the north,
but their names are too many and their services too varied to be men-
tioned and properly estimated here. It can and should fairly be said,
however, that practically all the desirable types of walnut now in the

*Silva of North America.

tThe historical side of the subject is well treated by Lelond, in Rep. Cal. State
Board of Hort. for 1895-96.

172

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

State trace back in their first introduction either to Mr. Sexton or to
Mr. Gillet, and that the few isolated exceptions to this rule occurred
largely by chance, and were not systematically carried on and continued
by any one person.

FIG. 19. — Joseph Sexton, originator of the Santa Barbara Soft Shell walnut.

The old fashioned hard-shell walnuts were planted quite commonly in
California after the commencement of the American era, although not
extensively in orchard form at first. The Kellogg orchard near Napa is
said to have been planted in 1846 and the Heath orchard at Carpinteria

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 173

was also one of the earliest plantings. Other scattering plantings were
made, composed mostly of dooryard rather than orchard trees, but it was
not until a number of years later that the walnut began to be looked
upon as a commercial crop worthy of being planted extensively in
orchard form. The latter stage of the industry came about largely as a
result of the development of the so-called Santa Barbara Soft Shell nut
by Mr. Sexton. The history of this variety has been given to the writer
by Mr. Sexton as follows : In the spring of 1867 he bought in San Fran-
cisco a sack of walnuts which came probably from Chile. These nuts
were planted that spring and from them about 1,000 trees were raised,
of which Mr. Sexton planted about 250 himself in orchard form on his
place at Goleta. Sixty of these proved to be of the so-called paper-shell
type, the rest being ordinary hard-shells. Only one of these 250 trees is
still in existence, this being a hard-shell. Nuts from these trees, mostly
from the paper-shells, were planted in the nursery by Mr. Sexton, and
from these came the first of the so-called Santa Barbara Soft Shell
trees. Of the first of these second-generation seedlings sent out by
Mr. Sexton several groves are still in existence, mostly in Santa Barbara
and Ventura counties. The trees vary considerably in type, some being
typical hard-shells, some paper-shells and others of an intermediate type,
which represents what may be called the typical soft-shell. The latter
type was considered the most desirable, the trees being of more vigorous
growth and making greater size than either the hard-shell or paper-shell,
while the nuts were larger than those of either of the other types and of
a more desirable thickness of shell. The oldest of these original Santa
Barbara Soft Shells are now between 30 and 40 years of age. Nuts
were again planted from the best of these trees and soon the present
walnut industry of southern California began its development, based
almost entirely upon the type of nut originated by Joseph Sexton.
Extensive planting began in Santa Barbara, Ventura, Los Angeles and
Orange counties, all the groves with practically no exception being com-
posed of seedling trees of this new type. The industry developed very
rapidly and under an enormous demand for trees; nuts of all sorts were
planted with no regard to selection in many cases. The result has been
that at the present time the Santa Barbara Soft Shell seedling groves
are composed of a most heterogeneous collection of trees in regard to
type of nut and bearing qualities. Comparatively few trees of the
many, many thousands now in existence are equal to the best of those in
the oldest groves, and there is a still smaller percentage of trees superior
to these oldest ones. The oldest and best soft-shell trees produce a fairly
uniform type of nut and are all heavy bearers, turning off, in spite of
blight and other vicissitudes, more than 300 pounds of nuts per year.
They are fine, large, thrifty trees, still in healthy, vigorous condition
wherever planted in good soil, and it may truly be said that were the

174

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

present groves composed of trees of as gocd average quality as the best
of these oldest trees, the walnut industry would be at present in far
better condition than it is.

FIG. 20. — Felix Gillet, introducer of the best French walnuts into California
and originator of most of the French seedling varieties.

As plantings and the number of bearing trees of the Santa Barbara
Soft Shell type multiplied, particularly thoughtful growers here and
there began to notice the variation in the trees and to consider the possi-
bility of propagating from the best of them, both by seed and by grafting.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 175

Many orchards were planted with seedling trees derived from especially
selected nuts, but the greatest step in advance was taken when trees of
special excellence began to be picked out here and there and propagated
by grafting or budding in the same manner that other fruit tree vari-
eties are propagated. Thus originated; for instance, the Placentia Per-
fection, Ford's Improved, Disher's Prolific, El Monte, and various other
varieties of which the original trees were Santa Barbara Soft Shell
seedlings. Much difference of opinion existed at first as to the merits
and qualities of the grafted tree in comparison to the seedling, and there
was in the beginning a strong prejudice against the former and an idea
of inherent superiority of the seedling tree in thrift, vigor and pro-
ductiveness. As time went on, however, abundant proof was afforded,
through the rapidly increased plantings of grafted trees, that this dif-
ference was entirely imaginary and that no radical difference existed
between the walnut and other fruit trees, whereby the superior qualities
of particularly desirable individuals could not be reproduced and multi-
plied indefinitely. Thus at the present time the planting of seedling
trees has practically ceased and no well-informed grower would consider
the planting of a seedling grove.

In the northern part of the State the walnut industry has had quite
a different development. Trees of the old hard-shell type were planted
in this portion of the State as early as in the south, but the extensive
development of the industry in the latter portion of the State based on
the Santa Barbara Soft Shell type of nut did not extend north of
Santa Barbara County. The pioneer and chief promoter of walnut
culture in northern California was Felix Gillet of Nevada City. Born
in France in 1835, Mr. Gillet came to this country in 1852, arrived
in California in 1858 and in 1859 in Nevada City, which place
thereafter remained his home. Mr. Gillet had a natural interest in
horticulture, and in 1871 began the development of his Barren Hill
Nursery. He was particularly interested in nut culture and at a very
early date began introducing from France the best of the nuts grown
in that country, particularly the walnut. From 1871 on he imported
many shipments of scions and nursery trees, and was the first intro-
ducer into California of practically all the French walnut varieties
which we now have. He likewise propagated trees of these varieties
in his own nursery and also raised many seedlings from French varie-
ties with the idea of developing new varieties of special adaptation to
California. As a result of Mr. Gillet 's efforts the Franquette, our lead-
ing walnut in the northern part of the State, was established in Cali-
fornia, while from seedlings of his raising originated the Concord, San
Jose, and possibly the Chase varieties.

Following Mr. Gillet, further introductions from France were made

176 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

by various parties of the varieties to which he had called attention, and
the planting of the best of these, particularly the Franquette, was car-
ried on by various people. Without question, the chief credit for the
present popularity of the Franquette variety is due to the late Mrs.
Emily Vrooman, who planted an extensive grove of this variety near
Santa Kosa at a time when walnut growing on a commercial scale in
northern California was still considered doubtful or impossible. As
a result of the success of Mrs. Vrooman 's grove, others came to appre-
ciate the possibilities of walnut culture in the northern part of the
State and the valuable qualities of the Franquette variety. In later
years there has been a growing interest in walnut culture in the cen-
tral and northern part of the State, which has been shared in and
assisted by numerous individuals who cannot be mentioned individ-
ually here.

LOCATION FOR WALNUTS.

CLIMATE.

The limitations of commercial walnut growing are rather closely
drawn by climatic conditions.

Frost. — In regard to temperature, the tree is able to withstand a
considerable degree of cold so long as it is not subject to severe frost
and freezing outside the period of dormancy, and also provided the
trees do not suffer for moisture during the dormant period. English
walnut trees are not uncommon in the Atlantic States as far north as
New York, and there are trees even in Northwestern New York which
bear well every year. The most evident effects of freezing upon the
walnut are seen in cases where heavy frosts come on suddenly in the
fall while the trees are still green and not yet in a dormant condition,
or when the same thing occurs in the spring after the trees have com-
menced growth. In the latter case, even in southern California, wal-
nut trees are sometimes badly frozen. In general, it may be said that
so far as winter temperatures are concerned, the tree is almost as hardy
as the peach or apricot and will flourish almost anywhere in California
where these trees do well. In regard to late spring frosts, it is for-
tunately the case that different walnut trees and varieties vary widely
in regard to their time of coming out in the spring, ranging in this
respect over a period of several months. It is thus possible in a locality
subject to late spring frosts to select a late variety of walnut and thus
escape the danger period. It may, therefore, be said in respect to low
temperatures that walnuts can be grown in practically all the culti-
vated portions of California, so far as this one feature is concerned, by
choosing varieties of the proper foliation period in the spring. In the
central and northern parts of the State there has been in general too

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 177

much fear of spring frosts in relation to walnuts. About almost any
of the towns in this portion of the State there may be found early trees,
which to all appearances produce as regularly and abundantly as those
in the south. While walnuts are sometimes damaged by frost even in
the best of the southern California districts, the tree is not unusually
sensitive in this respect and even the earliest of our walnuts come out
later than many of our ordinary fruit trees. We very much doubt
whether the walnut in many northern California districts would be
injured by frost any more than the almond, apricot, peach or grape,
and the prospective grower need not absolutely discard all early vari-
eties for this one reason alone. It may further be said that during the
spring of 1911 when there was much late frost in the State, some of
the latest varieties of walnut were badly injured, when earlier varieties
in the same locality had reached sufficient development so that they
withstood frost with no injury whatever.

Trees which suffer for moisture during late fall and winter are likely
to be severely killed back at temperatures which otherwise would not
affect them. See Die Back, page 372.

Heat . — The walnut tree is one which does not take kindly to extreme
summer heat, and its commercial culture is limited to a considerable
extent by this factor. In the extremely hot desert valleys of the State
the tree is not at all well adapted, becoming injured and repeatedly
killed back by drying and burning of the leaves and tender shoots.
The idea which once prevailed, however, that walnut culture is possi-
ble only in the immediate vicinity of the coast has become considerably
modified in recent years. Sufficient plantings have been made to indi-
cate that the tree flourishes practically all over the State, except in
the very hottest and driest portions, and it has been demonstrated that
nuts can be produced over a similar territory. A serious drawback,
however, is the burning or discoloration of the nuts by the sun even
in localities where the tree flourishes well. Here again the matter of
choice of varieties becomes important since there is much variation in
its susceptibility to sunburn. The most serious form of sunburn takes
the form of an actual shriveling and blackening on one side of the
green hulls of the immature nuts. This is worst on the nuts which are
most exposed to the sun, also on trees which are unthrifty or not in a
good vigorous condition. Walnut trees or varieties best adapted to
the hottest localities are, therefore, those which have the most abundant
foliage, in which the nuts are borne well down among and under the
leaves, and which are naturally of thrifty, vigorous growth. Burning
by the sun is also less severe upon trees standing in good soil with
plenty of moisture than upon those in light dry soil. A less prominent
effect of sunburn consists in a burning or discoloration of the thin pel-

5—231

178 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

licle which envelopes the kernel of the nut. In very hot places such
discoloration occurs even without visible burning of the outside of the
husk. This effect, however, like that of frost, is one which we believe
to have been largely overestimated. There is much difference in differ-
ent trees or varieties as to the color of the pellicle, but in good, white-
meated varieties we have seen nuts of perfect quality in this respect
produced in very hot localities in the interior of the State. Where the
heat is not so severe as to scorch the foliage, stunt the growth of the
tree, or visibly burn the nuts, little attention need be paid to this dis-
coloration of the pellicle so long as proper varieties are planted. The
chief consideration in the warmer localities should be to choose vari-
eties of vigorous growth, with abundant foilage, well shaded nuts and
thick husks.

Hot dry weather at the time of blooming in the spring is sometimes
as disastrous or even more so than frost. There is little danger of this
in the northern part of the State, but in the south the setting of nuts
is sometimes seriously damaged by conditions of this sort, and indeed
this danger is sufficiently great to make the planting of any late variety
of doubtful advisability in the south.

Specifically, we may say in regard to the climatic limitations of wal-
nut culture in California that wherever suitable soil and water supply
can be obtained and by the proper choice of varieties, the crop can be
successfully produced in all the counties of southern California save
in the desert portion, in almost all the coast counties of the State, except
in localities very much exposed to cold wind and fog a large portion of
the time, in all the valleys about San Francisco Bay and in most of the
country within 200 miles of San Francisco or even further. In the
interior valleys no definite line can be drawn where commercial walnut
possibilities cease, as in these warmer regions much depends upon soil
and moisture supply. In the mountain districts walnuts can be grown
almost anywhere except at the higher altitudes where spring and sum-
mer frosts are of regular occurrence.

SOIL.

A fairly heavy, deep soil with an abundance of moisture, though at
the same time thoroughly well drained, presents by far the best condi-
tion for successful walnut culture. Very little success can be expected
on light sandy soil subject to a fluctuating moisture supply and walnut
culture should not be attempted under such conditions. Trees on such
soil are less thrifty, less productive? and much more subject to all the
troubles which affect the walnut in this State. Walnut trees on light
soil may flourish for a time, especially if plentifully supplied with
water, and in the beginning of the industry in this State it was thought
that such were the best conditions for walnuts. Trees grown in this

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 179

way, however, have proven to be short lived and more subject to disease,
and nothing has been more positively demonstrated by experience than
the desirability of heavy soil for the walnut. The quality of the subsoil
is of particular importance since the roots of the walnut go down fairly
deep. A strong or heavy (though not wet or impervious) subsoil is
absolutely essential.

A uniform and abundant supply of soil moisture is necessary, although
the tree is considerably resistant to drouth, especially when grown on
proper roots. Walnuts are frequently grown in California without irri-
gation even in the southern part of the State, but unless planted upon
soil of exceptionally good water-retaining capacity more or less irriga-
tion is almost always beneficial and profitable. In many cases where the
trees survive and do fairly well without water they would grow much
more rapidly, come into bearing sooner and bear much larger crops if
supplied with water. Too great an amount of moisture in the soil with
water constantly standing near the surface is very unfavorable to wal-
nut culture and the trees will not long withstand conditions of this sort.
Some latitude can be obtained in this respect by the use of a root best
adapted to excessive moisture, but it is hazardous to attempt walnut
culture on land where the water level stands within less than eight feet
of the surface or where it is likely to rise after the trees are planted.

DISTANCE OF PLANTING,

In practically all the older walnut groves in the State the trees were
planted too near together. The walnut tree is one which continues
growth for many years, making a large, spreading top} so that the trees
very soon come together unless planted a long distance apart. Further-
more, the production of nuts seems to be particularly favored by exposure
to the light and open air on all sides of the tree. The mistake of plant-
ing the trees too close together should therefore be carefully guarded
against. With vigorous growing varieties on good soil 60 feet apart is
none too much, and less than 50 feet should not be considered in any
case. Sixty by sixty feet gives about 12 trees per acre, 50 by 50, 17
trees per acre and 40 by 40, 27 trees per acre, when planted in squares.
By alternating the rows these numbers are slightly incrpased.

Inter planting. — With trees planted at these wide intervals and also,
somewhat slow in coming into bearing as compared with many fruit
trees, it becomes quite desirable when planting walnuts to interplant
with some other tree or crop in order to get something off the land while
the walnuts are coming into bearing. Fortunately, this is not especially
objectionable, as the walnut is a deep rooting tree, and, if properly
treated, shows no injurious effects from judicious interplanting. In
some cases interplanting or double planting with walnuts is practiced,

180 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

either with the same variety as that of the permanent planting, or with
another more precocious, though ultimately less desirable, variety.
Such interplanting with walnuts may be done either in one or both direc-
tions, so that there may be two, three, or four times as many trees per

o i o 1 o

0 i o 1 0

o i o i o

o i o i o

Diagram, showing method of quadruple-planting of walnuts in squares, (^perma-
nent trees, 60 feet apart. Irrtrees for first cutting out. 2=second cutting. 3=third
cutting.

acre as will remain permanently, according to the extent to which the
interplanting is done. The only objection to such interplanting as this
lies in the reluctance of the average man to cut out the temporary trees

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

181

when the proper time arrives. So weak has human nature proven
itself in every instance of such interplanting with which we are familiar
that we hesitate in recommending this method. The trees grow rapidly

FIG. 21. — Top — Interplanting with peaches. Center — Grapes.

by planting nuts in place.

Bottom — Grove started

and for proper results must be ruthlessly slaughtered just as they are
coming into their prime. Unless one is fully prepared to carry out such

182 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

a slaughter, however, just as soon as the tops begin to reach out and
touch each other, he should not consider interplanting with walnuts. If
double planting is practiced in both directions, using four times the
number of permanent trees per acre, the cutting may be extended over
at least three years, taking out one fourth of the trees each year. Inter-
planting is frequently done with peaches, apricots, grapes, berries and
other quick-maturing fruits, also with all sorts of vegetables and annual
crops. There is no objection to any of these, so long as the walnut
trees are protected from injury and do not suffer for moisture. The
latter is one of the greatest dangers and should be carefully guarded
against. Interplanting with alfalfa is a common practice and a very
desirable one if the alfalfa does not rob the walnut trees of moisture.
The latter, however, is frequently the case. In order to guard against
this, the walnuts should not depend for irrigation upon the water
which they get along with the irrigation of the alfalfa. A cultivated
strip should be maintained on each side of the walnut rows and water
should be run in separate furrows for the irrigation of the trees.

CULTURE.

SOIL HANDLING.

The various operations of stirring the soil, such as plowing and culti-
vating, do not appear to be of as much importance in walnut culture as
in the case of some other trees. In relation to the conservation of soil
moisture cultivation has its importance, particularly where the water
supply is somewhat limited, but given plenty of moisture and suitable
soil the walnut tree is one which seems to flourish and produce satisfac-
tory crops whether the ground be thoroughly cultivated or not. It is,
indeed, a matter of common observation to see large, thrifty walnut trees
producing the best of crops while standing in the hard-packed soil of the
dooryard or roadside with no cultivation whatever. In fact, trees in
such situations seem sometimes to flourish actually better than those in
neighboring orchards where some degree of cultivation is practiced.
Many growers call attention to trees standing in the dooryard or about
the buildings where they receive no cultivation and little or no irriga-
tion, which are noticeably in better condition and more productive than
trees near by planted in orchard form. The superiority of such trees
is not due, however, to their lack of irrigation and cultivation, but rests
largely upon the fact that being planted away from other trees they
have better exposure to the light and air than trees in the orchard,
which appears to be a very essential factor with the walnut. Again, it
is true that walnut trees, if they stand in fairly good soil, actually do
better without any cultivation than they do if the ground is plowed or
cultivated occasionally in a superficial, unsystematic manner. The tree

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 183

apparently retains much of the nature of a forest tree in this respect and
does better when left to itself with the soil undisturbed than when the
soil is cultivated in the above-described irregular manner. This by no
means goes to prove, however, that good cultivation is injurious or
unnecessary in walnut culture, for experience has shown this to be far
from the case. Especially in regions where the rainfall is limited and
the dry season long and hot, regular, thorough cultivation is as beneficial
and profitable in the walnut orchard as with citrus or other trees. In
regions with more abundant rainfall and less severe dry seasons cultiva-
tion is not so essential ; the chief consideration in all cases is that of the
conservation of soil moisture. The latter must be maintained, but
whether by irrigation or cultivation matters little. If the soil is suffi-
ciently moist cultivation is not as essential with the walnut as with many
other fruit trees.

In practice it is customary to plow the grove once a year during the
spring, followed by harrowing and cultivation to put the soil into good
mechanical condition. After this, the ground is usually cultivated
occasionally during the summer, at least after each irrigation if this be
practiced, in order to keep it from baking, keep down the weeds and
hold the moisture. A number of growers in southern California have
tried in recent years the experiment of carrying on their walnut groves
with no plowing or cultivation whatever, but with abundant irrigation.
In some cases permanent irrigation furrows have been made between the
trees, while in others the water is simply turned into the orchard and
allowed to flood the whole ground as thoroughly as possible. The weeds
and grass have been allowed to grow up or pastured off with horses and
cattle. Under such treatment an actual improvement has been mani-
fest in the condition of some walnut groves. Whether such improve-
ment, however, is due to the lack of cultivation we are inclined to doubt,
but would rather attribute it to the increased water supply which the
trees have received. Such experiments have strengthened the opinion,
however, that cultivation is not particularly essential with the walnut so
long as it receives plenty of moisture. In cases where walnuts are
grown without irrigation there can be no question that thorough^ syste-
matic cultivation during the summer season will assist in holding the
moisture of the soil. That many trees grow and flourish without such
cultivation and without irrigation is again no indication of beneficial
effects of non-irrigation, but simply shows that in these particular local-
ities sufficient soil moisture is present without any special efforts toward
its conservation.

IRRIGATION.

The walnut tree, while not dependent upon constant irrigation like the
orange and many other more shallow-rooted trees, is at the same time a
large consumer of water and needs plenty of moisture for successful

184 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

development. The majority of the trees in the northern part of the
State are grown without irrigation, and even in the southern part many
groves receive little or no water in addition to the natural rainfall. In
seasons of abundant precipitation trees under such conditions get along
very well, and it may be said that the walnut is as well adapted as almost
any of our ordinary fruit trees to grow without irrigation. There are
localities, especially in the northern part of the State, where the crop
can be produced successfully and regularly without irrigation. Further-
more, there is considerable variation in the moisture-gathering ability of
the various kinds of root upon which the tree may be grown so that by
proper choice in this respect much may be done to make walnut growing
possible on non-irrigated lands. In general, however, it is true of wal-
nut growing, as with all other fruit growing in California, that no one
factor is as desirable or useful as the possibility of an abundant and
regular water supply. Even though the trees may be able to live with-
out irrigation and may grow quite well and produce good crops during
most seasons, it is still true that even as a matter of insurance against
dry years a possible water supply is extremely valuable. Furthermore,
there is no spot in the State so favored with natural soil moisture but
that with irrigation during the first few years the trees would grow much
faster, come into bearing earlier, and produce more satisfactory returns
to the owner.

By this, however, we do not intend to discourage the planting of wal-
nuts on non-irrigated lands. The tree is, as we have said, as well adapted
to such conditions as any other fruit tree, and, indeed, may be grown
more successfully without irrigation than most other fruits if grown
upon a proper root.

As to the particular methods of irrigation practiced with the walnut,
it may be said that the tree is most likely to suffer from lack of moisture
during the fall and winter after the crop of one season is off and before
that of the next year has started to develop. Quite frequently it is the
case that the fall rains are late in commencing and the walnut tree is
especially likely to suffer from such a condition. Although it may not
be in active growth and practically dormant, a lack of moisture at this
times dries out the branches, twigs and buds, lowers the vitality of the
tree, impairs its vigor for the following season, makes it more susceptible
to injury by cold, and is in many other ways injurious and disastrous.
For this reason it is coming to be more and more the practice among
the best walnut growers to irrigate heavily during the fall and winter,
supplementary to the winter rains and creating a storehouse of moisture
in the soil for the summer. If the subsoil is thoroughly soaked down
and not allowed to become dried out during the fall and winter, the
tree, on fairly heavy soil at least, is much less dependent upon sum-
mer irrigation than is the case with citrus and many other trees.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 185

During the summer it is ordinarily desirable to irrigate at least once
or twice, especially toward the time of maturity of the crop, in order
that the nuts may have plenty of moisture for their proper develop-
ment. Walnut irrigation therefore resolves itself very largely into,
first, guarding against drying out of the soil during the fall with irri-
gation at this time if necessary to accomplish such a result; second,
copious irrigation during the latter part of the winter, unless the rains
have been sufficient to thoroughly saturate the subsoil down to the
depth of the lowest roots ; third, at least one irrigation during the sum-
mer, usually in August, when the nuts are approaching maturity.
When interplanted with other crops greater care must be given to irriga-
tion than otherwise, since these other plantings will draw a large amount
of the moisture which would otherwise be available for the walnut
trees.

FERTILIZATION.

Very little of a specific nature can be said upon this subject since
no definite data are available in connection with the fertilization of
walnut groves. Fertilization has been practiced to some extent by
walnut growers and an extensive experiment was arranged and carried
on for several years at one time by ourselves. In no case, however,
have sufficiently definite results been obtained to justify any specific
recommendations in regard to the requirements of the walnut tree in
this respect.

The experiment mentioned may be described at this point.

Fertilizer Experiment. — A cooperative arrangement was made with
the Cudahy Ranch, situated just south of the city of Huntington Park,
near Los Angeles, to carry on a fertilizer experiment upon walnut trees
on a considerable scale. A block of Santa Barbara Soft Shell seedling
trees was chosen for this purpose, consisting of 56 rows of 21 trees
each, a total of slightly over 1,000 trees, comprising between 50 and 60
acres of grove. Each of the various fertilizers or combinations used
was applied to two rows of trees, so that there were 42 trees in each
plot. At the time of commencing the experiment in 1907 part of the
grove was five and part six years old, the different applications being
arranged in such a way as to bring about comparative tests on trees of
the same age. The soil of the experimental orchard consisted of a
sandy loam, being decidedly more sandy on the west end and gradually
becoming heavier toward the east. The rows ran north and south so
that the westernmost plots were on much lighter, sandier soil and the
trees were smaller than those farther east. Except for these smaller
trees at one end the grove was as uniform as any seedling grove of
this size which could be obtained. This variation was provided for by
duplication of plots. The fertilizers were applied for two successive

186

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

years, 1907 and 1908, all expenses being met by the Cudahy Ranch.
Applications were made as follows, each plot consisting, as said before,
of two rows or 42 trees :

Plots.

1907.
Pounds per
tree.

1908.
Pounds per
tree.

1 and 2

No fertilizer

3

Dried blood

10

30

4

Sulphate of potash

10

10

j Steamed ground bone

15

20

5

IBone superphosphate

15

20

6

Stable manure

( Sulphate of potash

0

5

7

/Stable manure

Heavy

8

Dried blood

o

20

9

Bradley's fruit and vine

40

50

10

A. O. W. walnut fertilizer

40

50

11

No fertilizer _

12

Nitrate of soda

24

25

13

Sulphate of ammonia

20

20

14

Tankage

30

35

15

Muriate of potash

10

10

16

Sulphate of potash _ __ _

10

10

17

Stable manure

Very heavy

18

No fertilizer _ ___

19

High grade rock phosphate

35

40

jSteamed ground bone

15

20

20

/Superphosphate _

15

20

(Nitrate of soda

15

25

21

< Superphosphate

20

40

'Sulphate of potash

4

10

(Nitrate of soda —

15

25

22

(Sulphate of potash

4

10

jNitrate of soda

15

25

23

( Superphosphate

20

40

(Sulphate of potash

4

10

24

} Superphosphate _ __ _- __

20

40

25

Sugar factory lime (2 tons per acre each year)

26

No fertilizer

It will be noted that many of these applications were comparatively
large, costing in the vicinity of $1.00 per tree per year. No record of
the crop was kept until 1909, when a careful weighing was made of
the crop of each individual tree in the whole experiment. The detailed
results will not be given in this bulletin for the reason that they were
not sufficiently conclusive to warrant their publication. So far as the
effects of the various fertilizers were concerned no conclusions what-
ever could be drawn. This is due partly to the extreme variation in
yield of the individual trees, which completely obscures any effect
of fertilization, and also to the fact that even where fairly good com-
parisons could be made the fertilizer applied showed a surprising lack
of decided effect. The crop on the various trees in the experiment
varied from a minimum of less than one pound up to a maximum of
117.5 pounds. With such a range it is almost impossible to draw any
conclusions from the effects of the fertilizer, even when the crops of
the 42 trees in each plot were averagd.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 187

The most valuable results obtained from the experiment were, first,
the demonstration of the variation in production in seedling trees, and
second, the relation of soil texture to walnut production. On the first
point we may repeat what has been said, that the various trees varied
from one to 117-J pounds in their total production.

On a block of 400 trees on fairly uniform soil 148 trees, or 37 per
cent, produced less than 10 pounds each; 118 trees, or 29J per cent,
produced from 10 to 25 pounds each; 82 trees, or 20£ per cent, pro-
duced from 25 to 50 pounds each ; 26 trees, or 9 per cent, produced 50
to 60 pounds each ; 10 trees, or 2J- per cent, produced 60 to 75 pounds
each; 5 trees, or 1^ per cent, produced 75 to 100 pounds each; and 1
tree, or | per cent, produced over 100 pounds.

To show further the variation in production in seedling trees under
almost exactly the same conditions, the crop from adjacent trees in
some of the individual rows may be stated. In row 20, for instance,
the production in pounds per trees was as follows: 1.4, 16, 45.6, 10.5,
21.5, 97.4, 20.5, 8, 26.3, 0, 16.4, 1, 18.6, 13.5, 10.6, 21.5, 2, 31, .7, 14.8.
Another row, 3, 72.5, 32, 27.5, 58.9, 9.8, 69.5, 22.2, 30.5, 8, 44.5, 38.5,
20.1, 19.1, 13.5, 34.8, 5.5. In the case of the 117.5 pound tree, the 6
trees surrounding it produced as follows : 6, 24, 14, 28.5, 27, 23. These
were all Santa Barbara Soft Shell seedling trees in their eighth year
in the orchard at the time these weighings were made. The same vari-
ation runs through all the figures and it is impossible to deduce any
reliable conclusions as to the effect of the fertilizers. A study of the
figures obtained, taken together with an examination of the trees as
to general appearance, gives one a fairly strong impression that the
greatest benefits were derived from the application of stable manure
and that of nitrogenous materials. Such results would certainly be
expected, especially in this rather sandy land, yet even so, it is sur-
prising to note the lack of pronounced results from the application
of the large quantities of these materials which were used. For
instance, in the plot of 42 trees which received during the two years
40 pounds of nitrate of soda, 60 pounds of superphosphate and 14
pounds of sulphate of potash per tree, the average product of the 42
trees was about 28 pounds of nuts. In the plot which received the
same minus the nitrate of soda, the average product was exactly the
same ; in that which received the same minus the potash the average
was 33 pounds, while in that which received the same minus the
superphosphate it was also 33 pounds. These plots were all near
together on the same type of soil and with trees as uniform in appear-
ance as can be found in any seedling walnut grove. The stable
manure plot averaged about 31 pounds, while the adjacent check plot

188 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

which received no fertilizer averaged only 20 pounds, which difference
is the only striking one obtained in the whole experiment.

The effect of differences in soil is very marked in comparing the
crops of the west and east ends of the orchard, on the light and heavier
soils respectively. On the ten west rows of the eight-year-old trees,
the crop averaged 16.3 pounds per tree, while on the ten east rows of
the same block on heavier soil it averaged 30 pounds per tree. These
were all trees of approximately uniform appearance and not especially
stunted where the smaller yield was obtained. The westernmost row
averaged 7.56 pounds per tree, while the easternmost averaged 32.56.
Between the two the average production per row graded off fairly regu-
larly regardless of the fertilizer used.

The results of this experiment are typical of all experience in ferti-
lizing walnuts. Many attempts have been made to determine the most
effective practice in this respect, but all of these have shown no
positive effect on account of variation in the trees and an apparent lack
of response to fertilizers. In regard to walnut fertilization it is,
therefore, impossible to offer definite advice based on actual experi-
ments, but the most that can be done is to suggest such practice as
may reasonably be expected to give good results with any crop on
California soils. We know in general that nitrogen and phosphoric
acid are our most needed elements and that the application of these
substances, especially on older plantings, is almost certain to result in
improved growth and vigor in almost any plant. We also know of the
walnut that individual trees produce as a general rule in proportion to
their size, and that the larger they become the greater crops they will
bear. It is, therefore, our conclusion that in fertilizing walnuts nitro-
gen and phosphoric acid should be the elements most largely supplied.

Along with fertilization there should not be forgotten the importance
of keeping the soil in good mechanical condition, especially in order
that it may absorb and retain the greatest possible amount of moisture.
Indeed, it is evident from the results of the Cudahy experiment, as
well as from general observation, that this factor is much more impor-
tant, at any rate for several years, than that of fertilization. To keep
the soil in good condition applications of stable manure are very effec-
tive, likewise the growing and turning in of green manure or cover
crops to as great an extent as possible. The latter practice, in southern
California at least, is not as feasible with walnuts as with the citrus
crop, since it is not practicable to plant the crop until after the walnuts
have been gathered, which brings it quite late in the season. For a
cover crop in walnut groves Canada field peas have been found one
of the best in southern California, as they start quite readily during

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 189

the winter. In addition to stable and green manure, if other fertilizer
seems desirable, we would suggest the application of tankage, or dried
blood and superphosphate, either of which supplies nitrogen and phos-
phoric acid in an available but not too soluble form.

In fertilizing the walnut it is evident that comparatively large
quantities of material must be used to obtain any real effect. The idea
of applying a few pounds -per tree of any substance with the expecta-
tion of producing some specific effect upon the tree or nuts is absolutely
futile. With large trees we would advise not less than 50 to 100 pounds
per tree of high grade materials, composed largely of fairly available
nitrogen and phosphoric acid, if any real effect is to be obtained.
This we would apply during the winter or spring at the time of plow-
ing the grove.

PRUNING.

The pruning of the walnut tree in the orchard has not resolved
itself into any such systematic practice as is the case with most fruit
trees. In almost all of our present groves, in fact, no pruning at all
is done, save that most growers usually go through each winter with
an ax and cut off all the limbs which have come down upon the ground,
in order to facilitate cultivation. There is quite a common impression
that walnut trees should not be pruned any more than is absolutely
necessary and that cutting in the top results in injury of some sort or
other. One suggestive fact is evident with the walnut tree, however,
namely that as the trees grow older and their tops closer together the
setting of nuts through the interior of the tree declines very notice-
ably, and also that trees in outside rows or isolated trees which stand
out by themselves produce decidedly more heavily than those in the
interior of the orchard. This is especially noticeable in isolated door-
yard trees, which are almost invariably heavy producers. These obser-
vations have led some growers to take out some of the inside limbs
as the trees become older and more crowded, in order to maintain a
better exposure to the air and sunlight. Such a practice is in our
observation an excellent one and we would recommend in the case of
large, old trees with crowded tops that a considerable amount of wood
be taken out in the center of each tree in order to open them up. In
young trees little pruning is ordinarily necessary, except that in very
windy localities it may be necessary to keep pruning to some extent
on the side away from the wind in order to counteract the tendency
toward a one-sided growth. The walnut tree, except when influenced
by wind, has a very strong tendency toward symmetrical development,
regardless of the form in which it starts. If a large limb develops on
one side during one year's growth this growth usually drops back the
second year and the tree develops more rapidly on the other side,

190

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

bringing it back into a symmetrical form. It is, therefore, often
better to let the tree take care of itself in this way, unless, as we have
said, it is distorted by wind, rather than to try to balance it up by
pruning. In case it is attempted to bring young walnut trees into
symmetrical form by pruning, and likewise in forming the tops of top-
grafted trees which have a tendency to become very top-heavy, better
results seem often to be obtained by summer pruning while the trees

FIG. 22. — Santa Barbara Soft Shell seedling walnut grove in which the trees have never

been pruned.

are in full growth and foliage rather than by cutting off limbs during
the winter. In the latter case large, strong suckers are apt to come
out at every cut and the shape of the tree becomes even worse than
before. On the other hand, by cutting back the green shoots while
they are growing their growth is decidedly checked, while those of
other parts of the tree, being in an active condition, develop rapidly
and produce the effect desired.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 191

Figures 22 and 71 illustrate walnut trees which never have been
pruned at all, the branches coming down upon the ground, which is
the natural tendency of the tree. This practice is not without its
advantages, although it is doubtful whether the latter are sufficiently
great to warrant its general adoption. The walnut, like the lemon
and orange and some other trees, seems to have a tendency to produce
its fruit with particular abundance on branches close to the ground.
It is certainly true that such branches are very prolific and produce
more fruit proportionately than those higher up in the tree. For this
reason some growers consider that the interference with cultivation by
these low branches is more than counterbalanced by the increased crop
obtained. This is largely a matter of personal preference, but in
most orchards a higher-headed tree is to be preferred. In the young
tree shown in Fig. 71 the object of the owner is to allow the trees to
take this form during their early life in order to obtain quick returns,
while as they grow older and higher it is his intention to gradually
prune them up. Some growers may find it profitable to follow this
method.

Another matter which may be discussed under the subject of prun-
ing is that of the breaking off of large limbs of walnut trees, which
frequently happens especially in the northern part of the State. The
large lateral branches which develop from the main stems have a con-
siderable tendency to form a very poor union in the angle of the
crotch between the branch and the stem and many large limbs break
off at this point. Trouble of this sort is much more common in the
northern part of the State, possibly on account of the fact that the
growing season is shorter and that during the rapid growth of the
branches the crotch joints do not have time to properly unite. Where
such large limbs break off nothing can be done but to make as clean
a cut as possible at the point of breaking, and cover tfre wound with
paint or grafting wax. One observation upon this subject is of value,
namely, that in the walnut there are usually at least two buds, one above
the other, at each axil, and of these the upper bud is the one which
normally grows out, forming these branches which break off so readily.
It has, therefore, been suggested that in localities where there is much
trouble of this sort the upper bud at each axil where a limb is to be
produced be cut off and the second bud forced into growth, with the
idea that this lower bud will form a branch having a better union.
There appears to be considerable value in this idea.

192

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

CROP HANDLING.

The following account describes the methods of handling the walnut
crop most generally in vogue in southern California. In individual
cases various deviations from the methods described are made.

FIG. 23. — Top — Picking walnuts. Bottom — Washing; cylinder turned by horse power.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 193

PICKING.

Walnuts are gathered by picking them up from the ground, where
most of them fall naturally at maturity. When the nut is ripe the
outer hull opens and the nut falls out in the majority of instances.
The freedom with which the nut leaves the husk varies somewhat in
different seasons, a greater proportion of nuts falling out more freely
some years than others. Sticking of the husk to the nut is caused by
sunburn, and also appears to be due largely to a lack of soil moisture,
and to some extent to a dry condition of the atmosphere. In dry
seasons, as a rule, the husks are more inclined to dry down tightly over
the nuts rather than opening up freely while still green and succulent
than in years of abundant rainfall. If this be true, the benefit of irri-
gation just previous to the ripening of the nuts is very apparent.
The nuts are usually hurried off the trees to some extent by shaking, the
latter operation being carried on by means of long poles with hooks on
the end, by means of which the branches can be shaken without injur-
ing the tree. In southern California walnut picking is done largely by
Mexican families who camp in or near the groves during the season,
while young and old of both sexes take part in the work. In some
cases, however, growers are now employing able-bodied, adult labor for
walnut picking, considering such labor more profitable on the whole
than the cheaper class more commonly employed. Efforts have been
made to perfect machines for picking walnuts from the ground by
suction, but nothing of this sort has as yet come into practical use.

WASHING.

After being picked up and placed in sacks the nuts are carried to
some convenient point and washed, in order to remove dirt, portions
of the hull, etc., which may be sticking to them. Such washing is done
in large, cylindrical drums made of coarse wire netting in which the
nuts are slowly revolved under a stream of water, grinding against
each other and against the wires forming the sides of the drum. In
this way all the nuts which have fallen normally from the husk and
those in which most of the husk has been removed by hand during
picking are very thoroughly cleaned. For removing the more tightly
attached husks of the sunburned nuts and "stick-tights" various
devices are used, consisting in a general way of cylinders with sharp
projections from the sides by means of which a considerable propor-
tion of these nuts are cleaned up fairly well. There may still remain,
especially during certain seasons, a considerable proportion of nuts
with fairly good meat but with more or less of the hull tightly adhering
to the shell. Such nuts are sometimes gone over again by hand, remov-
ing the husks which can be gotten off without too much effort, but
6—231

194

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

ultimately there always still remains a greater or less proportion of
these "stick-tights" which must be picked out and discarded.

After these washing and other cleaning operations are over the nuts,
now in a dripping wet condition, are placed in large trays having
bottoms composed of slats spaced about one half inch apart, so that

FIG. 24. — Top — Drying nuts. Bottom — Delivering at packing-house.

the nuts may drain. These trays are commonly about 6 by 3 feet and
6 inches deep, thus holding several layers of nuts. The side boards
are allowed to project at the ends and are shaped into handles for
lifting the trays. In the trays the nuts are stirred, spread out in the
open or stacked up and covered, according to the weather, with the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 195

object of drying them as rapidly as possible without. too great exposure
either to the sun or to moisture. In the former case they are likely to
split open, especially in poorly sealed varieties. In the latter they
may become moldy and discolored. The larger and more progressive
walnut growers, both north and south, are coming more and more to
the use of artificial heat and enclosed buildings for drying their wal-
nuts, rather than depending upon the uncertainties of the weather. In
this way the nuts can be dried uniformly and quickly with no danger
of exposure either to rain or hot sunshine. In the northern part of
the State where early rains are more likely to occur and where later
varieties of walnuts are more commonly grown, such artificial dryers
are an absolute necessity in handling walnuts on a large scale and even
in southern California they are coming into use. We will not take
space to describe the details of such a dryer here but may say that
a very large and complete one has recently been installed by Mr. J. F.
Burgess of the Vrooman Kanch, Santa Rosa, which is well worth visit-
ing to one contemplating such an apparatus.

After drying it is necessary that the nuts be graded to some extent
at home in order to remove the culls and worthless nuts before delivery
at the packing-house. For this purpose the nuts may be spread out
again on trays or handled from sack to sack if working on a small
scale, while on a larger scale an arrangement consisting of an inclined
bin or runway large enough to hold several sacks or even several tons of
nuts is desirable. In such a contrivance the nuts pass out at the lower
end under the control of the operator, who picks out the culls and allows
the good nuts to run into sacks, in which they are carried to the
packing-house. Mr. C. B. Franklin of Carpinteria has an excellent
arrangement of this sort.

PACKING-HOUSE OPERATIONS.
SAMPLING.

According to the methods commonly in practice in southern Cali-
fornia the walnuts on delivery by the grower at the packing-house
are first sampled for quality. The inspector picks out one hundred nuts
here and there at random from the sacks and cracks each one to
examine the meat as to fullness and color. There are various require-
ments as to quality, but usually nuts which crack from 80 to 90 per
cent of sound, fairly-light-colored meats will pass. The standard varies
considerably from year to year, according to the general quality and
quantity of the crop and the condition of the market. Not over 10 per
cent of badly shriveled or entirely bad meats is often accepted, while
in color it is usually expected that 45 or 50 per cent must be white or

196 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

very light brown, and from 30 to 35 per cent amber, or not decidedly
dark. Having been accepted by the inspector, the nuts then go to the
bleach.

BLEACHING.

Various methods of bleaching walnuts have been practiced, the
object being to remove all dirt and discoloration from the shells and
give them a bright, light colored, attractive appearance. In the earlier
years of the industry most of the nuts were bleached by exposure to
the fumes of burning sulphur, this being done while they were wet.
Sulphur bleaching is quite unsatisfactory, however, owing to the fact
that the fumes penetrate the kernels of the nuts to a considerable
extent and have a decided effect upon their flavor. On this account
sulphur was largly abandoned several years ago and a process of
bleaching the nuts by immersion in a liquid took its place. This process
consists essentially in dipping the nuts into a solution of chloride
of lime and sal soda, to which sulphuric acid is added, the result being
a liberation of chlorin gas which brings about the bleaching action.
The following formula which was given out by the University of Cali-
fornia Experiment Station illustrates the details of this process : "Six
pounds bleaching powder (also called chloride of lime), twelve pounds
sal soda, fifty gallons water. Dissolve the bleaching powder in about
four gallons of water, stirring till dissolved. Dissolve the sal soda
in about four gallons of water. Add one solution to the other and
stir well; let the carbonate of lime settle to the bottom and draw off the
clear liquor and add water to make a total of fifty gallons. Put the
nuts in large dipping box or lath crate, immerse in the fluid, and then
add one and one fourth pounds of 50 per cent sulphuric acid and
agitate by raising and lowering the dipping box. The bleach should
be reached in five to ten seconds, and the nuts are then washed in clear
water and put out to dry. Of course to employ this process cheaply,
specially contrived dipping appliances are used. The same liquor can
be used with new batches of nuts so long as the proper effect is pro-
duced, and small additions of acid will prolong the efficiency of the
liquor. ' '

Owing to litigation over the rights to this process and a decision
in the California courts that it was covered by a patent, further efforts
were made by the walnut growers to obtain a satisfactory bleach and
quite recently they employed Professor Stabler of the University of
Southern California, Los Angeles, to devise a new process. Professor
Stabler brought into use the electric process, consisting essentially in
passing an electric current through a 4 per cent solution of common
salt by means of electrodes immersed in the liquid. In this process
chlorin is set free and becomes available for bleaching. It is possible

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 197

also that the electric current may exert bleaching action of its own. At
all events, walnuts bleached in this manner are decidedly free from the
odor and taste of chlorin which characterized many of those bleached
by the old liquid process. In the electric process, as first applied, the
walnuts were immersed directly in the liquid through which the electric
current passed. In its present, more improved form the apparatus
consists of a comparatively small, porcelain jar or cell containing the
electrodes, through which passes a continuous stream of the salt water
which is mixed in a preliminary tank, passed through the cell for
treatment, and goes on then into a storage tank. The bleaching device
proper consists of a series of slightly sloping, superimposed narrow
trays with coarse wire netting bottoms, down which the nuts are made
to travel slowly by means of a shaking device. These trays are placed
one beneath the other, the nuts dropping from the lower end of the
first on to the upper end of the second, and so on, back and forth to
the bottom. The electrically treated salt water is discharged in a fine
spray over the top tray upon the nuts, and drops down through upon
them more or less as they travel back and forth in traversing the
various trays. At the lower end of the apparatus the nuts pass
through a spray of clear water which cleans them of the salty solution.
The whole apparatus is enclosed in a tight wooden box which assists
bleaching to some extent by retaining the chlorin gas. This electric
method of bleaching walnuts is still in process of development and
improvement, but the results thus far obtained with it show clearly that
it is far the most satisfactory method yet devised for bleaching walnuts.
The nuts after treatment have a very beautiful, attractive appearance,
without the dead, unnatural whiteness which is given to them by strong
sulphur fumes and various other substances. The quality of the nut
is seemingly injured not at all, as no odor remains after drying, while
in respect to flavor there is also no objectionable effect. The only
effect of this sort which can be detected is in the case of nuts which
were partially open when passing through the bleach, which may have
a slight salty flavor. On leaving the bleaching box the nuts are dis-
charged on to a moving elevator belt which carries them into the
grader.

GRADING.

In this operation the nuts are graded into two sizes, the first grade
consisting of those which do not pass through an inch square mesh
screen, while No. 2s are those which will pass through such a screen
but not through a three quarter inch square mesh. Various devices
for grading are in use, some consisting of a cylindrical cylinder with
sides composed of a wire screen of the proper mesh, while more com-
monly they are graded over a horizontal screen which is shaken back

198 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

and forth by machinery so that the smaller nuts drop through, and all
sizes are carried automatically on to belts which elevate them into bins
for drying and storage. In some houses artificial drying is resorted to
at this point, since in a moist climate or in wet weather the nuts may
become moldy and discolored before drying. More or less grading for
quality is done after the nuts leave the bleach by picking out discolored
or otherwise objectionable nuts by hand at some convenient point in the
operation. The nuts which are simply discolored, but still contain
good meats, are sometimes run through the bleach a second time and
considerably improved in appearance. From the final bins the nuts
are drawn off into large sacks containing about 100 pounds each for
shipment to market.

WALNUT GRADES.

The commercial grades of walnuts commonly made in California are
as follows: "Budded," No. 1 Soft Shells, No. 2 Soft Shells, No. 1 and
No. 2 "Standards" or "Hard Shells," "Paper Shells" and culls. The
term budded walnuts, as commonly applied in the trade, includes the
Placentia Perfection, or nuts of equally good appearance graded over
a screen one and three sixteenths inch square mesh. Into this class
go all the good-sized nuts of any desirable variety which is worthy of
propagation by budding or grafting. These usually command a pre-
mium of two or three cents per pound over the best of the ordinary
nuts. The terms Soft Shell, Hard Shell and Paper Shell are of rather
uncertain meaning so far as the thickness of the shell is concerned.
As a matter of fact, very few or no No. 1 Hard Shells go on to the
market, but almost any good-sized nut is classed as a Soft Shell.

"Hard Shell" and "Paper Shell," so far as they have any definite
meaning, refer commonly in southern California to certain types or
varieties of trees rather than to nuts of a particular thickness of shell.
"Hard Shell" means commonly the old-fashioned walnut of the first
California plantings, which is a tree of quite characteristic type. The
bark is of decidedly whitish color, the general form of the tree rather
stocky and compact, while the nut is small, quite round and decidedly
hard-shelled. The tree is less thrifty and more inclined to die-back
and deterioration than the prevailing type of the soft-shell tree. Com-
paratively few of these typical hard-shell trees now remain in the
southern California groves. Any good nut of desirable size and shape
goes on the market as a soft-shell, regardless of its actual cracking
quality, so that extreme thinness of shell is not a necessary or even a
desirable quality. Any good-sized, slightly elongated nut is decidedly
better from a commercial standpoint for having a comparatively hard,
not easily opened shell, since such nuts stand handling better and are
also less liable to the trouble called perforation, which we describe else-
where.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 199

The term "Paper Shell" also denotes a certain, quite characteristic
type of tree rather than referring to any or all nuts with unusually thin
shells. The Paper Shell of southern California originated almost or
quite entirely among the earlier trees propagated by Joseph Sexton of
Goleta. These trees are of quite distinctive character, being of small
size as compared to soft shells or even hard shells of the same age, with
a slender, white barked trunk, rather large leaves, compact top, and a
small, round, more or less thin-shelled nut. Some typical Paper Shell
trees, however, bear nuts which are not especially thin-shelled and all
degrees of gradation may be found between paper shell, soft shell, and
hard shell trees. The typical Paper Shell is quite similar to the French
variety Chaberte in many ways. Most paper shell trees are particularly
susceptible to walnut blight and the variety has nothing whatever to
recommend it.

SELLING.

The walnut growers of southern California are quite generally united
into cooperative associations, each with its own packing-house and
officers. The members of each association carry their nuts to their
packing-house, where they are handled and sold by cooperative methods.
In addition to these various local associations the whole industry is
organized rather loosely into one general organization for certain lines
of business. The directors of the local associations hold a combined meet-
ing at least once a year and keep up a general organization, having a
president and the other usual officers, including a paid secretary.
Matters of general interest come before this larger meeting, including
the purchase of sacks for each season, and particularly the fixing of
prices for each year's crop. At a meeting held each year early in
the fall, reports and estimates are submitted as to the probable crop
of the season and minimum prices are fixed for nuts of the various
grades for that year. The actual selling is then done through out-
side brokers who receive a commission for their services. This method
of selling is not altogether satisfactory with many growers at present,
and the suggestion is frequently made that the general association
employ its own agents in the various trade centers all over the country
to sell the crop along the lines practiced by the California Fruit
Growers' Exchange, which handles the bulk of the citrus crop.* Grow-
ers who are not affiliated with any association usually sell their nuts
directly to brokers or commission men and commonly receive associa-
tion prices for the same. A few growers, especially in the northern
part of the State, whose orchards are composed of grafted trees of
the better varieties, have a special trade of their own and receive from
20 to 100 per cent more for their nuts than the ordinary prices. The

* Since the above was written an incorporated central association has been formed
along these lines.

200 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

prices received by the southern California associations during the
past few years have ranged between 12 and 15 cents per pound for No. 1
soft shells, about 1 cent less for No. 1 hard shells, and about 3 cents
less for No. 2s than No. Is. Some income is also derived from culls,
which, if fairly good, may bring at least 5 cents per pound, and also
from the selling of meats which are removed by hand from the broken
or very poorly sealed nuts. The grower usually receives about one
cent less per pound than the fixed price, this difference representing
a portion of the broker's commission and packing-house expenses. The
remainder of these expenses is covered by a small profit made by the
associations on the sacks, which are bought through the general asso-
ciation at very low rates.

PROPAGATION OF THE WALNUT.

In starting a walnut orchard various methods of procedure are pos-
sible, all of which have their merits and their enthusiastic supporters.
Of these methods the three following are most important : Planting the
nuts in place in orchard form for subsequent grafting when the trees
are large enough ; planting nursery-grown seedlings in orchard form for
subsequent grafting, and the use of nursery-grafted trees for orchard
planting.

ROOTSTOCKS.

Inasmuch as various roots upon which to grow the English walnut
are available, it is not to be expected that any one species will necessa-
rily be the best under all conditions. It would rather seem reasonable
that the walnut, like most fruit trees, would do better on some soils
or under some conditions upon one kind of root, while under other
conditions a different root would be most suitable. In the case of the
walnut much still remains to be done in regard to testing various roots.
The planting of grafted trees is so recent that very little careful test-
ing has been done and in the majority of cases it is only known in
regard to the root that they are " English" or "Black," the latter
including all sorts of forms. After discarding the English root, which
nurserymen have now done quite universally, they have in most cases
simply gathered nuts from the most convenient black walnut trees, and
thus we have among the so-called black walnut roofs both the northern
and southern California species, some straight eastern and many hybrids
of various mixtures and generations. It is therefore possible to tell
very little from existing plantings as to root, since it would be necessary
to know the particular tree from which certain seedlings came in order
to duplicate them. A few of the most advanced nurserymen have com-
menced in recent years to segregate seedlings of the various species,
hybrids, and those from cer.ain individual 1rops. and it is only in this

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 201

way that roots can be definitely tested on different soils and in different
localities with any possibility of duplicating the same roots after their
qualities have been determined.

In our own work the necessity of testing rootstocks as well as differ-
ent varieties of the nut itself was recognized from the first, and in
the planting of our experimental orchard on the Whittier State School
grounds, an effort was made to obtain trees of the various varieties on as
many different roots as possible when the first planting was made.
We soon found, however, that the roots of these first trees purchased
from various nurseries came a long way from representing definite
species or types, but that as a matter of fact they were a very much
mixed lot. After commencing propagation of our own, root-testing
was still kept in mind, and further plantings for this purpose have been
made. We have now trees growing on various types of soil in various
parts of the State and on different, definitely known roots, from which
plantings results of some value can be looked for. A few other
propagators are doing the same thing. Experience has abundantly
proven that on account of the extreme variation in the seedlings of
various black walnut trees and the freedom with which trees hybridize
or cross with any other walnuts in the vicinity, the matter of rootstock
must come down to a determination of the qualities of the seedlings of
certain individual trees rather than those of all the trees of any given
species or form.

The general requirements in a root are that it should produce a
thrifty and vigorous tree, the more so the better, under as many differ-
ent conditions as possible. In other words, it should be one which is
not easily affected by unfavorable conditions, but which will produce
and maintain a good, thrifty tree even if the ground is a little too
dry or too wet, and upon as many different types of soil as possible.
Having a large variety of types to choose from, however, it is not to be
expected that any one root will be the best under all conditions bat
rather that we shall ultimately find one type to be the best for dry soil,
another the best where there is an excess of moisture, one for heavy
soils, one for light soil, and so on. At the same time a good all-round
root or one which is not easily affected by any variation from its
favorite condition is by far the best for general purposes. It is not
impossible that we shall ultimately find a difference in regard to varie-
ties of the English walnut as to root, some kinds doing better on one
root and others on another. There is already some evidence that this
is true. From the nurservman's standpoint, it is desirable that a tvpe
be chosen for the root wherein the parent tree is a large producer of
nuts, one in which the nuts srerminate readily and uniformly, producing
a uniform lot of seedlings with a £ood affinity for the English walnut.

202 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

The nurseryman growing any considerable number of trees cannot
afford to run about picking up a few nuts from a tree here and a tree
there, even though they may give seedlings of unusual excellence. Hav-
ing found good trees from which to propagate, some nurserymen are
coming to the practice of reproducing a considerable number of these
trees by grafting and planting them out on their own grounds for seed
production purposes.

English Walnut Root. — The propagation of the English walnut
upon its own root has been almost entirely abandoned in California.
This is on account of the fact that this root, while very vigorous and
thrifty under perfectly favorable conditions, is easily affected by ad-
versity and very susceptible to unfavorable conditions, either perma-
nent or temporary, such as dryness, excessive moisture of the soil or
any other condition not perfectly favorable. The English root delights
in a deep, fertile, well drained, fairly heavy soil, with uniform and
abundant moisture, and under such conditions trees grafted upon it
are thrifty and vigorous, but experience has shown that comparatively
slight variations, such as dry years or other influences, react very
quickly and unfavorably upon trees on this root. The root is also
more susceptible to crown gall, gophers, root rot and some other
injurious influences than are those of any of the black walnuts. For
these reasons propagation upon the English root is practically obsolete
in California.

Eastern Black Root, Juglans nigra. — This root has been tried to
some extent in California, but the species is of such extremely slow
growth in this State as compared with other black walnuts that it can
scarcely be considered as a commercial root for general use. The im-
pression is general that this root is better adapted to wet land than
any other, on account of the native habitat of the tree in river valleys.
Even under such conditions, however, it is probable that for use in
California a better root can be chosen for planting in any soil which
is worthy of consideration for walnut culture.

Northern California Black Root, Juglans hindsii. — The black walnut
of northern California is an extremely thrifty, vigorous tree under
most conditions at all favorable to tree growth, and this is one of
the most popular and satisfactory roots for the propagation of the
English walnut. For general use, where no special study of selection
of rootstocks is made, it is probably the best root which can be recom-
mended for California planting. It should be remembered, however,
that the progeny of various individual trees of this species vary greatly,
and the seedlings of some trees are much more uniform and much
better trees than those of others. Indiscriminate planting of northern

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 203

California black walnut is, therefore, not advisable if the grower desires
to produce the best possible trees upon this root. It is much better
to plant separately the nuts from various trees and determine the
nature of the offspring in each instance. Only trees of large produc-
tion should be chosen for this purpose, since it is not profitable to
gather nuts here and there from a great many different trees. Seed-
lings from the best types of the northern California species produce,
when worked to the English walnut, a thrifty, vigorous tree, of very
good growth, more resistant both to excessive moisture and drouth than
those upon the English root, not susceptible to gophers or root rot, and
in every way a very good, all-round tree. The root is only excelled by
certain special hybrids which will be discussed later.

Southern California Black Walnut Root, Juglans californica. — This
root has been quite commonly employed for the English walnut in the
southern part of California and has much to recommend it, particularly
for that part of the State where it has been most tested. The quite
common impression that the southern California walnut root has a
dwarfing effect on trees worked upon it is entirely erroneous, as such
is certainly not the case. The tree no doubt gets this reputation from
the fact that as it grows wild on dry hillsides it often has a dwarfed,
shrubby form. When planted in good soil, however, with even a mod-
erate supply of moisture, it is a tree of extremely rapid growth,
especially in diameter, and actual experience shows that with trees upon
this root there is no indication whatever of a dwarfing effect. In our
southern California nurseries we have found no walnut which gives as
uniform a growth of seedlings in the row or as uniformly good grafted
trees during the time that they are in the nursery as this. From
the nurseryman's standpoint, in the south at least, it is an ideal
tree, the nuts sprouting early and uniformly and the seedlings making
a uniform, vigorous growth kept up until very late in the fall. Trees
of this species remain green and still growing while the northern Cal-
ifornia and other forms have become dormant and dropped their
leaves in the fall, while in the spring they are the first to come out.
The tree is, therefore, especially good for budding on this account.
The southern California walnut unites readily with the English, and,
as we have said, for the southern part of the State at least, we believe
it to be one of the best roots. Other objections to this root have been
that it is especially susceptible to wet land and also that trees grafted
upon it are more apt to blow over than those upon other roots. The
first objection is not without foundation, since the southern California
walnut, from the first sprouting of the nut, is extremely susceptible
to an excess of moisture. This root should not be used for trees to be
planted on very heavy land which is likely to be extremely wet at times.

204

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

We should, in fact, hesitate to use the southern root at all for the
northern part of the State, except on decidedly light soil. One should
also not attempt to grow it in a nursery where the soil is heavy and wet.
In this connection see seedling root rot, or wilt, page 379, a decay of
the root of seedlings in very wet or heavy soil. This trouble seems to be
limited to this species. The matter of the trees tipping over is not
usually a very serious objection, although such trouble does seem more
common on this root than on any other. There is some experience
available which seems to indicate that for late varieties like Franquette
and Eureka, the southern black walnut root is not quite as well adapted
as for early varieties like Placectia, Chase, or Prolific. With the latter

FIG. 25. — Ten-year-old Placentia tree on southern California black root.

it certainiv makes a magnificent tree, as shown in many existing
orchards. Even with the late varieties it makes an unusually fine tree,
in the nursery at least, and the most uniformly large and the best
stands of Eureka which we have ever grown were on this root.

HYBRID ROOTS.

The remarkable vigor and rapidity of growth of some walnut trees
of hybrid oHgin such as we have described elsewhere has led to the
very n?it Mr? I inference that seedlings of such trees should be extremely
desirable MS a rootstock for the English walnut. Working on this idea,
we have oynerimented with such roots quite largely during the past
five years and several other investigators have done the same.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

205

Paradox Hybrid Roots. — It would seem at first thought that seed-
lings of some of the very large, wonderfully thrifty Paradox hybrid
walnut trees found in California should give an ideal root for the

FIG. 26. — Four-year-old Placentia tree on Paradox root. Trees shown in Figs. 27 and

28 in the background.

English walnut. In order to test this, nuts from many of these trees
have been planted by ourselves and others, the resulting seedlings

206

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

grafted to various varieties of the English walnut and the trees planted
out for observation. We may say, however, at the outset, that such
trials have resulted without exception in proving the non-desirability

FIG. 27. — Four-year-old Placentia tree on northern California black root.

of the seedlings of these Paradox trees as a rootstock for the English
walnut. Trees on this root are invariably lacking in any unusual vigor

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

207

of development and these second-generation Paradox seedlings may
therefore be dropped out of consideration.

The next question which suggests itself is the possible utilization

FIG. 28. — Four-year-old Placentia tree on English root.

of first-generation Paradox trees; seedlings, in other words, which
come directly from black walnuts which have been cross-fertilized with
pollen of the English walnut. Such trees, as we have shown elsewhere,

208 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

occur in a greater or less proportion among the seedlings derived from
black walnut trees which stand in the vicinity of English walnuts.
These seedlings are those which grow into the extremely vigorous trees
seen here and there in the State and it is certainly to be expected that
an English walnut upon such a root would have some unusual vigor.
This we have found to be the case, by grafting upon the hybrids which
appear here and there among the black walnuts and by planting out
such trees for future observation. We cannot yet say that every tree
upon a first-generation Paradox root will have this unusual vigor but
so far as our observation has gone such trees have a general tendency
toward such a habit. Figs. 26, 27 and 28 illustrate a case of this sort,
these being Placentia Perfection trees grafted at the same time, of uni-
form size when planted in the orchard and planted adjacent to one
another under uniform conditions. The tree on the Paradox root in
Fig. 26 is fully twice as large as the one upon the English root, and
decidedly larger than the one upon northern California black. That the
production is proportionate to the size is shown by the crop of 1911,
when the Paradox root tree produced 18J pounds, that upon California
black 12J, and that upon English 9 pounds. English walnut grafts
unite readily with the Paradox root, which is a very desirable feature
from the nurseryman's standpoint. It is not probable, however, that
this root will ever be largely used by the general nurseryman, since only
a comparatively small and very uncertain percentage of hybrid trees
develops in the nursery, extra work and care are required to keep
separate the trees on these roots from those on the straight black and
only one who is something of a specialist and who is able to make a
special effort to obtain and segregate these roots can expect to make a
regular practice of growing trees upon them. For such trees he must
obtain a greater price than that received for those on ordinary roots,
in view of the extra expense and care necessary to produce them.
Good Paradox roots are especially well adapted to light, dry, or rather
sandy soils, as this hybrid is particularly vigorous under such condi-
tions as compared to any of the ordinary walnuts. On the other hand,
trees of the same nature have sometimes shown themselves likewise
resistant to an excess of moisture. It is, therefore, likely that the
exceptional vigor of this root enables it to withstand any unfavorable
condition to a considerable extent. It is to be expected, theoretically
at least, that Paradox trees containing eastern blood would be better
for wet- land than those consisting of English and California black.
Much remains to be done, however, in testing out various combinations
and especially in testing the seedlings of various individual trees
under various conditions. The whole question of the value of hybrid
roots is indeed one concerning the progeny of individual, special trees

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

209

I

FIG. 29. — A good Royal hybrid root; one year old. Southern Cali-
fornia x Eastern black.

7—231

210 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

rather than a matter of any general rules applying to all crosses between
certain species.

Royal Hybrid Roots. — Here again we enter the domain of the special-
ist rather than that of the average, commercial nurseryman. We have
stated elsewhere that in the Royal hybrid (the cross between California
and eastern black walnuts) many very thrifty, vigorous trees occur
and that this vigor is carried over into the second generation much
more than in the Paradox. In other words, experience has shown that
while seedlings from Paradox trees do not have the exceptional vigor
of the parents, there are some first-generation Royal trees which
transmit their exceptional rapidity of growth to their progeny of the
second generation. These trees vary greatly, however, in regard to
the character of their seedlings and it is only a very few which produce
nuts that give a uniform lot of seedlings as good as the parent. Such
trees, when found and thoroughly tested, are extremely valuable. We
wish again to emphasize the fact, however, that indiscriminate plant-
ing of nuts from Royal hybrid trees cannot be expected to give
uniformly good seedlings for grafting purposes but rather will result
in a most heterogeneous mixture of trees of all sizes, characteristics
and degrees of vigor. The Royal trees found growing about the State
are of various generations^ many of them of the second generation,
of which the seedlings are decidedly inferior, and the nurserymen
would do better to plant the nuts of the straight northern or southern
California black walnut than to pick up Royal nuts at random. The
propagation of English walnuts on the Royal root with the idea of
getting trees of marked superiority over those grown on the California
species is again, as in the case of the Paradox, the work of the specialist
who is disposed to try out individual trees carefully as to the nature
of the seedlings and that of trees grafted upon them, a process which
takes several years in the case of each individual Royal tree thus
tested. Trees of real excellence upon this root must also, therefore, be
grown by the specialist and command a considerably higher price
than ordinary trees. It should be equally understood that really select
trees on these exceptional roots constitute the very acme of perfection
in walnut trees as to vigor and hardiness, that they can be produced
only by the exceptional nurserymen and probably they will be purchased
only by growers who are willing to pay a premium in order to obtain
an exceptional orchard. Trees upon well-grown roots of either of
the ordinary California species are thoroughly good and first class, and
need not be deprecated on account of the fact that it is possible to grow
these exceptional trees to a limited extent on properly selected and
tested hybrid roots. Indiscriminate trees of the latter class, it should
also be understood, are no better than and perhaps inferior to those of

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 211

the former nature. The best Royal hybrid roots, in addition to giving
trees upon them of exceptional vigor, are also particularly adapted for
planting on rather wet, heavy soils on account of the blood of the eastern
black walnut which they contain. Well tested Royal roots are probably
the best for such soil. On the other hand, the vigor of the best Royal
root enables them to also do well on dryer soils or without irrigation,
so that they have a wide range of adaptation.

PLANTING THE NUTS IN PLACE.

A few years ago a very popular idea prevailed, especially in the
northern part of the State, that the only proper way to plant a walnut
orchard was to start black walnut seedlings directly from the nut in
the spots which the trees were to occupy in the orchard, so that these
seedlings could be grafted to the desired variety of the English walnut
later on without ever disturbing the taproot by digging and trans-
planting. In order to insure a good tree in each place, instructions
were given to plant about five nuts close together, like a hill of corn,
at each point where a permanent orchard tree was to stand. Out
of these five it was assumed that at least one would make a good tree,
and that this could be allowed to remain, while any others were to be
removed. A considerable acreage was planted and is still being
planted in the northern part of the State by this method. Its apparent
cheapness is attractive, and the idea of not disturbing the root has also
appealed to many quite strongly. In practice, however, we may say
without reservation that in no instance do we know of this method
proving practical or satisfactory. The objections to it are as follows:
In the first place, even though five or more nuts be planted in each
place, there are always in a large planting some hills where for one
reason or another no trees develop. Some will produce five good trees,
others none at all, and others one or more poor trees which do not
become fit to graft. In some of the hills very thrifty, rapid-growing
trees will develop, while in others the best tree will be of poor and
slow growth and thus at the end of the first year the planting will
consist of trees of great variation in size, with now and then a place
where there is no tree at all. This variation in the growth of the
trees becomes greater and more pronounced as years go on. Further-
more, in planting by this method, which presupposes that it will be a
number of years before any walnuts will be produced, some other crop
is ordinarily grown on the land in the mean time, and in cultivating
this crop between these little seedlings it is impossible to avoid a tree
here and there being run over, stepped on, or destroyed in one way
or another. Again a rabbit or squirrel may get one, some insect pest
another, and so the irregularity of the planting becomes more and more

212 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

pronounced. Again, it is impossible to give to trees planted out in
the field in this way the care which could be given them if planted in
the nursery, and their growth at best is much slower than it would be
under the latter conditions. When the best trees finally reach graft-
ing size, there are bound to be many others in the orchard of all sizes
and ages which struggle along over three or four years before they get
large enough for grafting. After grafting commences the same irreg-
ularity continues. In some trees the grafts do not take the first year,
consequently these must be grafted over again the second and often even
the third year. Thus the whole tendency of this method in practice is to
produce a most irregular, uneven orchard, and at the same time requir-
ing several more years for its development than is necessary under
other methods. More than all this, the absolute fallacy of the notion
that there is any disadvantage in cutting the taproot or in trans-
planting the walnut tree has been abundantly established, so that the
only object of using this method loses completely its value.

PLANTING BLACK WALNUT SEEDLINGS IN ORCHARD FORM.

This method represents a decided improvement over the last one.
It consists in growing black walnuts of the desired type in the nur-
sery, then selecting from these as good and uniform a lot as possible
and planting them out, ordinarily when one year old, in permanent
orchard form, with the idea of grafting them later on. By doing this
several of the objections to the last method are overcome. It is pos-
sible to get a very uniform stand of black walnuts, provided the stock
is of uniform nature, and by proper selection of seedlings, trees can
be obtained which will come along fairly uniformly and be ready for
grafting at about the same time. The advantages claimed for this
method are mainly two: first, that by allowing the black walnut trees
to reach considerable size they may be grafted at a height of about five
feet, thus obtaining a black walnut rather than an English walnut
trunk, which, with its rough bark, will be more immune to sunburn.
The second advantage is that in planting an orchard to be grown
without irrigation, grafts upon a well established black walnut tree will
be much better nourished and receive a better supply of moisture during
the first year or two, when a transplanted tree would be using up its
energies in developing new. roots, and thus the high-grafted tree will
obtain a much better start. Both of these ideas have considerable
merit, especially in planting where irrigation is not to be practiced.
Under such conditions a vigorous black walnut seedling, especially
if dug with a good root and cut back in the top, as described on pages
245 and 248, may usually be established without much difficulty by a
little hand-watering during the first season. If the soil is such that
non-irrigated orcharding is at all feasible, the tree will then go on to

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 213

vigorous development in subsequent years. A nursery-grafted tree, if
planted at the same time, and especially under rather dry conditions, is
likely to fall behind the black walnut seedling and never catch up to it
again in growth. After three or four years the black walnut may be
cut off and grafted high, whereupon its large, vigorous root will furnish
the grafts with an abundant supply of moisture and force them into
rapid development. There is also some advantage in regard to sunburn
in the black walnut trunk, although we have seen such injury even to
the black walnut on rather dry soil. It is also true that sunburn is not
apt to prove serious with properly grown English walnut trunks on
good soil.

The method of top-grafting black walnuts in place is open to one
objection in common with that of planting the nuts in place, namely,
that after grafting commences a uniform stand cannot be obtained the
first year, and the work will probably extend over at least three years
before all the trees bear a good top. In this way the orchard becomes
irregular and uneven. Again, it is objected with considerable reason,
that in this high grafting on trees several years old, very thrifty,
rapid-growing shoots develop from the grafts, which become extremely
top heavy, easily blown over by the wind, and a source of real difficulty
to keep up in shape until they are able to support themselves. On this
account there is now a tendency to graft low on such trees, within two
feet of the ground, even though most of the supposed advantage of the
black walnut trunk is thereby lost.

Altogether, we may say that if the walnut orchard is to be planted
in good soil with irrigation, the disadvantages of this method over
planting nursery-grafted trees by far outweigh its advantages. At
best it is slow in producing a bearing orchard, it results in much irregu-
larity in the size and growth of the trees, the tops are very difficult
to support, and, under the conditions mentioned of good soil and mois-
ture, there is no real advantage in the end to offset these objections.
In planting a walnut grove to be grown without irrigation, especially
on rather shallow dry soil, where the trees at best may have a rather
scanty moisture supply, this method in spite of its disadvantages is
probably the best one to use. In following it extra good, one-year-old
seedlings of the best kinds should be obtained, these to be treated for
planting by digging with as much root as possible and cutting the
tops back severely, as described on page 248, planted out early in the
winter so that they will obtain all possible benefit of the winter rains,
and given all possible care during their first season's growth. A good-
sized circle should be kept cultivated or hoed about each tree, they
should be given a copious watering by hand as many times as possible
during the first season, and it is well to dig into the soil about them a

214 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

good dressing of stable manure with a heavy mulch of the same mate-
rial, in order to retain moisture as well as add fertility to the soil.

As the trees grow they should be staked up if necessary and trained
to a single stem which eventually should be cleared of side branches
up to about five feet. It is not, however, necessary or desirable to prune
the tree to a single, bare shoot from the very first, since side branches
shade the trunk from the sun and also assist in growth, particularly that
in diameter. It is, therefore, better to take off the laterals gradually
from below at the end of each season rather than keeping them all
cleaned off continuously. For the best success of this method it is not
well to hasten the grafting too much, as better permanent results will be
obtained by allowing the trees to reach considerable size before graft-
ing. Grafting when the trees are less than three inches in diameter
at a point five feet from the ground is of doubtful advisability, and it
is better to wait until most of the trees in the orchard have reached
at least this size before commencing grafting. It is not advisable to
graft each year a few of the largest trees, thus scattering the grafting
over several years, on account of the unevenness of an orchard treated
in this way. For methods of top grafting, see page 230.

RAISING THE TREES IN THE NURSERY.

This, as we have shown in discussing other methods, is ordinarily
much the most satisfactory and successful, and the quickest and cheapest
method of starting a walnut grove.

SEED TREATMENT.

Walnuts to be used for planting in the nursery should, after gath-
ering, be kept in sacks or other receptacles in a cool, not too dry place
until planting time. If allowed to become extremely dry after gath-
ering the nuts germinate much less easily than otherwise. They will
usually keep in good condition if tied up in sacks and piled in a cool,
shady place. It may be found desirable to allow the outer hulls to
dry somewhat before sacking up the nuts, especially in the case of large
hybrid nuts, since if sacked and put away quite green the hulls decay
and become extremely soft and mushy. Early in the winter, not much
later than January, the nuts should be layered in sand or light strawy
earth in order to sprout them and segregate the best ones from those
that germinate feebly or not at all. This is most conveniently done by
constructing a frame about 18 inches deep, either above or below
ground, in the bottom of which should be placed 3 or 4 inches of sand,
then the layer of nuts which may be either one or several nuts in depth,
according to the available space. The nuts are then covered with 3
or 4 inches of sand, which should be washed down thoroughly between

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 215

the nuts by means of a stream of water. The whole bed will thus be
in a well-soaked condition by the time it is done. Instead of placing
the nuts directly in the bed, it is more convenient in getting them out
to put them in shallow wooden boxes or flats, imbedding these in the
sand as above described. If this is done it is much easier to get the
nuts out for planting than if they are placed directly in the sand.
Other materials may be substituted for sand, such as earth mixed with
fine straw or manure, or any substance which holds moisture well, and
from which the nuts can be easily removed. The bed should be so
arranged that water will drain away from it and not accumulate
sufficiently to rot the nuts, and it should be protected from rain if
there is any danger of such an effect from that source. The nuts need
to be constantly well moistened, however, in order to start germina-
tion, and if drainage is good there is not much danger of getting them
too wet. The bed should be located in a place where it will receive
the heat of the sun in order that it may not be too cold for germination,
and it may be underlaid with manure if it is desirable for any reason
to hasten the sprouting of the nuts. Nuts of the different species
vary quite widely in respect to freedom of germination, those of the
southern California black walnut being especially quick to sprout.
These also rot more easily than other black walnuts. They need not,
therefore, be put into sand so early and should not be kept as wet as
northern California blacks or Eoyals. The latter especially need much
moisture and warmth to make them sprout. For prompt and uniform
germination they should be put into the sand quite early, in a single
layer of nuts, and be kept well moistened and as warm as possible.
Otherwise many will not sprout until the second or even third year, if
they be put into the ground before starting to germinate.

As soon as a considerable portion of the nuts has begun to sprout
in the sand bed they must be gotten out into the nursery as soon as
possible. In preparing the nursery ground special care should be
taken, as the growth of walnut seedlings is very easily affected by
slight differences in soil conditions. The ground should be prepared
in the fall by thorough and deep plowing and cultivation, in order that
it may be loosened up to as great a depth as possible and brought into
a fine, mellow condition, free from lumps and with no hard layer of
soil near the surface. A soil free from rocks, hard, unbreakable lumps
or shallow hardpan should be chosen for the nursery if one expects to
grow good trees. Greater growth is obtained on a fairly heavy soil,
although the heavier the soil the more difficult it is to work. The
future digging of the trees should also be considered, as this is a
question of importance in connection with the nature of the soil. A
somewhat sandy soil is easier to handle and much more convenient for

216 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

getting out the trees when ready for market than a heavy soil, as the
latter is likely to be muddy and unworkable at the time when the
trees should come out. Larger trees, however, are grown on heavy soil
and big trees commonly bring the best prices. By means of fertiliza-
tion and an abundant use of water, the growth of trees on lighter soil
may be accelerated to a considerable extent. Walnut nursery trees
are grown more or less without any irrigation at all in the northern
part of the State, but under such conditions only a fairly heavy soil
with strong water-retaining properties should be considered.

In planting the nursery, rows about three feet nine inches apart
should be furrowed out with a single plow, and the best sprouted nuts
may then be planted at a distance of from nine to twelve inches apart
in the row. Particular care is desirable at this point, placing the
nuts carefully in place by hand with the sprout pointing straight down
rather than dropping them in indiscriminately regardless of position.
In practice it will be found that some of the sprouts have made several
inches growth before planting commences and these should be handled
carefully and planted with a trowel. It is well for the planter to
carry such a tool in one hand, filling up the low places in the furrow,
digging holes for the longer sprouts and planting each nut as carefully
as possible. In some cases, on account of rainy weather or other
reasons, it is impossible to start planting early enough and many of the
nuts will form long sprouts and commence sending up a stem before
planting. These can still be planted out, although the work requires
more care. Root sprouts which are several inches or a foot or more in
length usually become broken, but will still grow successfully if not
broken off close to the point where they come from the nut. It is
indeed advisable to cut back long sprouts to a length of a few inches
rather than attempting to preserve each one and dig a deep hole for it.
Such trees will often form a large, branching root, more desirable than
one produced by the uninterrupted growth of the original tap root.
If the upward-growing sprout be broken off the nut should be dis-
carded. It may sometimes be necessary to go over the bed two or more
times in order to get all the good nuts out before the earliest have made
too much growth. For growing the best trees, however, only the nuts
which germinate most promptly and vigorously should be used, and it
will be found necessary to discard a considerable percentage of the nuts
placed in the sand. After planting, the nuts should be covered to an
average depth of about three inches, which may be done with a single
plow, if the nursery is large, going over the ground afterwards with a
harrow in order to smooth over the irregularities and even-down the
ridges. Special care should be taken not to plant too deep.

If the nuts have been well sprouted, the seedling trees will soon begin

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 217

to appear above ground, although if heavy rains occur before this time
the surface may crust over, especially on heavy soils, to such an extent
as to make it difficult for the young sprouts to break through the surface.
Under such conditions it may be well to go over the nursery with a rake
or light harrow in order to break up this crust. As the trees grow they
should be given good care, such as would be given to a crop of corn or
potatoes, by frequent cultivation and hoeing. Seedlings are grown
without irrigation in some localities, and there is a fairly common
impression that such trees are more hardy and desirable than those
grown under irrigation. We cannot coincide with this view, however,
having found no undesirable features in irrigated trees, while their
superior growth is desirable from every standpoint. As ordinarily
grown without irrigation, two seasons' growth is necessary to get the
majority of the seedlings up to sufficient size for grafting, while with
good soil and abundance of water, fine large trees of ample size for
grafting can be produced in one year, with roots proportionate to the
top in size and with no undesirable qualities whatever on account
of having been given sufficient moisture for their best development.
The difference, in fact, is fully as apt to be in the other direction, non-
irrigated trees being stunted and reaching grafting size only after
several years' growth. Again, in unusually dry years, non-irrigated
trees may be badly injured or even killed by drouth.

GRAFTING.

With good care and sufficient moisture the majority of the seedlings
should reach sufficient size for grafting during their first year's
growth and be ready for grafting during the next winter following
that when the nuts were planted. The size of tree which is suitable
for grafting depends largely upon the size of the scions available,
since seedlings can be used nearly down to the size of the smallest good
scions. In practice it will be found that trees of from one to two inches
in diameter close to the surface of the ground are best adapted for
grafting, while with the best of the smaller scions trees down to that of
three quarters of an inch or a little less may be used. This assumes
that the trees are grafted close to the ground.

There are various methods of nursery walnut grafting in practice,
the majority of which we will not attempt to describe. The operation
at best is one which requires much skill and practice, the walnut being
less easily grafted than most fruit trees, and among those who are
doing the work successfully each has his own method to which he has
accustomed himself by long use and which might hold no particular
advantage for the beginner. We will, therefore, describe but one
method of nursery grafting, which is that which has proven most
successful with us.

218

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Time of Grafting. — The time most commonly chosen for grafting
walnuts in the nursery is the period just before the seedling trees
commence growth in the spring, or even after the buds have unfolded
and the leaves developed to some extent. Various ideas will be found
upon this subject, and it may also be said that results vary to a con-

FIG. 30. — Face and side view of scion for nursery graft.
These are somewhat larger than the most desir-
able size.

siderable extent from year to year, even though the grafting is done at
apparently the same stage of development. The best average results,
however, have been obtained by commencing the work just in time to
complete it as the seedlings are coming into leaf.

In grafting by the method which we shall describe, the first operation

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 219

consists in hoeing away the dirt from about the seedlings in such a
manner as to expose the trunk down to the crown of the root. Several
inches of surface soil must be soft, moist and mellow at this time, and
if not already in this condition, they must be made so by irrigation,
cultivation, or whatever method is necessary. The young trees are then
cut off with pruning shears or a saw close above ground. With a sharp
grafting knife the operator then cuts a sloping bevel on one side of the
stub and then with his knife splits the stub down on this side for about
an inch, as shown in Fig. 31 — 1.

The Scion. — Scions of the desired variety should be chosen and cut
from the tree at some time during the winter after growth has ceased
and the tree become dormant, choosing scions from the most productive
and best trees and branches. Most propagators prefer to cut their
scions some little time ahead of the time of grafting, as they consider
a sort of curing process beneficial. The best wood for scions consists
commonly of that of the previous season's growth, bearing well-formed
buds fairly close together, and with as much as possible of solid wood
rather than pith. Occasionally two-year-old wood may be used for
scions, but such wood commonly is deficient in good buds. Some con-
sider only terminal buds desirable for scions and use therefore simply
the tips of the shoots, but lateral buds develop equally well and their
use enables the propagator to utilize his wood to a much greater extent.
Grafting wood is commonly cut up into sticks about one foot in length,
each of which bears from 4 to 6 buds if the wood is of the most desir-
able form. During the period between cutting the scions and the time
of grafting, the wood must be stored in such a manner that it will retain
its moisture and vitality without at the same time getting too wet and
becoming water-logged. There is commonly more danger of the scions
becoming too wet than too dry, unless they are carefully handled. With
some it is the practice to bury the grafting wood in moist sand, which
method is good provided the sand is not kept too wet. In this method
the grafting sticks should be buried in sand which is barely moist, and
watched carefully to see that they are kept from extreme dryness,
without at the same time keeping the sand decidedly wet. There is
some objection to this method on the ground that more or less sand
clings to the scions and tends to dull the knife and adhere to the
surface of the cuts in grafting. Others keep their scions in moist
sawdust or sphagnum moss, which does away with the latter objection
and keeps the scions in good condition, provided again it is not made
too wet. We have found sawdust the most satisfactory material.
Others place the scions in a cool, out-of-door shed with only the butt
ends stuck into moist sand or sawdust, leaving a considerable part of the
length exposed to the air. Whatever method is followed the chief

220

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

consideration is to keep the wood barely moist without soaking and
water-logging it. In the latter case the wood becomes dark colored
and if in this condition should be cut off and discarded in grafting.
Scions properly kept will remain in good condition for several months,
often callousing over on the ends if kept until late in the spring.

Fio. 31. — 1, Splitting the stock for nursery graft; 2, Scion inserted and tied;
3, Waxing ; heating stove at the right.

Grafting. — In grafting, the sticks should be cut up into lengths
bearing at least two buds each, one near each end. The operator
provides himself with a considerable supply of such scions which he
carries along in a pocket apron, box, or basket. In grafting he makes
a long, clean, sloping cut on one end of the scion, on the side opposite

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 221

the bud. The surface of this cut should be smooth and uniform and
it is usually made by the experienced operator in one stroke. A split
is then made with the knife between the bark and the pith on the longer
side of the scion, this split extending nearly down to the bud. It is
made nearer the bark than the pith, raising only a thin chip of wood
with the bark. For each stock a scion is chosen a little smaller in
diameter than the stock, the larger scions being put upon the largest
stocks, and vice versa. Fairly large stocks are always desirable, espe-
cially in propagating new varieties where grafting wood is scarce, as
upon them can be used both large and small scions. The stock should
not, however, greatly exceed the scion in size, since in such a case
complete healing over may not take place the first year. After split-
ting the scion it is inserted upon the split in the stock as shown in
Fig. 31 — 2. In this operation the object is to make as tight a fit as
possible, and to so place the scion that the cambium layer or inner
bark will come into contact with that of the stock at as many points
and as closely as possible. It will be seen in the illustration that in
this method of grafting, the cambium of the stock and scion may be in
contact upon at least three different surfaces. The grafter should
carry along a whetstone and keep his knife blade clean and razor-sharp
at all times.

After placing the scion upon the stock the next operation is that
of tying. This consists in wrapping soft cotton twine or raffia fibre
tightly about the union of stock and scion in such a way as to hold
them firmly together. If raffia is used, it should be soaked in water
to make it more pliable.

The next operation is that of waxing, which consists in thoroughly
painting over the stock and scion in the vicinity of the union and also
the upper end of the scion with grafting wax. It is better to leave a
narrow strip on the back of the stock unwaxed in order that the raffia
or twine used for tying may decay more readily, or may, if necessar3r,
be cut at this point. With twine it is especially necessary to cut and
loosen it after growth from the scion is well started.

Various formulae for preparing the wax are in use, but all usually
consist essentially in a combination of beeswax and resin in various
proportions, to which a little oil or paraffine is added, together with
other substances in some cases. The following formula is a good one :

Resin 4 pounds.

Beeswax 1 pound.

Linseed oil 1 pint.

The resin and beeswax are melted in a kettle and thoroughly mixed
with the oil while in a liquid condition. Some use raw and some
boiled oil. The former sometimes foams up to a troublesome extent

222 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

in boiling. The formula may be varied by using as much as 10 or
as little as 2 pounds of resin to the pound of beeswax, according to the
desired consistency of the wax. The greater proportion of resin the
harder will be the wax, and vice versa. Harder wax is necessary in
hot weather, as it should not be soft enough to melt and run. This
is less likely to occur in nursery than in top grafting. If too much
resin is used, the wax is then hard and brittle. Resin is much cheaper
than beeswax, and in nursery work may usually be used in the larger
proportions mentioned. One half pound of tallow may be substituted
for the pint of oil. In some cases one pound of flour or one to two
pounds of powdered charcoal is added to the formula and thoroughly
mixed in, with the idea of giving the wax more body and elasticity.
Some have substituted paraffine for part of the beeswax in nursery
grafting. This is much cheaper. The wax requires heat in order to
keep it in a liquid condition, which may be supplied by means of a
small fire, or more conveniently, by such an arrangement as that shown
in Fig. 31 — 3. This consists of a coal-oil can with a round hole in the
side, over which a disk of tin is fastened in such a manner that it may be
raised or lowered for a door. In the bottom of this can is placed a
small oil stove on which is set the pot of wax. A handle at the top com-
pletes the apparatus, which, while crude, is very satisfactory. Another
very good device is that used by plumbers for keeping a pot of solder
in a melted condition.

After thorough waxing, in which no cut portion of the stock or scion
should be left uncovered, the dirt should be hoed back again about
the newly grafted trees, covering scion and bud completely with soil.
This must be done very carefully, in order not to displace or knock out
the scions, and the dirt should be worked up as fine as possible with
the hoe and all hard lumps and rocks removed. This is a consideration
to be kept in mind in choosing soil for a walnut nursery, as the success
of grafting by this method depends quite largely on thorough cover-
ing of the grafts with loose soil.

In grafting by this method on a large scale several men can work
in combination to advantage, rather than for one man to do everything.
It is of advantage, for instance, for the man who does the actual graft-
ing to do nothing else but this, since otherwise he must be continually
getting up and down, going ahead and back, and losing much time.
The better arrangement is for one man to hoe the dirt away from the
trees before they are cut off, hoe it back again after grafting is com-
pleted, and perhaps help in some other way if this does not keep him
busy. One man can cut off the seedlings and also do the tying and
waxing, first working on ahead of the grafters until he has cut off
enough trees to keep them busy for some little time, then coming back
and attending to the grafts which they have put in. He should not get

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

223

too far behind in the latter operation, avoiding any danger of the grafts
drying out before they are tied, waxed and covered.

Many other methods of nursery grafting are in vogue, but as we have
said, the one described is as good as any for the beginner, and in our
opinion no other method is superior to it. This style of grafting has
been developed and very successfully practiced for several years by
Mr. George Weinshank, of Whittier, to whom credit should be given in
this connection.

FIG. 32. — Grafted trees in nursery, five months after grafting.

After grafting the scions which have taken will soon begin to develop
and along with them numerous sprouts from the seedling rootstock.
The latter must be continually and very carefully removed before they
choke out the growth of the scion or become so large as to leave unde-
sirable scars when they are finally removed. Growth from the scion
should be well started, however, before any suckering is done. Sucker-
ing is an important operation, since if done carelessly the graft is likely
to become displaced even after it has made considerable growth. If

224 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

more than one bud on the scion sends up a shoot all but the strongest
one should be removed as soon as its growth is assured. The successful
grafts will send up shoots very rapidly, and soon these must be tied up
to stakes in order to prevent their falling over and becoming crooked or
pulling out the scion. If a scion sends up more than one sprout only
the best one should be allowed to grow. For tying up stakes at least six
feet in length should be used, employing either ordinary lath of this
length or 1 by 1 strips, which are very satisfactory. The stakes should
be driven in a perfectly upright position as close to the sprout as pos-
sible and the latter should then be tied to the stake at least two points
in its length with large soft twine or small rope. This tying should be
done carefully and not too tightly, as the young sprouts are very tender
and increase rapidly in diameter.

Meantime, proper care should be given to the soil by means of the
necessary cultivation, hoeing^ and irrigation if the latter is practiced.
Here, again, there is a common impression that trees grown without irri-
gation are hardier and more desirable for planting than those to which
water is applied during their growth. It is true that a non-irrigated
tree becomes dormant earlier in the season and hardens up its terminal
growth possibly more completely than does a tree which is kept growing
by irrigation as late in the fall as possible. Even though this is true,
the fact still remains that the largest trees are everywhere considered
most desirable for planting, and the price received by the nurserymen
varies in direct proportion to the size of the trees. A tree ten feet high
sells commonly for nearly twice as much as one four feet high, and is at
the same time more in demand. If properly treated in planting, the
larger tree is cut back in any event to perfectly sound, well formed
wood, and we know therefore of no disadvantage, either theoretically or
in actual experience, in the planting of larger trees which result from
irrigation as compared to that of small trees grown without water. In
fact, many trees grown where no irrigation is possible have their roots
injured, their growth stunted and their trunks sunburned on account of
drouth.

If grown with plenty of moisture and on good soil, the majority of
the trees should make sufficient growth the first year to bring them
up to proper size for selling and planting in orchard form. In the
southern part of the State, where the season is long, there is as much
trouble from the trees becoming too large as in their being too small at
the end of the first season's growth. Trees of ten to twelve feet in
height are very common, while the largest specimens run up to fifteen or
even eighteen feet during the first season from the graft. There is
always a considerable variation in the trees, however, and nurserymen
commonly sell walnut trees on the basis of height, making the following
grades : 4 to 6 feet, 6 to 8 feet, 8 to 10 feet, and 10 feet and up. A

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 225

grafted tree of less than four feet in height at the end of the first season,
when grown among trees some of which go up to ten, twelve and more
feet, is of doubtful value, as it should presumably have made a better
growth if on a good root and with a good union.

From the seedlings where the grafts did not take, numerous suckers
usually spring up and it is customary to take off all but one of these,
letting the latter grow up into a new seedling top. This will soon grow
over the scar where the original top was cut off and may be grafted
again the next year if this seems desirable. It is not, however, to be
recommended that such trees be grafted again and again the third and
even the fourth year, as practiced by some nurserymen in case the grafts
do not take. In such cases the root becomes extremely large, and with
each year's cutting off of the top the scar at the base becomes greater.
It is better to discontinue grafting after the second year and destroy
all the remaining seedlings on which the graft has not taken. By far
the most desirable grafted tree consists of a two-year-old root and one-
year-old top, as described above. Thus the top and root are of nearly
uniform size, and, if a good union is formed, complete healing at the
point of grafting takes place the first season.

BUDDING.

The operation of budding the walnut is by no means as uniformly
successful as in the case of ordinary fruit trees, yet some have per-
formed it with considerable success. Even at best, results in this
respect have been somewhat uncertain. Many different methods have
been practiced, but these we will not go into in detail, as they are largely
a matter of personal skill and there is no reason for supposing one
method to be better than the others under all conditions. In general,
we may say that most of the walnut budding in this State has been done
in the fall, usually in September^ the buds remaining dormant over
winter and starting into growth the following spring. In some of our
own experience, however, we have had good results with spring budding,
putting in the buds during May, June and early July and growing from
them trees up to as much as ten feet in height during the same season.
Spring buds of ' this height are exceptional, but we have found no diffi-
culty in getting a large percentage of them up to from four to six feet
during the same summer when they were budded. Such budding was
done mostly on new sprouts coming from one-year-old seedlings upon
which grafts had failed, or seedlings which had been too small to graft
during the previous winter. For such work the best buds are those
upon dormant wood cut during the previous winter at the same time of
cutting scions for grafting. Such wood may be easily kept over with
the buds dormant until June if properly stored in a cool place with
neither too much nor too little moisture. The buds on this grafting
8—231

226

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

wood do not come off readily when the scions are first cut, but when
budding time arrives in the spring the scions, if well kept, will begin to
callous at the ends, and the buds will then slip off readily. Wood which
is too large, and also that which is too soft and pithy for scions, can be
used for buds, and thus it is possible to make considerable more use of a
given amount of grafting wood. Buds of the current season may also
be used, and for fall work it is necessary to use such buds. We have
found that these can be handled most readily, by selecting the best

FIG. 33. — Top-budding; 1, bud completely healed and starting to grow; 2, showing
the shoot developed from the bud and tied up to the stub of the limb. The latter
is soon cut off just above the bud. The ring of bark attached to the bud would
be better if it reached less completely around the limb. Note the constriction at
the bud and swelling above it.

developed buds at the base of leaves on the oldest wood of the present
season's growth, and cutting off the leaf stalks just beyond the buds
about two weeks previous to the desired time of budding. If this be
done the leaf stalks drop off cleanly in a few days, leaving the buds
ready for use. If the leaves are cut too soon the buds sometimes start
into growth while still on the parent shoot. Good buds may sometimes
be obtained during the summer and fall on the last wood of the previous
year's growth.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 227

The most successful form of bud with us has been a partial ring or
flute bud extending only part way round the stem. We have had the
best success with buds having a portion of bark attached about one half
to three quarters of an inch wide and three quarters of an inch long.
The former dimension is that measured around the stem and the latter
the vertical distance. For cutting and placing such buds a double-
bladed knife is most suitable for which we have found a home-made
contrivance entirely satisfactory. Two blades are fixed upon a handle in
such a manner that they are about three quarters of an inch apart.
With this cuts are made on either side of the bud on the bud stick, after
which similar cuts are made in the bark of the stock about six inches
above ground if the seedling is large enough. These cuts should not
extend more than halfway round the tree, leaving the bark intact for
halfway round on the other side. Referring to the sentence above, where
we state the proper size of the piece of bark attached to the bud, it will
be seen that the buds should be put on at a place where one half the cir-
cumference of the stock amounts to at least one half to three fourths of
an inch. Perpendicular cuts are then made with one of the knife blades
at either end of the ring of bark on the stock and this is removed. The
bud, previously cut, is then removed, cut off if necessary to the proper
horizontal width, so that it will just fit the opening in the bark of the
stock. In stripping off the bud the core of wood inside the bud itself
usually remains in place without difficulty if the bud is mature enough
to be worth using. Usually buds in which the heart wood pulls out are
so immature that they would not take in any event. With good buds it
is simply necessary to strip off the bark without attempting to include
any of the wood. The operator uses his judgment in selecting the seed-
lings of such a size that the strip of bark bearing the bud, with its one
half to three quarters of an inch horizontal width, will be of the right
size to extend not more than halfway round the stock. Where the bud
reaches nearly or quite around the stock, forming a more or less complete
ring bud, a bad constriction and swelling is often produced at this point,
making an undesirable sort of tree. The bud may be put in just above
ground, or at any other point where the stock has the proper size, as
well as at six inches from the ground, as above stated. The object of
the latter is to leave space for further attempts below the first bud in
case it does not take. The bud is slipped into place and tied either with
waxed cloth, such as is used in budding citrus seedlings, or with soft
cotton budding twine. We have had the most uniform success with
waxed cloth. The tying should be done very carefully, bringing the
inner surface of the bud bark into smooth, close contact with the exposed
wood of the stock, especially close about the bud itself. After securing
the buds in place they should be watched carefully and if successful
they will remain green and soon unite with the stock. Spring buds may

228 UNIVERSITY OP CALIFORNIA— EXPERIMENT STATION.

usually be unwrapped within from one to two weeks, the latter period
being usually about right early in the season. In later budding the
wrapping must stay on longer, usually at least three weeks in July,
while with fall buds which are to remain dormant over winter six or
seven weeks will do no harm. With spring or summer buds which are
to be forced into growth the same season about one third to one half of
the seedling top should be cut off after the buds are unwrapped. After
the bud has started into growth and its further development is assured,
the stock should be still further cut back as closely as possible to the bud
without injuring it and the end waxed over. In the case of fall buds
which are to remain dormant over winter the seedling top should not be
cut off at all until spring, when it may be cut off entirely at one time if
the growth of the bud commences vigorously early in the season, or if the
bud does not start promptly it may be safer to cut off only one half of
the top and the remainder after the bud commences to grow.

This form of bud is shown on a top-worked tree in Fig. 33. The buds
in the figure, however, extend further around the stem than we now
think desirable. A bud which does not reach more than halfway round
does not produce the swelling and constriction of the stock seen in these
pictures.

Other methods than the above have been tried for budding walnuts
and some have given more or less success both with us and others. The
ordinary shield bud has been entirely unsuccessful in our experience,
and it seems to a certain extent that the larger the portion of bark taken
off with the bud the better are its chances to stick. Some who have used
an inverted shield or T bud, pushing the bud up rather than down and
slipping it under the bark, have had better success than by the ordinary
method of making this bud. Complete ring or annular buds take as
readily as the flute bud described above, but there is objection to this
form on account of the constriction produced in the stock at the point
of budding. Where a strip of bark is left on the back side of the stock,
as in the flute bud which we have described, this objection is obviated.

E. J. Kraus, in Circular Bulletin No. 16 of the Oregon Agricultural
Experiment Station, recommends what he calls a hinge bud, which is
a large, rectangular patch bud inserted under the bark of the stock.
In this form of budding two transverse cuts are made in the bark, one
above the other, about half an inch long and three quarters of an inch
apart. The two are connected in the center with a longitudinal inci-
sion and the bud, after being cut with a portion of attached bark of
the proper size and shape, is slipped down under the bark of the stock
in the same way as in the ordinary shield or T bud.

The uncertain results which almost always accompany walnut bud-
ding, even at the best, appear to come about largely on account of the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 229

tendency of the freshly exposed tissue of the walnut to oxidize and
turn black. After this has once happened the tissue is sure to die and
no union takes place. A further uncertainty is connected with the
growth of the bud even after it has apparently formed a perfect union.
Quite frequently a good union seems to have taken place, the bark of
the bud remaining fresh and green, but after this the bud dies and
therefore no sprout is able to develop. In all walnut budding partic-
ular skill and dexterity is necessary in order that the fresh surfaces or
cambium of the bud and stock may be exposed as little as possible to
the air during the operation. The operator must work rapidly and at
the same time carefully, making a close fit in each case, tying each bud
so that the inner surface of the bark will come into close contact all
over the exposed surface of the cut in the stock, arid getting the buds
cut and into place just as quickly as possible without unnecessary expo-
sure to the air. The buds should not be taken off until the last possi-
ble moment so that only one bud can be cut at a time. In working with
a single-bladed knife, it is usually necessary to cut the bud first and
then lay it on the stock in order to make the cut on the latter of the
same size. By using a double-bladed knife this becomes unnecessary,
and the bark can be removed from the stock before the bud is entirely
removed. In case of any little delay after cutting the bud it is a good
idea for the operator to put the bud in his mouth until he is ready to
place it upon the stock, rather than to keep it exposed to the air. In
nursery budding on a large scale it may be found economical for the
men to work in pairs rather than for each man to do all the work. One
man, for instance, may make the cut on the stock, cut and place the
bud, while the other ties, waxes or otherwise assists to the best advan-
tage. There should not be the slightest delay, however, at any stage
of the operation.

As a general proposition, there are but few advantages in nursery
budding over grafting for one who is particularly skilful in the latter
operation. Grafting can be done more rapidly, and is certain to pro-
duce good-sized trees the same year if they are well cared for. Bud-
ding, however, may be valuable at times, especially if practiced in con-
junction with grafting. In the case of propagating varieties where
grafting wood is scarce, the available supply goes considefably further
in budding than in grafting, since only one bud is used for each tree
and buds can be taken from sol't, pithy wood, or large wood which
would not make a scion. Another useful feature of budding is that it
may be practiced in spring and early summer upon trees which were
too small for grafting, or upon the sprouts coming from trees on which
grafts did not take. It also extends for several weeks the rather lim-
ited season during which grafting may be done. Another advantage

230 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

of budding lies in the fact that very little suckering has to be done,
such as is necessary after grafting, and this is a valuable consideration.
Again, the budded tree, having the union well above ground, is not
as liable to decay or heal poorly at this point as is the graft. Both
operations may often be practiced to advantage by the nurseryman,
grafting in February and March all the stocks which are large enough,
budding in April and May those which were too small for grafting, and
in June and in early July the sprouts which have come up from the
unsuccessfully grafted trees. By budding several inches from the
ground those seedlings which do not take can be budded again a little
lower down, and thus by diligent and continuous work it is not impos-
sible to obtain a nearly perfect stand of salable trees during the first
year. Fall budding upon stocks in their second year of growth pro-
duces very large trees the following year, and so is of some advantage.
With very thrifty seedlings it is possible to do a good deal of budding
during the late summer and fall of the same year in which the nuts
were planted, and this again may sometimes be of advantage in obtain-
ing a long season during which the stock may be worked. Inquiry is
sometimes made as to the possibility of producing salable trees in one
year by sprouting nuts early, forcing their growth in the nursery so
that they may be budded in June or early July of the same year, and
then pushing the sprout along to make a tree that same season. While
this is possible with peach and other fruit trees, it is not likely that
it can be accomplished with walnuts to any extent or that the green,
immature buds thus produced would have any ultimate advantage in
orchard planting. The future care of buds is the same as that of grafts
and need not be particularly described.

METHODS OF TOP-WORKING.

In working over good-sized walnut trees, either in the case of black
walnuts planted in orchard form, black walnuts standing along road-
sides, in dooryards, or any other place where it is desired to work them
over into English walnuts, or in the case of English walnuts which the
owner wishes to change over into other varieties, somewhat different
methods are usually employed than those used in nursery work.

Top-Grafting. — In regard to the time of grafting, choice and care of
the scions, making of grafting wax, and other operations common to
both processes, the same general rules apply. Trees to be worked over
may be cut off either in the main stem from two to five feet above
ground, if this is at least 3 to 4 inches in diameter, or the limbs may
be cut off and grafted either just above the main forks of the tree or
further out, according to the size of the limbs and the amount of graft-
ing wood available. It is not usually advisable to cut off extremely

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

231

large limbs, exposing a large surface of wood to decay and also making
the growth of the scions somewhat less certain than if they are inserted
in smaller limbs. Usually cuts of 3 or 4 inches in diameter are the
most desirable size, although larger and also smaller cuts can be grafted
with more or less success. In grafting over orchard-planted black wal-
nut trees it is not usually advisable to graft them before they have a
diameter of at least 3 inches at the point of grafting, and 4 inches is

FIG. 34. — Views of four different sides of scion for top-grafting by side cleft method.

even better. If the trees are grafted while quite small, the tops are
likely to greatly outgrow the trunk and form a topheavy, undesirable
form of tree. In working over trees in the top less time and fewer
scions are required if the limbs are cut well back toward the main forks,
making fewer stubs to work upon, than if the limbs are cut off further
out where the branches are more numerous. In the latter case, how-
ever, the chances of success are somewhat better than when the work

232

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

is done on very large stubs. Usually cuts of less than 2 or more than
4 inches diameter are undesirable.

A method used in some cases is that of cutting off the tops quite

FIG. 35. — Top-grafting. Bottom — Making the cleft. Top — Scions inserted and waxed.

severely one year and then allowing the stubs to sprout, which they
usually do very vigorously, and grafting on the best of these young
sprouts the following year. In following this method some have cut

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 233

off trees a foot or more in diameter directly through the main trunk
and then worked the following year on the sprouts coming from this.
Such a method is of doubtful expediency on account of the great
liability to decay of so large a cut surface.

The time chosen for cutting off the top or limbs for top-grafting is
usually that when the grafting is done, namely, just before the trees
commence to send out new growth in the spring. One of the most im-
portant considerations in this respect is that of the bleeding of the
trees when cut off, which sometimes takes place quite profusely. No
general statement can be made as to the time or conditions under which
such bleeding takes place, or does not take place, since its occurrence
is quite irregular. In some soils, especially light sandy ones, and in
some seasons it seems almost impossible to find a time when the trees
can be cut off without bleeding. We have seen practiced a method of
cutting off the tops and branches early in the winter, in December for
instance, when there is practically no danger of bleeding, and then at
the time of grafting making a fresh cut just back into normally green
tissue. In this way some who have had trouble with bleeding have
thought that much benefit was obtained. Another method consists in
cutting off the tops just before grafting and then, if bleeding takes
place, boring several half-inch holes in the butt of the tree near the
ground in order to allow the surplus sap to escape at that point. Usually
the tops may be cut off at the proper time for grafting without any
serious trouble from bleeding except now and then in certain individual
trees, or sometimes in certain individual orchards on an especially warm
soil. The cuts should be made carefully in order not to split and tear
down the stubs. The best method consists in first making a cut on the
under side in the case of a horizontal limb, or cutting partially through
on one side in the case of a tree cut off in the trunk, then cutting com-
pletely through on the other side an inch or two above the first cut.
After taking off the limb or top a fresh cut is made clear across, just
below the first cuts, in sound wood.

The question sometimes arises, especially in working over good-sized
or large trees, whether to cut off all the limbs at one time or to work
over only part of the top the first year, leaving part of the original
branches over until the second or even later years, thus extending the
grafting over two^ or more years. Most experience has been against
the latter method and in favor of cutting off and grafting the whole
top at one time, even with the largest trees. Ordinarily, if part of the
original top is left, very little growth results from the scions, the whole
vigor of the tree seeming to go into the remaining portion of the original
top. We have heard the plan proposed of grafting the north side of
the tree fiist, then the east, south and west in successive years, this
idea being based on the well-established observation that grafting is

234

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

decidedly more successful on the north than on the south side of the
tree. We do not know that this method has been tried sufficiently to
enable final judgment to be passed upon it, but certainly with trees of

FIG. 36. — Top-grafting; scion inserted.

not extremely large size and especially in grafting over orchard-planted
black walnut trees, it is more practical to cut off the whole top, either
in the trunk or main forks, and graft it all at once.

The method used in top-grafting is usually the ordinary cleft graft

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 235

or a modification of the same. Some operators simply split the stock
through the middle, insert the wedge in the cleft, trim the split edges
of the bark and cambium smoothly with a sharp knife, cut the scion
to a smooth bevel on either side, and insert the same carefully, taking
special pains to make a good fit and bring the cambium layers of the
stock and scions into intimate contact. After removing the wedge some
grafters fill the cavity across the heart of the stub with paper or some
other material before waxing. Another, and in our opinion somewhat
better method of cleft-grafting, especially on stubs more than two
inches in diameter, is that shown in Fig. 35. This differs from the
ordinary method in that instead of making one cleft across the middle
of the stub two or more are made at uniform distances apart out
near the edge, splitting off slabs about one half an inch in thickness.
A special tool is useful both for this or for ordinary cleft-grafting, as
shown in Fig. 35. In making the splits the splitting wedge is held
in a horizontal position over the place where the cleft is desired and
driven in to a depth of about one half inch. It is then tilted up in a
slanting position and driven down to a depth of one and a half to two
inches, first at one end of the cut and then at the other. The limb in
Fig. 35 was 3J inches in diameter. In this two clefts were made,
each J inch thick by 2J inches long and 2 inches deep. The rough
edges of the bark were smoothed with a sharp knife and the cleft held
open with the terminal portion of the tool, as shown in Fig. 36. The
proper scion for such grafting is shown in Fig. 34. This is prepared
by beveling off one end into a wedge shape, cutting entirely through
the pith on one side, and then down to the pith on the other. The back
side of the wedge, that which is placed toward the outside of the tree,
is made wider than the side which goes toward the interior of the tree.
There should be two buds on each scion, one near each end as shown
in the illustration. Two scions are carefully fitted into each cleft,
taking great pains to make a good fit and bring the cambium portions
of stock and scion into intimate contact. If the bark splits irregularly
it should be smoothed with a sharp knife. In all cleft grafting it is
well to slant the point of the scion a little toward the center of the
stock so that the upper end of the scion points out a little in order to
be certain that the cambium may cross at least at one point. In
grafting limbs up to 4 inches in diameter two clefts or four scions
are commonly put in by this method. In larger limbs more clefts and
scions may be used. It is desirable to put in as many scions as possible
without at the same time splitting off slabs of too little thickness, since
the more scions that grow the quicker will the cut surface heal over.
It is much better to get several scions started, even though it be neces-
sary to cut off all but one the following year rather than having only

236

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

one scion from the first with a large surface exposed to decay. After
inserting the scions and removing the wedge the scions may be tied in
with soft budding twine, wrapped several times around the whole stub,

FIG. 37. — Large, top-grafted tree. J. B. Neff's orchard.

but this is not ordinarily very necessary. Only in cases where the
work is being done with extreme care is tying often resorted to.

One of the most important operations of the whole process is that of

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 237

waxing. Grafting wax should be prepared as described on page 221, and
every part of the exposed surface should be very carefully painted over
with a solid coating of wax. Great pains should be taken to see that
no spots are left, however small, either on the cut end of the limb or the
clefts containing" the scions, which are not completely covered with wax.
If any opening is left through which the air may penetrate, drying and
oxidizing the fresh surfaces of the scion or stock, the grafts will almost

FIG. 38.— Top-grafting; scions starting into growth.

certainly perish. Much care should be taken while waxing not to knock
out or disturb the scions in the least. One waxing is not sufficient, but
after a few days the grafts should be gone over again, closing carefully
any places found to be unwaxed. A little later, when the grafts begin
to grow and swell more or less, it will be found that the wax is very
likely to split or peel off and so they should be watched very carefully
until thoroughly united and kept liberally covered with wax. The pro-

238 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

portion of resin and beeswax contained in the material may require
variation after the first waxing. Too much beeswax makes a soft wax
which melts easily in the sun, running away from its proper position,
while if too much resin is used the resulting wax is stiff and brittle and
readily cracks. Beeswax is much more expensive than resin, and it is
therefore desirable for economy's sake to limit its use.

It is the practice of some grafters to enclose each stub, after grafting,
with a large paper sack, hood or cuff, in order to protect the tender
young sprouts from sun, wind or frost. As the sprouts elongate the
paper is pulled open at the top to let them through. If the scions are
tied in with string this must be cut as soon as they are well started in
order that it may not cut into the growing scion.

Top-grafting at best is not always successful, even with the most
experienced operators. Much depends on the condition of the tree at
the time of grafting in regard to the activity of the sap, and this cannot
be foretold or controlled in many instances. At the same time a skillful
operator, especially if he has a sufficient choice of grafting wood, can
in most cases top-graft the walnut with fairly uniform results. Even
after successful grafting has been done, the young sprouts coming from
the scions are extremely susceptible to injury from frost and also from
hot winds, and failure somtimes results from these sources.

These scions which establish a successful union soon commence to
grow after grafting, sending out sprouts from one or both buds which
grow very rapidly, having at first a very tender, delicate nature. At
the same time, the tree itself sends out numerous suckers which must
be suppressed to a large extent in order to give the grafts every oppor-
tunity for development. Considerable judgment must be exercised in
regard to removing the suckers, especially in cases where some or all of
the grafts do not grow. If the grafting is entirely unsuccessful, some
of the suckers must be allowed to develop in order to permit the tree to
carry on its normal functions. If the grafts grow on some of the limbs
but not on all, it may be well to leave a few suckers on the limbs where
the grafts did not take. Again, it may sometimes be better to leave at
least one sucker on a large limb on which only one graft is growing.
The main object should be to give the scions every opportunity for de-
velopment without allowing suckers to choke them out, while at the same
time not depriving the tree too much of an opportunity to produce
foliage. After grafting, the trunk and branches of the trees should be
painted over with a thick, heavy whitewash as a protection against
sunburn. Those stubs in which the grafts do not grow should be kept
as carefully waxed as those where successful grafting occurs, inasmuch
as the wood is extremely susceptible to decay and must be protected
against the same as much as possible.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

239

During the first season it is usually well to allow all the grafts which
grow to remain, even though they are too numerous for the ultimate
tree, as such growth causes a more rapid healing-over of the cut-off
stub and this is very desirable. As soon as the sprouts begin to grow
from the scions preparations must be made to support them in some
way or they will become topheavy, twisted and broken out by the wind.
The most convenient method of doing this consists in nailing six-foot
lath directly to the stubs into which the scions were put, and tying the

FIG. 39. — Top-grafting; growth well started and tied up to lath.

sprouts loosely and firmly to these laths. In the case of orchard-planted
black walnuts which are grafted directly in the trunk, it is usually neces-
sary to employ a large, tall stake set in the ground, especially during
the second year, as the tops on such trees become extremely large and
top-heavy. This is one of the objections to this method, as it is sometimes
almost impossible to keep the tops up in shape during their early years.
At the end of the first season's growth top-grafted trees should be
gone over, the laths removed if they seem no longer necessary, the extra

240

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

shoots cut out where they are too numerous, the stubs cut off and
waxed over very thoroughly where they have died back, and all sprouts
from the tree itself either cut off or grafted again if the latter seems
necessary. During this second grafting it is usually better to work the

FIG. 40. — Top-grafting ; showing growth during the first season.

sprouts rather than the old stubs if the former are available. They
may sometimes be budded to advantage. Sometimes when no good
sprouts have developed it is necessary to cut the old stubs off again
further back and graft into them.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

241

FIG. 41. — Top-grafting; new top produced on a seedling English walnut tree in one

season.

9—231

242

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Top-Working by Budding. — Trees may sometimes be top-worked to
advantage by budding rather than grafting, working on smooth-barked
limbs not much over one inch in diameter or on suckers coming from
large limbs cut off the previous year. The methods already described
as to cutting the tops, treatment of the stubs and methods of budding

Fig. 42. — Top-grafting; two years' growth on orchard-planted
black walnut. Dr. W. W. Fitzgerald.

will apply. Fig. 33 shows the partial ring bud after forming a union
and the same with considerable growth developed, the bud-sprout being
tied up to the partially cut off limb. The ring of bark on these buds
extends a little further around the limb than is desirable.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

243

FIG. 43. — Top-grafting; large black walnut tree top-worked,
gess, Superintendent Vrooman ranch.

Mr. J. F. Bur-

244 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 245

DIGGING.

For removing walnut trees from the nursery no better method has
been devised than simply digging out each tree individually by hand
with long-handled shovels. Plowing the dirt away is of very little
assistance and puts the ground into bad shape for walking and standing
upon during digging, especially in muddy weather. Usually the best
that can be done, especially with good sized trees, is to simply dig out
each tree entirely by hand. In doing this opinions differ as to the
amount of the taproot which should be preserved, and often the desires
of the purchaser must be followed to some extent in this matter, whether
or not they agree with the ideas of the nurseryman. One of the most
popular fallacies is that concerning the taproot of the walnut tree,
many people holding strongly to the view that the root must be kept
intact, even to a length of three or four feet, in order to insure proper
growth of the tree after planting in the orchard. This idea has been
abundantly disproven, and the fact is well established that a root not
more than eighteen or twenty inches in length, if well branched, and
especially if the top is properly cut back, usually makes a better tree
than one much longer. Walnut taproots are very large in diameter in
proportion to the size of the top and are composed of very soft, spongy
bark and wood. This tissue, if conditions are not such as to start the
root into growth promptly, is very susceptible to decay, and a long, un-
branched taproot is muclj more likely to remain in the ground without
sending out new growth until it begins to decay than a shorter, well
branched root. Fig. 45 represents the most desirable types of walnut
roots, 2 being of a more branching type than 1. Roots like these send
out new growth quickly and are in all respects the most desirable form.
In digging, therefore, care should be exercised not to cut off or bruise
the lateral roots within about a foot of the main stalk and the taproot
may then be cut off at a depth no greater at most than two feet. Even
this is more than is necessary if the root is well branched. Some roots
will be found which do not have any taproot even of this length, and in
such cases the main laterals should be preserved in good condition. It is
well to dig the trees as early as possible in the winter in order to have
them ready for sale to the first customers and to avoid the danger of
being caught by long-continued rainy weather during which the trees
can not be dug. Digging may commence as soon as the leaves have
fallen, although unless fairly heavy rains have fallen it may be found
necessary to irrigate the ground in order to facilitate the work. After
the trees are dug, if they are not wanted for immediate delivery they
may be heeled in at some convenient place by digging a trench in which
the roots are placed and thoroughly covered with earth. It is sometimes
convenient to put each tree back in the same hole from which it was dug,

246

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

covering the root again with loose earth, when it can easily be pulled
out by hand when wanted. Before delivery or planting the trees should
be carefully gone over with shears and pruning saw, cutting off all
broken roots and ragged ends back to good tissue, trimming off all

7

FIG. 45. — 1, a good graft union and root; 2, a good graft union and ideal branching
root. A, original seedling nut ; B, graft union ; C, upper end of original scion.

remains of sprouts or stubs of any sort and cleaning them up into a good
sound root and a clean stem. All cuts on the crown or stem should be
covered with grafting wax. Fig. 46 — 1 shows a grafted tree which has
made a very poor union, leaving a large, dead, decaying stub where the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 247

original seedling top was cut off. It is not necessary that every tree
should have this stub completely grown over in the nursery in order to

Fig. 46. — 1, a poor graft union; 2, a good graft union on a root which has been
grafted unsuccessfully once or twice before.

make it worthy of planting, but those with very poor union such as this
are of doubtful value and should be discarded if first-class trees are

248 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

desired. Fig. 46 — 2 shows a one-year-old graft on a root which was two
years old at the time of grafting, a graft having failed the previous year.
In this case the crown of the root is still sound, showing scars of suckers
which have completely healed over except when recently cut. This tree
is unobjectionable, but such are sometimes seen with very large, old
clumsy roots with a poorly healed union and scars at the crown. These
are not to be desired. Fig. 45 shows perfect trees, although the rough
ends where the roots were cut off have not yet been trimmed. In
Fig. 45 — 2 the original nut from which the seedling grew may be seen
at A, the point of grafting at B and the upper end of the scion at C.

After cleaning up the roots and lower part of the stem the next ques-
tion is that as to cutting back the top. Here, again, radical differences
of opinion exist, some growers holding a strong preference for plant-
ing the largest sized trees without cutting back the top at all, some
preferring a small tree likewise without cutting, while others would
cut the top back at various heights. Assuming that the root and top
are of the same proportionate size, the same rules as to cutting back
must apply either with large or small trees. There is considerable
unanimity on one point, namely, that the walnut tree in orchard form
should be headed considerably high, at a point about five or six feet
from the ground. It is, therefore, possible to obtain this with trees of
about this height when planted by not cutting them at all, with trees
of greater height than this by cutting them back to such a height, or
with smaller trees by planting them either as they are or after cutting
back and allowing one shoot to grow up into a trunk, heading this at
the desired height. Even when very tall trees are planted without cut-
ting they usually branch naturally at somewhere about this height, and
if the tops do not die back the ultimate form of the tree is very much
the same with a tall tree whether it is cut or not. The chief objection
to planting out trees with uncut tops is that the roots have necessarily
been cut off more or less and are, therefore, not able to send up as much
moisture to the top as is required. Such being the case, there is dan-
ger of the top dying back before a proper connection with the soil is
reestablished by the root, or if it does not die back it may remain nearly
dormant for some time, making very little growth and becoming very
liable to sunburn. In such cases the tree may stand for one or several
years before starting vigorous growth in the top and during this time
the trunk may become so badly sunburned that it is seriously crippled
for life. The liability of such an occurrence depends largely upon the
size of the root, amount of moisture in the soil and the degree to which
the root dried out during the time after it was dug from the nursery
and before it was planted in the orchard. Trees which are moved only
a short distance, especially if the root is dug with extra care, may start

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

FIG. 47. — A tree planted when about four feet high without cutting back. The space
between the hands indicates the following year's growth of the leader, and that
above the left-hand the growth of the second year.

250

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

into good growth the first season and flourish satisfactorily even with-
out any cutting back of the top. More often, however, the root becomes
more or less dried in handling and shipping, the ground in the orchard

FIG. 48. — Three-year-old tree, which was cut back to five and one half feet before

planting.

may lack moisture to some extent during the first season and altogether
the chances are strong that the tree planted without cutting back will
not get a very good start the first year and may receive a serious

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 251

setback. In planting an orchard to be grown without irrigation the
chances of this are very much greater and the objections to planting
without cutting back are increased many fold. If the tops are to be
cut at all, one thing is clear ; namely, that they should either be cut at
the point where the head is to be established; namely, at a height of
five or six feet, or if cut lower one sprout must be brought up and
formed into a new trunk. Trees cut off five or six feet from the ground
are more likely to start well than those not cut at all, but even at this
height a long stretch of the old wood remains, which under slightly
unfavorable conditions may become sunburned, dried out, or semi-dor-
mant. After this has once happened during the time while the root is
establishing a new connection with the soil, the flow of the sap becomes
sluggish and impeded and the tree cannot develop with full vigor until
new wood is formed.

Observation and experience have led us strongly to the belief that
in the long run and in the majority of instances better and more vigor-
ous trees will be obtained by cutting back the top fairly close to the
ground and bringing up one strong, new shoot to form a new trunk and
top of the tree, rather than by attempting to preserve any considerable
portion of the original stem. If such cutting is to be done there is no
apparent advantage in leaving more than two feet of the original trunk
at the most, since the whole idea is based on the belief that it is better
to grow a new trunk than to keep the old one. If such is the object
desired, there is manifestly no advantage in cutting off at four or three
feet, since in such a case we still have remaining a considerable length
of wood subject to the objections mentioned, and at the same time a
length which would be attained within a few days by a vigorous new
shoot. It is, therefore, our belief that the best results will be obtained
by cutting the tops back so that there remain simply enough buds to
insure one good sprout to form a new stem. This can be obtained by
leaving not over eighteen inches or even twelve inches in most cases.
It will sound to many extremely radical and unnecessary with nursery
trees, some of which may be twelve or fifteen feet in height and two
inches in diameter at the base, to cut off these fine tops ruthlessly to
a length of only twelve or eighteen inches. Yet, such a tree with a
twelve-inch top and a strong, well-branched eighteen- to twenty-four-
inch root will send up a shoot which in almost every instance will pro-
duce a top superior to that of trees which were left uncut or cut back
to a height, say, of five or six feet. Furthermore, the new trunk will
be composed of absolutely fresh, vigorous tissue, highly resistant to
sunburn, free from die-back, and of the most desirable type in every
way. It is, therefore, our well-considered recommendation that in pre-
paring walnut trees for planting the tops should be cut off to a length

252 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 49. — Tree cut back to two feet before planting. The whole top above the finger
is composed of new growth.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 253

of not over eighteen inches, after which the cut ends should be carefully
sealed over with grafting wax. We would do this with trees of all
sizes, and would insist particularly upon such a practice with trees
going into non-irrigated orchards. After trimming, cutting and wax-
ing, the roots should still be kept moist, either by heeling them in,
planting at once in the orchard or proper packing, if they are to be
shipped.

PLANTING.

In planting the walnut orchard the ground should be thoroughly pre-
pared as for other fruit trees and staked off for the trees at the desired
distance apart, which subject we have discussed elsewhere. A large
hole should be dug for each tree, considerably larger than the root, and
with the heavy subsoil best suited to the walnut it is extremely advisable
that a stick of dynamite be discharged at a still greater depth below the
hole. This should then be filled in with top soil, up to proper depth
for the tree. The tree is then put in place, planting it fully as deep or
a little deeper than it stood in the nursery and the soil should be thor-
oughly tramped and settled about the roots. If not well planted, a thick
soft root like that of the walnut is liable to decay, and special pains
should therefore be taken to settle the soil firmly about the roots so that
they will immediately begin to absorb moisture and commence new
growth. Planting may be done at any time after the trees are ready,
usually the earlier in the winter the better, in order to take advantage of
the settling and moistening of the ground by the winter rains. After
planting, the trees should be carefully watched to see that they are all
doing as well as possible and not suffering in any avoidable way. If a
considerable portion of the top has been left without cutting back, this
should be protected from sunburn by tying about it a rather loose wrap-
ping of cornstalks, tules, or special protectors made for this purpose.
It is not well to wrap the trunks tightly in paper or cloth, as this makes
the bark more tender after the wrapping is removed. If the tops have
been cut black close to the ground one good sprout should be selected to
form the new stem, and as soon as the growth of this is assured all the
others which start should be cut off. Usually the most vigorous sprout
should be chosen, but, other things being approximately equal, it is
better to take the one closest to the ground and one on the windward
side of the trunk. A good sized, at least a 2 by 2 stake should be set in
the ground close to the tree, to which the shoot may be tied up. The
shoot should then be tied once or twice to this stake in a similar manner
as is done in the nursery until it reaches a height of about six feet, when
it should be topped and caused to branch. After this shoot is well estab-
lished the remaining stub of the old stem should be cut off closely above
it and the scar waxed over.

254 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

VARIETIES OF THE ENGLISH WALNUT.

The fact has been frequently alluded to in this bulletin that great
variation exists in various individual seedling trees of the English
walnut, and that as a result of such variation a fairly large number of
distinct varieties has been established, each of these having originated
from a particular tree which was selected by some one as being particu-
larly desirable on account of certain qualities. Some of these varieties,
notably certain French varieties close to two hundred years old, have
been kept pure since the original tree was first selected, by budding or
grafting. Others, especially the majority of the varieties now most com-
mon in California, are of comparatively recent origin and represent the
grafted or budded offspring of certain seedling trees in the State which
have seemed especially desirable and have therefore been propagated
from and in some cases widely advertised and sold on quite an extensive
scale. The variations which occur in seedling walnuts consist in a
marked difference in the vigor and size of the tree, its rapidity of
growth, its general form or aspect, and that of its foliage, the color and
texture of the bark, the time of budding out in the spring, the amount of
catkins and pollen produced, its productiveness, season of maturity of
the crop, and the size, form, color, flavor, and other characteristics of the
nut. Also the susceptibility of the tree to various diseases and inju-
rious influences. Seedling walnuts vary very greatly in these respects,
although certain general types of a certain degree of similarity among
themselves may be recognized. Thus, in California, almost all the
so-called Santa Barbara seedlings come out comparatively early in the
spring, they are usually thrifty, large trees under favorable conditions,
and the nuts are mostly of the soft-shell type as regards cracking qual-
ity. The old fashioned hard shells represent another fairly uniform
type, even when grown from seed, having rather small, round, very
hard-shelled nuts borne upon trees with a certain similarity to one
another. The same, is true of the so-called paper shells. Trees of all
these types bear nuts of about the same color, a dull, neutral or greyish
brown. Taking the French varieties we find among most of them the
habit of coming out extremely late in the spring, so that a Franquette,
Mayette, or Parisienne, and almost all the seedlings derived from nuts
of these varieties, leaf out several months later than Chase, Placentia
Perfection, or most of the Santa Barbara Soft Shell seedlings, even
though planted in the same locality. They also bear nuts almost always
of a brighter, more yellowish color than do the California varieties. The
meat of the nut is also usually lighter colored.

In other words, we find in walnuts certain types differing very
widely in various respects from one another, while among the seedlings
from one of these types there is a considerable variation, but not so great

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 255

as that between the different types themselves. The various types, indi-
vidual trees and varieties now to be found in California have almost all
descended, as we have shown on page 171, from two sources, namely, the
Santa Barbara Soft Shell type, first produced and propagated by
Joseph Sexton of Goleta, which came probably from Chile, and second,
various French varieties and their derivatives, almost all of which were
first introduced or developed by Felix Gillet. It is doubtless true that
more than 99 per cent of the walnut trees now growing in this State are
descendants of one or the other of these sources. The only noticeable
exception to this is the Eureka, which originated as a chance seedling
from a tree introduced through another source. It is undoubtedly true
that with the exception of the Eureka all the varieties which are worthy
of discussion for California planting are either Santa Barbara Soft
Shell seedlings, old French varieties, or seedlings of some of these later
varieties which have originated in California.

In discussing the various varieties now before the public we should
first of all formulate an idea or standard as to what constitutes an ideal
walnut. In regard to this, the first and most important quality is un-
doubtedly that of production. A variety however fancy or otherwise
desirable which does not produce comparatively large crops of nuts can
not be considered satisfactory, whatever may be its other qualities. As
to the ideal or greatest possible production, we may say that while the
crop of the present producing seedling groves of southern California
averages only about 50 pounds per tree, or 1,000 pounds per acre, there
are numerous individual seedling trees in the State which average close
to 300 pounds, and a very large number which produce regularly more
than 200 pounds. Since thrifty walnut trees, after reaching an age of
twelve to fifteen years, should have a distance of at least fifty to sixty
feet apart, which means an average of not over fifteen trees per acre,
we may estimate that at 200 pounds per tree the crop per acre would
equal 3,000 pounds of nuts, which at an average price of 12 cents would
amount to $360 gross per acre. This figure, as compared with present
returns from the citrus industry, is fairly modest, yet if it could be
maintained as a regular income it would represent a very satisfactory
return on much of the land in this State which is adaptable to walnut
culture. On the highest priced citrus lands of the south, walnuts even
on this basis could hardly compete with lemons and oranges. Three-
hundred-pound trees would add 50 per cent to the figure estimated and
such production should be ultimately attained in an ideal tree having
plenty of room at least by the time it reaches fifteen or twenty years
of age. As we have said above, however, these results are far above those
actually being obtained at present in the walnut industry. At this
point we may also consider the relative merits of a fancy variety, pro-

256 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

ducing nuts which may sell for at least 25 cents per pound, but pro-
ducing only 50 to 100 pounds on mature trees, as against a 12 or 15
cent variety which produces 200 or 300 pounds. The comparative desir-
ability of such varieties for planting, so far as they actually exist, can
be judged fairly well from our description of the various kinds. The
relation between quality of nut and the amount of the product should
be very carefully considered in choosing a variety for planting and the
grower should not be too much influenced by the appearance of a few
sample nuts without regard to the quantity in which they are produced.
The ideal tree, of course, is one which would produce large crops of the
most desirable type of nuts, but this combination has not been fully
attained. Another important point in regard to production is that of
the precocity or age of coming into bearing, in which great differences
exist in different varieties and between individual seedling trees. Some
varieties begin to produce nuts quite abundantly, even in the nursery,
and give a commercial crop within three years from planting in the
orchard, while others are several years later in coming into bearing.
Here, again, this quality must be carefully weighed in choosing a variety,
considering its relative value in proportion to other qualities. There is
in this connection the possibility of inter-planting, either with more pre-
cocious walnuts or some other crop, which may offset the disadvantage
of an otherwise desirable variety which is slow in coming into bearing.
The next important consideration is that of the size and weight of
the nuts. In almost all varieties and seedling trees the nuts are of good
size when the trees are young and first come into bearing, but in many
there is a tendency for the nuts to become smaller and smaller as the
trees get older and the crops heavier. The size of commercially first
grade California walnuts, as we have shown on page 197, is repre-
sented by nuts which will not pass through a one inch square opening,
while those above 1 3-16 inches command a considerable premium.
Nuts of a size considerably greater than this are in demand at still
higher prices to some extent, but ordinarily the market for such large
nuts is quite limited, owing to the fact that most varieties of this sort
are poorly filled with meat. Whether an extra large, well filled nut
and one of good flavor, if such exists or could be produced, would be
desirable for general planting, is somewhat problematical, although
certainly such a nut would command a ready sale and at a good price
to a considerable extent. However this may be, it is true that on the
basis of present standards the most desirable size is that which is not
graded out by a square-mesh screen of 1 3-16 inches, but not so very
much larger than this. The weight of the nut is equally important,
since this varies widely in nuts of the same size, as may be seen in the
table on page 300. It may be seen here that some of the largest

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 257

varieties are considerably lighter in weight than others in which the
nuts are decidedly smaller. A desirable nut should be well filled with
plump meat without too much air space between the shell and the meat.
A comparatively heavy shell is more desirable than a very thin, light
one, since the nut is better protected, less susceptible to perforation and
similar troubles (see page 376), and it is also to be considered that
since walnuts are sold by the pound, the heavier the shell the greater
is the weight and the more the returns from a given number of nuts.
Next to be considered is the shape, smoothness, uniformity and color of
the nuts. These qualities may be sometimes of minor importance where
walnuts are grown on a very large scale and put upon the market without
individuality of any kind, yet for an ideal nut or for one which is to
command the highest price, certain qualifications are very desirable
in these respects. The most attractive form is usually considered to
be a somewhat elongated walnut, rather broader at the base than at
the apex. This is not very important, however, since the smoothness,
symmetry, and uniformity of the nuts affect their attractive appear-
ance more than their shape. An ideal nut should be quite smooth, free
from decided ridges, grooves, or other irregularities of surface ; it should
be symmetrical rather than one-sided or irregularly shaped, and all
the nuts should be of the same general shape and appearance, giving
them uniformity and individuality. A variety in which the nuts are
decidedly uniform so that the variety is easily distinguished and recog-
nized, even by the ordinary purchaser, has a marked advantage over
one in which the nuts are of all sorts of shapes so that only an expert
can distinguish the variety from others. The color of the nut is also of
considerable importance, although walnuts are almost always bleached
before putting them on the market and in this way they are all brought
to about the same color. A variety, however, which is of a light, attrac-
tive color, is entitled to considerable merit over one which is dull, dark
or unattractive.

Next we may consider the cracking quality and sealing of the nut.
A thin-shelled- easily-opened nut is somewhat more attractive to the
eater than one which is hard and difficult to open, yet from a com-
mercial standpoint this quality is a comparatively unimportant one.
A rather firm-shelled nut, and especially one which is strongly sealed
at the natural line of opening or suture between the two halves of the
shell, is very much to be preferred to one which pops open at the
slightest pressure. In the latter case many of the nuts open in drying,
or when shaken about in the sacks and bins, moisture and mold spores
are admitted, many are spoiled in handling, and such a nut is in every
way very undesirable to the grower and of only very slight advantage
to the consumer. Concerning walnuts for the table, they are almost

10—231

258 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

always cracked beforehand in any case, and the necessity of a little
pressure more or less is of very slight importance. No variety can be
harvested, handled, marketed and kept for any length of time with
good, plump, white meats, free from mold and discoloration unless the
shell is fairly hard and thoroughly well sealed. Extreme thinness of
shell is one of the least important qualifications and is in fact decidedly
undesirable. The color of the meat is of considerable importance. As
commercially graded in California, nuts with the lightest colored meats
are considered most desirable, while those which are decidedly dark,
even though plump and of good flavor, are discriminated against. It
is, therefore, true that the lighter colored the meat the more desirable
is the nut, and a variety in which the nuts run uniformly quite dark-
meated is decidedly objectionable. The flavor of the meat varies con-
siderably in different varieties and is of much importance in a high
class, fancy trade. In some varieties the nut is sweet and of a pleasant
flavor, while the most common undesirable quality in this respect is a
bitter flavor. This should be guarded against in choosing an ideal
variety.

To sum up, then, the most important qualifications in a walnut
variety from a strictly commercial standpoint are that it should be a
uniformly large producer of nuts the majority of which will not pass
through a 1 3-16 square mesh, and of which very few pass through a
smaller opening than a 1 inch size. These nuts should be well sealed,
even though somewhat hard shelled, and should be uniformly well filled
with meat of light yellowish brown color or not darker than light brown
or amber. For a more fancy trade the nuts should be of attractive,
uniform shape and color, smooth surface, and particularly high quality
and agreeably flavored meat. A variety which would combine all these
characteristics to a very high degree, including both those of production
and quality, would form the basis of a crop which even the citrus in-
dustry could scarcely equal in attractiveness and profit.

COMMERCIAL VARIETIES.

The following seven varieties will be most fully described, being those
of which nursery trees are most commonly available and those which
we have been able to see growing and obtain nuts from for a period of
several years. Some of the varieties in our second, miscellaneous list
may be better than any of these, but, if so, their merits have not yet
been fully established.

CHASE.
Origin.

This variety originated in a tree standing about three miles south
of Whittier upon a ranch formerly called the Chase place, which has
changed hands several times during the last few years. The tree is said

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 259

to have been planted in 1886 among a lot of seedlings obtained from
Felix Gillet. One story has it that the tree is a seedling of the Mesange
variety, although we are unable to trace the origin of this idea. The
nut certainly has no resemblance to that of the variety mentioned but
seems to be of the Santa Barbara Soft Shell type. The variety owes
its prominence to Mr. A. R. Rideout, of Whittier, who has propagated,
sold and advertised it widely during the past few years. It has not yet
been tested to any extent in the north, although quite extensive plant-
ing of the variety has recently been made in that part of the State.

NUT.

Size.

Medium to large on young trees, small on original tree. On young
trees average 1J by If by If inches, with many larger. Nuts on old
tree much smaller, with many less than 1 inch long.

Form.

Broadly oval or rounded, symmetrical, flattened, apex and base of
equal breadth. Apex terminating in a short and pronounced point or
beak.

Surface.

Quite smooth and even.

Color.

Neutral light brown, without the pinkish cast of Placentia Perfection.

Uniformity.

Strong, in trees of real Chase origin. In some cases the variety has
become mixed with other kinds, which probably accounts for some
apparent deviations from the type.

Cracking Quality.

Nuts poorly sealed, both at apex and base, so that they are very easily
opened with the fingers.

Pellicle.

Light tan to light brown.

Meat.

Uniformly plump and well filled. Averaging nearly 50 per cent of
total weight of meat, at the same time having a heavy shell.

Flavor.

Not pronounced. Mild and free from any decided characteristic.

TREE.
Foliation Period,

Very early. About the earliest of any named variety. Earlier in
southern California than the average of the seedlings.

260 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Growth.

Very vigorous and thrifty. Young trees have a characteristic, up-
right, rather stiff appearance, the branches being straight and all
coming from the uprights at the same angle. This appearance is lost
after fruit spurs become abundant.

Foliage.

Abundant and thrifty.

Harvest Season.

Early.

Precocity.

Quite strong in the south. One of the best in this respect.

Production in Older Trees.

The original tree is said to have produced 325 pounds in one year
and is uniformly a large producer. This is due to its great size as well
as fruitfulness, as there are few larger walnut trees in the State than
this. Our own five years' observation of this tree has shown it to be
unusually thrifty and vigorous and a bearer of heavy crops, even under
adverse conditions. Its long sustained vigor of growth is in fact the
most valuable characteristic of the variety.

Susceptibility to Blight and Other Troubles.

The original tree shows considerably less blight than its neighbors,
although not immune tr the disease. It is so large, vigorous and thrifty
that good crops are produced in spite of the disease. The same vigor
of growth, together with the abundance of foliage protects the nuts to
a large extent from sunburn and other climatic injuries. The nuts of
the original tree have been decidedly free from sunburn as compared
with those of neighboring trees.

Some young groves of this variety have shown considerable perfora-
tion in the nuts, but the old tree is noticeably free from this trouble.
See page 376.

GENERAL REMARKS.

From the above description we may sum up the characteristics of the
Chase variety by saying that it is a very large, thrifty, vigorous-growing
tree, which on account of its vigor of growth is a good producer and
comparatively free from disastrous losses by blight or other injurious
influences. Its nuts have no exceptional characteristics, but are of good
average quality as compared with the product of the present groves of
southern California. The tree has considerable precocity in bearing and
may therefore be recommended to those who desire quick results, both in
growth of tree and production of nuts.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

261

FIG. 50. — Chase walnut, natural size.

262 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 51. — Chase walnut, natural size.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

263

CONCORD.

Origin.

This variety originated in a seedling tree on the place of Mr. George
M. Westcott, of Concord, Contra Costa County. The original tree came
from the late Felix Gillet and is said to have been a seedling of the
Cluster variety. It was planted about 1893. The variety obtained con-
siderable fame in its own immediate neighborhood and was propagated
there quite extensively by top-grafting upon native black walnuts some

M- ^S^P'-f ;*&*

FIG. 52. — Chase walnut, original tree.

time before it was exploited in a popular way. Mr. Ely Hutchinson
of Concord propagated the variety quite largely on his place, thus
giving it a thorough test in that locality. It was taken up by Mr.
Leonard Coates, the nurseryman, about 1908 and propagated, adver-
tised and sold quite extensively by him thereafter. Not yet much
tested in the south. One of the first descriptions of the Concord is

264 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

found in an article by Mr. Coates in the California Cultivator of October
7, 1909, page 339.

NUT.
Size.

Medium.

Form.

Broad and short, with a square cut base slightly wider than the apex
in most specimens. Apex very broadly pointed. Some of the nuts
slightly elongated and somewhat unsymmetrical at both ends.

Surface.

Medium smooth, with a considerable percentage of rather rough speci-
mens.

Color.

Tan. Lighter than most of the southern California varieties, but a
little duller than San Jose, Franquette, and the best Mayettes.

Uniformity.

Fair. A considerable proportion of the nuts rougher and more
pointed than the type. There is also a considerable variation in color.

Cracking Quality.

Nuts fairly well sealed, but cracking in the fingers without much diffi-
culty.

Pellicle.

Very light and attractive.

Meat.

Plump and well formed, filling the shell very completely.

Flavor.

Mild and free from any decided characteristic.

TREE.
Foliation Period.

Medium late. Decidedly later than Placentia Perfection, but consid-
erably earlier than Franquette. According to Mr. Hutchinson, it is
about a week later than the Placentia and three weeks earlier than the
Franquette in his locality. In the south there is considerably more
difference than this between the Placentia and Franquette, and the Con-
cord is apparently nearly intermediate between them. Its foliation
period is very nearly the same as that of Eureka. The foliage is held
well into the fall.

Growth.

Vigorous and rapid 'in the case of young grafts. The original tree is
decidedly small for its age and the apparently favorable conditions
under which it stands, but young trees or grafts observed in various
parts of the State appear to be particularly thrifty in growth.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 265

Foliage.

Abundant and vigorous, persisting in good condition late in the fall.

Harvest Season.

Medium or fairly early.

Precocity.

Apparently fairly good. Considerably more precocious than Fran-
quette and perhaps less so than Placentia Perfection, Chase and Prolific.

Production in Older Trees.

The possibilities of this variety as to permanent production cannot be
accurately judged. The original tree is rather small, and its production
could certainly be much exceeded by well grown, grafted trees. Mr.
Hutchinson 's trees consist of top grafts on large black walnuts, growing
without irrigation. The variety is probably a better bearer than Fran-
quette, but less productive than some of the southern varieties. More
than this cannot be said at present. The possibilities of this, like all
other varieties, will probably vary to a considerable extent in various
parts of the State.

Susceptibility to Blight and Other Troubles.

The Concord has been advertised as being especially desirable on
account of immunity to blight. On account, however, of the very slight
extent to which it has been tested in this respect, we do not feel that any
statement upon this matter is justified. There appears to be consider-
able doubt as to the extent to which true walnut blight exists in the
original locality of the Concord, arid in any event it is certainly one
where conditions are not favorable to the occurrence of this disease.
Being late in coming out in the spring, it is probable that the Concord
will prove considerably free from blight as compared with earlier varie-
ties. In respect to sunburn, this variety appears to be well adapted to a
hot, sunny region, inasmuch as conditions of this sort exist to a con-
siderable extent in its original location and the nuts produced there are
of very light meat, with no serious discoloration from the sun. The
foliage, moreover, is abundant and thrifty, affording shade to the nuts.

GENERAL REMARKS.

The Concord is perhaps next to the Franquette the best tested variety
for the north and central interior portions of California. In Contra
Costa County it is to be found to the extent of several hundreds of trees
of various ages, and has proven itself there to be of thrifty, vigorous
growth, fair quality, and a regular producer of satisfactory crops. It
is late enough in coming out to protect it to a considerable extent from
frost and blight, yet not extremely late in maturing its crop in the fall.
Young trees make a quick, vigorous development and appear to be
fairly precocious in bearing. The nut is of fairly good appearance

266 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Fig. 53. — Concord walnut, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

267

FIG. 54. — Concord walnut, natural size.

268

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

and of decidedly good fullness and color of the meat. Against the
variety, it may be said that the nuts are of only medium or even rather
small size, especially as the trees grow older, and of no more than
average quality in appearance. For the southern part of the State the
Concord has not been sufficiently tested to justify any positive statement

FIG. 55. — Concord walnut, original tree.

concerning its development there. For the north it is reasonably certain
that this variety will make a vigorous, quick-growing tree, producing
good commercial crops, of full, sweet-meated, not very large nuts, within
a reasonable time. It is inferior to Franquette in size and quality of
the nuts, but will probably surpass it in production and precocity.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 269

EUREKA.
Origin.

This variety originated in a seedling tree on the Stone ranch, at
present owned by Mr. William Holve, one mile south of Fullerton, Cali-
fornia. The particular tree stands directly in front of the house by
the roadside and is one of a group of about six trees which were planted
about 1890 or earlier, from nuts obtained at the old Meek place, near
Hayward, California. The parent tree was one of the Persian or
Kaghazi type which we have described under that name. The desir-
able quality of this tree was first appreciated by Mr. E. G. Ware, of
Garden Grove, who named the variety Stone's Eureka, about 1903.*
Mr. D. C. Disher of Garden Grove was associated with Mr. Ware in
first propagating and calling attention to the merits of this variety.
Up to about 1909 very few Eureka trees were propagated except by Mr.
Disher and almost all of his were bought by Mr. C. W. Leffingwell,
Jr., and planted on his ranch at East Whittier. Messrs. Ware and
Disher planted a few on their places at Garden Grove, and Mr. J. B.
Neff of Anaheim also had a few of the earlier trees. There are also a
very few of these on some of the ranches in the vicinity of the Stone
place where the variety originated. In 1909 Mr. Neff top-grafted
about 200 orchard trees, mostly Placentia Perfection, to this variety,
and the Experiment Station, through the Whittier Laboratory, began
sending out Eureka scions for trial to all parts of the State. In 1911
several nurserymen began listing this variety.

NUT.

Size.

Large. Average 1J by If. Many larger.

Form.

Decidedly elongated, with parallel sides; apex and base of equal
breadth, or a little thicker at the apex. Rather rectangular or square
in end view. Nuts very blunt, with a little more taper at the base
than at the apex.

Surface.

Quite smooth, sutural ridges not prominent except at one point a
little toward the apex from the middle.

Color.

Dull, light brown, more attractive when bleached or well washed.
Very pleasing to the eye when properly bleached.

Uniformity.

Pronounced. One of the strong qualities of the variety. Nut easily
distinguished from any other kind.

*The Pacific Rural Press of January 23, 1904, contains what appears to be the first
printed mention of this variety.

270 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Cracking Quality.

Shell hard, rather thick, heavy and very strongly sealed. Never
splitting open in handling and not easily cracked with the fingers.
Meat easily extracted after cracking.

Pellicle.

Straw color, light and attractive.

Meat.

Full and heavy in good specimens. Averages 45 to 50 per cent of
total weight of nut, while the shell is extra heavy.

Flavor.

Excellent. Particularly sweet.

TREE.

Foliation Period.

Medium late. About midway between the early blooming varieties
like Chase and Placentia Perfection and the very late ones, such as
Franquette. A little later than Concord. Earlier in the north than
in the south.

Growth.

Extremely vigorous and rapid, especially in nursery and top grafts.
Young trees form a few large leaders, with few fruit spurs until the
fourth or fifth year. The smooth bark of the trunks of young trees has
a yellowish color. The bark on the trunk of the older trees is cracked
or furrowed up and down in a manner characteristic of the Kaghazi
type.

Foliage.

Very thrifty and abundant, shading the nuts well.

Harvest Season.

A little later than that of the earliest varieties, considerably earlier
than Franquette.

Precocity.

Not marked in southern California. About two years later than
Chase, Placentia Perfection, etc., in coming into bearing. Experience
in the northern part of the State indicates that Eureka is more preco-
cious there than in the south.

Production In Older Trees.

Can only be judged from the original tree. This was said to be
averaging somewhat over 200 pounds of nuts per year when sixteen
to eighteen years of age, before being heavily cut for scions. The tree
is positively known to us to have borne this amount in at least one or
two years. From the oldest propagated trees of the variety, Mr. E. G.
Ware obtained a few nuts during the fifth year after planting and as
high as 20 pounds on some trees during the seventh year. In Mr. C. W.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 271

Leffingwell, Jr.'s grove, the first nuts were produced in the fourth year
after planting and only a very few trees had nuts on them during that
year. During the fifth year there was a sprinkling of nuts on every
tree, but hardly enough to be measured in pounds. In the vicinity of
Stockton, Eureka top-grafted on good sized black walnut trees by
Dr. W. W. Fitzgerald produced a few nuts the first year after grafting
and quite a sprinkling of them during the following season. Mr. Ely
Hutchinson of Concord had the same experience. The variety has
shown a wonderful vigor of growth wherever tried in this way.

Susceptibility to Blight and Other Troubles.

From all experience with Eureka we are justified in stating that this
is the most resistant to blight of any variety thus far observed. That
it does not merely escape the blight by late blooming, but actually
resists it to a considerable extent seems to be the case from the fact
that still later blooming varieties are more susceptible to blight than
Eureka. It may be said of this variety that it has been very thor-
oughly tested in regard to blight resistance, which is not the case with
many kinds which are advertised as immune. The original tree stands
in a locality where the disease has prevailed for many years and caused
immense losses. The tree is surrounded on all sides by seedling wal-
nut groves in which the blight has occurred at its worst. The state-
ment, therefore, that no sign of the disease has ever been seen on this
tree seems a strong one, yet if not absolutely true, it is certainly a fact
that year after year, when seedling groves all about were very badly
blighted, no blight could be found upon this tree, and so far as we know
in five years' observation it has never been affected to any appreciable
extent by the disease. While young trees planted in other localities and
in new localities may possibly lack this absolute immunity from blight,
it is certainly true that the Eureka has shown the greatest freedom
from the disease under the most severe test of any variety which is now
before the public. In this respect it has fully justified the name given
to it by Messrs. Ware and Disher nearly ten years ago in their search
for a blight-resistant variety. In respect to other troubles than blight,
the Eureka has thus far been entirely free from perforation, and it is
not likely that the variety will ever develop this trouble on account of
its strong, thick shell. It is also free from sunburn on account of
its abundant foliage and thick husk, and in every way the variety is
healthy, thrifty, and free from disease.

GENERAL REMARKS.

The Eureka comes very close to satisfying the requirements of an
ideal walnut for California. It is a fine, large nut of strikingly
handsome appearance, extra full meat and weight, perfectly sealed,

272 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 56. — Eureka walnut, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

273

Fig. 57. — Eureka walnut, natural size.

11—231

274

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

light-colored meat, fine flavor, marked immunity to disease, a strong,
vigorous grower and ultimately a heavy producer. Its worst defect
thus far has been a tendency toward a slightly imperfect development of
the meat in certain seasons, especially a shriveling of the meat at the
basal end of the nut. This has been most pronounced during dry years,
on lighter soils and on trees which received little or no irrigation. The
same shriveling has usually occurred at the same time in other varie-

Fig. 58. — Eureka walnut, original tree.

ties. The variety is strong as compared with any other southern Cal-
ifornia kinds in its freedom from blight and perforation, extremely
thrifty foliage and growth, large size, uniformity, and attractive
appearance of the nuts, especially when bleached, and their strong
sealing and heavy weight. While the percentage of meat is slightly
lower than in Placentia Perfection and a few other varieties, this is
not due to a lesser amount of meat, but rather to the greater weight of

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

275

the shell; in other words, Eureka nuts are heavier than those of the
same size of any other variety, thus making fewer nuts per pound

Fig. 59. — Eureka walnut tree, three years old.

or more pounds per sack. Compared with Franquette or any other
French variety or California variety of French origin, Eureka is a
more precocious and heavier bearer, more thrifty in growth and foli-

276

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

age, equally proof against ordinary spring frosts by lateness in its
foliation period, and considerably earlier in maturing its nuts in the
fall. In the south it is less precocious than the best southern varie-

FIG. 60. — Eureka walnut tree, six years old.

ties, but promises ultimately to exceed most of them in production.
In the north it seems as precocious as any variety yet tested commer-
cially. The size of its nuts is well sustained, contrary to the case in
some of the other varieties. From present information this variety

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 277

appears especially promising in the northern part of the State, and
the expectation is well justified that Eureka may become the best va-
riety for the northern districts. In the south the variety has disap-
pointed some on account of its slowness in bearing as compared with
Placentia Perfection, but it is significant that those who have known
the variety best and longest, walnut growers of the immediate locality
of the original tree, are very enthusiastic about the Eureka and express
themselves very strongly in its favor. In all events, present knowl-
edge seems to indicate the particular adaptability of this variety to
the northern part of the State and to fairly heavy, well irrigated land.

FRANQUETTE.

Origin.

A French variety said to be nearly two hundred years old. First
introduced into California by Felix Gillet in 1871. Most of the Fran-
quettes at present growing in the State have been derived from Gillet 's
importations, although the variety has possibly been brought from
France by others in one or two instances. The present standing of the
Franquette as the leading northern California and Oregon variety is
based on the success of the Vrooman grove at Santa Rosa. This sixty-
acre walnut orchard was planted by the late Mrs. Emily Vrooman at
a time when commercial walnut growing north of Santa Barbara County
was absolutely unknown, and as a result of Mrs. Vrooman 's investigation
of and confidence in the Franquette the qualities of this variety are
well established. In more recent years the Franquette has been exten-
sively taken up by the Leibs of San Jose, who have become the leading
exponents of this variety. Through the influence of the Oregon Nursery
Company, who bought the scions and nuts from the Vrooman orchard
for a period of several years, the fame and popularity of the Fran-
quette have been largely extended and many others have become familiar
with and planted the Franquette on a considerable scale, both in
central and northern California and Oregon. In southern California
there is a large tree on the old Experiment Station grounds near
Pomona, Mr. Neff of Anaheim has a few trees top-grafted to Fran-
quette, and there are several young and top-grafted trees at the Whit-
tier laboratory and at the Pasadena City Farm.

NUT.

Size.

Medium to large. Well sustained on old trees.

Form.

Decidedly elongated and pointed. Base much broader than apex.

Surface.

Medium smooth. Sutural ridges quite prominent.

278 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Color.

Light yellowish brown.

Uniformity.

Strong.. The uniform and characteristic shape of the Franquette
nuts makes them easier to identify than those of almost any other
variety.

Cracking Quality.

Nuts strongly sealed, but quite thin shelled so that they are readily
cracked.

Pellicle.

Pale yellowish tan, giving the meat a very light colored, attractive
appearance.

Meat.

Moderately plump and filling the body of the shell fairly well. The
shell is considerably longer than the meat, leaving a hollow space within
the apical point of the nut.

Flavor.

Sweet and free from bitterness, with a characteristic nutty flavor ap-
proaching that of a hickory nut. The consistency of the meat is also
characteristic, being unusually soft or oily.

TREE.
Foliation Period.

Very late. The latest of any important variety in California. Often
two to three months later in coming out in the spring than the earliest
varieties. The Franquette is also noticeably early in dropping its
foliage in the fall so that its seasonal period of growth is comparatively
short.

Growth.

Fairly vigorous and rapid, but decidedly less so than that of many
other varieties. The best growth of the Franquette is seen in compara-
tively cool, moist localities, as for instance in the coastward region of the
central and northern parts of the State. In the south and in the inte-
rior, especially without irrigation, the Franquette is of slower growth.

Foliage.

Abundant and thrifty, but developed late and shed early in the season.

Harvest Season.

Late. One of the undesirable features of this variety.

Precocity.

Not pronounced. The Franquette is one of the slowest in coming into
bearing.

Production In Older Trees.

So far as can be judged by the oldest Franquette trees in the State
the Franquette is a regular and consistent but not a heavy bearer. Trees

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 279

ten to fifteen years of age have averaged not over 40 pounds per year
and 100 pounds is probably a maximum production for large, mature

FIG. 61. — Franquette walnut, natural size.

trees of this variety. Groves of nursery-grafted trees in their sixth year
after planting have scarcely averaged 10 pounds per tree.

280 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 62.— Franquette walnut, natural size.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

281

Susceptibility to Blight and Other Troubles.

The Franquette is noticeably free from blight in most cases on account
of its extreme lateness in coming out in the spring. The variety appears
to have very little actual resistance to the disease, since in foggy locali-
ties the nuts and twigs sometimes blight quite badly. The thick husk
and abundant foliage protect the nuts from sunburn to a very large
extent, and the variety is not especially susceptible to any other trouble,
except that in some years the meat shrivels rather badly.

FIG. 63. — Franquette walnuts, Vrooman grove.

GENERAL REMARKS.

The Franquette is undoubtedly our best proven variety for central
and northern California and has one great advantage over any other
variety for that section, that it has been thoroughly tested and its merits
and demerits well established. It is thus possible to judge the variety
more critically than can be done with any other northern variety, and
for this reason our description of it may sound more unfavorable
than the Franquette really merits. As regards quality of the nut, this

282

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

variety may be taken as a standard, as it is undoubtedly the best of any
variety which has been widely tested in California. Its characteristic
and uniform shape, light, attractive color, both of shell and meat, firm
sealing yet easy cracking quality, and the particularly pleasing flavor

and consistency of the meat all go to make the Franquette nut one of
the very highest quality. The variety is also strong in freedom from
blight and spring frost injury on account of its very late season of com-
ing out. The most prominent faults of the variety are its slowness in

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 283

coming into bearing, the late period of maturity of the nuts in the fall,
and the fact that the tree is by no means as heavy a bearer as should be
looked for in an ideal variety. All in all, then, we may say that the
Franquette is a variety of unusually high quality and rather poor pro-
duction. For southern California, where it has been tested to some
extent, we do not believe that this or any other extremely late variety
is to be considered. Farther north it is undoubtedly true that for the
ultra-conservative planter, at least, no other variety can be considered
as safe as this, since its behavior in orchard form can be very closely
forecasted. Franquette nuts have commonly sold for nearly twice the
price of southern California seedlings, which offsets to some extent the
light bearing and lack of precocity of the variety.

PLACENTIA.

(Placentia Perfection.)
Origin.

Originated in Placentia, near Fullerton, California, as a seedling of
the Santa Barbara Soft Shell type. The original tree stood in an
orchard of Geo. Hind & Company, about one mile north of the Placentia
sehoolhouse ; the first propagation of the variety was done by Mr. Hind
about 1893, and the variety received its name from this gentleman.
Mr. J. B. Neff of Anaheim was the first to plant any considerable acre-
age of Placentia Perfections, the first trees which he bought of Hind
& Company being bench-grafted on piece roots, using about six to ten
inches of the root and making three to four nursery trees from one root.
In former years Mr. Neff sold many scions and seed of this variety to
nurserymen over the State, as much as 1,600 pounds of nuts and 20,000
scions in one season. In later years he refused to sell either seed for
planting or scions, on account of the susceptibility of this variety to
walnut blight. He also grafted over all his younger Placentia trees to
the Eureka variety on account of the blight.

At present there seem to be in southern California two fairly distinct
types of the Placentia walnut, even among trees which are supposed to
have been grafted from pure stock. These two types, while in most
respects identical, differ in that the nut of one is quite elongated while
the other has a decidedly round nut. The quality of the nut in the two
types is apparently identical, as well as the general characteristics of
the tree. Mr. Neff's trees, which are certainly of the purest original
strain, bear nuts of the round type, but the majority of the younger
groves of this variety in southern California bear the longer type of nut,
which is that which we are about to describe. This latter type is more
variable in form and smoothness of the nuts than the other. That this
variation has occurred in the grafted progeny of one original tree rather
than by mixing of the stock seems very possible, as the different types
are too much alike to be considered entirely distinct varieties.

284 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

NUT.
Size.

Medium, averaging 1£ by 1J by 1J inches. Buns largely to average
size, with few very large or very small nuts.

Form.

Regular, oval, somewhat elongated ; base and apex nearly equal in
breadth. Flattened, with greater diameter at right angles to the
sutures.

Surface.

Quite smooth. Sutural ridges not especially prominent.

Color.

Light neutral brown, mottled with gray, giving the nut a distinctly
pinkish cast.

Uniformity.

Not especially strong. Nuts quite uniform in size, but varying consid-
erably in shape and smoothness. Some quite elongated, others nearly
round, some quite rough.

Cracking Quality.

Nuts poorly sealed, causing them to open very readily between the
fingers or when exposed to the sun. Shell thin and strong. Septum
almost free from the shell, so that the nut can be very easily opened
with the fingers and the whole meat taken out intact.

Pellicle.

Light tan colored, or very light silvery brown, with a glossy, waxed
appearance. Decidedly attractive.

Meat.

Quite smooth, with comparatively few convolutions. Uniformly
plump and full, averaging fully 50 per cent or slightly more of the total
weight of the nut.

Flavor.

Mild and pleasant, with no pronounced character.

TREE.

Foliation Period.

Quite early. Nearly two weeks later than Chase and the average of
the Santa Barbara Soft Shell seedlings. From one to four weeks earlier
than Concord and Eureka.

Growth.

Vigorous, making a large, tall tree, the more erect, taller branches
standing up from the lower portion in a characteristic manner.

Foliage.

Very abundant and thrifty.

Harvest Season.

Early.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 285

Precocity.

Fair. Commences bearing fairly well while quite young, at least in
southern California.

Production in Older Trees.

Very good, but not exceptionally heavy, so far as can be learned from
present plantings.

Susceptibility to Blight and Other Troubles.

Badly affected by blight under conditions favorable to the disease.
Nuts sometimes badly perforated, especially on young trees. Otherwise,
not especially susceptible to disease.

GENERAL REMARKS.

The Placentia Perfection is in many respects the best walnut which
has yet been thoroughly tried in southern California, and, all things con-
sidered, is entitled to be called the best proven variety for that part of
the State. It comes close to being an ideal nut save for two defects, but
these are so great as to preclude all idea of considering it a thoroughly
satisfactory variety. These defects are the poor sealing of the nuts and
the susceptibility of the variety to blight. The nuts crack open badly
in ordinary handling, and still more so if exposed to the sun to any
extent in drying. In regard to blight, the Placentia Perfection is very
susceptible to the disease, which again belies its name. Aside from these
two defects, however, the variety is one of high quality and is probably
unequaled by any other as a commercial walnut for southern Cali-
fornia. It is of a desirable and attractive form and size, heavy and
very plump meat running a full 50 per cent or better. The meat is of a
very attractive color and appearance and can easily be taken out of the
shell whole with the fingers. The nuts are almost invariably well filled,
even in seasons when the average quality of walnuts in this respect is
very poor. The tree is thrifty and vigorous, one of the easiest to propa-
gate by grafting, quite precocious, and becoming large and well formed
while still comparatively young. In regard to production, the variety is
not old enough to be critically judged. Trees in their fifth year from
planting in the orchard have produced from twelve to twenty pounds
of nuts, which is as good as almost any other variety will average, and
better than most. We know of one grove which produced slightly more
than one ton of nuts per acre in its tenth year, which is a very satisfac-
tory yield compared with present groves, although by no means up to
the possibilities of an ideal variety. Since the Placentia has no im-
munity to blight and is superior only in the quality of the nut and satis-
factory development of the tree, it is probable that varieties will be
found among our present seedling trees equally good in these respects
and at the same time less subject to the defects mentioned. The
Placentia Perfection is usually looked upon in southern California at

286

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

the present time as representing the best type of commercial walnut in
that section.

The variety has not been much tested outside of Orange and Los

ail

w

FIG. 65. — Placentia walnut, natural size.

Angeles counties. In the central and northern portions of the State no
experience is available upon which to base an opinion as to its merits

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

287

FIG. 66. — Placentia walnut, natural size.

288 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIG. 67. — Five-year-old Placentia tree on southern California black root.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 289

or the advisability of planting it in those localities. It certainly should
not be planted in localities where the blight is very prevalent, on account
of fog and moisture in the spring and early summer. Farther inland, as
for instance in the Mount Diablo country and the dryer portions of the
other coast valleys, and in the Sacramento and San Joaquin valleys as
far as walnut culture may prove feasible, the variety is worthy of con-
siderable consideration, especially in regions not too much subject to
late spring frosts. In the latter case the Placentia probably blooms too
early to be worthy of consideration. There are a few young trees of the
variety in the northern portion of the State, but they are scarcely old
enough to be critically judged. In growth and general development
they are doing very well but have not yet begun to fruit abundantly.
Given freedom from late frosts and conditions not too favorable to
blight, there is no apparent reason why the Placentia should not do as
well in the north as in the south.

PROLIFIC.

(Disher's Prolific, Ware's Prolific.)
Origin.

This variety originated in a Santa Barbara Soft Shell seedling tree
at Garden Grove, Orange County, California, which was selected by Mr.
D. C. Disher as being worthy of propagation. According to Mr. E. G.
Ware, who was closely associated with Mr. Disher, the tree was first
selected on account of the desirable form and size of the nuts rather
than for the quantity, which the present name of the variety implies.
It was found, however, that after young trees planted in orchard form
came into bearing they had a pronounced tendency toward early and
heavy bearing, from which the present name of the variety is derived.
Mr. Disher propagated a considerable number of trees of this variety,
mostly by budding on the southern California black root, and they
have been planted in orchard form to some extent, the oldest being now
in about their sixth year since planting in the orchard. Mr. C. W. Lef-
fingwell, Jr., has a considerable number of the trees upon his ranch at
East Whittier, Mr. Ware has five acres of six-year-old trees, and there
are a few other orchard plantings of this variety in the southern part
of the State. The variety has also been recently introduced into the
north, but cannot yet be judged in that part of the State.

NUT.

Size.

Rather large on all the young trees of this variety and apparently
well sustained on the original tree.

Form.

Oval, quite elongated and decidedly symmetrical. Base and apex of
equal breadth, very obtusely pointed at both ends.
12—231

290 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

FIQ. 68. — Prolific walnut, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 291

Surface.

Quite smooth, with several quite conspicuous longitudinal seams or
grooves which give the variety a characteristic appearance.

Color.

Dull light brown, requiring bleaching for the best appearance.

Uniformity.

Quite strong, both in size, shape and surface.

Cracking Quality.

Poorly sealed at the apex, so that the nuts open easily.

Pellicle.

Amber to dark brown, or in many cases nearly black after exposure
to rain. The weakest quality of this variety.

Meat.

Decidedly plump and well filled, averaging a full 50 per cent. Equal
to the best in this respect.

Flavor.

Mild and pleasant. Sometimes rather musty after exposure to rain.

TREE.
Foliation Period.

Early. Not later than the average of the Santa Barbara Soft Shell
seedlings.

Growth.

Fairly vigorous, with a strong tendency toward the formation of
fruiting wood, making a low, spreading tree, with a few straggling,
upward-growing leaders. Very numerous fruit spurs develop all over
the tree as soon as it is established in the orchard.

Foliage.

Abundant and thrifty.

Harvest Season.

Early.

Precocity.

The strongest of any well tested variety. During the first ten years
in the orchard will probably produce at least twice as many nuts as any
other southern variety and many times more than any of the French
varieties or their derivatives.

Production in Older Trees.

The original tree of this variety stood in a grove of Santa Barbara
Soft Shell seedlings and was not selected as being a tree of unusually
heavy production. The chief merit of the Prolific in regard to produc-
tion appears to be its decided tendency toward heavy bearing from
about the third to the tenth year in the orchard as compared to other
varieties. Mr. Ware's grove averaged about 20 pounds of nuts per tree

292 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

the fifth year and 1,000 pounds of dried nuts per acre in the sixth
season after planting in the orchard, which crops may be considered ex-
tremely satisfactory. A tree of our own, likewise in its sixth year,

FIG. 69. — Prolific walnut, natural size.

produced 35 pounds of nuts, whereas our best Placentia Perfection
of the same age and nearly twice as large as the Prolific tree produced

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

293

FIG. 70.— Four-year-old Prolific walnut tree. Note abundant fruit spurs.

294

UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

less than 20 pounds. The heavy, early bearing of this variety is well
established.

Susceptibility to Blight and Other Troubles.

This variety has no particular resistance to blight but is affected by
the disease as badly as the average of our soft-shell seedlings. It is also
of about average quality as regards sunburn and other injurious in-
fluences.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 295

GENERAL REMARKS.

The Prolific is worthy of special consideration on account of its
marked precocity in bearing. This does not mean simply the production
of a few nuts by trees in the nursery or soon after planting, but more
than this it is well established that this variety will come into commercial
bearing within three years after planting in the orchard and by the
sixth or seventh year will turn off as many nuts as may be reasonably
expected from old, mature trees of some of our most prominent varieties.
The nut is of excellent size and shape, but badly handicapped on account
of its poor sealing, dark colored meat and susceptibility to blight. On
these accounts it cannot be considered an ideal variety for permanent
planting. It is particularly worthy of consideration for interplanting
with such varieties as the Franquette, Eureka, or even Placentia Per-
fection. It should, however, be remembered that for the northern part
of the State the variety has not been tested and therefore its adaptability
for interplanting with Franquette in that region cannot be positively
stated. If its quality of heavy, early bearing is carried out in the north
as in the south there is no question that this variety would pay all
expenses, including the purchase price of the land, while Franquette was
coming into bearing.

SAN JOSE.

(San Jose Mayette; Wiltz.)
Origin.

This is a Mayette seedling propagated by Felix Gillet and planted
near San Jose some years ago. The variety was first taken up by Mr.
Rudolph Wiltz of San Jose and afterward extensively advertised and
sold by Mr. Leonard Coates. One of the first public notices of the
variety is found in the Pacific Rural Press of January 26, 1907, where
Mr. Wiltz gives the name San Jose to this variety. Mr. Gillet also has
an article in the same number upon the same subject.

NUT.

Size.

Large; decidedly above the average of most varieties, although not
of abnormally large size.

Form.

Rounded, oval, slightly elongated, very symmetrical.

Surface.

Quite smooth, with rather few quite conspicuous seams and veins.

Color.

Bright yellow tan. Unusually light and attractive without bleaching.

Uniformity.

Strong. Nuts easy to identify by their shape, size and color.

296 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

A/i

FIG. 72. — San Jose walnut, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

297

FIG. 73. — San Jose walnut, natural size.

298 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Cracking Quality.

Nuts poorly sealed and very thin shelled, opening easily in the fingers.

Pellicle.

Light colored and attractive.

Meat.

Rather small in proportion to the shell and poorly developed.

Flavor.

Mild. Not pronounced.

TREE.
Foliation period.

Quite late, but earlier than Franquette.

Growth.

Slow and not particularly vigorous.

Foliage.

Rather sparse.

Harvest Season.

Medium.

Precocity.

Not well tested.

Production in Older Trees.

No information is available upon this point, except that obtained from
Mr. Wiltz' place where the trees are of various ages and top-worked on
black walnuts of various sizes. It is evident, however, that the variety
is not a heavy bearer.

Susceptibility to Blight and Other Troubles.

The San Jose has not been widely tested in this respect, yet its
behavior in respect to blight can probably be accurately estimated on
account of the favorable conditions for disease in the locality where the
variety originated. On Mr. Wiltz' place it appears to be decidedly free
from blight, even compared with the Franquette which is later in coming
out. We have little doubt but that the San Jose will prove decidedly
free from blight in any portion of the State. As regards sunburn and
other unfavorable climatic and soil influences, the variety is rather less
promising on account of its slow growth and sparse foliage. The nuts
are quite susceptible to perforation.

GENERAL REMARKS.

It is to be said to the credit of the San Jose variety that it is without
doubt the most attractive and handsome of any walnut which has thus
far been brought forward in California. Its large size, pleasing shape,
and particularly its bright, yellowish-tan color, even when not bleached
or even washed, makes it a most attractive nut and one which is in-
variably selected at first sight from all others, when in their natural

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 299

condition. For a few, extra handsome walnuts of average quality we
have no variety at present equal to this. As a commercial nut, however,
little more can be said in its favor. The tree is of slow growth and
scanty foliage, a light producer, and the nuts are extremely light in
proportion to their size, poorly sealed, susceptible to perforation or
poorly formed shells, and with small, poorly developed meats.

OPINION OF AN EXPERT WALNUT BUYER.

Samples of all these varieties were submitted to the head buyer for
one of the largest fancy grocery firms in California for his opinion as to
their relative merits. This gentleman had already expressed himself in
regard to the Placentia as follows: "The nut we have found most sat-
isfactory is the Placentia. This variety combines good size, handsome
appearance, good quality, good color and full meat." There would be
little question of the all-round superiority of this variety over any other,
for southern California at least, were it not for its blighting and poor
sealing qualities. Fair samples of the following varieties were submitted
to the expert, each under number rather than by name: 1, Eureka;
2, Franquette; 4, San Jose; 5, Concord; 6, Disher's Prolific; 7, Chase;
8, El Monte. His opinion follows: "Numbers 1, 2 and 8 are the finest
nuts in the assortment, although it is very difficult to say which might
be the best of the three for the reason that all possess some qualities
which the others lack. For instance : No. 1 has a very handsome shell,
a good fat kernel with exceptionally fine flavor, but the meats tend
slightly toward a brown shade. No. 2 has a handsome shell but the
kernel is not so fat as in No. 1, although the color of the meat is very
good and the flavor excellent. No. 8 is not so handsome in appearance
but the kernel is fat with good flavor but meat slightly brown. We
believe, taking all things into consideration, that No. 1 has the most good
points and if this variety bears well it would undoubtedly be a big
success. No. 4 has the advantage of a thin shell, although this tends to
perforation and we notice that the shell is not well filled, although the
meat has a good appearance and flavor. No. 5 can hardly be compared
with the others. This nut is more like the ordinary seedling nut which
has been on the market for many years, although of a better quality
than the average. No. 6 we find very similar to No. 1. This nut is very
symmetrical in appearance, having a full, fat kernel but not quite so
good a flavor as No. 1, while the meat is quite brown. No. 7 is good as
far as size and quality of meat is concerned but in appearance not so
good and the meat is too dark. Now to take all things into considera-
tion, we would rate these nuts in the following way : Nos. 1, 2, 8, 6, 4, 7,
5." It should be understood that this gentleman passed simply on the
quality of the nuts, without considering the producing or other quali-
ties of the tree.

300

UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

Size and weight of average specimens of principal walnut varieties. Weight in grams.
Volume in cubic centimeters. Dimensions in inches.

Variety.

Weight.

Volume.

Dimensions.

Number
per
pound.

Per cent
meat.

Specific
gravity.

Chase

12

19

.5 by 1.2 by 1.35

38

47

63

Concord _

11

17.5

.45 by 1 2 by 1.3

42

50

63

El Monte

14 5

22

7 by 1 4 by 1 4

32

50

60

Eureka -

14 5

22

75 by 1 25 by 1 3

32

47

66

Franquette

12

20

.75 by 1.25 by 1.3

38

46

60

Mayette* ___

13.5

21

.6 by 1.25 by 1.25

34

50

63

Neff _ _.

14.5

21.5

1.7 by 1.3 by 1.4

32

47

67 5

Placentia

10.8

19

1.6 by 1.2 by 1 3

43

50+

57

Prolific

12

20

1.7 by 1 3 by 1 35

38

50+

60

San Jose

11 1

25

1 75 by 14 by 1 5

41

46

44.5

A. Bijou

25

50

2.25 by 1.5 by 2

18

35

50

Seedling No. 3

13

18

1.5 by 1.2 by 1.3

35

50

72

Seedling No. 2

11

18

1.5 by 1.2 by 1.3

41

55

60

*These samples may have been a little heavier than the average.

In the above table a very careful effort has been made to present
average statistics of the varieties given. The reader should know, how-
ever, that this is an extremely difficult thing to do, since some of the
varieties mentioned perform differently in one part of the State than
in another, and, furthermore, nuts of the same variety vary widely on
trees of different ages and under various conditions in the same locality.
Again, especially, in regard to weight and specific gravity, walnuts
vary to a considerable extent from year to year. For absolutely
average statistics, sample nuts would be necessary from various parts
of the State from trees of various ages and on different types of soil
and from the crops of several different seasons. It is impossible to
obtain such samples at the present time in the case of practically all
the varieties mentioned. The best that we can do is to present what
in our judgment and as a result of our experience are fair, average
figures for these varieties. We have endeavored particularly to bring
out the comparative size and weight of the different varieties and
believe that the figures given are fair and representative in this respect.
The figures given were obtained as follows:

Weight. — Average weights were obtained by weighing large num-
bers of nuts, especially in the case of the more prominent varieties, and
averaging these. In most cases nuts of more than one season's crop
were included. Many weighings were also made by picking out indi-
vidual nuts of average size and weighing these.

Volume. — The volume was obtained by partly filling a graduated
cylinder with water, then immersing a given number of nuts and not-
ing the height to which the column of water rose in the cylinder. The
increase was then divided by the number of nuts, giving the average
volume per nut in cubic centimeters. Here, again, large numbers of

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 301

nuts were measured in some cases and the results then averaged, while
again an effort was made to pick out single nuts of average size and
these were measured by the same method. It should be clearly under-
stood in regard both to weight and volume that many nuts of the varie-
ties mentioned are larger than these figures indicate and others are
smaller. The figures are intended to represent the average size which
the grower may expect to obtain from trees of these varieties over a
series of years. It will be noted that size and weight are not always
proportionate. San Jose, for instance, is about the same weight as
Concord, but nearly 50 per cent larger.

Dimensions.— The dimensions were obtained by picking out nuts of
average size and measuring the length of their three axes, first longi-
tudinally, second through the shorter diameter and third at right angles
to the last through the longer diameter.

Number per Pound. — This figure is intended to represent the aver-
age number of nuts per pound, as they would average in large quan-
tities and without grading as to size.

Percentage Meat. — This figure represents the percentage of meat in
the total weight of the nut. For instance, in the first variety given,
Chase, there would be 47 pounds of meat and 53 pounds of shell in 100
pounds of nuts. The percentage of meat varies somewhat according to
the degree of dryness of the nut. It is, therefore, impossible to give
definite figures in this respect without some standard as to the dryness or
moisture content. Nuts of the same variety may vary nearly 10 per
cent in the amount of meat, according to the age and moisture content
of the samples. After the first drying out of the nuts, however, fol-
lowing the harvest season and before they have become extremely dry,
that is during the period from about December 15th to March 1st fol-
lowing the gathering of the nuts, they have a fairly constant weight
when kept constantly dry at room temperature. This is the basis upon
which the figures given are calculated. In each of the varieties given
the percentage of meat sometimes runs higher and sometimes lower
than the figures given, but these represent as nearly as possible aver-
age figures and we believe them to be accurate on a comparative basis
between one variety and another. In weighing the meat and shell
everything except the meat proper, that is particularly the septa or
partitions between the divisions of the meat, is included with the shell.

It will be noted that in all the good varieties the percentage of meat
lies between 45 and a little over 50. A variety which averages less
than 45 per cent of meat in fairly dry nuts can hardly be considered
worthy of consideration, while one which runs over 50 per cent is
exceptional. The comparative percentage of meat in various varieties

302 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

FIG. 74. — Neff walnut, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 303

is influenced largely by the actual weight of the meat and shell; some
varieties have a good meat, but also a heavy shell, while others may
have no more or even less meat per nut, but a rather lighter shell, giv-
ing a higher percentage to a variety with less meat. Eureka and Neff,
for instance, have 47 per cent meat against 50 per cent or more in
Placentia. The two former varieties, however, average only 32 nuts to
the pound, while with Placentia it takes an average of 43 to make a
pound. In other words, in one average Eureka nut there is about 7
grams of meat, while in a Placentia nut there is only 5.4 grams,
although the two nuts are of nearly equal size. Varieties like Eureka,
Neff and El Monte have heavy shells, as well as heavy meats, and the
same is true to a considerable extent with Chase, Franquette and Pro-
lific. This condition is indicated by the high specific gravity of these
varieties.

An instructive comparison is afforded by the figures given at the
end of the table for Seedlings No. 1 and No. 2. These nuts average
exactly the same size, both in volume and dimensions, but No. 1 is
considerably heavier than No. 2, the number of nuts per pound being
respectively 35 and 41. No. 1 is a nut of exceptional weight both of
meat and shell, being of only medium size, yet one of the heaviest
varieties in the list and at the same time having 50 per cent meat. Its
specific gravity, 72, is the highest of any nut which we have tested, yet
it is a soft shell and easily cracked in the fingers, though well sealed.
Seedling No. 2, of the same size but lighter weight than No. 1, is a nut
of exceptionally heavy meat ( 55 per cent) and very light, weak shell.
On the latter account it is probably worthless, commercially, although
of such exceptionally good meat.

Specific Gravity. — This figure is obtained by dividing the weight in
grams by the volume in cubic centimeters. This represents the com-
parative weight of nuts of the same volume or size in the different vari-
eties. For instance, with Chase and Placentia, which are practically
of the same size, the weight of sacks of nuts of equal size would be as
63 to 57 in favor of Chase, while the number of nuts would be the same.
Chase and Concord having the same specific gravity, 63, would weigh
alike in sacks of the same size, but it would take more Concord than
Chase nuts to fill the sack in the proportion of 19 to 17.5. Comparing
the Eureka and San Jose, sacks of equal size would weigh 66 pounds
of Eureka to every 44.5 pounds of San Jose, while at the same time
there would be more Eureka nuts in the sack in the proportion of 25
to 22. Comparing Eureka with Franquette, the weights of sacks of
equal size would be as 66 to 60, with the size of the nuts and, there-
fore, the number of nuts per sack about the same. The most desirable
qualities are high specific gravity, fairly large size, small number per
pound and high percentage of meat.

304 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

FIG. 75. — El Monte walnuts, natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA, 305

MISCELLANEOUS AND LESS PROMINENT VARIETIES.

The following is intended to complete as fully as possible a list and
description of all the walnut varieties of any importance in California.
Many of them are old French varieties which have not proven worthy
of extensive commercial planting. Others are varieties not yet fully
tested and most of the remainder have been discarded or never become
prominent for various reasons. Bearing trees of most of the varieties
in this list which are of any importance may be found in the State.
At the California Nursery Company, Niles, there is a collection of most
of the French and some other varieties; S. F. and F. A. Leib, of San
Jose, have a large miscellaneous collection; Mr. Ely Hutchinson, of
Concord, has a great many in bearing ; Dr. W. W. Fitzgerald, of Stock-
ton, has younger trees of many different kinds, and there are various
other places in the north where, collectively, authentic specimens may
be found of bearing trees of almost all the varieties which we mention.
In the San Joaquin Valley the Fancher Creek Nursery Company has
bearing trees of a number of varieties. In the south there are several
of the French varieties on the old Experiment Station grounds near
Pomona, and our Whittier Laboratory has a collection of practically
every important variety growing either at Whittier or on the Pasadena
City farm near Alhambra.

ACME.

Introduced by F. C. Willson, of Sunnyvale, California, in 1910. An
extra large nut of Bijou origin. The nut is fairly smooth, rather elon-
gated, larger at the apex than at the base and almost square in end
view. The shell is quite heavy and fairly well filled with meat, which
forms less than 40 per cent of the total weight. The variety is not
apparently of any special value for general commercial purposes.

BARTHERA.

Introduced from France by Felix Gillet in 1871. Of no apparent
value in California.

A BIJOU (Gant).

A French variety, noteworthy for the extremely large size of the
nuts. Nuts very rough and poorly filled with meat and of no commercial
value, save as a curiosity. Bearing trees are quite abundant in the
State. Numerous Bijou seedlings are to be found in California, many
of which have much smoother and better nuts than those of the parent.
See "Acme," "Klondyke," and " Wonder."

13—231

306

UNIVERSITY OP CALIFORNIA — EXPERIMENT STATION.

Fia 76.— Various walnut varieties. A, Meylan ; B, Mayette ; C, Hale; D, Kaghazi
E, Seedling 501 ; F, Acme ; G, Bijou. Natural size.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 307

BISHOP.

We designate by this name a tree of some local fame, which stands
on the Bishop, formerly the Colonel Hollister and still earlier the Denn
Ranch, north of Goleta in Santa Barbara County. This tree is upwards
of forty years old, and is the one remaining survivor of a former plant-
ing, now surrounded by a young orchard composed of its own seedlings.
The tree is said to have been grown from a French nut and is called
locally a Grenoble tree. It is a large, heavy-bearing tree, coming out
decidedly late in the spring and practically free from blight. The nuts
are not particularly attractive, though of average quality. The tree
is not extremely late, but would probably come out about with Con-
cord and Eureka if grown in the same locality. We doubt whether the
nut is good enough to make the propagation of this tree desirable as a
special variety, by grafting, although its good bearing qualities and
freedom from blight are valuable characteristics. Many nuts from this
tree have been planted by Mr. Robert Main, superintendent of the
ranch, and in this way a local seedling strain has been developed, called
the Main nut. There is a large orchard of these seedlings on the Bishop
place surrounding the old tree, Mr. Main has a number of acres of
them on his home place at Goleta, and there are others scattered about
the neighborhood. Many of these are now old enough to bear consid-
erable crops. It is remarkable that the seedlings of this comparatively
late and blight-free tree have proved almost without exception to be
early in coming out and particularly susceptible to blight. The tree
has apparently been crossed by the surrounding Santa Barbara Soft
Shell seedlings, or in any event almost all of its own seedlings come out
decidedly early in the spring and blight very badly. Only one of the
seedlings of this tree has yet been found which shows any promise of
freedom from blight. This is the so-called Hicks tree, growing on Mr.
William Hicks' place, between Santa Barbara and Goleta. This par-
ticular tree comes out early in the spring, but has thus far been quite
free from blight, although surrounded by badly affected trees. It bears
a nut of rather rough shape, but well filled, well sealed, light colored
meat, good size and excellent flavor.

There is reason to hope that among the seedlings of the old Bishop
tree there may yet be found some particularly good and blight-free
individuals.

CHABERTE.

An old French variety which was introduced into California by
Felix Gillet and considerably planted in the central and northern part
of the State some years ago. The tree is a good producer of small nuts
with plump, light colored meat. Not worthy of commercial planting
in California.

308

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

CLUSTER.

One of Felix Gillet's varieties, introduced by him from France, and
so named on account of the habit of producing nuts in large clusters.
Not commercially important.

EL MONTE (El Monte Large).

A Santa Barbara Soft Shell seedling from the vicinity of El Monte,
which has been propagated locally in southern California to some

FIG. 77. — Willson walnut, showing young tree next year after transplanting.

extent. The variety appears to be worthy of some little consideration
although we have not much definite information concerning it. It is a
large, quite rough, somewhat irregularly shaped nut, with pronounced
sutural ridges and a decided beak or short, sharp point at the apex. The
nuts are well sealed and filled with fairly light colored meat of pleasant
flavor. The tree is a decidedly precocious bearer and thrifty grower.

BULLETIN 231] WALNUT CULTUBE IN CALIFORNIA. 309

It is early in foliation and harvest period, with probably no particular
blight resistance, although definite information is lacking on this point.
The large, well-filled nut and precocious bearing of the tree make this
variety rather promising.

EUREKA No. 2.

Another of the Stone Kaghazi seedlings, standing just west of the
original Eureka tree. Mr. Ware has six-year-old trees of this. It
is a large, full-meated nut, a little rougher, softer-shelled and darker-
meated than the Eureka.

FORD'S IMPROVED.

A selection from the Santa Barbara Soft Shell introduced by G. "W.
Ford, of Santa Ana. This variety appears to have been propagated
largely by seedlings, and has now become almost lost, or at any rate
it is no longer planted or propagated under the above name.

FORD'S EUREKA.

A Santa Barbara Soft Shell selection. Obsolete.

GRENOBLE.

A general name applied in California to walnuts of French origin.
The name is supposed to indicate the Mayette type to some extent.

HALE.

A variety named and propagated to some extent by the Experiment
Station, originating in a seedling tree in the orchard of Mr. William
Hale, between Fullerton and Placentia. The variety was first men-
tioned by name in Bulletin 203 of the California Experiment Station,
where it is figured on page 25. In this orchard there was formerly
a considerable block of seedlings of some French variety, the trees of
which varied widely in size, foliation period and character of the nuts.
Among these one particular tree was selected as being of some promise
for commercial planting. This tree was medium late in coming out,
free from blight, large and thrifty, and a fairly heavy producer. A
considerable amount of top-grafting with this variety was done on
orchard trees in Los Angeles and Orange counties about 1907 and
1908. When thus propagated the variety proved to be fairly quick
in coming into bearing, but of rather slow growth, making very stocky
branches with considerable tendency toward the production of fruiting
wood, but of rather short annual growth in length. The variet}T, like
all others with a late foliation period in the spring, has not fully
established its value in the south, but it may yet become of commercial
importance in some portions of the State. The original tree, together

310 UNIVERSITY OP CALIFORNIA — EXPERIMENT STATION.

with the whole grove in which it stood, was cut down in 1911 to make
way for oranges. The nut is medium large, decidedly elongated, with
the apex as broad as the base. Considerably like Franquette (of which
it may be a seedling) in form and size, but broader and less pointed
at the apex. The nuts are strongly sealed but easily cracked, with a
light-colored meat which is usually plump and well filled, with a par-
ticularly sweet and agreeable flavor. This is the sweetest nut of any
variety which we have tested.

The value of this variety for commercial planting has not been thor-
oughly established, and we do not wish to recommend it for such
purposes at present. It is possible, however, that it may prove worthy,
especially in the north. The nut is quite similar to that of the Fran-
quette, but slightly inferior to it in some respects. Judging from the
original tree, however, it may prove a heavier and more precocious
bearer than the Franquette. It is late enough in the spring to escape
frost, decidedly free from blight and not objectionably late in the fall.
Its foliation and harvest season is much the same as that of Concord
and Eureka. We recommend this variety for limited trial, more par-
ticularly in the north.

HICKS (see Bishop).

HILDEBRAND (see Mayette).

KAGHAZI.

This is a name occasionally heard in California in connection with
walnut varieties and is supposed to denote a variety native to Persia.
In an article quoted from the Gardners' Chronicle in the Rural Cali-
fornian, No. 9, Vol. 19, September, 1896, we find the following state-
ment : ' ' The Persian walnut is about a third or a half larger than the
English walnut ; of an elongated shape, with a very rich meat or kernel
and a shell as thin as paper. It is not an unusual thing for a tree
eight to twelve years old to bear 30,000 nuts or 1200 pounds. " * * *
11 There are four kinds, the Kanate, the Wanter, the Denu and the
Kaghazi, the last of which is the finest nut grown. ' '

In Fuller's "Nut Culturist" we find the following: t( Kaghazi.— This
is supposed to be a variety of the Persian walnut of fair size with a
very thin shell. The tree blooms very late in the spring, and for this
reason is recommended for localities where there is danger from injuries
by frost. The tree is said to be a very rapid grower and much more
hardy than the general run of varieties of this species. We have been
unable to learn its origin, but it has been planted to quite an extent in
California and some of our eastern nurserymen are offering the seedling
trees for sale, but whether they will possess the merits of the original
or not must be determined by experience."

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 311

In Wickson's "California Fruits," we find the following: "Kaghazi:
A variety called Kaghazi was grown and propagated for several years
by the late James Shinn of Niles, who described it is follows: 'very
much larger than the ordinary kinds and thinner shelled. The tree is
late in putting out leaves and blossoms, and is therefore especially good
for places that are in danger of late frosts. ' :

It appears from the above quotations that the Kaghazi is an extra
large, elongated, extremely thin-shelled nut, borne on a tree which
comes out late in the spring. The variety would have no particular
importance in California at the present time were it not for its apparent
relation to the Eureka, the parent tree of which resembles very closely
the above description of the Kaghazi. We have mentioned in describing
the Eureka the fact that the original tree at Fullerton was found to
be a seedling from a still older tree standing on the Meek homestead
near Haywards. The particular tree which is the mother of the Eureka
is the southernmost one of two which stand just east of the Meek resi-
dence. This old tree bears an unusually large, long, extremely thin-
shelled nut, coinciding exactly with the description of the Kaghazi.
In regard to the origin of this tree, Mr. H. W. Meek, now deceased,
made the following statement : ' ' All I know about these trees is that a
neighbor of my father's gave him a few walnuts a number of years ago
which he claimed he had received from the United States representative
in Persia. My father planted the nuts, and the two trees which I have
at present are the result. I do not know whether the walnut propa-
gated by the late James Shinn has anything to do with the trees or
variety which I have growing here. The Stones of Fullerton have some
trees growing from the nuts from my trees here, but I have never heard
how they turned out." In regard to the Shinn trees, Mr. J. C. Shinn
states as follows: "The Persian walnuts we have possibly came from
the same party referred to in a letter from Mr. Rixford which I enclose,
though my memory is that they came from some one in Illinois who had
tried trees raised from nuts direct from Persia and found them too
tender. They were bought about the year mentioned by Mr. Rixford.
The late James Shinn bought, as he understood, the whole stock of the
party who brought the nuts over. The party sent a few nuts as a
sample and they were a very large, thin-shelled nut. There had been
some report in a United States agricultural report about that time that
had aroused his interest. "We sold many seedling trees, much seed for
planting, and later quite a number of grafted trees of the Persian or
Kaghazi walnut. There must be thousands of bearing trees in the State
from those we sold." The letter from Mr. Rixford, referred to, states
as follows : "In September, 1873, Mr. Finch of Alameda ordered from
Rosse & Grant, Topeka, Kansas, fifty Persian or Kaghazi walnut trees.

312 UNIVERSITY OF CALIFORNIA— -EXPERIMENT STATION.

The stock being short, he secured but thirty-six. Of these he sold to
Mr. Latham ten at ten dollars each,, to Mr. Selby two, to J. D. Roberts
four, and to Mr. Meek of Alameda twelve. Rosse •& Grant claim to have
obtained the seed from the Cashmere Valley, Persia. ' '* Further inquiry
of Mr. Shinn in regard to the parties mentioned in this letter brought
out further information in regard to the extensive scale upon which
Kaghazi trees, mostly seedlings, were sold by his father during the
eighties and nineties.

It is evident from what we have said that this is a fairly distinct
variety, and that, if Mr. H. "W. Meek's memory was correct, it was
introduced independently into California by his father, William Meek,
and the late James Shinn. Trees are still to be found here and there
about the State which are evidently of this sort. There are several long
rows of the seedlings on the old Meek place, some extending from the
residence toward the town of Hay wards and others along various other
roads. There are a number of trees of similar nature in Contra Costa,
and in that locality one particular type of this sort has been quite
extensively propagated by grafting under the name of Persian. A large
number of the older, top-grafted walnut trees in the San Ramon and
other valleys in the Mount Diablo country are of this so-called Persian
variety. There is quite a number of trees of Kaghazi type in the
vicinity of the Shinn place at Niles and also about the Niles High School
and vicinity. Near Goleta there is a considerable orchard of similar
seedlings on the ranch of the Goleta Walnut Company. These trees
vary quite widely in many respectsz but as a whole they are marked by a
late and irregular coming out in the spring and the peculiar appearance
of the bark on the trunk, which is cracked or grooved characteristically
in an up and down direction. A great many of the trees bear nuts
which are extremely thin-shelled and poorly sealed, and some of them
are quite desirable except for this defect. Some of them are nuts of the
highest eating quality, of fine shape and beautiful, light-colored shell
and meat, but with shells which open at the slightest pressure of the
fingers. It is remarkable that of the many hundreds and thousands of
seedlings of the Kaghazi type which have been brought into bearing in
California only one, the Eureka, has shown exceptional worth. It seems
probable that this is the result of a cross of the original Meek Kaghazi
tree with some hard-shelled English walnut in the vicinity, as the shell
of the Eureka is particularly hard, strong, and well sealed.

"The Kashmir Valley lies just northwest of India rather than in Persia, and is,
we are credibly informed, the home of the Kaghazi walnut.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. : , 313

KEESLING.

A rather promising walnut has recently been, sent us by Mr. H. G.
Keesling, of San Jose. This is the variety called Seedling No. 2 in the
table on page 300. The nut is particularly well filled, of good quality,
and has the highest specific gravity of any which we have mentioned.
We know nothing of the bearing quality or other characteristics of the
tree.

KLONDYKE.

A name applied in southern California to very large walnuts of the
Bijou type. The name seems first to have been given to a particular
tree of this sort in the vicinity of Santa Ana.

LAC1NIATED.

A variety introduced by Felix Gillet, having finely cut or divided
leaves, giving an ornamental effect. Not commercially important,
although the tree is a good bearer of very good nuts. The tree is
decidedly ornamental on account of its graceful foliage. Specimen
tree at California Nursery Company, Niles.

LANE.

This is a local Santa Barbara variety which has been propagated by
grafting to a slight extent in that vicinity. The variety receives its
name from Mr. Miles P. Lane who has a young grafted tree, the scions
having been obtained from Mr. W. H. Johnson, on whose ranch the
original tree is growing. The latter is a Santa Barbara County seedling
of unknown parentage. The variety is decidedly early in coming out
in the spring, but yet, as thus far shown, it is entirely free from blight,
although immediately surrounded by badly blighted trees in the same
orchard. The nut is of light color and heavy, well flavored, light colored
meat. The tree appears to be a prolific and precocious bearer. It has
much promise of making an unusually good variety, save for the one
fact that the nuts are very poorly sealed, breaking open at the slightest
pressure. For this reason there is some doubt whether this can be con-
sidered a good commercial nut. It appears to have real resistance to
the blight organism, inasmuch as the trees come out so early and still
. are free from the disease, though abundantly exposed. This variety is
the Seedling No. 1 mentioned in the table on page 300.

MAIN (see Bishop).
MAYETTE.

This is an old French variety and is considered the choicest of the
French kinds.

The Mayette in California varies quite widely in character and leads
one to suppose that either there has been considerable mixing in the

314 UNIVERSITY OP CALIFORNIA — EXPERIMENT STATION.

introduction of this variety or else the Mayette in France represents a
general type propagated largely by seedlings, like our Santa Barbara
Soft Shell, rather than a distinct variety propagated exclusively by bud-
ding or grafting. Most of the so-called Mayettes in California have a
general resemblance to one another and appear to be seedlings or deriva-
tives of the same general type.

The variety is characterized by the shape of the nut. In the true
Mayette type the base of the nut is decidedly flat and square-cut, so that
the nut can easily be set upon the basal end without falling over. The
nut rounds broadly to a point at the other end, giving it a sort of flat-
iron shape. In good Mayettes the meat is plump and well developed,
averaging close to 50 per cent of the total weight, and very light colored
and attractive. In flavor there is considerable variation in various
Mayette types found in this State, but the best of these are excellent in
this respect. The shell is thin but strong and well sealed. The Mayette
is a tree of comparatively late coming-out in the spring, though usually
somewhat earlier than the Franquette. It is decidedly later than the
southern California seedling trees. In most cases the time of maturity
in the fall is fairly early as compared with late varieties, though some-
what later than ordinary California seedlings. Of the so-called Mayettes
to be found in California some have no resemblance whatever to this
variety and need not be considered. Among those which have the true
flatiron shape Mayette type of nut, with a flat base upon which the
nut can easily be set up, there is still considerable variation. Of the
older trees which are attributed to Felix Gillet, many are evidently
seedlings and thus vary to a greater or less extent. No especially desir-
able true Mayette type has thus far appeared among the older Gillet
trees. Probably the best Mayettes in the State are to be found on S. F.
Leib's place at San Jose, these being trees grown from a large lot of
scions which Judge Leib imported from France about five years ago. In
this importation an effort was made to obtain the best type of the true
French Mayette, but among the trees grown from these scions wide
variations have appeared. Some of these trees, however, represent,
as we have said, what appears to be the best Mayette type in the State.
These are large, smooth, light colored, attractive looking nuts of typical
shape. They are well filled with very light colored meat of excellent
flavor. The growth appears to be more vigorous than that of the Fran-
quette. It is not improbable that had a Mayette type as good as this
been introduced and planted on a large scale a number of years ago, it
might have proved as good or even better than the Franquette. Under
existing circumstances, however, it is not possible to judge the variety
critically as to production and other important considerations. Mr.
Ely Hutchinson, at Concord, has a number of trees of a Gillet Mayette

BULLETIN 231] WALNUT CUL1URE IN CALIFORNIA. 315

with which he has been quite well satisfied and which he is inclined to
put ahead of the Franquette for his locality at least. On the former
Kerr ranch near Elk Grove, now belonging to a Mr. Powell, there is a
valuable collection of fairly old, producing walnut trees top-grafted on
California blacks, which originated from scions which Mr. Kerr imported
from France a number of years ago. There are trees here of the
Parisienne, Franquette and some other varieties, and also a considerable
number of Mayettes of a very good type. This Mayette has received
more or less prominence through Tribble Brothers of Elk Grove, who
have propagated it to a considerable extent. There is some variation
between the various Mayette trees on the place, but this may be largely
accounted for by differences in soil and moisture conditions where the
various trees stand. This Tribble Mayette is the best tested of any in
California, and appears to have no little merit. The trees are growing
in a region with a very hot, sunny, summer climate, and various speci-
mens may be seen about Elk Grove which are growing over shallow
hardpan and entirely without irrigation. Nevertheless the nuts are
uniformly white meated, with no discoloration by the sun, and the trees
are thrifty growers and fairly heavy producers. Another tree, appar-
ently a Mayette seedling, is the so-called Hildebrand tree which stands
on the ranch of this name a few miles above Linden and not far below
Milton in Calaveras County on the south fork of the Calaveras River.
It is said that this tree came from a nut distributed by Mr. J. P. Rixford,
then of the San Francisco Bulletin, in 1878. In an article in the Pacific
Rural Press of April 17, 1909, the suggestion is made that this tree
is probably of the Kaghazi variety. Such is probably not the case,
however, as the character of the nut gives every reason to suppose that
the tree is a Mayette seedling. The tree is unusually large, being 70
feet high with a spread of about 60 feet, and is in a perfectly thrifty
condition with no sign of die-back or deterioration. During recent years
the tree is said to have produced from 300 to 500 pounds of nuts per
year. The nut is of fairly good Mayette type, but not of exceptional
quality. It is possibly of some promise on account of its freedom from
sunburn, as the tree is growing in a very hot region. It is also unusually
thrifty, although this is partly accounted for by the fact that the tree
stands alone in excellent soil. We have two Mayette trees on our own
grounds which were imported from France as grafted trees by Felix
Gillet in 1907. These trees are just coming into bearing and have pro-
duced nuts which appear to be of an excellent Mayette type.

In general, then, we may say of the Mayette that it is very much
mixed in this State, and outside of one or two special strains, the grower
has very little assurance of what he is getting in buying Mayette trees.
The best type of the variety is represented by a nut of very high quality,

316 UNIVERSITY OF CALIFORNIA— EXPERIMENT STATION.

and it is possible that such a Mayette may become of increased impor-
tance in the future in the northern part of the State, even outranking
the Frariquette. It does 'not appear probable, however, that any of our
Mayettes are especially heavy bearers in the south, and it is doubtful
whether any variety as late as this will ever become of great importance
or value there.

MAYETTE BLANC.

This name is supposed to indicate the true Mayette.

MAYETTE ROUGE.

A variety supposed to be a variation of the Mayette, with a reddish
colored shell. Not commercially important.

MESANGE.

A French variety described as bearing a nut with a very thin shell.
The name is derived from a little lark which pecks the kernels through
the thin, tender shell. Not important.

MEYLAN.

A French variety having the reputation of being the finest of all
walnuts. The nut is somewhat of the Mayette type, having a broad,
rather flattened base, rounding to a very broad point at the other end.
The surface is smooth, having a light, attractive color. Meat very light
colored and fairly well filled. Good flavor. This variety in California
is probably not a sufficiently heavy bearer to warrant its commercial
planting, although the nut is beautiful in appearance and of high
quality.

MONSTREUSE.

A French variety of which there is a tree in bearing at the California
Nursery Company, Niles. Never distributed in California to any extent.
The nut is rather large, rounded, with smooth surface and of fine appear-
ance. Probably not commercial in California, but a nut of exceptionally
good appearance.

NEFF (Neff's Prolific.)

A tree selected from his orchard for propagation by Mr. J. B. Neff,
of Anaheim. The original tree stands in Mr. Neff's old orchard and is
presumably a Santa Barbara Soft Shell seedling. Mr. Neff selected
this tree on account of the fact that it was averaging about 200 pounds
of nuts annually, which production far exceeded that of any other tree
in its vicinity. Mr. Neff therefore cut back many of his poorest pro-
ducing trees and grafted them over with scions from this heavy
bearing tree.

The original tree is decidedly free from blight, although not totally
immune to the disease. The nut is of good size, well sealed, excep-

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 317

tionally heavy and well filled with light-colored meat. The flavor of the
nut is good. In form the nuts are rather rough and irregularly shaped,
this being the greatest defect of an otherwise very promising variety.
The shell is heavy, giving the nuts good weight in the sack. The variety
has not been propagated to any extent, save in top-working old trees,
so nothing can be said as to its behavior as a young tree. For a heavy
bearing, heavy weighing variety for the ordinary commercial trade, the
variety has considerable promise. For a fancy, attractive nut, it is
not so good, on account of its rough, irregular shape.

PAPER SHELL.

This is a general name applied to walnuts with exceptionally thin
shells. The name is also applied to a certain type of tree which
originated with Joseph Sexton, of Goleta, along with the original trees
of the Santa Barbara Soft Shell type. These paper shells were so called
from the thinness of the shell, but the name as applied in the Santa
Barbara section refers to a certain type of tree, some of which have real
paper shell nuts, while others do not. These trees are of a characteristic
small size, round dense top, and bear a small, usually roundish, smooth,
light colored nut. Many of them resemble very closely the Chaberte
variety. These typical paper shell trees are decidedly susceptible to
blight, and on account of this quality and the small size of the nuts and
trees the type is not considered desirable.

PARISIENNE.

A French variety introduced by Gillet and others.

This is one of the best of the French varieties and might become com-
mercially important in California except for its light production. The
nut is rather long and pointed, somewhat resembling the Franquette, but
broader in the center. The shell and meat are both light colored; the
nut fairly well filled and of good flavor. Very late in coming out in
the spring.

PERSIAN (see Kaghazi).

POWELL (see Mayette).
PRIDE OF VENTURA.

A Santa Barbara Soft Shell seedling tree selected by E. 0. Tucker
of Ventura, California.

This is said to be a very precocious and heavy bearer, but with no
special immunity to blight. The nut is decidedly large, rather round
and somewhat rough. This variety has been propagated and planted
to some extent in the vicinity of Ventura.

318 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

PRCEPARTURIENS.

A French variety introduced by Gillet, which was planted quite ex-
tensively in central and northern California some years ago. The nut
is rather small and the variety can no longer be considered worthy of
commercial planting.

SANTA BARBARA SOFT SHELL.

This is the prevailing type of seedling walnut of southern Cali-
fornia, originated by Joseph Sexton. Its history has been described at
length on page 173. The trees and the nuts which they bear vary
to a considerable extent among themselves, but yet are mostly of the
same general type. The nuts are usually of good size, easily cracked
in the fingers, and of excellent flavor and quality. The trees come out
fairly early in the spring and usually produce an abundance of pollen.
This type is particularly well adapted to southern California, except for
its susceptibility to walnut blight and the variation in trees produced by
seedling propagation through several generations. Some of the varie-
ties, like Placentia Perfection, Discher's Prolific, Neff, El Monte, Pride
of Ventura and others, obtained by selecting individual trees of this
type, are most excellent in every way except for the susceptibility to
blight or individual minor defects. An ideal variety may yet be found
among the many hundreds of thousands of trees of this type now grow-
ing in southern California.

SANTA ROSA.

A variety first introduced by Luther Burbank and considered at one
time of great promise on account of its productiveness. The nut is
rather small, however, and has proven to be one of the most susceptible
of all varieties to the blight. Consequently, its further planting cannot
be considered advisable. The Payne tree at San Jose is top-worked
with this variety and bears immense crops of nuts.

SEEDLING (see Santa Barbara Soft Shell).

SEROTINA.
A French variety introduced by Gillet. Of no commercial importance.

SOFT SHELL (see Santa Barbara Soft Shell).
TREYVE.

A French variety of the Mayette type introduced by Gillet. But
very little planted in California. This is a beautiful nut, especially on
account of its almost pure white meat. Mr. Ely Hutchinson, of Concord,
has the variety in bearing. Probably not commercially important on
account of poor production.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 319

TRIBBLE (see Mayette).
VOUREY.

A very good French variety introduced by Gillet, but, like most of the
other French varieties, a poor producer in California.

WAGNER.

A Royal hybrid tree which has been progagated, advertised and sold
by Mr. J. B. Wagner, of Pasadena. The tree was recommended for
shade, wood, and timber. The original appears to have been a cross
between the southern California black walnut and an eastern or pos-
sibly Royal black. It is a thrifty, vigorous type, like other good Royals.

WILLSON (Willson's Wonder).

A Bijou derivative propagated by F. C. Willson, of Sunnyvale. The
nuts are very large, but much smoother and better filled than those of
the Bijou. The variety is claimed to be extremely immune to blight
in the locality of its origin. It is also particularly claimed for the
Willson that it is extremely precocious, bearing nuts while still in the
nursery and coming immediately into bearing after planting in the
orchard. Figure 77 shows a young tree of this variety, the picture
being taken, it is said, the next year after the tree was planted
in its present location. The variety has not been widely enough tested
to warrant any strong statement either for or against it. Its precocity
in bearing appears to be well established, and being quite late in coming
out in the spring, its blight immunity may be counted upon to a con-
siderable extent. As to the desirability of so large a nut as this for
general commercial planting, there is some difference of opinion. Some
consider the nut too large except for a novelty; Mr. Willson claims
that the quality of the nut is so excellent that its large size is an ad-
vantage rather than otherwise. It may certainly be said that the
Willson appears to be much the best of any of these extra large nuts.
The flavor is mild and sweet. The nut is decidedly smooth and sym-
metrical for one so large, being somewhat broader at the apex than
at the base and nearly square in end view. The largest nuts on some
trees measure nearly 2 by 3 inches, while on older trees an average size
of perhaps 1J by 2 inches may be expected.

We name this variety "Willson" rather than "Wonder" with the
approval of the originator.

320 UNIVERSITY OF- CALIFORNIA— EXPERIMENT STATION.

DISEASES AFFECTING THE WALNUT.

WALNUT BLIGHT OR BACTERIOSIS.

This is by far the most important trouble affecting the walnut in
California. So serious has been this disease that the loss of a large
portion of the crop has in some years been charged to this source;
legislatures have made special appropriations for its investigation, and
the growers have offered a large reward for a practical remedy. The
ravages attributed to blight were the occasion of the investigations de-
scribed in this bulletin and the prevalence of the disease has resulted
in changing the whole aspect of walnut culture in California within
a period of comparatively few years. The following account has been
prepared mainly by Mr. C. 0. Smith, who has carried out most of this
portion of the work.

The bacterial diseases of plants are more and more engaging the at-
tention of plant pathologists. Most of these have only within recent
years been well understood. At present, however, there are a number
of very definite plant troubles due directly to these micro-organisms
living in plant tissues. One of the most important of this class of
plant troubles is the bacterial blight of the Persian or English walnut.

Bacterial diseases of plants are, as a rule, much more difficult to con-
trol than those caused by fungi, and do not readily yield to treatment
by spraying. Our experiments in spraying will be described in full at
another point in this article, but the unsatisfactory results we secured
in checking the development and spread of the disease show quite con-
clusively that the solution of this problem lies along other lines.
The solution of the trouble is quite as much a horticultural as a phy to-
pathological problem, involving as it does the growing of varieties that
show a certain amount of resistance or in which the nuts escape the
blight because of their late period of blooming in the spring after the
period of blight infection is largely past. The walnut industry is
just now in a state of transition from the seedling orchard to one con-
taining only the best and most productive, non-blighting varieties. A
number of these have been quite thoroughly studied by the Laboratory
of Plant Pathology in southern California and some of our observa-
tions are given in detail in another part of this bulletin.

Host. — The natural occurrence of bacteriosis or walnut blight is
probably confined to the English walnut, or its hybrids with the blacks.
Blighted nuts have been collected from a Paradox walnut tree (a hybrid
of English and California black) and the organism has also been
isolated from the leaves of Paradox seedlings growing in the Experi-

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 321

ment Station nursery. The disease has never been found on the straight
California black or on Royal hybrids, although it can be produced
artificially by puncture inoculation on various species of Juglans.
In one instance a case of blight infection was observed in the nursery
on the leaves of California black seedlings near a badly diseased
branch, caused by artificial puncture inoculations. It is probable that
these leaves were infected from the disease on the branches.

Popular Name of Disease. — Newton B. Pierce first described this
disease as walnut bacteriosis, but locally it is also known as walnut
blight. In this paper, however, the more suggestive term Bacteriosis
will be used for the most part.

Geographical Distribution. — It is not definitely known just how
widely spread this disease may be. In the United States it is found
more or less scattered over California, some localities being more
severely infected than others, due either to climatic conditions or to
the disease not yet having obtained a foothold. California has had
the disease for a quarter of a century, and now it is beginning to show
itself in Oregon.1 The disease has also been reported from Texas,2
and is said there to attack nearly every year all the native nuts of the
walnut family. This Texas trouble has not yet been, with certainty,
identified as the same disease as the walnut bacteriosis in California.
Diseased walnut leaves have been received from at least one point about
midway down the Pacific coast of Mexico. From this diseased material
typical walnut blight cultures were grown. The walnut trees were,
however, imported from California. This disease will probably appear
wherever the English walnut can be commercially grown in the United
States, and the only reason that it is of no economic importance in the
Southern and Eastern States is because the walnut industry has not
yet been developed there. In foreign countries the disease has been
reported from New Zealand.* California walnut growers who have
visited France report having seen our trouble on French walnut trees.
Too much reliance cannot, however, be placed on these observations
because of a fungus disease (Marsonia juglandis) that produces quite
a similar appearance to that of our walnut blight. (See description of
Marsonia juglandis, page 325. The testimony of these growers is,
however, strengthened by certain observations of our own. In 1907
walnut scions were imported from France, and among these were several
that had what appeared to be typical walnut blight lesions. Cultures

1C. I. Lewis, Oregon Experiment Station, Bui. No. 92, p. 19.

2G. E. Schattenberg, Texas Department of Agriculture, Bui. No. 2, pp. 42-43.

*W. A. Boucher, New Zealand Department of Agriculture, Report 1900, pp. 334-335.

T. W. Kink, New Zealand Department of Agriculture, Report 1907, p. 167.

14—231

322 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

were made from these diseased scions, but from the limited material at
hand no true walnut blight organism was isolated. These scions were
grafted into black walnut trees and in the new growth from some of
the scions typical walnut bacteriosis appeared close to the old wood of
the scion, although there was no walnut blight in the vicinity, local
scions did not develop the disease, and on the shoots from the French
scions blight developed only close down to the original imported wood.
While the evidence seems to indicate that this disease may have been
introduced from France, we have found no report of its occurrence in
that country in available literature. It may, however, be confused with
their Marsonia, and really occur there to a limited extent.

History of Disease in California. — The disease has been known for a
considerable time in California. The first published account which we
have found occurs in the report of the Secretary of Agriculture for
1893.* At that time the true cause of the trouble had not been demon-
strated, although the presence of a bacterial organism had been found
constantly associated with the disease, and pure cultures of an organism
had been made by Professor Newton B. Pierce, who was then in charge
of the Pacific Coast Laboratory of the Division of Vegetable Physiology
and Pathology of the United States Department of Agriculture.

Growers affirm that the trouble had been known for several years
before this time. According to local accounts, it appears that the dis-
ease first became noticeable in the principal walnut districts of Los
Angeles County about 1891. The disease occurred then in a very limited
way and seems to have attracted attention, not on account of the extent
of its ravages, but simply from the fact that it was something new.
Growers who observed the blight at that time claim that its occurrence
coincided with the distribution of trees from a certain nursery in Orange
County, the proprietor of which nursery imported walnut trees from
France a few years previous. Whether or no these statements are cor-
rect, it appears to be undoubtedly true that the blight was first noticed
in Los Angeles County about 1891, that it came thence from Orange
County, and that the disease then spread northward to Ventura and
Santa Barbara counties until at present it occurs in practically all parts
of the State where walnut trees exist.

Walnut bacteriosis is by far the most prevalent in the older walnut
sections. Some differences as to amount and severity can, of course, be
noted in different places, due either to different climatic conditions or
to the fact that the disease has not yet been introduced. The newer
groves that are now being grown in central and northern California are

*Report of Secretary of Agriculture, Division of Vegetable Pathology, 1893, p. 273.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 323

at present only troubled with this disease to a limited extent. In
northern California and Oregon there are few commercial bearing
groves at the present time. This disease shows the greatest variation in
the amount of infection from year to year, and while it may seem to be
scattered throughout a grove, yet there are trees here and there that
are almost free from attack. Some years there is almost no blight or
only a small amount of early infection. There is less infection in a
bright spring that is free from fogs and cloudy days.

The disease is now distributed all over California, being often found
even upon isolated walnut trees situated a long distance from any others
of the same kind. It has no doubt been generally disseminated through
nursery stock, which is often infected, and may also be carried through
the air. Localities with much foggy or moist weather during the spring
show the most severe attacks of blight, but in places where the crop is
largely grown, as in the southern part of the State, the disease becomes
more conspicuous, although it is really more prevalent and virulent in
some other parts of the State where the walnut crop is less important.
The occurrence of the disease varies everywhere in direct proportion to
the amount of atmospheric moisture during the spring and early sum-
mer months, from the time the trees start into growth until the nuts
are well advanced in development. The amount of blight likely to occur
in a given locality or given season can be closely estimated on this basis,
as the connection between the occurrence of the disease and the amount
of atmospheric moisture is well established. Localities with much spring
and summer fog may expect a considerable development of walnut
blight, while those where such weather does not prevail may safely count
upon being reasonably free from this trouble, even though it be fre-
quently introduced. The same rule applies as to the occurrence of the
disease in different seasons.

Losses from Blight. — The amount of loss actually caused by this dis-
ease has been every year very large for the past ten years or more, but
has varied considerably from year to year. It is also true that much
has been attributed to blight which in reality had nothing to do with
this disease, such as the effects of drouth, frost and other unfavorable
climatic or soil conditions. At the same time the losses directly attribu-
table to blight have been extremely large. One significant fact in this
connection is that while the walnut acreage in southern California has
multiplied many times during the past decade, the total walnut crop of
the State has increased very little during this time. In fact, the crop
has been actually much less during several years of this period than it
was in some of the best years of the preceding decade. This loss or
failure of the crop to increase has not been entirely attributable to
blight, yet it has certainly been due to the disease much more than to

324 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

any other one factor. In the year 1903, one of the first bad blight years,
the total crop of the State fell off to only a little more than one half
of that of the previous year. It is probably conservative to state that
in the seedling groves of southern California an average loss of at least
50 per cent of the crop which would otherwise have been harvested has
been caused by the blight during the past ten years. Many individual
trees may be seen some years which show a loss of practically all the
crop from blight. This disease affects the quantity and, to some extent,
the quality of the crop much more than it does the growth of the tree,
being of less importance in that respect than pear blight, for instance,
and many other plant diseases. While the leaves and young shoots
become affected to some extent, as we shall describe later, this injury
in otherwise thrifty trees is soon overcome during seasons when the dis-
ease is less prevalent, and is not usually a serious matter. In occasional
instances, especially on light, dry soils where the trees are at best none
too thrifty, sufficient twig infection sometimes occurs to actually stunt
and dwarf the trees to a considerable extent by a continual killing back
of the young twigs. Damage is also done in such cases by the loss of
the fruit spurs which should produce the catkins and nut-bearing shoots
the following year.

It should be clearly understood that walnut blight is not conspicu-
ously a die-back disease of the tree, but is more especially a source of
loss in the amount of the crop, varying widely in prevalence from year
to year, and not, in the majority of instances, seriously affecting the life
or growth of the tree.

Earlier Studies. — Reference has already been made to the work done
by Pierce. He first isolated the organism and printed quite a full and
accurate, technical description1 of the disease and its physiological and
pathological characteristics. He also published several more popular
accounts of the trouble.2 Various experiments in spraying were made
by him in trying to control the trouble by such means, the results of
which will be more fully discussed under another heading. He also
observed that certain walnut trees seem to possess a certain immunity
to the disease, but did not indicate that the time of blooming had any-
thing to do with the amount of blight that developed.

In 1905 the California legislature made a special appropriation to
the Experiment Station for carrying on an investigation of this disease,
and Mr. A. M. West was appointed to work on the problem. He isolated
and studied the organism and confirmed in most respects the work
previously done by Pierce.

^Botanical Gazette, 1901, 31, p. 273.

^Pacific Rural Press, 1896, 57, No. 25, p. 387.

California Fruit Grower, 1896, 19, Nos. 13, p. 243; 16, p. 316.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 325

The work here recorded covers the results of previous investigators,
verifying them in most cases, while some new data has also been added.

Cause of Disease. — The disease thus far discussed has been con-
clusively proven to be produced by a species of bacteria growing in
the diseased parts, and hence is very properly referred to as Bacteriosis.
A microscopic examination of diseased tissue shows countless numbers of
these small, rod-shaped organisms to be present. By employing
bacteriological methods pure cultures of these germs were obtained and
then these pure cultures were used in making artificial inoculations into
healthy nuts and shoots, thus again producing the typical disease. The
organism has been isolated many times, and no difficulty has been
experienced in always producing the disease by inoculation from culture
if the tissue was in an active growing condition.

The walnut blight organism belongs to what are called the bacteria;
low forms of plant life that are ^extremely small in size and increase
rapidly in number by elongation and division or fission. When grown
in artificial cultures in mass they have a shiny yellow appearance.

Confusion with Marsonia juglandis. — It is important to refer to this
trouble in some detail for it has been confused with our walnut bac-
teriosis and bears a close resemblance to it in very many respects. This
disease is caused by a fungus that is not uncommon in the Eastern
States on the leaves of the butternut, Juglans cinerea, and on the leaves
of the black walnut, Juglans nigra. So far as our observations have
gone the trouble does not affect the nuts or branches of these trees. In
France the fungus occurs on the nuts of the English walnut as well as
on the branches, causing them to have a black appearance, like our
Bacteriosis. This disease is described* by Prillieux and Delacroix of
the Institute National Agronomique and Laboratoires de Pathologic
Vegetale. No mention in this article or any other scientific literature is
made of our Bacteriosis occurring in France.

In California no species of Marsonia is known to occur on English
walnuts. There is a species of Marsonia recorded by A. D. McClatchief
as occurring on the leaves of Juglans calif ornica, but this trouble is not
at all common. In the spring of 1910 a species of Gloeosporium was
found attacking the leaves of Juglans calif ornica. This occurred only
on the leaves and could not be confused with the Marsonia referred to
in the following paragraph :

The following is an abstract from the article by Prillieux and Dela-
croix: Marsonia juglandis (anthracnose) is parasitic on leaves, young
shoots and fruits of the Juglans regia. The disease forms round spots

*Maladies des Plantes. Les Maladies des Noyers en France.
t Seedless Plants of Southern California, p. 378.

326 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

on leaves, yellowish brown in color on the upper surface, and grayish
brown on the under side. Hemispherical masses appear, the acervuli, as
little pulverulent brownish bodies.

On the young shoots the color of the diseased portions is far different.
Spots are irregular, shrunken, with edges more highly colored and

FIG. 78. — Bacteriosis on green shoots of English walnut.

thicker, bearing the pulverulent cushions of the fungus. The appear-
ance of the disease on the shoots is a canker, reminding me of the true
anthracnose of the grapevine.

Upon the fruits the parenchyma of the epicarp is invaded in its entire
thickness by the parasite. The cankers on the fruit are browner than on

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA.

327

FIG. 79. — Bacteriosis on green shoots.

328 UNIVERSITY OP CALIFORNIA EXPERIMENT STATION.

the shoots and are more spread out over the surface. The disease does
most serious damage on the fruit and is worse in wet seasons and in
certain valleys. If the disease starts early the nuts remain small and
undeveloped and the amount of fruit is greatly reduced. The disease
is frequent in walnut-growing sections of France. Bordeaux mixture
has been tried for this disease and while it proved somewhat successful,
yet it was too costly and difficult to apply.

Characteristics of Bacteriosis. — Walnut bacteriosis may occur on all
the tender, new, growing parts of the tree, such as young nuts and
branches, the petioles of leaves, as well as midveins, the fine lateral veins
and adjoining parenchyma. On the affected parts characteristic blackish
colored areas or quite pronounced lesions are produced. The blackening
is, as Pierce suggests, brought about by oxidation of the tannic acid in
the tissue. At any point of injury in the tender growth of the walnut
a very similar black coloration will occur.

On Branches. — Bacteriosis is at first confined to small areas, but under
favorable conditions these increase in size to a lesion or diseased area
extending two or three inches in length on the green shoot. The disease
always has its beginning on the young succulent growth which may be
near the growing end or at any other point. When the disease infects a
branch near its end, that part may be killed back, but this seldom occurs
except when the diseased lesion is very near the end. In the worst dis-
eased lesions the tissue is killed inwardly to the pith, while in less severe
cases only the bark and wood are diseased. As the shoot becomes more
woody it is more and more difficult to infect and no tissue ever becomes
affected after the first few months of its growth. The disease after the
first year, even in well defined lesions, gradually dies out and the tissue
heals over the old lesion, although in some cases short lengths of the
worst diseased shoots may die back for a few inches. The diseased
portion on the twig at first forms a small, discolored or water-soaked
area which gradually increases in size, and at length the central portion
is black and is surrounded by a water-soaked margin or fermentation
zone. As the shoot becomes more and -more woody the active develop-
ment of the disease is checked and no further tissue is involved. Then
the whole diseased area becomes blackened in color. The diseased por-
tion in many cases comes to have a somewhat shrunken, dried-out,
deformed, cracked condition because of the killing and drying-out of
the tissue.

During the spring when the flow of sap is active there is often quite an
accumulation of liquid in the pith cavity beneath very badly diseased
lesions. This liquid has been tested at different times to see if this was

""'Diseases of Walnuts," Bailey's Encyclopedia of Horticulture.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 329

a source of infection. The test did not seem to show that the blight
organism was present in any great abundance in this liquid. Pierce
states* that the blight organism winters in the pith cavity, but we have
not found the organism any more abundant in this place than in the
partly live wood and bark of the diseased lesion. The diseased twigs of
the previous year are without doubt the chief source of the initial infec-
tion each spring. From our study we believe the old lesions to be the
only place where the organism can live over the dormant period of
winter and start the first infection the following spring, although Pierce
states that the old nuts and soil are a source of infection.

Bacteriosis is not Die-Back. — Walnut blight causes very characteristic,
comparatively small, sunken, black areas on the small shoots of the tree.
It does not attack branches of any size and does not injure them to such
an extent that they die back for several feet, as in the case of die-back.
See Die-Back, page 372.

On Nursery Trees. — Bacteriosis is especially severe in rapid-growing
trees in the nursery. Walnuts are grown for two years in the nursery,
being grafted the second season. The scions, after they start, usually
grow rapidly and are in a very favorable condition for this disease to
attack them. This infection in many cases comes from using diseased
scions. Rapid sucker growth in the orchard is very apt to become
infected and show the disease in a manner similar to that which occurs
in nursery trees.

Leaves. — The leaves are sometimes diseased, especially the petioles and
veins, which become a blackish or brownish color. The disease also
attacks the parenchyma or soft tissue of the leaf, causing spots of a
brownish color and of various shapes. These spots are rather common
on rapidly-growing leaves, and especially on the very large leaflets of
young nursery trees. The spots are circular or angular in outline and
by confluence often cause quite large diseased areas. Here the small
lateral veins in the diseased areas are a browner color than healthy ones.
Fig. 80. The disease does not cause serious defoliation of the tree and
should not be confused with the falling of the leaves that sometimes takes
place after a period of hot weather during the summer months.

Catkins. — The catkins are probably not diseased by walnut bacteriosis.
They often turn black, but this is probably only due to the natural
process of dying and drying up after their work is done. Various
attempts have been made to obtain the blight organism from these dark-
ened catkins, but without success.

Nuts. — Bacteriosis on the young nuts is especially virulent and
destructive under favorable conditions. The disease on the twigs and

^Pacific Rural Press, 1899; Vol. 57, No. 25, p. 387.

330

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

leaves ordinarily does very little injury and the disease would be of
little economic importance di'd it not attack the nuts. Many of these
may become diseased and fall when they are one eighth to one half an

, FIG. 80. — Bacteriosis on leaves.

inch in diameter, and continue to drop more or less all through the
summer. Pierce estimated a loss of from 50 to 80 per cent in badly
diseased groves. We have never made a careful estimate of the loss

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

in actual per cents, but know that it is very heavy in some groves when-
ever the disease is severe. The loss may, however, be more apparent
than real, especially when there is a heavy crop, as the relieving of the

FIG. 81. — Walnuts affected by Bacteriosis, mostly stigma or blossom-end infection.

tree of a part of its load will better fit it to bear a good crop the follow-
ing year, instead of periodic heavy and light crops. For the past few
years, in spite of this disease, there have been good crops of nuts.

332

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Young trees are much more free from bacteriosis than are those that
have been in bearing for a longer time.

It should be remembered that other causes than bacteriosis may make
the small nuts fall, as for instance poor pollination, which may result
from a lack of pollen or unfavorable climatic conditions, the small nuts
being very susceptible to cold at this time. In the English walnut the
catkins and nuts are produced in the spring in separate clusters on the
same tree. (See Fig. 1.) The catkins are the male flowers and bear
the pollen. They are always found on the old wood, and these may be
seen as rather long buds in the late autumn. The small nuts are found
on the new growth. These two kinds of flowers should appear at about

FIG. 82. — Half-grown walnuts affected with Bacteriosis.

the same time, but on the seedling trees there is the greatest variation.
A tree may have a very limited number of catkins or may be abundantly
provided. These may appear at the same time as the nuts, or too early
or late to be of much service in fertilizing them.

Blossom End Infection. — While the nuts may be infected at any
point in the surface, by far the most common as well as most virulent
form of infection is at the blossom end near what is technically called
the stigma. This is the weakest part of the nut and is especially sensitive
to the blight. The bacteriosis is very bad on the small nuts, and when
once it has started at this point it rapidly continues its growth within
the tissue, until the small nut is sufficiently weakened to fall. Not all

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 333

the infected nuts fall when they are small, but some remain on even until
harvest time. In the nuts the disease gradually grows within the tissue
until the kernel is reached which at length becomes blackened and then
destroyed. The disease may start at any place on the nut and gradu-
ally extend through other tissues into the kernel, but by far the most
of the infections that injure the kernel are from the blossom end.

Lateral Nut Infection.— The disease on the nuts starts at one or more
points on the surface as a small, circular, raised, discolored area that
at first has a water-soaked appearance and may not be larger than the
point or head of a pin when first visible. The diseased area in its
earliest stages is slightly raised above the surrounding healthy tissue,
but as the disease progresses, the spot becomes more or less sunken below
the normal tissue. The spot gradually enlarges in size and becomes
black in appearance. Surrounding the blackened area is a paler zone,
having the same water-soaked appearance already referred to. This
band of tissue lies between the healthy tissue and the blackened area
and represents the cells of the tissue that are being acted upon by the
ferments secreted by the organism, which break down the tissue and
prepare the way for the further advance of the bacteria. In the early
infection,, if climatic conditions are favorable, lesions or dark spots are
formed which often extend through the hull and shell-forming tissues
into the kernel. The nut in such cases is deformed in shape as the
diseased part ceases to grow. Such nuts do not bark clean, as the outer
covering clings very tightly to the shell, and the kernel at best is only
poorly developed. Such nuts are usually never picked up from the
ground, and in any case are only fit for culls.

Late Infections. — It often happens that during the summer months
weather conditions are favorable for natural infection of nuts. At
this time the outer tissue is beginning to harden and is not in condition
for the deep growth of the disease that occurs earlier in the season when
the tissue is more tender. Then, too, the disease may start in the sur-
face rather late in the season and suddenly conditions become unfavor-
able for its further development, thus giving a very shallow, superficial
development of the disease. These points of infection appear as small,
dark-colored areas scattered over the surface of the nut. Each little
infection can be distinctly seen, or its confluence with others may make
a large spot. In these late infections the development is shallow and
does not penetrate much through the epidermis, and the disease seems
to dry out and die. Occasionally a more severe case of late infection
occurs where the blackening and lesion extend to the hard shell, causing
the hull to cling to the shell of the nut.

334

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

FIG. 83. — Walnuts with late infection ,by Bacteriosis.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 335

White Deposit on Diseased Tissue.— On the surface of the diseased
tissue of both the branches and the nuts can often be observed a whitish
substance that accumulates during the summer but at length disappears.
When this is properly stained and examined with a compound micro-
scope, it is found to be composed of countless numbers of bacteria and
broken-down plant tissue. Cultures made from this substance gave a
large number of typical walnut disease colonies. A somewhat careful
study was made of this white deposit in small nuts. Small diseased
nuts having this white substance were put in 10 per cent chromic acid
and the deposit swelled up and became soft and gum-like. It is thought
that this white substance containing so many organisms is an important
source of natural infection. Larger nuts, diseased at the blossom end,
sometimes show gum-like streaks running down over the nut from the
diseased portions. This substance also was found to contain bacterial
organisms. From laboratory experiments it is known that the organism
is quite resistant to desiccation and probably the condition described
is an important factor in bringing this about.

Winter Habitat of Germ. — The germ of the organism without question
winters in the old lesions of the branches. Much work has been done
in making cultures at short intervals of time throughout the year from
the different diseased tissues in order to see if the disease organism was
alive and where it best could pass through the winter or dormant period.
This work of making artificial cultures is given more in detail on page
343. The work began in October, 1907, and continued until the follow-
ing spring, at which time the disease again appeared on the new growth.
In every series of cultures the disease organism was found, showing
conclusively that the disease was still alive in the old lesions of the wood
and bark. The cultures made from the old nuts, both those on the
ground and some still on the tree, gave some walnut blight cultures
early in the autumn, but as the season advanced the organism seeined
to die out and toward spring it was almost impossible to secure blight
cultures from the old nuts found about the orchard. Pierce* states that
the organism "winters in fallen nuts beneath the trees and probably
upon fallen leaves and upon the soil." We believe that the old nuts
are not an important source of infection, since in all well-cared-for
groves these are plowed under before the tree starts out in leaf. This
is especially true of those groves where a cover crop is sown. We have
never tested soil and leaves to see if the germ could be found wintering
in them.

The most prolific source of new infection is the lesions on diseased
twigs. Here the germs remain in almost a dormant condition until the
warm weather of spring, which arouses them to a renewed activity, when
they exude on the surface and are carried to the new growth, leaves,

* Pacific Rural Press, Vol. 57, No. 25, p. 387.

336 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

PIG. 84. — Above — Sections of two walnuts with Bacteriosis at the left, two
normal nuts at the right. Below — Old, blighted nuts.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

337

branches and nuts. From our observation, the young leaves seem to be
infected very early and probably are one of the chief sources of the
secondary infection.

Secondary Infection. — The first or initial infection may occur on only
a few nuts and new growth, then quite suddenly the disease seems to
spread and infect many small nuts. This sudden increase of the disease
is due to an infection from the earlier diseased nuts and new growth,
and can thus be termed the secondary infection.

Effect of Climate. — Walnut bacteriosis is a disease that is quite
susceptible to variations in climatic conditions. It is a matter of com-

FIG. 85. — Bacteriosis lesions on older wood. Healing over.

mon observation among growers that the amount of blight varies from
year to year in a given locality, also that some sections are freer from
the disease than are others, even during the same periods of time. A
given grove may be very bad one year and nearly free from the disease
the following year. This is well illustrated by a comparison of the years
15—231

338 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

1907 and 1908. In 1907 there was an abundant amount of bacterial
infection and quite a severe loss of nuts. There was at the same time a
large crop of nuts. In 1908 there was almost an absence of blight and
a very much lighter crop of nuts. It is rather difficult to always fully
account for these variations because of the great number of conditions
that must be considered.

Fogs and Moisture. — The amount of moisture present in the air has
without question considerable influence on the quantity of disease that
may develop, as humid conditions are especially favorable for its spread.
It has been proven again and again by our experiments that infection is
produced when water containing the disease germs is sprayed on the
surface of the young nuts, while the untreated ones are free from the
disease. Then, for infection to take place under natural conditions, it
only becomes necessary for virulent germs to come in contact with
immature nuts, and water is apparently the principal agent in convey-
ing the germs from the diseased lesions to the young growth or small
nuts below. Rains very rarely occur in the spring after the nuts appear,
but foggy weather is often more or less frequent. What are called high
fogs, a cloudy condition of the sky, but with little moisture, which in
some sections occur during the spring months, do not cause infection,
although such cloudy conditions are favorable for bacteriosis to develop
where infection has already taken place. Low fogs and especially foggy
nights are very favorable for the dissemination and new infection of
the small nuts. During one of these fogs the trees become saturated,
water dripping from one portion of the tree to another which could
easily carry the disease organisms to healthy tissue. Observations go to
show that the secondary infection, in which large numbers of the small
nuts become diseased, is very likely to follow one of these foggy periods.

Insects.— It is more difficult to say just what part insects play in the
spread of this disease, as it is not necessary for the nuts to be bitten in
order to cause infection. Insects are present in quite large numbers
about the tree. Several species of flies and beetles are most numerous.
Flies have been observed on diseased nuts, probably attracted by the
exuding of organic matter mixed with walnut blight germs that is some-
times present, and these flies have been collected and culture media
inoculated by placing them in it, with the result that the characteristic
organism has developed in the cultures. This shows that the living
germs of walnut blight were on their bodies and only needed to be
placed in contact with the nut to cause infection. A species of aphid
is often abundant on the leaves, rarely on the nuts and branches. This
insect, however, appears some time after the nuts, and probably does
not cause much infection of any part of the tree except possibly the
leaves. The honeydew is secreted and deposited on leaves and nuts,
and in this a sooty mold grows.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

339

How the Germ Enters the Tissue. — Nuts, as well as the leaves and
young shoots, are provided with stomata or breathing pores through
the epidermis into the in-
terior of the tissue. These
stomata on the nuts are ar-
ranged in groups of from
five to a dozen or more, and
are to be found on the paler
green specks that spot the
surface of the husk of the
green nuts. It is through
these openings that the bac-
terial organism can gain
entrance to the interior of
the tissue of the young nuts.

The blight organism is
motile and when carried to
the surface of the nut by
moisture, such as fogs and
heavy dews, can use this
moist surface to swim
directly into the stomata
or breathing pores just de-
scribed. When once in the
interior of the nut the con-
ditions are favorable for
further development. While
these stomata have the power
to open and close, they are
probably never so closely
shut that the small germs
could not enter. The moist
conditions favorable for the
entry of the germ or bac-
terium through the stoma
are also just the conditions
necessary for keeping this
entrance open.

Two Seasons Compared. —
The two years of 1907 and
1908 well illustrated the two
extremes of much and practically no bacteriosis of the walnut. The
year 1907 was very favorable for the development of this trouble, while

FIG. 86. — Surface of green walnut, showing two
groups of stomata through which the blight
germ enters. Much enlarged. Each group
represents one of the light-colored spots on
the surface of the green hull.

340 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

the following one showed comparatively little of the disease. It will be
instructive to observe a few of the reasons for this difference.

The winter of 1906 and 1907 was a rather wet season, there being
about 20 inches of rainfall in the vicinity of Los Angeles. The spring
opened very early, some walnut trees beginning to show leaves during
the last week in February. Some of our preliminary inoculation work
was done at this time, February 22d. Small nuts appeared early in
March, and on March 7th we inoculated our first small walnuts for
bacteriosis. It is safe to say that the season was at least three weeks in
advance of the average time of blossoming, which gave a longer period
favorable for infection to take place. This is an unusual situation, and
has not been repeated.

The winter of 1907 and 1908 was a dry winter, there being about
twelve inches of rainfall in the regions around Los Angeles. The earlier
trees began putting out leaves about April 1st. Too much importance
should not be given to the difference in the amount of rainfall of the
two years, as its relation to the amount of bacteriosis is exceedingly
doubtful.

Another favorable condition of 1907 was the cloudy weather during
March, April and May, the time of year when the bacteriosis is most
active, as compared with the conditions of the same period during the
following year. This is well shown in the following table compiled
from data very kindly furnished by Mr. A. B. Wollaber, the local fore-
caster of the United States Government Weather Bureau at Los Angeles.
It is well known that sunlight is fatal to most kinds of bacterial germs
and the walnut bacteriosis is no exception to this rule. The table shows
that the nuts during the spring of 1908 had a much greater amount of
sunshine during their first three months of growth than did those of
1907 during the corresponding three months. May not this in some
measure be the reason for the difference in the amount of this disease
during these two years?

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

341

TABLE I.
Showing average daily hours of sunlight for periods of five days.

1907.

1908.

Date.

March.

April.

May.

March.

April.

May.

1-5

5 4

7 8

6.1

7.1

10.5

9.8

6-10

6.8

10.7

9.7

10.9

8.5

12.9

11-15 ._

10.0

3.3

11.5

11.8

11.3

9.6

16-20

5.6

8.3

11.9

5.2

11.0

12.7

21-25

4.9

7.4

10.8

9.3

8.1

9.3

26-end .

9.8

2.9

4.8

10.6

11.6

11.6

1907— March had 3 days with 1 hour or less of daily sunshine.
March had 7 days with 2 hours or less of daily sunshine.
April had 6 days with 1 hour or less of daily sunshine.
April had 15 days with 6 hours or less of daily sunshine.
May had 2 days with 1 hour or less of daily sunshine.
May had 9 days with 6 hours or less of daily sunshine.

1908— March had 1 day with 1 hour or less of daily sunshine.
March had 3 days with 2 hours or less of daily sunshine.
April had 0 day with 1 hour or less of daily sunshine.
April had 2 days with 2 hours or less of daily sunshine.
April had 2 days with 6 hours or less of daily sunshine.
May had 0 day with 1 hour or less of daily sunshine.
May had 2 days with 6 hours or less of daily sunshine.

Average amount of possible daily hours of sunshine in California
for March is about 12 hours ; for April, 13.5 hours ; for May, 14 hours.
For April, 1907, there was 52 per cent of the possible amount of sun-
shine ; for April, 1908, there was 78 per cent ; for May, 1907, there was
65 per cent of the possible amount of sunshine; for May, 1908, there
was 74 per cent of the total number of hours.

Non-blighting of Late Blooming Trees. — As previously stated in the
comparison of the two seasons, the season that opened late, that is 1908,
had almost no walnut blight. What was true of the majority of bear-
ing trees during that season is always true of trees that bloom late. The
majority of the bearing orchards of California are at this time seedling
trees, differing greatly in their blooming periods. The difference in
time is frequently from one to two months and may be as much as three
months between the earliest and the latest French varieties. Such a
wide range in time of blooming gives considerable chance for difference
in climatic conditions. We find that the early or medium blooming
trees are in blossom at a favorable period for the blight to develop
while the late bloomers come into flower at a time when bacteriosis can
make little headway. Particular attention has been given to this
phase of our investigation in the hope of finding a commercially profit-
able tree that blooms at a season when conditions for the infection of
the small nuts is at a minimum. While this work is not yet completed

342

UNIVERSITY OP CALIFORNIA EXPERIMENT STATION.

enough has been done to show that nuts in such late trees are compara-
tively free from the disease. Some of these late varieties are described
in another part of this bulletin.

Immunity. — Certain trees are some times spoken of as being immune
to the blight, but while there is probably no such thing among walnuts
as absolute freedom from this disease, where conditions are favorable
for blight infection, yet some trees do show quite a marked resistance,
and, if otherwise desirable, are given precedence in new plantings on
this account. (See Eureka, etc.) It may be that in certain localities
there is no blight, but this probably is not due to any immunity that
the trees possess but is rather the effect of climatic conditions or due to
the fact that the specific organism has not yet reached this particular
locality.

Isolation. — Pure cultures of the walnut bacteriosis are most easily
obtained from recently diseased nuts, although they have also been
secured from diseased leaves, old lesions and young blighted shoots, as
well as from certain flies that are quite abundant about walnut trees
during the period of infection.

Table shoiving dates and results from various attempts to isolate the walnut blight
organisms from diseased tissue.

1907.

Diseased tissue.

Number
of isola-
tions.

1908.

Diseased tissue.

Number
; of Isola-
tions.

Oct. 25

Pith __

+ —
0 1

Feb. 4

Wood and bark

+ —
1 2

Wood and bark

1 0

Wood _

1 0

Wood and pith -

0 1

Nut from tree

1 0

Bark

1 0

13

Five nuts

0 5

Inside hull

0 2

Wood and bark

0 1

Nov. 5

Pith

4 0

19

Wood and bark

3 1

Wood and bark

3 0

Wood __

1 0

6

Green hull

0 1

Mar. 2

Wood and bark ___

1 2

Dry meat

0 2

12

Wood and bark

2 3

16

Bark

1 0

16

Wood and bark

0 3

Wood and bark

3 0

24

New growth

0 1

Pith

1 0

30

Pith

0 1

26

Wood

1 0

Nut

0 1

Bark

2 0

Wood

0 1

Leaf petiole

0 1

Wood and bark

1 0

Portion hull

0 1

Apr. 3

Wood _.

0 1

Healthy bark

0 1

Wood and bark

2 0

Dec 3

Bark and wood

1 2

8

Young nuts

2 0

Healthy bark

0 1

Young shoots

0 1

Blackened shell

0 1

Petiole

0 1

12

4 3

14

Small nuts

2 0

19

2 2

17

Blackened leaves

3 0

26

Wood and bark

0 8

21

White substances on surface

1908

of lesion

3 0

Jan. 7

Wood and bark

2 8

Wood

0 2

Totals

23 24

Nut on tree

1 0

16

Wood and bark

4 0

Wood and pith __

0 2

30

Wood and bark _ .

2 2

Nut from tree

0 1

Totals — _-

33 42

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 343

The usual method of securing pure cultures was as follows: A
scalpel sterilized by flaming was used to remove the outer blight portion
of the young nut. Then some of the diseased interior of the nut was
transferred to liquid media, such as acid Dunham solution or acid
peptone meat bouillon. About twenty-four hours after inoculation
there is usually some evidence of growth and dilution cultures were
then made in nutrient agar. In two to five days at a temperature of
20° C. the colonies will appear and can then be transferred to potato
cylinders or other solid media. The organisms are usually abundant
enough in the diseased nuts to plate out directly from the diseased
tissue without incubation.

The preceding table shows that the organism was alive at all seasons
of the year in the different diseased tissues. The number of isolations
was not at any time very great, but sufficient to show a large number
of positive results. The negative results obtained do not mean there
was lack of growth in the tubes inoculated with the diseased tissue, but
that there was usually some other sort of bacterial growth. There are
several kinds of saprophytic organisms that can be found in these old
lesions. In the dilution cultures a saprophytic yellow organism was
very often present and could not always be distinguished in color or
manner of growth from that of the walnut bacteriosis. The difference
in growth on potato cylinders, however, readily distinguish the two.
Even when lack of growth did occur, too much importance should not
be placed upon it, for the walnut blight organism grows more slowly
than do the saprophytic organisms and could readily be crowded out
by them in artificial cultures.

A MORE TECHNICAL STUDY Of THE WALNUT ORGANISM.

Pseudomonas juglandis Pierce.
MORPHOLOGY.

These characteristics were studied in bouillon, agar and potato cul-
tures from twenty-four to forty-eight hours' growth, except in old
cultures that have been examined for spores.

Form. — The organism has rounded ends and occurs as single rods or
often in pairs, and more rarely in chains of several individuals, com-
monly four to eight.

Size. — The rods as found in diseased tissue and stained with carbol-
fuchsin measure 1.5 to 3.01 microns in length by 0.3 to 0.51 microns in
width.

Staining Reactions. — The organism stains readily with the usual bac-
teriological stains, carbol-fuchsin, aniline gentian violet, aqueous solu-
tion of methylene blue, gentian violet, and by Gram's method. Nothing
especially characteristic was observed from the use of the various stains.

344

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Spores. — No spores from this organism have thus far been demon-
strated. Old cultures have many times been studied and special stains
used. Hauser 's method was used, but did not show anything suggestive
of spores.

Capsule.— The organism has never showed a true capsule, although
its viscid growth might suggest one, and a microscopic examination of
this viscid growth from potato cylinders and other culture media often
shows a very distinct and rather thick wall, that can easily be seen by
using some of the special stains recommended for capsules. This may
appear as a hyaline membrane from one fourth to one half as thick as
the remaining width of the organism. The following capsule stains were
used: Robberts' dahlia, Welch's and Bonis'.

FIG. 87. — 1, the walnut blight organism, Pseudomonas
juglandis, greatly enlarged ; 2, a mass of the bacteria
in diseased walnut tissue.

Flagella. — The organism is motile by means of a long, single polar
flagellum, as may be demonstrated by using BowhilPs method. The
movement of the organism is a slow, sinuous one in the direction of the
longer axis.

CULTURAL CHARACTERISTICS.

The culture media were carefully prepared, following directions as
given by Smith1 and Moore.2 The formula for preparing nutrient
bouillon was Witte's peptone 10 grams; (c.p.) sodium chloride 5 grams;
500 grams of finely minced beef to 1,000 c.c. of once-distilled water. In
making this the directions given by Moore were followed.

1Bacteria in Relation to Plant Diseases.

laboratory Directions for Beginners in Bacteriology.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 345

Agar Plates (Surface Colonies). — In beef peptone acid agar, plus 15
Fuller's scale, temperature 17° to 18° C., the colonies became visible
after forty-eight hours as minute whitish specks that changed with
growth to straw color (stramineus),* and at length to a lemon yellow.
After five days' growth at 18° C., the surface colonies measured 1.5 to
2.5 mm. in diameter. At this time they are straw color (stramineus),*
and appear raised to the eye, especially at the center, where they are a
deeper yellow color, or nucleated. This nucleated character of the
colony is quite constant, being observed even in quite small colonies.
The colonies are nucleated, circular, moist, shining, pale yellow with
regular margins. When examined with the low magnifying power of
the compound microscope the margins are coarsely granular, while the
center has a finer and denser granular structure. Under the low power
magnification the colony is seen to have several concentric zones which
probably represent different regions of growth. The margins are entire
or slightly undulatory. After twelve days' growth the colonies have
become 5 to 10 mm. in diameter and are still zoned when examined
microscopically. The center of the colony (nucleus) is a pale lemon
color, while the margin is of a still paler yellow.

Deep Colonies. — These colonies are at first white, but later become
lemon color. They vary somewhat in shape, being biconvex, angular, or
oval to circular in outline.

Agar Slant. — On acid meat peptone agar after twenty-four hours
incubation at 18° C. there appears a slight whitish growth along the
streak and on the adjacent surface of medium. In five days there is a
fairly abundant growth spreading on either side of the streak. Growth
shining, pale lemon-yellow (W. and N.)t with wavy margins. In ten
days growth covers entire surface of medium and often shows small
colonies at side of main growth. In the older tubes there sometimes
appears a whitening of the agar just beyond the line of growth. This
same characteristic was also observed on litmus lactose agar, as well as
on stab cultures of both of the agars. This characteristic, however, is
not a constant one, and was only observed a very few times.

Agar Stab. — On acid meat peptone agar after twenty-four hours at
18° C. growth takes place along the line of puncture and on the sur-
face of medium around the puncture. Growth on surface piled up,
yellowish. The growth along puncture tuberculate-echinulate (Ches-
ter's terminology).

Carbohydrate Agars. — The organism was grown in 5 per cent dex-
trose, lactose and glycerine agar. Shake cultures were made in each

*Chromotaxia seu Nomenclator colorum — P. A. Saccardo.

fWinsor and Newton's specimen tints of oil and water colors. Plate 5.

346 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

of the above agars, as well as in plum agar. In three days at 24° C.
there was fine growth at surface of medium in each case, but no growth
deep in medium in tubes and no indication, at any time, of gas forma-
tion. The walnut organism seems to be a strict aerobe.

Litums Agars. — The walnut organism was also grown on litmus lac-
tose, litmus galactose, litmus dextrose media and litmus saccharose.
This was made up as follows: Distilled water, 2 per cent Witte's pep-
tone, 0.5 per cent (c. p.) sodium chloride, 2-J per cent agar, and 2
per cent of the above-named sugars; titration was plus 12 Fuller's
scale. In three days at 23° C. there was abundant growth along the
line of puncture and over surface. The cultures in galactose after
seventy days showed slight reddening of the agar near the bottom of the
tube, but not nearly so decided a reaction as was secured with the olive
organism, Pseudomonas olem (Arc.) Trev. In the litums dextrose and
litmus lactose there was no visible change in color of medium, even after
two months' growth.

Gelatin. — Ten per cent gelatin and beef peptone bouillon was used.
After twenty-four hours at 20° C. there was a slight yellowish growth
along the line of puncture. Liquefaction begins within a short time at
the surface. The type of liquefaction is crateriform (Chester's termi-
nology) , the liquefaction being at first restricted to the mouth of the stab
and forming a deep pit. As growth continues the liquefaction extends
laterally, and in about five days the upper portion of the gelatin in the
test has become liquefied and would be termed stratiform. However,
after a layer of liquefied gelatin has formed, further liquefaction at
17° C. is very slow and does not take place at all along the line of
puncture. It often requires a month for the 10 c.c. of gelatin in the
test tube to be entirely liquefied.

Potato. — Growth abundant, moist, shining, slimy, raised and piled
up, forming a thick coating that in about two months becomes viscid,
finally filling up the fluid with a yellow, slimy growth. Color of the
growth on potato cylinders was at first white, changing in a few days
at 18° C. to sulphureous (Sacc. Chrom.), and in about six days to
a pale lemon yellow (W. and N.). At the end of a month the color fre-
quently became citron yellow (W. and N., plate No. 5). In cultures
two months old the color changed to raw umber shade (W. and N.)

The growth on sterilized potato is very characteristic because of
the white fermentation band that appears just beyond the margin of
growth. This can be observed on potato cylinders, or better still on
slices of potato sterilized in petri dishes. The white zone usually is
visible within three days from inoculation when the organism is grow-
ing at a temperature of 20° C. to 26° C. In a few days the fermenta-

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

347

tion band spreads over the entire surface of the potato slices. The
starch where growth has taken place fails to give normal starch reac-
tion when treated with iodine, but gives a reaction for grape sugar.
This fermentation band is quite a constant characteristic and usually
appears. When the organism is growing slowly and at a rather low
temperature, the fermentation band is more likely not to show.

The organism lives for several months on potato cylinders, having
been found alive at the end of four months when growing at a temper-
ature of 15° to 18° C. In some cases the cultures die after three
months. In the old tubes the cultures are very viscid and much darker
in color, raw umber. (W. and N.)

FIG. SS. — Typical growth of Pseudomonas juglandis: left in glucose bouillon, right

on potato.

Fermentation Zone. — Special attention was given to the study of this
fermentation zone. Early in the study it was found that this was a
varying characteristic, one that appeared constantly during the warm
weather of the spring and summer, but failed to appear during the
cooler winter weather. This point was tested experimentally by ster-
ilizing two series of five petri dishes, each containing slices of potato
heated at 110° C. in autoclave for fifteen minutes. These two series of
five plates each were inoculated at the same time and from the same
culture. Both series of cultures grew well. Series I at a temperature
of 12° to 15° C. This we did not vary for five days from 15° C.
Growth was as vigorous as in those at the higher temperature. No

348 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

fermentation zone was observed during the fourteen days of the exper-
iment.

In the incubator at 23° to 26° C. growth began to show after twenty-
four hours. In forty-eight hours on December 16, 1908, the growth
had increased and was very vigorous and the fermentation zone was
just beginning to appear in all of the five cultures as a very faint,
whitish line outside the margin of growth. This zone constantly became
more evident, and on the fourth day from inoculation was at its best.
Further growth was slower and no great change was to be observed
during the two weeks of observation.

Professor Pierce in his study laid stress upon this characteristic to
separate the walnut organism from the closely related species, Pseu-
domonas campestris. To test this, we secured a culture of the latter
organism from Dr. H. A. Harding of the Geneva Experiment Station
of New York State. On July 1, 1911, potato slices were inoculated in the
same way as has already been described. Black rot of cabbage (Pseudo-
monas campestris) and walnut organisms were used. July 5th, the two
series of cultures were examined. Both cultures from the incubator at
26° to 28° C. showed fine fermentation zone formation. In fact, it would
be difficult to distinguish one from the other. The culture of the walnut
organism grown in the culture room at a temperature of 20° C. showed
very good fermentation zone formation, while that of Pseudomonas
campestris was much less developed. Dr. H. A. Harding, in his study
of this organism, speaks or a "white margin or halo just outside of the
line of growth."*

Other Solid Media. — The organism was also grown on slices of sweet
potato, turnip, garden beet and carrot, Irish potato being used as a
check. Slices of these vegetables were sterilized for fifteen minutes in
the autoclave at 110° C., then inoculated from the same source and
grown in the incubator at 23° to 26° C. for several days. After six
days there was abundant growth on each of the different vegetables,
but nothing characteristic on any of these media except that of the
Irish potato where the white fermentation zone appeared, as has been
before described.

Bouillon. — On meat peptone bouillon, plus 15 Fuller's scale, the
organism grows well, and in forty-eight hours at 18° C. the liquid is
uniformly turbid. In seven days there is a slight flocculent precipi-
tate at the bottom of tube. A true pellicle has never been observed
to form over the surface of this medium, but a ring-like growth
develops readily at margin of liquid on the surface of test tube.

*New York Agricultural Experiment Station, Geneva, Technical Bulletin No. 13.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 349

Dunham Solution. — The growth in this medium shows very much the
same characteristics as in bouillon. In cultures over a week old the
liquid is clouded.

Carbohydrates in Bouillon. — The walnut organism was grown in the
following bouillons, containing, respectively, 2 per cent glucose, dex-
trose, lactose and glycerine saccharose. These solutions were made up
by adding the carbohydrate to a solution of meat peptone, solution made
after the formula: 1 per cent Witte's peptone, 0.5 per cent sodium
chloride, 0.5 per cent Liebig's meat extract. These solutions titrated
plus 12 Fuller's scale. Growth took place within forty-eight hours,
and at the end of five days fine growth showed in all the tubes of
this series. The glucose series of tubes showed a well developed ring
formation, while in the other media there were traces of ring formation,
but much less than in glucose. There was no complete pellicle observed
in these tubes. They were titrated, but showed no increase of acid.

Cohn Solution. — Formula as given by E. F. Smith was used.* Five
tubes were inoculated with forty-eight-hour culture of walnut organism,
but after three months there was no growth in tubes.

Milk. — The cream was removed from milk that had set over night in
an ice box. The same was filtered and sterilized in steam sterilizer.
Reaction was plus 10 to 15 Fuller's scale. These tubes were inoculated
and grown at temperatures 25° to 27° C. In three days the separation
of the casein was first observed. The coagulum is formed rather slowly
and even after five days there is little separation of the whey, and no
pellicle to be seen at this time. The curd and whey gradually separate
from each other, the former becoming solid. The casein is soon acted
upon by another enzyme and is gradually redissolved, probably by a
trypsin ferment. This process of digestion takes place usually rather
slowly, several months often being required for completion. After a
month the white curd may be observed at the bottom of the tube
while the liquid above is of a yellowish color (yellowish straw color ).t
At first the whey is clear and nearly colorless, but changes to a yellowish
color, as stated above, when reabsorption of the casein has taken place.
Upon a microscopic examination of the liquid directly above the casein
that is in process of reabsorption many crystals can be seen. The most
conspicuous of these are long, needle-like crystals. A pellicle at length
forms on the surface of the liquid in the milk tubes.

Litmus Milk. — The characteristics are very much like those just given
for milk. Separation of casein takes place by a rennet ferment, or
rarely digestion occurs without casein separation ; the tubes under these

* Bacteria in Relation to Plant Diseases.
tRepertoire de Couleurs, Henri Dauthenay.

350 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

conditions have a wine-colored liquid. Litmus was slowly changed so
as to give a pinkish or wine-colored appearance to liquid, sometimes
after one to two months.

Methylene Blue Milk. — This medium was made by adding 2 per cent
aqueous solution of methylene blue (Merck) to milk and sterilizing
same. In one to two days at 19° to 20° C. the color completely dis-
appeared and could be restored by boiling or shaking the liquid in the
tube a few minutes. The disappearance of color seems to take place
first at the lower part of tube. The color entirely disappears some time
before separation of casein can be detected.

Plant Juices. — The walnut organism grows well in plant juices.
While no great number has been tested, the following extracts gave
abundant growth: Leaves of walnut (Juglans regia), loquat, castor
bean and fig. A ring formation and pellicle as well as a flocculent
precipitate are produced in these media.

Viability in Media. — In order to test the period of viability, transfers
were made to potato cylinders from milk culture at the end of five,
seven and eight months. Growth resulted in several cases. Old potato
cylinders were also tested. All these cultures were growing in dark
at a temperature from 15° to 20° C.

From potato cultures made December 10, 1910, transfers were made
on September 28, 1911, a period of about nine and one half months.
On October 4, 1911, there was growth in one of the two tubes tested,
the other showing fungus growth. These old potato cultures just
referred to seemed to be thoroughly dried out, hard, and for the most
part brittle. When placed in the liquid of the potato cylinder tube
the old, dried-out portion absorbed water, becoming swollen and more
like its former viscid condition. Another potato culture six and one
half months old also produced fine growth when transferred to sterile
potato cylinders. In these cases of old potato cultures it is perhaps more
an instance of resistance to desiccation, also possibly this resistance may
be due to spore formation, although these have never thus far been
demonstrated.

Indol. — This reaction was tested in Dunham solution made as fol-
lows: Witte's peptone 1 per cent, sodium chloride 0.5 per cent, and
distilled water. After two weeks, the cultures were tested for indol
with sodium nitrate 0.02 per cent and a few drops of concentrated
sulphuric acid. The tubes after treatment did not at once show the
characteristic pink reaction, but when warmed for five minutes at 75°
to 80° C. in a hot water bath, a strong indol reaction resulted, the color
being deep cherry red.

Nitrate Reduction. — A meat-peptone medium was used that titrated
plus 12 Fuller's scale. It was made after this formula: 1 per cent

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 351

Witte's peptone, 0.5 per cent sodium chloride, 0.5 per cent Liebig's
meat extract, 0.5 per cent potassium nitrate (Merck). Good growth
took place in these tubes after five days at 25° to 27° C. They were
tested by the KI H2S04 starch method as recommended by E. F. Smith.*
Not the slightest nitrate formation was shown in any of the tests.

Enzymes. — The walnut organism produces at least four enzymes,
diastatic (starch-destroying), cytohydrolytic (cellulose-dissolving), ren-
net (casein-forming), proteolytic (peptonizing). Professor Pierce
statesf in his article on this disease that he found that these enzymes
are especially active at a temperature between 65° to 75° F., and this
agrees very well with our study of growth of the organism on potato
slices and the accompanying fermentation zone.

Attention was called by Professor Pierce to the marked similarity
between the organisms of walnut bacteriosis and the black rot of the
cabbage. While few comparative studies have been made, yet the
cultural characteristics of the two are very similar indeed. The few
cross-inoculations made with Pseudomonas campestris on walnut and
Pseudomonas juglandis on cabbage show that the pathogenic proper-
ties are distinct. The walnut organism also grows more readily on
plant juices.

The group number of the organism, in accordance with the system
prepared by the American Society of Bacteriologists, is 211.3332513.
It will be observed that this is identical with that of Pseudomonas
campestris.

ARTIFICIAL INOCULATIONS.

Methods. — Inoculations have been successfully made at various seasons
of the year and in two different ways, by puncture and by atomizing.
The puncture method is the most likely to give positive results. A steri-
lized needle is used to transfer some of the germs from a pure culture
into a wound made by a slight pricking of the surface. The atomizing
method was used also quite effectively on the young nuts, but gave no
results on foliage or the young shoots. A young pure culture of the
walnut blight organism grown on potato for about three days was mixed
with distilled water and the mixture sprayed on the nuts or shoots with
an ordinary medical atomizer, without injuring the tissue. This experi-
mental work has extended over two seasons. The season of 1907 was
one favorable for blight development from natural infections, while that
of 1908 produced very little walnut blight. The time and results from
atomizing during 1907 and 1908 are given in tables which follow.

Atomizing on Late Tree. — The results summarized in the following

* Bacteria in Relation to Plant Diseases.

t Bailey's Encyclopedia of American Horticulture, p. 1961.

352

UNIVERSITY OP CALIFORNIA EXPERIMENT STATION.

table represent work done by spraying healthy nuts with a water solu-
tion of the organism on a rather late blooming tree, being in blossom
from the middle to the last of April. The nuts were always very free

FIG. 89. — Below — Stigma exudation from blighted nuts,
infected with Bacteriosis.

Above — Nuts artificially

from blight, and when the atomizing work was begun no blight of any
kind could be found on this tree nor did it ever develop to any extent at
other points than those that were atomized.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

353

Atomizing results on nuts of late blooming tree with water solution of the walnut
blight organism from pure cultures,, at different periods.

1907.

Nuts
| atomized.

Diseased Healthy
nuts. nuts.

Date of
observation.

April 27

! 28

20 3

May 27

April 29

15

7 4

June 8

May 2

__ 6

5 0

June 1

May 16

22

14 8

June 1

May °0

18

18 0

June 1

June 8

76

65 1

June 24

June 26

__ ... 42

30 7

July 16

June 27

1 5

5 0

July 16

June 29

15

9 5

July 23

July 2

10

7 3

July 23

July 3

16

15 0

July 23

July 6

5

0 4

August 13

July 7

2

1 1

August 1

July 9 _-

25

20 3

August 1

July 13

67

28 35

August 14

Totals

352

244 74

The table shows that a total of 352 nuts were atomized at the different
dates and that 244 or about 69 per cent of those treated contracted the
disease. Thirty-five of tfie treated nuts dropped before final results
were obtained and were not counted in the results, although the chances
are that a large number of these were also diseased and would still
farther have increased the percentage of diseased nuts.

Table showing results from atomizing nuts on an early-blooming tree.

Observation.

Experi-
ment.

l? II

!
j

Nuts
atomized.

P1

Diseased

nuts

li

It
!

Diseased
nuts

!f|

P

Diseased
nuts

fl

P^

Healthy..

1

1 431

7

11

0

0

17

2

0

21

2

0

20

3

?

1 431

7

11

o

o

17

s

1

21

3

3

?.

1

3 _. ._

1 431

8

11'

o

0

17

5

1

21

7

1

2

0

4

1 431

21

11

o

o

17

7

9

21

13

4

30

0

5

1 431

punctured

branch

21

positive

1 203

6

14

0

o

21

3

1

25

2

a

20

1

7

1 203

10

14

0

o

17

9

1

21

3

a

?,0

0

g.

1 203

7

14

o

o

17

1

9

25

1

2

?0

1

9

1 203

21

positive

10

2 203

23

14

o

o

17

n

4

25

5

10

90

j

11 __. _.

2 203

9

14

0

0

21

0

3

25

0

5

?,0

o

12

2 203

13

g

o

o

21

2

o

25

1

s

90

10

2 203

punctured

branch

25

positive

25

10 220

10

17

1

0

21

9

0

25

5

8

26

0

33

14 444

g

25

o

4

5-2

o

6

5-20

o

1

90

1

34

14 444

11

25

1

7

5-2

?

7

5-20

4

7

9,0

0

35

14 297

10

21

o

0

4-25

1

4

5-2

4

4

90

36

17 462

5

25

o

o

5-2

9

0

5-20

2

1

90

q

37

17 462

19

25

0

q

5-2

5

V>

38

17 462

12

25

2

4

5-5

fi

o

90

0

39

17 462

punctured

«•

twig

4-25

positive

50

21 462

13 large

25

0

9

5-2

o

2

5-20

7

5

<>0

1

51

21 462

12 large

25

0

0

5-2

0

6

5-20

4

8

90

0

53 ..

21 462

22

25

4

4

5-2

1

14

5-20

5

1F>

90

9

64 . __

28 462

6

5-5

0

1

5-20

4

1

10

1

65

28 2

8

5-5

o

0

5-20

9

1

5-20

2

1

20

5

Totals-

247

8

31

51

74

70

79

34

Atomizing on Early Tree.— The preceding table shows the results
from inoculation by atomizing of small nuts on a very early blooming
16—231

354

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

tree. The season of blooming for 1908 was about three weeks later than
that of 1907. During the period that this experiment was taking place
there was no natural infection developing on the nuts of this tree or in
the orchard. The climatic conditions were decidedly unfavorable for
blight development. From these inoculations a fair percentage of the
nuts became diseased, while from those that dropped no accurate data
was secured.

It should be remembered that the season of 1908 was one in which the
nuts were practically free from blight, and yet from our atomizing
experiments the blight could be produced when the germs were placed
on the nuts, although the percentage was somewhat less than that of
1907, because of the less favorable conditions. The small amount of
blight for 1908 was due largely to a lack of foggy weather, which is one
of the chief ways in which the germs are distributed to the nuts from the
old natural sources of infection on the branches.

Table showing source of culture and tests of puncture inoculation on young shoots.

Number of
culture.-

Date
of isola-
tion.

Source of
isolation.

Date
puncture
inocu-
lations.

Results.

Date

of 'obser-
vation.

Remarks.

13

06

Unknown

4- 2-08 i

Positive

4- 4-08

Cultured two years

330
36C

1- 3-07
1- 3-07

Pith _.__
Pith

2-22-08
2-22-08

Positive
Positive

4-24-07
4-24-07

86B
92A

2-6-07
2- 6-07

Wood and bark-
Bark

3-19-07
4- 2-08

Positive
Positive

5-10-07
4-25-08

Cultured one year

97A

2- 9-07

Wood

3_27-07

Positive

5-30-07

133B

2-22-07

Inner bark

4-11-07

Positive

5-30-07

144A
145A

2-27-07
2-27-07

Wood and bark...
Wood

4-24-07
4_ 2-07

Positive
Positive

5-27-07
5- 9-07

186A

3-14-07

New growth

4-16-07

Positive

5- 9-07

202B

3-27-07

Small nuts

4-16-07

Positive

5- 9-07

203B

3-27-07

Small nuts

4-16-07

Positive

5- 9-07

203B

3-27-07

Small nuts

4- 1-08

Positive

4-11-08

Year-old culture.

220A

4- 2-07

Small nuts

4-27-07

Positive

5-16-07

289A

5-17-07

White substance

Positive atomizing experi-

290A

5-17-07

on surface of
lesion.
Twig

6- 8-07

Positive

6-19-07

ments .

323A
325B

10-25-07
10-25-07

Wood and bark___
Bark

4- 2-08
4- 2-08

Positive
Positive

4-25-08
4-25-08

Fine results.

335A

11- 5-07

Pith —

5-11-08

Doubtful

6- 1-08

344B

11-16-07

Bark

4- 2-08

Positive

4-11-08

347A
348B
363A
366B
367A
371B
372O
399B
403C
417A

11-16-07
11-16-07
12- 3-07
12-12-07
12-12-07
12-19-07
12-19-07
1- 7-08
1-16-08
2- 4-08

Wood

Wood and bark-
Wood and bark___
Wood and bark
Wood and bark
Wood and bark___
Wood and bark-
Nut on tree. _
Wood and bark
Wood

4-2-08
4- 2-08
5- 5-08
5-20-08
5- 5-08
5- 5-08
5-5-08
5- 5-08
5-20-08
5-20-08

Positive
Positive
Positive
Positive
Positive
Positive
Positive
Positive
Positive
Positive

4-11-08
4-11-08
6- 1-08
6- 1-08
6- 1-08
6-1-08
6- 1-06
6-1-08
6- 1-08
6- 1-08

421X
431X
435A

440B
444A
460B

2-4-08
2-19-08
2-19-08

3-3-08
3-12-08
4- 3-08

Nut on tree
Wood and bark—
Wood and bark—

Wood and bark
Wood

Bark

5-20-08
4- 1-08
5-20-08

5-20-08
4-14-08
5-11-08

Positive
Positive
Positive

Positive
Positive
Positive

6- 1-08
4-17-08
6- 1-08

6-1-08

5-20-08
6-20-08

Fine results.
Isolation from puncture in-
oculation 97A.

461A
462A

4- 3-08
4- 8-08

Wood and bark-
New nuts -

5- 5-08
4-17-08

Positive
Positive

6- 1-08
4-25-08

Fine results.

465

4-14-08

New nuts

5- 6-08

Positive

5-20-O8

467

4-17-08

New leaves

5-6-08

Positive

6-1-08

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 355

Puncture Inoculation. — The puncture experiments shown in the pre-
ceding table were on young growing shoots with culture from potato
cylinders after three ,to five days' growth. These experiments give
almost uniformly positive results. During the past two seasons many
such inoculations were made and a few of these are summarized in the
preceding table. Many other cultures of yellow organisms that some-
what resemble the walnut blight growth were also tested, but with nega-
tive results. The table shows, furthermore, that cultures isolated from
pith, wood, bark, nuts and leaves all produced the typical blight lesions.
In several instances cultures that had been grown on artificial media one
and two years gave positive results from puncture inoculations.

MORE DETAILED ACCOUNT OF INOCULATION EXPERIMENTS.

The following description gives more detail regarding certain of the
more suggestive experiments :

1. Puncturing of Nuts. — April 2, 1907, seven young nuts were inocu-
lated by puncture with a sterilized needle carrying germs from a pure
culture of walnut blight. April 12th five of the nuts were still attached,
and all showed infection at every place where punctured.

2. Contact Inoculation. — April 2, 1907, six small nuts were inculated
by simply placing the sticky bacterial growth from a pure potato culture
in contact with the nuts without making a puncture of any kind. April
12th four of the nuts were still attached and showed positive infection
at points of inoculation.

3. Atomizing Nuts. — From culture isolated about six months previ-
ously and cultivated .during the meantime in artificial media. April 12,
1907, 5 p. m., eight small nuts were atomized with culture from potato,
eight days' growth. The day had been cloudy most of the time and
was still cloudy when the experiment was made. April 30th six nuts
were attached, three of them healthy and three diseased at one or two
points. May 9th six nuts were attached and four of them had one or
two points of infection. A shoot inoculated at the same time by punc-
ture showed positive infection.

4. Atomizing nuts from culture of 'blight isolated from diseased new
growth. — April 16, 1907, six small nuts were atomized with six days'
growth of organism on potato cylinders. This culture was originally
isolated from blight on new growth. May 9, 1907, the six nuts were
still attached and showed fine positive results with many points of
infection. Is the use of a culture recently made from blight on new
growth the cause of so fine positive results ?

5. Atomizing nut by using solution of water and diseased tissue. —
April 27, 1907, six small nuts on a late blossoming tree were atomized

356

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

by using a solution of water and diseased nuts. May 21st six nuts were
attached and four of these were diseased, each on one to four places.
Other nuts on the tree were free from blight.

6. Atomizing at Various Hours of the Day. — June 8, 1907, small nuts
were atomized at different periods, 9 to 10 a. m., 5 to 6 p. m. The
results are tabulated in the following table :

June 8,

1907.

Number
atom-
ized.

Results
June 14.

Results"
June 19.

Results
June 24.

Remarks.

9:00a.m.

6 nuts

+ -

0 6

6 0

9:10

7 nuts

1 5

3 3

6 0

1 nut dropped.

9:25

5 nuts

0 5

1 5

5 0

9:35

12 nuts

__

5 0

7 nuts dropped.

9:56

7 nuts

1 6

7 0

4:20 p.m.

10 nuts

0 10

5 5

10 0

4:25

5 nuts

0 5

0 5

4 0

1 nut dropped.

4:35

5 nuts

__

2 3

4 1

5:20

4 nuts

0 4

0 4

4 0

5:35

9 nuts

0 8

0 8

8 0

1 nut dropped.

5:50

6 nuts

0 6

1 5

6 0

Totals-

76 nuts

2 49

12 44

65 1

10 nuts dropped.

The results from experiment 6 show no difference in the infecting
power of the organism for the different hours of the day. The day was
bright, sunny and warm. Another interesting fact was that the orchard
was being irrigated at the time the atomizing inoculations were made.
The ground continued to be wet for about a week after the experiment
was made, and the results were exceptionally fine, as all the inoculations
showed many points of infection. The nuts treated, with hardly an ex-
ception, were all badly blighted with hundreds of points of infection.
The extreme virulence of the infections are probably because of favor-
able external conditions, due without doubt to the additional moisture
in the air from the evaporation of the irrigation water. On this tree,
as well as on trees in orchard not treated, no additional development of
blight occurred, and it is not probable that irrigation in any way in-
creases the amount of blight in an orchard, as at the time walnut
orchards are irrigated the conditions necessary for carrying the germs
from the sources of infection are usually lacking. From our field obser-
vations we have never associated in any way an increase of blight with
orchard irrigation.

7. July 2 and 3, 1907. — Atomized twenty-six nuts of different sizes,
as follows: 5 nuts 1J inch diameter, 13 nuts 1J inch diameter, 8 nuts
If inch diameter. The weather at this time was very bright and hot, as
it was for several days following. The temperature was about 100° F.
during the middle of the day. The atomizing was, however, done be-
tween 5 and 5 :30 p. m., when it was somewhat cooler. The results on
July 16th showed' 5 of the If inch diameter nuts to be negative and 3

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

357

positive, 10 of the 1J inch diameter nuts negative and 3 positive, and
3 of the 1J inch diameter nuts negative and 2 positive. August 1st,
however, showed all of the 26 nuts to be more or less diseased. The
smaller nuts were covered with many different points of infection, while
the larger nuts had a much smaller number of diseased places, usually
about twelve on each.

8. The following table shows that there was very slight infection in
the afternoon, when the sun was shining brightly and the spray from
the atomizer evaporated rapidly. The influence of the bright sunlight
would also kill many of the organisms in the liquid atomized on the nuts.
The nuts that were infected from the afternoon atomizing had very few
places of infection as compared with those of the early forenoon. The
atomizing in the early forenoon produced a large number of infections
one month after inoculation; those atomized in the afternoon showed a
very small percentage of infection as well as few points of infection :

Results Results

July 13,
3907.

Number
atom-
ized.

July 23.

August 14.

1

Infection points on each nut.

Positive.

Negative.

Positive. Negative.

7:20 a.m.

8 nuts

0

7

6

0

10 to 50.

7:30

3 nuts

0 3

0

3

Negative results.

7:35 I 3 nuts

0

3

3

0

7:45 j 10 nuts

0

10

10

0

5 to 100.

7:50

2 nuts

0

2

1

1

Diseased at I

8:00

15 nuts

1

14

5

10

10 to 20. \

3:00p.m.

4 nuts

0

5

1

2

1 spot.

3:20

4 nuts

0

4

1

3

1 spot.

3:25

5 nuts

0

5

1

4

3 spots.

3:30

3 nuts

0

3

0

3

3:40

7 nuts

0

7

0

7

INOCULATIONS ON OTHER SPECIES OF JUGLANS.

Puncture inoculations were tried on the several species of Juglans that
were available. These trees were not of an age to produce nuts, so little
atomizing was done. Experiments were made on the eastern black,
Juglans nigra; on the northern California black, Juglans hindsii; on the
southern California black, Juglans calif ornica; on butternut, Juglans
cinerea; on Japanese walnuts, Juglans cordiformis and sieboldiana. Be-
sides these experiments, others were made on several hybrids. Paradox
hybrid, a cross between the English and the California black walnut ; the
Royal hybrid, a cross between the eastern and California black.

Eastern Black. — These were seedlings that had grown two years in our
nursery from Iowa, black walnuts. Last season 's growth had been cut
off in grafting and vigorous-growing sprouts had come up from the roots.
Inoculations were from pure cultures on these vigorous-growing sprouts.
No difficulty was found in producing the typical disease lesions.

358 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Northern California Black. — These were seedling trees growing in our
station nursery. Vigorous, fast-growing sprouts from roots that had
been grafted were inoculated by puncture and gave definite positive
results. One observation is worthy of mention. In a single case the
walnut bacteriosis was observed to have spread from one of the positive
puncture inoculations to the nearby leaves of the tree. On these leaves
typical black spots appeared on the soft tissue of the leaf, as well as on
the veins, which were blackened. The black areas of the leaf appeared
to be quite characteristic and somewhat different from the effect on the
English walnut, in that the black, diseased and partially dried-out
tissue was surrounded by a narrow, yellowish-green zone just between
the dried-out and healthy tissue. Artificial cultures were made by
plating out directly from the diseased tissue and gave yellow colonies
which produced the characteristic growth on potato cylinders.

Southern California Black. — A single tree about five years old was
first used in this experiment work. Nuts were atomized in the same way
as with English walnuts and gave positive results. May 11, 1909, nine
nuts were atomized with a water solution of the walnut organism that
had grown on potato for six days. May 18, 1909, three nuts showed
positive infection and six negative. Later observations did not show
further infection on the other atomized nuts. Puncture inoculations on
nuts and shoots were also made. The punctured nuts often gave positive
results, but inoculations on the shoots of this tree gave negative results.
This may be accounted for because of the woody, hard growth. Later
puncture experiments on young southern California black seedlings gave
fine positive results and there can be no doubt as to the organism being
able to infect the southern variety.

Butternut. — Puncture experiment on a two-year-old seedling gave fine
positive results.

Japanese Walnut. — J. cordiformis and J. sieboldiana were inoculated
by puncture, but gave rather uncertain results. Positive inoculations
were produced in a few cases, but usually the lesion formed did not
appear typical, being simply a depressed, blackish spot without the usual
water-soaked zone surrounding the puncture. These later healed up
readily and would seem to show negative results. Results on these two
species are not as conclusive as could be desired: but we believe that on
young, vigorous, succulent growth infection could be produced.

Hybrids. — Fine positive puncture inoculations were produced on the
Royal Hybrid, the Paradox and Strong Hybrid (a local Paradox
Hybrid). These hybrids are vigorous in growth and the disease
develops fully as well as on either of the blacks or the English walnut.

Walnut blight was found during the spring of 1909 on the nuts of a

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

359

Paradox Hybrid and typical cultures were obtained from the diseased
nuts. Probably all species of Juglans can be made to take the disease,
although it has not been found in nature on either the eastern or Cali-
fornia black. Even the black seedlings in the nursery, where the dis-
ease usually appears, are free from the trouble. Blight infection occurs
not uncommonly on hybrids.

Pecan seedlings were also inoculated very thoroughly to see if it
would be possible to produce the blight by using pure cultures of the
walnut organism. Only negative results were obtained.

Desiccation. — Several experiments were made to test out the effect of
drying or desiccation on the walnut organism.

Methods. — The general method of testing out the resistance of the
organism was as follows :

First a tube of Dunham solution or other liquid medium was inocu-
lated from a pure culture and after a faint cloudiness, was visible usually
after twenty-four hours, a loopful of this growth was placed on half inch
cover glasses that had been sterilized in a petri dish. These were kept
in darkness and tested out by dropping them in tubes of sterilized liquid
media and if growth took place, dilution plates were poured and trans-
fers made from them to potato cylinders. If the characteristic, vigor-
ous, piled-up, yellow growth occurs here there is little doubt of its being
that of the walnut bacteriosis. In some of the last of our desiccation
work it was found to be necessary to make dilution cultures from the
tubes which had been inoculated with the desiccated cover glasses, in
order to be positive that the growth was due to that of the walnut blight
organism. In this work transfers were made directly to potato cylinders
from these inoculated tubes. The growth on potato is the most con-
clusive single test by which to identify this organism.

Experiment I. — November 5, 1908, 3 p. m. Sterile cover glasses were
inoculated with a two-millimeter loopful of a 22-hour culture made by
inoculating a tube of Dunham solution. These cover glasses were kept
in darkness at 20° C. and tested out as indicated in the following table :

Time of desiccation.

Number
tubes.

Date of
inoculation
media.

Date of
planting.

Result.

Date of
observa-
tion.

] day -.

9

11- 6-08

11- 9-08

8 tubes show blight

11-18-08

2 days

8

H_ 7_08

11 10-08

7 tubes show blight

11-18-08

3 days

9

11- 8_og

11 10-08

0 tubes show blight

11 18-08

4 days

9

11_ 9-08

11 13 08

1 tube shows blight

11-30-08

6 days

9

11-11-08

11-18-08

3 tubes show blight

12-10-08

8 days

10

11-13-08

11-18-08

3 tubes show blight

12-15-08

360

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Experiment II. — Made further test of resistance to desiccation on
December 18, 1908, under similar conditions to those indicated under
Experiment I. The following table shows tabulated results :

Day of desic-
cation.

Number
tubes.

Date of
testing
covers.

Date of
planting.

Number with
growth.

Number with
walnut blight.

Date of
obser-
vation.

3 days

10

12-21-08

12-26-08

2 tubes with growth

2 show blight

-12-09

5 days

14

12-23-08

12-30-08

2 tubes with growth

2 show blight

-12-09

7 days

17

12-25-08

12-31-08

3 tubes with growth

1 show blight

-12-09

8 days

10

12-26-08

12-31-08

1 tube with growth

1 show blight

-12-09

10 days

13

12-28-08

1- 4-09

1 tube with growth

1 show blight

-12-09

12 days

20

12-30-08

1- 4-09

2 tubes with growth

1 show blight

-12-09

9Q days

14

1_ 7_o9

1 12 09

4 tubes with growth

4 show blight

1-21-09

29 days

13

1 16-09

1 20-09

3 tubes with growth

0 show blight

1 15-09

The experiment showed very few tubes with the blight organism alive
even after three days, but some of the tubes show growth of the organism
even after twenty days.

Experiment 777.— January 2, 1911. Used a three-day-old culture
growing in a meat peptone glucose bouillon made as follows : 5 gm.
Liebig meat extract, 5 gm. NaCl, 10 gm. Witte's peptone, 1,000 c.c.
distilled water, 5 gm. glucose (Merck). Tfiis same medium was also
used in which to test the desiccated cover glasses. A loopful of culture
was placed on each sterilized one half inch cover glass, using a 2 mm.
loop on the platinum needle. These covers were dropped into the above
medium at given intervals of time, as is shown in the following table :

Date of inoculation.

Number
tubes.

Number days
desiccation.

Results.

January 1 1911

5

3 days

4 tubes with walnut bacteriosis

January 9, 1911 - .

10

7 days

5 tubes with walnut bacteriosis

January 12, 1911 .__

10

10 days

10 tubes with walnut bacteriosis

January 17, 1911

10

15 days

10 tubes with walnut bacteriosis

January 20, 1911

10

18 days

10 tubes with walnut bacteriosis

January 25 1911

10

23 days

8 tubes with walnut bacteriosis

February 10, 1911 __

11

39 days

7 tubes with walnut bacteriosis

March 1, 1911 . __

10

57 days

4 tubes with walnut bacteriosis

March 16, 1911

10

73 days

1 tube with walnut bacteriosis

The inoculated tubes were incubated at 20° to 25° C., as well as the
inoculated potato cylinders. The desiccating cover glasses were kept at
about 15° C. This organism belongs to a genus in which are several
yellow chromogenic organisms that are quite resistant to drying.

Experiment IV. — This experiment was a combination of desiccation
and influence of light. March 9, 1908, a tube of Dunham solution was
inoculated. After three days' growth at 20° C. this liquid was atomized
on living olive shoots about one year old.

Series 1. The same liquid was atomized on a small English walnut

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

361

tree one year old that had been cut off. The bark, however, was still
green and had not dried out at the time of the experiment.

Series 2. Pieces of the atomized bark were then cut out from time
to time and dropped into the test tubes of nutrient media, in the same
way that cover glasses were used in the other desiccation experiments.

SERIES I.

Number days drying.

Number tubes.

Positive.

Negative.

1 day

3

2

1

2 days

3

1

2

H days *

3

1

2

1 days _ _. -_- - _-

3

2

1

1? days - - _ _-

3

0

3

SERIES II.

' day

3

2

1

2 days

3

1

2

4 days _ _____

3

2

1

17 days

3

0

3

Growths in the inoculated tubes were plated out and transfers of
yellow colonies were made to potato cylinders. The characteristic
growth on this medium was taken to be conclusive evidence that the
growth was that of the walnut bacteriosis organism.

ACTION OF GERMICIDES ON THE WALNUT ORGANISM.

Considerable work has been done in experimenting upon the effective-
ness of various germicides in killing the walnut organism. Copper
sulphate, mercuric chloride, formalin, potassium permanganate and
sodium benzoate were used in this work.

Method. — The following method was employed in testing the killing
of organism :

A pure culture of the walnut blight organism was grown for twenty
to forty-eight hours in Dunham solution. The culture tubes at this time
were considerably clouded with growth. Then three loopfuls of the
culture were transferred with a 2 mm. loop to tubes containing the
germicide under experimentation. The germicide was always made up
with distilled water and of several different strengths. In each tube
there was a definite amount of the germicide, either 5 or 10 c.c. In all
cases, except formalin, the tubes were sterilized on three successive days
for twenty minutes.

Copper Sulphate.— In this experiment the commercial copper sulphate
was used with distilled water. The following strengths were tested :
1/10 per cent, 1/100 per cent, 1/500 per cent, 1/1000 per cent,
1/2500 per cent, 1/5000 per cent.

362 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Each of the tubes to be tested had 5 c.c. of the copper sulphate solu-
tion and was sterilized on three successive days. There were three
tubes of each of the preceding dilutions as well as three check tubes
of distilled water. Each of the tubes was inoculated with three loopfuls
of a walnut blight culture grown in Dunham solution for forty-eight
hours. The loop of needle was 2 mm. in diameter. Three hours after
being inoculated dilution plates were made from each of the tubes under
experiment by transferring three loopfuls of the inoculated germicidal
tube to meat peptone agar. These plates constituted series I of the
experiment. After six hours from inoculation of tubes containing the
germicide a second plating out from the tubes was made in the same
manner as the first.

The results after seven days' growth in the Petri plates showed that
no growth resulted in the plates of series I made from 1/100 per cent,
1/500 per cent, 1/1000 per cent or 1/2500 per cent copper sulphate.
In the check tubes as well as in the 1/5000 per cent, a large number of
colonies developed.

The three plates made from the 1/5000 per cent had 8, 30 and 60
walnut blight colonies, while the two check plates had 200 and 225
blight colonies, and the third plate had a spreading, white, foreign
organism that covered the entire surface of plate and covered up the
walnut blight growth.

In series II, plated out after six hours' incubation, no growth
occurred during seven days.

Another experiment made earlier in the study gave almost the same
results. The 1/100 per cent, 1/500 per cent and 1/1000 per cent killed
the organism, while the 1/5000 per cent failed to do so. No test was
made of the 1/2500 per cent in this experiment. The per cent of
copper sulphate sufficient to kill is somewhere between 1/2500 and
1/5000 per cent.

Mercuric Bichloride (corrosive sublimate). — The same general
method was employed as with copper sulphate. Four tubes each of
the following strengths were used in distilled water : 1/100 per cent,
1/500 per cent, 1/1000 per cent, 1/5000 per cent, and 1/10000 per
cent and two check tubes of distilled water. All were sterilized and
then inoculated with four loopfuls of a 24-hour growth of the organism
in meat bouillon. In four hours from inoculation, plates were made
from each tube. After six days' time no growth developed in any but
the check plates and these showed 41, 48 and 150 colonies each.

Another experiment with corrosive sublimate, using more dilute
strength in distilled water, was made. Three tubes of each of the
following strengths were tested: 1/1000 per cent, 1/10000 per cent,
1/50000 per cent, 1/100000 per cent, 1/500000 per cent, and 1/1000000

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 363

per cent. Dilution plates were made after three hours' time, using
four loopfuls from each tube to inoculate the agar tubes. In seven
days the following results were given: Growth in 1/10000 per cent
and the weaker strengths.

Carbolic Acid. — The following per cents were made, using distilled
water to properly dilute the 5 per cent stock solution of carbolic acid
(Merck) : 1/2, 1/4, 1/10, 1/25, 1/50, 1/100 per cents, four tubes of each
and three check tubes of distilled water. Tubes were inoculated
with three loopfuls of walnut blight culture and dilution plates were
made after three hours. After six days 1/2 and 1/4 per cents showed
either no growth or at least not walnut blight. The other lower per
cents 1/10, 1/25, 1/50, and 1/100 showed some growth. The 1/10 per
cent developed 12 and 7 colonies in two of the plates, while the other
two showed no growth.

An attempt wus at first made to use the carbolic acid with a solution
containing peptone, but the results are not exact because there was a
precipitate due to the chemical action of the acid with the peptone. A
series of tubes containing Dunham solution and carbolic acid was made
and the tubes inoculated with three loopfuls from a four days' growth
in meat bouillon. Growth and cloudiness of tubes occurred in 1/25,
1/50 and 1/100 per cents. No growth in tubes having 1, 1/2, and 1/4
per cents. Plates were made from the tubes and the results obtained
agree with the statements above.

Formalin. — A 1/25 per cent solution acting for three hours on the
organism was effective in killing. A solution of 1/50 per cent formalin
acting for the same time did not kill.

Potassium Permanganate — A solution of 1/500 per cent acting for
three hours killed the organism.

Sodium Benzoate. — This chemical was tested but showed poor germi-
cidal action. A solution of 1 per cent did not kill the organism even
after six days' time. This strength was sufficient to inhibit growth of
organism when used in Dunham solution, but when plates were made
from these tubes colonies of walnut blight developed.

CONTROL OF WALNUT BLIGHT.

Spraying. — The earliest attempts at the control of this disease con-
sisted, as has been the case with most plant diseases, in spraying with
Bordeaux mixture. Pierce carried on a considerable amount of such
work and at his suggestion a number of growers gave this method of
treatment quite a thorough trial. As a result of his work Pierce recom-
mended spraying with Bordeaux mixture just before the trees came

364 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

into leaf in the spring, and also a later spraying during the early
summer if the latter should be considered necessary or practicable.
He likewise urged the removal of all affected twigs and fruit spurs.
Professor Pierce stated that by following these recommendations
thoroughly it was possible to reduce the number of blighted nuts by
fifty per cent. Mr. E. G. Ware, of Garden Grove, while in charge of
a large walnut grove near Placentia, which belonged at that time to
Thum Brothers, carried on what was probably the most extensive and
most carefully conducted experiment along this line. For several
years he sprayed thoroughly with Bordeaux mixture, using large blocks
of trees and leaving unsprayed trees or rows as checks. Mr. Ware
came to practically the same conclusion as Professor Pierce, namely,
that the number of blighted nuts could be reduced about 50 per cent
by spraying with Bordeaux mixture just as the buds are swelling.
Neither of these experimenters was able to state any distinct increase
in the crop obtained by spraying, but it should be said that such a
measure of results is practically impossible in seedling walnut groves
on account of the extreme variation in the production of the various
individual trees. Mr. Ware also experimented with the application
of lime to the soil after Professor Pierce 's suggestion, with the idea
that this might produce a firmer, harder tissue in the growth of the
trees and thus render them less susceptible to blight. He believed
that some benefit was derived from such an application, using large
quantities of air-slacked or sugar-beet factory refuse lime. Other
growers have sprayed their walnut trees with Bordeaux mixture and
various other materials at different times, but it may be said in a
general way that such practice has never become common and for
several years it has been entirely discontinued.

At the commencement of this work in 1905 plans were made to carry
on very thoroughly and systematic spraying experiments in order to
determine definitely the extent to which blight control could be accom-
plished by this means. In the spring of 1906 several large blocks of
good sized seedling walnut trees were obtained for this purpose in the
vicinity of Whittier and spraying operations were commenced. The
principal experiments were made with three different fungicides,
Bordeaux mixture, lime-sulphur, and a sulphur spray made by boiling
together sulphur and caustic potash. The work was done with a power
sprayer, and was carried on more thoroughly and carefully than any
grower would be likely to do such spraying and without regard to
expense. In one instance a large block of trees was sprayed with
Bordeaux mixture, using a 5-6-50 formula, in another a heavy lime-
sulphur was used, the spray being prepared by boiling, while in the
third the potash-sulphur spray mentioned above was used. It was

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 365

found in all this work that to spray large walnut trees thoroughly is
an. extremely slow, difficult, and expensive operation. In the case of
the largest trees no attempt was made to spray more than two thirds
of the tree from the bottom up, inasmuch as the top could not be
thoroughly covered without using a very high platform. Our experi-
ence was that to spray a good sized tree thoroughly or to cover even
two thirds of an extra large tree required at least twenty gallons of
material. We found further that with the outfit used, consisting of
three men to spray and one to mix, not more than fifty good sized
trees could be sprayed in one day, while with the largest ones thirty
was about the limit of a day's work. It was found further that even
when the work was done with apparent thoroughness on these large
trees many portions of the top remained unsprayed the first time
over. This was detected particularly in spraying with lime-sulphur,
where the sprayed and unsprayed portions of the tree showed up in
strong contrast as soon as the spray had dried. For this reason it was
found necessary with these large trees to go back over them sometimes
two or three times in order to be sure that every twig and branch
which might harbor blight lesions was covered with the spray. As
regards expense, we found that we could not thoroughly spray good
sized trees for less than about 50 cents each, counting labor and
materials, while with many of the largest trees the outlay amounted to
at least $1.00 per tree even though the top of the tree was not sprayed
at all. As a result of this experience we were led very soon to believe
that the general spraying of California walnut groves for blight con-
trol would be extremely difficult of accomplishment during the period
of time available for such work, and also that it would be extremely
difficult, if not absolutely impossible, for the average grower to get
the work done thoroughly enough, even though the spraying done by
ourselves should prove extremely effective in controlling the disease.

During the summer following our spraying careful observations
were made from time to time of the condition as to blight of the sprayed
and unsprayed trees in the experimental orchards. From such obser-
vations no difference whatever in the prevalence of the disease on the
nuts could be detected. Many of the sprayed trees lost a large portion
of their crop from blight, and even on individual, rather small trees
or individual branches which had been especially well sprayed and
absolutely covered with the mixture much blight developed on the nuts,
and it soon became apparent that no satisfactory degree of control, if
any, had been secured by our work. In the fall weighings were made
of the crop from the various trees and blocks, but owing to the extreme
variation in the crop of individual seedling trees the result was the
same as in our fertilizer experiment described on page 185, namely that

366 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

no conclusions whatever could be drawn. This much, however, was
very evident from observation, that a very large amount of blight
developed on many of the sprayed trees and that no decided benefit in
the season's crop of nuts had been obtained by the spraying. Even
where trees or branches had been perfectly and entirely coated with
heavy lime-sulphur solution, a large number of blighted nuts appeared.

As a result of our experience in 1906, first with the cost, difficulty,
and slowness of spraying large walnut trees, and second with the lack
of effect of such spraying, we became thoroughly convinced that the
possibilities of walnut blight control did not lie in this direction.
Furthermore, as the prospect of obtaining varieties of the walnut more
or less immune to the disease, and likewise of much better quality and
much greater production than the average seedlings, became brighter
and brighter the undesirability of spraying methods became still more
pronounced. For these reasons no further extensive spraying experi-
ments were made by us and we still believe that the ultimate control of
walnut blight does not lie in this direction. It should be stated, how-
ever, that during the following year, that is in 1907, the appearance of
the trees sprayed in the spring of 1906 gave some reason to believe that
the blight was less prevalent on the sprayed than on the unsprayed trees.
This was particularly true in the case of trees sprayed with lime-
sulphur. It is, therefore, not improbable that while infection of the
nuts during the year when the spraying was done was not prevented,
that the twig and shoot infection was somewhat controlled and that on
this account less blight was carried over winter and less nut infection
took place the following year. It is further possible and quite likely
that thorough spraying year after year would have a cumulative effect
and might eventually reduce the amount of blight to a noticeable and
satisfactory extent. Even if this were true, however, we have not felt
that it would be practical to accomplish this to any general extent on
account of the reasons mentioned above.

During the past season or two there has been a considerable revival of
interest in walnut spraying in one portion of the State, namely, in
Santa Barbara and Ventura counties. This has been due to the impor-
tance of the walnut industry in that region, the serious prevalence of
blight, and to the fact that a certain proprietary remedy or mixture has
received considerable prominence in that locality and has been used in
a large part of the spraying which has been done there. Walnut spray-
ing having thus become somewhat customary in the counties mentioned,
some work has been done there with Bordeaux mixture and various other
materials which have suggested themselves to the growers. We do not
wish to discourage such attempts at blight control in a region where
some of our oldest and finest seedling groves exist, one which is espe-

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 367

eially adapted to walnut culture, and where the maintenance of the
present groves is of as much or perhaps more importance than the possi-
bilities of planting new ones. The chief problem in walnut blight
control by spraying lies, in our opinion, not so much in the discovery of
a specific for the disease, since there is no reason why any good fungicide
should not be as good as any other for this purpose, but rather in the
development of means of spraying these large trees rapidly and econom-
ically and at the same time thoroughly. Investigations are still being
continued along this line, particularly in cooperation with Mr. C. W.
Beers, horticultural commissioner of Santa Barbara County, and a
renewal of spray work along new lines and upon a considerable scale is
being prepared for.

Blight Control by Means of Applications to the Soil. — Various sug-
gestions and experiments have been made along the line of applying
various substances to the soil with the idea of controlling walnut blight
by this means. Especially prominent has been the application of lime,
mostly beet factory refuse. It is impossible to state definitely just
what may have been accomplished by such methods as these, but it is
very certain that nothing of this sort has resulted in blight control to an
extent at all significant or important. In trees which are suffering for
plant food the growth may be stimulated and increased by heavy appli-
cations of stable manure or nitrogenous fertilizers, and as a result of
this the crop may be increased and the loss by blight lessened. This we
believe to be the extent of any good results which may be obtained by
the application of any substance to the soil.

Resistant Varieties. — It has been noted ever since walnut blight first
became prevalent in California that there is a great difference in indi-
vidual trees as to the extent to which they are affected by the disease.
Some trees regularly lose almost all their nuts by blight, others are no-
ticeably free from it, while others vary from year to year, being badly
blighted one year and comparatively free from the disease the next. As
a result of such observations the possibility of selecting or producing
blight immune varieties was suggested several years ago. Pierce in his
work considered this phase of the matter, and brought together a collec-
tion of walnut species and varieties from various parts of the world, as
well as local selections, with this object. On account, however, of the
discontinuance of his walnut work no definite results along this line have
ever been announced by Professor Pierce. Various nurserymen have
also worked to some extent along the same line, endeavoring to pick
out and propagate from individual trees of uniformly large production
of nuts. The fact was early established that the extent to which indi-
vidual trees blight depends with much regularity upon the season at
which the trees develop in the spring, trees late in coming out being

368 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

freer from blight than those which open their buds earlier in the
season. The reason for this difference was easily apparent, being con-
nected with conditions of atmospheric moisture. Trees coming out late
escape the spring rains and fogs, which period is by far the worst for
blight infection. Some observations seem to indicate that trees com-
ing out unusually early in the spring are also freer from blight than
the average, and there appears to be some truth in this fact. If this
is correct, it is probable that these early trees escape blight infection
owing to the lower temperature which prevails at the time when their
shoots and nuts are young and easily susceptible. We have shown
elsewhere that the blight organism requires a fairly high temperature
for its most vigorous development. These early and late blight-free
trees really escape infection therefore, rather than actually resisting
it, or rather they escape it at the time when they are most susceptible
and then are able to resist any later infection on account of the maturity
of their tissues. It is true, however, that certain individual trees have
some actual resistance to the disease, even at susceptible periods, and
those having such immunity are of course the most desirable type.

In seeking blight-resistant or immune walnut trees there must at the
same time be kept in mind the fact that freedom from blight is not
the only quality necessary in the walnut, since we must also have a
tree of heavy production, with nuts of desirable size, form, color, full-
ness of meat, flavor and other qualities which go to make up an ideal
walnut. The strongest emphasis should also be laid on the fact that
the performance of a single tree in a given locality, either as to blight,
bearing qualities, or character of the nuts does not justify its exploita-
tion for all parts of California under the widely different conditions
which exist in different localities. Freedom from blight in a certain
tree or variety in a given locality may be due simply to the fact that
the disease is not present or conditions not favorable to its development
in that particular place. When planted in another locality the same
variety may prove to be one of the very worst affected by blight. Again,
a given variety may produce very heavily in one locality under certain
climatic conditions and not in another. Again, a tree may be free from
blight and produce a very large crop of nuts one year or even for several
years, and then later on develop the disease very badly and produce
only a very few good nuts. Again, a tree or variety may be actually
immune to blight to a large extent and still be a very small producer
or produce nuts of an undesirable type in size, form, color, flavor, or
some other characteristic. Still again, a variety may have only slight
immunity to blight and yet have so much vigor of growth and tendency
toward heavy production that the resulting crop, in spite of the blight,
will be much larger than that of a more resistant but less productive
tree. Still further, one variety may produce very heavy crops of nuts

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 369

of only fair quality, while another may be a small producer of extra
fancy nuts. All these and other considerations go to show that one
cannot be too careful and conservative in recommending and exploit-
ing a variety for general planting on the basis of its immunity to blight
or the quality and quantity of its product. Only after several years'
experience in any given locality can the qualities of a certain variety
be fairly estimated, and even then its behavior in other localities, where
conditions are considerably different, cannot be safely foretold without
actual trial. Many a walnut grower has bought high-priced trees from
a distance on account of enthusiastic advertising and extravagant praise,
when there were scores of trees in his own locality which might have
been propagated from with much better results than those which he
will obtain from his high-priced trees, brought from a distant portion
of the State, where the whole reputation of the variety rests perhaps
upon the performance of one individual, original tree. We have dis-
cussed the various varieties now on the market as fully as possible in
another place. If our descriptions and estimations seem to be lacking
in positive, definite statements, it may be understood that this is not
on account of lack of acquaintance with the varieties mentioned, but
is simply due to the fact that they have not been widely tested, and
their qualities cannot be positively stated in justice either to the variety
or to the public.

The control of walnut blight by means of immune varieties presup-
poses to a very large extent the planting of new groves in place of the
present seedling, irregular, blight-susceptible ones. Many, however,
will feel that such a solution of the problem falls far short of complete
satisfaction on account of the large acreage of seedling trees now in
existence which have cost much effort and expense to produce, which
would be fairly profitable were it not for the blight, and which it is
a very serious matter, or perhaps almost entirely out of the question, to
think of replacing with new trees of better varieties. Especially in
Orange, Los Angeles, Ventura, and Santa Barbara counties do such
groves exist, and this bulletin would not be complete without a dis-
cussion of the future prospects and best methods of handling these
seedling groves, composed of large healthy trees in normal, thrifty
condition, save for the attacks of blight upon the crop.

Working Over Seedling Groves to Better Varieties. — The situation
now confronting the seedling walnut growers of California is not a
unique one, inasmuch as the same condition has confronted in turn
the growers of the apple, peach, orange, lemon, and all our other culti-
vated fruits. The seedling orange grove is still with us to a consider-
able extent, and the seedling apple orchard is still easily within the
remembrance of the present generation. It is not, therefore, an unusual
situation which the walnut grower has to face, and he may rest assured

17—231

370 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

that it will eventually result in the entire replacement of the seedling
tree by definite varieties propagated by grafting or budding. In our
most familiar instance, that of the orange, the problem of what to do
with the thrifty old seedling grove has been easily solved by top-working
these trees to better varieties. With the orange and other citrus fruits
this is a comparatively easy operation. With the walnut, however, it is
by no means as simple and yet not at all impossible. A few growers,
notably one, have attacked the problem in this way with very excellent
results. Mr. J. B. Neff, of Anaheim, who had an old walnut grove
planted as seedling trees, commenced a systematic effort several years
ago of improving his trees by top-working. For several years he
observed the grove carefully, picking out the poorest-producing and
most blight-susceptible trees, and also one tree which seemed by far the
heaviest producer and least affected by blight of any in the orchard.
Having located his very poorest trees and the best one, he commenced
operations by cutting off the tops of the poor trees just above the main
forks and top-grafting them with scions from the good tree. The suc-
cess of the first year's grafting was very good, although some misses
occurred which had to be worked over again the next year. During the
second year more trees were cut off and worked, and with the working
over of the previous .year's misses the whole work extended over three
or four years before the grove reached a condition satisfactory to the
owner. The ultimate outcome has been, however, that the average
quality and productiveness of trees were very much increased, and
after about four or five years practically all the grafted trees have as
large tops as those which had not been top-worked. As to the effect of
this work upon the production of the grove, Mr. Neff states that he does
not think that the cutting off of the poorest trees diminished his total
crop after the first year. One eighth of all the trees in the orchard
were top-grafted the first year and one fourth of the total trees the
second year, making altogether three eighths of the trees which were
cut off and worked over. The total number of trees cut off and grafted
was about 200. In 1907, the year previous to the first grafting, the
total crop was 20,406 pounds. The grafting was done in 1908 and 1909.
In 1911 the total crop was 26,297 pounds. During the intervening
years the crop was smaller than in either 1907 or 1911, varying consid-
erably along with the walnut production at large in southern California.
Mr. C. B. Franklin of Carpinteria has also done considerable work
along this line, working over his poorest trees into better kinds. At
the Pasadena City Farm, near Alhambra, a large number of seedling
trees about six years of age have been worked over into various varie-
ties, in this case top-grafting a whole row or a solid block of trees at one
time rather than picking out the poorest ones. The work here was
quite uniformly successful at the first attempt and very little regrafting

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 371

has been necessary. Various other growers have top-worked a greater
or less number of orchard trees with varying success. The whole
matter rests largely upon the skill of the operator who does the grafting
and the care and attention given to the trees after grafting until the
new tops are well established. Men who are able to top-graft the
walnut with fairly uniform success are decidedly uncommon and yet
there is no particular mystery or secret about the operation. It depends
entirely upon mechanical skill in this sort of work, knowledge and
judgment of the peculiarities of the walnut tree, and particularly upon
great care, thoroughness and attention to details in selecting and keep-
ing the scions, doing the grafting, and the subsequent care of the grafts,
especially during the first season. Unless prepared to give the work
this special care and attention until new tops are well established upon
the trees we would not advise any grower to attempt to improve his
walnut grove by top-working. If, however, he can give the work such
attention, either in person or through reliable, competent help, we would
strongly advise any grower to follow Mr. Neff's example, pick out his
poorest trees and work them over into a better variety, either by select-
ing scions from an especially good tree in the immediate neighborhood
or by putting in some good variety among those which we describe
elsewhere. Again, however, we would emphasize the fact that if the
grower cannot undertake this work with the assurance of giving it
careful, continuous attention, he would much better leave his grove in
its present conditionz since otherwise he will find himself with a lot of
trees composed of a mass of sprouts coming from the cut-off branches,
the latter decaying and dying back in the stubs where they were cut,
leaving the grove in much worse condition than before.

Other than top-grafting, the only method of bringing about improve-
ment in a seedling grove is by means of more regular and abundant
irrigation, pruning and thinning out the tops if they are too thick,
heavy fertilization with stable manure or nitrogenous fertilizers, and
such other improvements in cultural practice as may suggest them-
selves. These matters we have discussed on pages 182-192.

The problem of the seedling walnut grove is being readily solved in
many portions of southern California by the rapidly increasing value
of land and the prosperous condition of the citrus industry. Many
hundreds of acres of thrifty seedling walnut trees have been cut out in
Los Angeles and Orange, and, to some extent, in Ventura County, during
the past few years, and planted to citrus fruits, especially lemons. At
the high valuation now placed upon the best land in these counties, it is
doubtful if any present variety of walnut could compete with the lemon
or Valencia orange, and the walnut acreage is very rapidly being trans-
formed into citrus groves. This tendency becomes more and more pro-
nounced every year.

372 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

DIE-BACK.

The most conspicuous disease or trouble affecting walnuts in southern
California is that characterized by this name. Two general types of die-

FIG. 90. — Die-Back, caused by dry soil and cold weather.

back may be distinguished, one on old trees, particularly hard shells,
which die back slowly all over the top, and another occurring suddenly
during a single winter in all or part of the limbs, which may die back

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 373

down to the main forks of the tree or the tree may die outright clear to
the ground. The former type of die-back, affecting old trees slowly,
occurs mostly on light soils where the roots find insufficient moisture as
they become crowded together and extend down into a dry, sandy sub-
soil. The second form of die-back mentioned, that occurring in trees
which have formerly been thrifty, killing them down to the forks or
even to the ground, is sometimes an effect of frost, but occurs especially
with or without freezing in cases where the ground has become too dry
during the fall and winter. This is of quite common occurrence in
walnut groves, especially in certain seasons when the rainfall is deficient
during the fall and early winter. At this time of year irrigation of
dormant deciduous trees does not seem to be urgent and serious damage
sometimes occurs. In a cold locality or season this damage may be very
much increased by frost, when, if the soil had been sufficiently moist, no
die-back would have occurred. The remedy is therefore obvious, and it
is significant that fall and winter irrigation of walnut groves is coming
much more into practice every year. It may be said in general that
almost all die-back of walnut trees is connected with the matter of soil
moisture. Usually it is the direct result of a dry subsoil, although in
old, closely planted groves the trouble may be increased by a lack of
proper distance between the trees, deficiency of plant food, and similar
factors.

Instances are sometimes seen when the opposite condition prevails,
die-back being caused by an excess of moisture in the subsoil, a condi-
tion of which the walnut tree is extremely intolerant. Such damage
may be seen to a marked extent in some of the coastward regions of
Ventura County and in other parts of the State, where, on account
of floods or other unusual conditions, the ground water has risen in
walnut groves close to the surface.

SUNBURN— BLACK SAP.

Serious damage is sometimes caused from this source, both to the
fruit and the tree. This we have already discussed to some extent on
page 177, in considering the relation of climatic conditions to walnut
culture. The sudden occurrence of extremely hot, sunny weather
when the nuts are nearly full grown may produce a blackening and
burning of the husk on one side, causing the husk to stick to the shell,
making separation difficult and causing a black spot which may extend
through into the meat. Continuous hot weather may cause a darkening
or brownish color of the meat which would otherwise be nearly white,
without a burning of the outer husk. This varies to a large extent in
different varieties.

374 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

FIG. 91. — Sunburn or "black-sap" on trunk.

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

375

On the tree itself the trunk is frequently affected by sunburn,
causing on large trunks a condition frequently called by the growers
"black sap." This consists of a considerable area on the south or
southwest side of the trunk where the inner bark is dead and from
which the sap of the tree oozes out, oxidizing and turning black, as is
the habit of walnut sap whenever exposed to the air. This form of
sunburn occurs more commonly in the winter rather than in the
summer, and takes place at times when the days are hot and the
nights are cold. These conditions produce an irregular activity of
the sap, which causes the trunk to be especially susceptible to the
heat of the sun. The cambium is killed, usually on the southwest
side of the trunk, and the sap then escapes, oxidizes and ferments in
the affected area and a large wound may result in which ordinary

FIG. 92. — Sunburn on nuts.

decay sets in. It is on account of this form of sunburn that high
grafting on black walnut stock is advocated in order to obtain the rough-
barked trunk of the black walnut. We have seen cases, however, when
even the latter was affected by this form of sunburn. Young trees
during their first year after planting in the orchard often become
badly sunburned in the trunk and on this account should be protected
after planting, as discussed on page 253. For the same reason it is
better to cut the trees well back before planting and grow a new stem
from one of the lower buds, as described on page 251. The whole
matter of sunburn, either on the fruit or the wood, is influenced to a
very large extent by the moisture conditions of the soil. In all cases
trees with an abundant moisture supply, and especially if in fairly
heavy soil of good water-retaining properties, are much less affected
by any form of sunburn, either summer or winter, than those which
are suffering for water.

376 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

PERFORATION.

This has come to be one of the most serious troubles of the walnut
grower during recent years. The effect is that shown in Fig. 93 and
consists in a non-development of the outer hard layer of the shell.
The meat or seed of the walnut is covered normally by four different
layers of tissue. The first of these is the pellicle or seed coat, the thin
membrane just over the meat which adheres closely to it and follows

I «

'"'• <•*
• (

f*.

FIG. 93. — "Perf oration" of walnuts.

all the convolutions and irregularities of its shape. Outside of this
is what we call the shell, which consists of two distinct layers, a thin,
inner, parchment-like one, forming the lining of the shell, and a hard,
bony outer layer. The fourth coating mentioned is composed of the
husk on the outside of the nut which opens and allows the nut to fall
out at maturity. In perforated nuts the hard shell is not actually per-
forated, but rather fails to develop. In such nuts the meat and pellicle
develop normally and over them the thin, inner lining of the shell.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 377

The hard, outer shell is deficient and fails to develop properly. This
failure, or in other words the cause of perforation, is not thoroughly
understood, but is probably connected with one of two factors, or
possibly both. These are, the fertilization or pollination of the nut dur-
ing the blooming period and its nutrition during development. Per-
foration has been especially abundant under two conditions: first, in
unusually dry years, especially when the trees were badly affected with
the walnut aphis; second, in young trees which are making a particu-
larly thrifty growth. The trouble also varies to a considerable extent
in individual trees, some being affected every year and others never
showing this trouble. In some instances there has been some indication
that the trouble was worse in years when pollination was interfered
with, either by extremely dry weather or frost during the blooming
period. This, however, is not well established. It seems most probable
that the disease is due to lack of nutrition of the nuts due to dryness of
the soil, exhaustion of the trees by aphis attacks, or, in the case of young
trees, a vigorous development of wood at the expense of the nuts. If
this be true it may be expected in the case of young trees that they
will gradually outgrow the trouble as they become older and divert
their energies more toward crop production, while in the case of older
trees abundant irrigation throughout the year and the control of aphis
(which we discuss elsewhere) offers most promise in the prevention of
perforation.

CROWN GALL.

This disease which is common in most fruit trees does not often
affect the walnut seriously, although now and then a badly affected
tree like that shown in Fig. 94 may be found. The trouble manifests
itself as a large swelling or gall at the base of the trunk either just
above or just below ground or both. It is caused by a bacterial organism
of a decidedly parasitic, infectious nature.

Occasionally a nursery tree is found affected with this disease,
although it is very much less common in the walnut than in the peach,
apricot, almond, apple and other trees. It has generally been sup-
posed that only the English walnut root is susceptible to crown gall,
but we have recently seen a case of a northern California black walnut
root badly affected with this trouble. This, however, is decidedly
uncommon. Any nursery tree which shows this trouble should be
discarded. Trees affected in the orchard show a failure of growth,
gradually falling behind the other trees in size, and should be dug
out and replaced as soon as detected. The galls may be chiseled out

378

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

and disinfected with some success, but the trouble cannot be entirely
overcome in this way. Usually decay sets in, as shown in the illustra-
tion, and the tree eventually breaks off.

FIG. 94. — Crown gall.

ROOT ROT.

(OAK FUNGUS— TOADSTOOL DISEASE.)

The English walnut root is quite susceptible to the so-called oak
fungus or toadstool disease, which occasions the loss of many fruit
trees of various kinds in California. This disease consists in a decay
of the roots, in which the white mycelium of the fungus may be found
between the affected bark and wood. Occasional clusters of toadstools
appear at the base of affected trees. The disease usually, if not always,
occurs in spots where oak trees formerly stood and when once started
spreads from tree to tree in quite a regular concentric manner.
Experience has amply demonstrated that our native black walnut roots
are immune to this fungus and we have seen cases where English walnut,
prune, almond and other roots have been picked out and killed, while
northern California black walnuts interplanted with these trees
remained entirely unaffected. It is altogether probable that all of our
black walnut species and hybrids are highly resistant if not totally
immune to this disease.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 379

SEEDLING ROOT ROT— WILT.

Nursery seedlings of the southern California black walnut occa-
sionally wilt and die rather suddenly and show, on examination, a
black rot of the main root just below ground. This may appear either
before or after grafting, and ordinarily, at the worst, picks out only
a tree or two here and there, even in a large nursery. We have known
of only one case where serious loss was experienced from this source,
and this on poorly drained land where the trees were injured by an
excess of water. The trouble is caused by a soil fungus, and seems to
be confined to the southern California black.

LITTLE LEAF, "YELLOWS."

In this disease spindling yellow shoots develop wihch usually die
back from the top. All degrees of the trouble may occur from slightly
unnatural yellowing and slenderness of the normal shoots to the produc-
tion of abnormal clusters of small, yellow, sickly shoots with very slen-
der, yellow, poorly developed leaflets. Such shoots in bad cases usually
die back at the end of each season. This disease affects the English
walnut and is even more pronounced on the northern California black
in certain seasons and places. It has been abundant even on black
walnut trees of large size in some parts of northern California during
the last two or three years and very prevalent in nursery trees of the
northern California species grown in the southern part of the State.
The southern California black walnut is, so far as our experience goes,
immune to this disease, while the Paradox and Royal hybrids, especially
the latter, are much less susceptible to it than either the English or
northern California black. This disease is not confined to the walnut
but is evidently the same as the so-called " Little Leaf" of the grape,
peach, apple, quince and umbrella treez and the mottled leaf of the
orange. The "Frizzles" or "Rosette" of the pecan seems also to be
of a similar nature. Experience has shown beyond any reasonable
doubt that the occurrence of all these troubles has been the result of
the abnormally long dry seasons of the past three years. These diseases
have occurred particularly, or in fact altogether, on soils where for any
reason the subsoil has become very dry during the latter part of the
season. Such condition has been most commonly caused by sandy or
gravelly subsoil but may also result from the presence of hardpan or
a layer of heavy soil within two or three feet of the surface. The con-
trol of this trouble lies entirely in irrigation, especially in the late
summer and fall during seasons when the rains are late in commencing.

380

UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

If the soil is kept well watered during this period this disease need
not be feared. In the case of hardpan or heavy soil underlaid by
dry subsoil some growers have resorted to the practice of blasting with

FIG. 95. — Little leaf or yellows ; on northern California black above, on
English at the left below. Normal branch at the right.

dynamite in order to let the water down through into the subsoil. We
believe this to be an excellent method of procedure. The most impor-
tant factor in the prevention or avoidance of little leaf lies in the choice

BULLETIN 231]

WALNUT CULTURE IN CALIFORNIA.

381

of a root for the walnut. Also the selection of soil upon which to
plant this crop. Land having a sandy or gravelly subsoil within four
or five feet of the surface should, if possible, be strictly avoided for
planting a walnut orchard. The same is true of soil underlaid by
hardpan. In any case it is very desirable to blast each hole with

FIG. 96. — Placentia walnut tree on English root, affected by yellows. Trees like
that shown in Fig. 63, on southern California black root, are of same age
and interplanted alternately with these.

dynamite before planting in order that the subsoil may be shaken up
and easy access of water permitted. No tree already affected with
this disease should be grafted, either in the nursery or in the case of
black walnut trees planted in orchard form. The pervalence of this
trouble is another argument in favor of the hybrid root or the southern

382 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

California black, the latter at least in the southern part of the State,
or for varieties which come out early in the spring. A very good illus-
tration of the difference in respect to this disease produced by differ-
ent roots was seen in a walnut orchard near Whittier during the past
season. In this case trees of the Placentia Perfection variety had been
double planted, the permanent trees on southern black root and the
fillers on English. During the latter part of the season of 1911 the
difference between the trees on the two roots was very marked, those on
the English being smaller, with yellow foliage and narrow leaflets, the
leaves falling to the ground early in the fall. The alternate trees on
southern California black root were larger, bore a better crop and had
dark green, vigorous looking foliage which remained on the trees much
later than that of the other trees.

SHRIVELED MEAT.

Much trouble is experienced with walnuts in certain seasons on
account of the meat being shriveled and poorly developed. This affects
some varieties and some individual trees more than others and is often
much worse the same year in certain localities than in others. The
trouble is more apt to affect varieties which come out late in the spring
than those which develop early. It is usually, though not always,
worse on such varieties in the southern part of the State than in the
northern, and this indeed is one of the principal reasons why very late
varieties are not adapted to southern California. A tendency toward
this trouble is one of the worst faults of the Eureka in the southern
part of the State, and the same is true of Franquette, Hale, Concord,
San Jose, and in fact almost every late variety that has been tested in
southern California. The northern part of the State is by no means
free from this trouble, but it is less common there and is usually con-
fined in certain seasons to certain localities, although it does not affect
the same locality every year. In 1911, for instance, the Franquettes
were quite generally poorly filled and light meated in Sonoma
County, while in the vicinity of San Jose and Stockton such was not
the case. In other or, in fact, in most years, Sonoma County Fran-
quettes have been as well filled as any. The cause of this poor devel-
opment or shriveling of the meat has been ascribed to various influences,
none of which have been positively proven to bring about this trouble.
The influences suspected have been the same as those to which per-
foration or non-development of the shell have been laid, namely poor
pollination, lack of soil moisture, and the attacks of the walnut aphis.
Which of these actually causes the trouble has not been positively
determined. In the southern part of the State it is probable that the

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 383

pollination of late varieties is hindered by extremely dry weather which
is likely to occur at the time when they are in bloom, and it is also
true that during the season of 1911 late spring frosts occurred in
many localities in the northern part of the State, which may have
interfered with the proper setting of the crop. Aphis has likewise
been very abundant during the last two or three years, and this con-
dition has been coincident with short rainfall and lack of soil moisture,
especially in the subsoil. While the disease cannot at present be
attacked specifically, we believe that its control, along with that of
perforation, yellow leaf, and, in fact, most of the troubles which affect
the walnut will be greatly contributed to by the control of the aphis
and attention to proper irrigation of the subsoil. The latter can usually
be readily accomplished where irrigation water is available and the
grower should watch carefully the moisture condition of his subsoil in
dry years by actual examination down to a depth of at least six feet.
Where no irrigation is possible dry farming methods should be sys-
tematically pursued, consisting in deep plowing so as to catch as much
as possible of the winter rainfall and deep and thorough summer
cultivation to retain such moisture in the ground. The control of
aphis we discuss under the next heading.

APHIS.

The walnut is comparatively free from insect enemies, and we shall
not attempt to present a complete description of every insect which
may at times be found attacking the tree. One enemy of this sort,
however, is of particular importance and should be mentioned here.
This is the green aphis or plant louse. This insect has become so
abundant during the past two years on walnut trees of almost every
species all over the State that it may be considered fully as important
as the much dreaded walnut blight.

The walnut aphis is a small, soft, green insect which occurs on the
under side of the leaves, often in considerable abundance. The insect
itself is less conspicuous than the secondary effects which it produces.
These are, first, an abundant secretion of honeydew, a sticky, liquid
substance with which the foliage and the ground or vegetation beneath
the trees becomes covered. The second conspicuous effect consists in
the development of a black, smutty mold which grows upon this
honeydew and covers the leaves and fruit of the walnut and every-
thing else upon which the honeydew has dropped. This insect and
its attendant effects have always been common in occasional seasons,
but during the past two years there has been an unusual prevalence
of aphis in most parts of the State, both on English and black walnut

384 UNIVERSITY OP CALIFORNIA EXPERIMENT STATION.

trees. The insect feeds by sucking the nutritive juices from the
foliage of the tree and when abundant it may injure the tree to no
little extent by so doing. In dry years, when the trees are already
somewhat weakened, the bad effects are increased. It is also probable
that the tree is injured more or less by being coated over with honeydew
and sooty mold. The insect multiplies most freely in seasons or places
of rather cool, moist, summer climate, and is largely suppressed by
continuous hot sunshine. Its effects are therefore worst in regions
near the coast. In addition to the direct injury to the tree caused by
the aphis and its honeydew, there is some possibility that these effects
are connected with perforation of the walnut and also shriveling or
poor development of the meat. In all events these troubles usually
occur together, and years when there is an abundant development of
aphis, there has also usually been more perforation and more poor
meats. This may be the effect of the insect or it may be that all these
troubles occur more abundantly under the same conditions, partic-
ularly in a season following a dry winter. Another well-established
effect of the aphis is connected with the spread of the walnut blight
organism. There is no question that these insects in crawling about
and puncturing the leaves spread the blight to a considerable extent.
All in all, therefore, we believe that the control of aphis is one of the
most important problems of the walnut grower if the insect continues
to develop as it has during the past two or three years.

APHIS CONTROL.

The only feasible means of controlling this insect appears to be by
spraying with the most effective substance at the most effective time.
No definite experiments have been made along this line, nor has the
insect ever been carefully studied so far as we are aware.1 It appar-
ently winters over upon the walnut tree, probably in the egg form,
so that it may be possible by a winter spraying to exterminate the
insect during the dormant season. Various winter spraying of wal-
nuts has been done by different growers, using lime-sulphur and other
similar sprays. The results of such spraying as to aphis control seem
to be somewhat doubtful. Some have thought that much benefit was
obtained, the amount of aphis during the following summer being much
reduced, while others could see no such effect. Summer spraying is
effective against many other kinds of plant lice, and there is no reason
why the walnut aphis could not be controlled in the same way, except
that the trees are large and the spraying expensive. Mr. George

'It is described and illustrated by E. O. Essig in The Monthly Bulletin, Cal. State
Com. of Hort., Vol. 1, No. 5, p. 190.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 385

f

Williams of Goleta has done a considerable amount of summer spraying
with a tobacco spray with very satisfactory results. The following
mixtures may be suggested for work of this sort.1 In applying them a
special effort should be made to spray the under side of the leaves, as
this is where the insects are found. Spraying should be done as early
in the season as possible in order to exterminate the insects before they
multiply. It is hoped that systematic experiments along this line may
be made during the coming season.

Soap Solution.

Soap 1 pound.

Water 5 to 15 gallons.

Whale-oil or fish-oil soap preferable, but for small amounts any yel-
low laundry soap will answer.

Tobacco Soap.

Blackleaf 40 _ 1 pound (1-10 gallon).

Cresol soap, 1 gallon or whale-oil soap 10 pounds.

Water 200 gallons.

The cresol soap requires no heating.

BLISTER MITE— ERINOSE.

This is a very common trouble of the walnut tree but not a serious
one. Its effects are seen in the form of blister-like swellings or eleva-
tions on the leaf surface, which are convex on the upper and concave
on the lower side of the leaf. These swellings are caused by numerous,
very small insects which live within the blisters on the under side of
the leaf amongst a felt-like, hairy growth which develops there. While
this effect is very common, it produces no appreciable injury and needs
no treatment for its control.

RED SPIDER.

This is a very small mite which sometimes becomes extremely abun-
dant on walnut leaves, causing them to dry and even to fall from the
tree. The insect is not ordinarily serious except in very hot climates, to
which the walnut is not well adapted. In such situations red spider
usually hastens the dropping of the leaves caused by too intense sum-
mer heat.

Circular 66, Cal. Agr. Expt. Sta.

18—231

386 UNIVERSITY OF CALIFORNIA — EXPERIMENT STATION.

%

APPENDIX.

WALNUTS IN FRANCE.

We have thought it worth while to present excerpts from a trans-
lation of the following excellent article by Mr. F. Lousourd, taken
from Revue Horticole, volume 83, 1911, pages 310, 329, 358, 378.

"We prefer to study the varieties by regions and have divided them
into three groups.

1. Nuts of the Southeast.

2. Nuts of Central France.

3. Varieties Belonging to Various Regions.

This classification has some advantages; the varieties cultivated in
the same region prove to be similar, and the comparison of character-
istics is thus easy.

NUTS OF THE SOUTHEAST.

Mayette. — The Mayette walnut is large, slightly elongated, widened
and flattened at the base, even slightly depressed toward the peduncle.
It easily stands upright on its base, and this characteristic alone
suffices to distinguish it from other varieties of the Isere to which it
has some resemblance. The shell, half-hard, of a light amber color,
terminates at the apex in an obtuse, somewhat pronounced point; it
protrudes slightly along the suture of the valves from the lower third
as far as the point. The average dimensions of the walnut are as
follows : length 44 mm., breadth 34 mm. ; it weighs, dry, from 10 to
11 grammes. A hectolitre (2.85 bushels) of the dry walnuts weighs
from 30 to 33 kilogrammes (66 to 73 pounds).

The origin of this variety is very obscure. It gets its name from the
name Mayet who, according to some, imported it from Naples and
according to others obtained it from seed. It has been cultivated nearly
one hundred and fifty years in the department of Isere, where it is
located within the cantons of Tullins, Vinay and Saint-Marcellin. It
is found on the well exposed terraces bordering both banks of the Isere
from Moirans to Vinay.

Of all the varieties of walnuts cultivated in France, the Mayette is
the most beautiful. The fine, fair shell, well filled, contains a kernel
possessing the delicate flavor of the hazelnut. The nut for dessert is
par excellence, and when the crop is light the merchants dispute over
the price. It always sells for a greater price than other varieties ;
in an ordinary year it brings from 75 to 80 francs per 100 kilogrammes,

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 387

dry. (About 7 cents per pound.) The highest price for which this
is sold ranges from 110 to 120 francs (10 to 11 cents per pound). It
is always sold in the shell ; it is exported to foreign countries, especially
to the United States.

The Mayette is a walnut of Isere which dries better, and, at the
same time, whose yield is most assured in a soil and climate which
favors its culture. But this variety is very exacting and in the valley
of Gresivaudan it scarcely exceeds an altitude of 400 meters (1300
feet above sea level) ; if it is cultivated beyond this limit, it loses in
quality. On the other hand it requires fertile soil and abundant and
regular manuring.

In spite of its quality, which places it in the first rank of table nuts,
it is hardly probable that the Mayette will extend outside the area
which it occupies in the department of Isere. Moreover, the agricul-
turists in regions producing the Mayette are making an effort to limit
it. For some years there have been planted here and there (Haute-
Savoie, Cher, etc. ) some walnut trees of this variety ; it is still too early
to form any conclusions from present results.

The tree is vigorous and blossoms late but rapidly. In consequence
it makes a fine sight. It is fitting to add that in the above mentioned
cantons, the Mayette comprises nine tenths of the orchards. It con-
stitutes orchards whose mass of stately trees give a picturesque aspect
to the country. In a certain number of townships of Isere, the pro-
ducts of the Mayette tree form the principal resources of the agricul-
turist.

Parisienne. — The Parisienne nut is large, oblong and nearly as wide
at the top as at the base. It stands less easily on the base than the
Mayette. The point, the apex of the shell, is almost imperceptible.
This is somewhat hard, rather rough and of dark color.

The average dimensions are as follows : length 40 mm., width 36 mm.
The average weight of a hectolitre (2.85 bushels) of dry nuts varies
from 30 to 33 kilogrammes (66 to 73 pounds).

Like the Mayette, the Parisienne is a special variety of the depart-
ment of Isere. The crop is produced especially in the canton of Vinay
and somewhat in the canton of Saint-Marcellin. The color is less
fine than that of the Mayette, but the kernel is good and completely
fills the shell. Although less choice than the Mayette, and selling for
less, it is, nevertheless, one of the better varieties for dessert. It is
less exacting than the Mayette and may thrive at an altitude exceeding
400 meters.

The tree is vigorous, flowering late and for rather long duration,
which favors its resistance to spring frosts and assures regularity of
crops. The crops are quite large.

388 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Franquette. — This variety was found by Franquet, a litte less than
a hundred years ago, close by the Notre Dame d 'Osier (a town in
the vicinity of Saint-Mar cellin). The Franquette nut is large, elon-
gated, narrow, exceedingly pointed, the apex terminating in a very
pronounced point. The shell, hard and of a dark color (?), presents
a pronounced depression along each rib of the line of suture of the
valves; it is rough and very wrinkled. The green kernel fills the
cavity well and the dry kernel is of good quality though inferior to
that of the Mayette. The average dimensions are as follows : length
48 mm., width 37. The average weight of a hectolitre (2.85 bushels)
of dry nuts varies between 33 and 35 kilogrammes (73 to 77 pounds).

The Franquette walnut is located in the department of Isere, where
it abounds on the hills situated between Vinay and Saint-Marcellin.
The tree is vigorous, spreading, flowering late; it produces regularly
and thrives well in dry soil. The fruits are exported in shell to
America. They bring on an average 5 francs less per quintal than
those of the Mayette.

The three varieties described above (Mayette, Parisienne, Fran-
quette) are designated in commerce by the name Noix de Grenoble
(Grenoble nut).

Noix de Vourey. — The Vourey walnut is scarcely harvested except
in the town of Vourey (Isere) and in neighboring localities. It has
somewhat the shape of the Mayette, although it is smaller. It is a
nut of average size, a little elongated, slightly flattened at the base,
and terminating at the apex in a very pronounced point. The shell
projects along the line of suture of the valves, extending from the
lower third to the point. The average dimensions are as follows :
length 35 mm., width 29 mm.

This is a nut of two purposes, good for table use and very good
for the manufacture of oil. Its shell, very thin and tender, of a clear
color, presents a good appearance; the kernel is of good quality.
The Vourey nut is not held in reproach for its small size ; but in spite
of its size, it is sold partly in shell for dessert, and very often it is
cracked and sold as green kernels which are fine and fill the shell
well. From the last point of view it is a very choice variety. Besides,
it bears from the third year. It is more precocious than the Mayette,
the Parisienne and the Franquette.

The tree is vigorous, spreading and very productive. It blossoms
late (on an average ten to twelve days after the Mayette and Fran-
quette).

Meylan. — This is originally from Meylan (Isere), where its culture
is nearly nil, nearly all the trees of the Persian type being on the road

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 389

to disappearance. But it is found here and there in the department
of Isere.

This nut is large or very large, round, flattened at the base, slightly
pointed at the apex. The shell, of a clear color, is soft and nearly
smooth. The large, delicate kernel fills the cavity well. The dimen-
sions are as follows : length 38 mm., width 36 mm.

The Meylan blossoms late and, for this reason, it escapes nearly all
the spring frosts ; its crop is a little more sure, especially in a year not
wholly favorable for the production of the walnut. The tree is vig-
orous and very spreading. For purchase when mature, this variety
is not as popular as the Mayette, which is ideal for dessert. It sells
for a little less, but the tree being less delicate and less exacting as
regards climate and fertility of the soil, the Meylan will give very
good results in a place not suited to the Mayette.

Gautheronne. — The Gautheronne is little known. However, the trees,
are scattered here and there in the canton of Tullins, (Isere). It has
very much the shape of the Chaberte, but it is larger and its shell is
smoother and the color clearer. It measures 40 mm. in length and
32 mm. in width. It is sold in the shell for dessert.

Chaberte. — This gets its name from Chaberte, its originator and pro-
pagator; it has been cultivated for a hundred and fifty years around
the environs of the department of Isere. It is a nut small or of aver-
age size, a little elongated, slightly pointed, having a hard, wrinkled
shell of dark color and very full; its kernel is delicate. The average
dimensions of the nut are, length 35 mm., width 30 mm. The nut,
dry, weighs about 9 grammes and the weight of a hectolitre (2.85
bushels) varies from 36 to 40 kilos (79 to 88 pounds).

The Chaberte blossoms late, almost as late as the Saint-Jean, which
it replaces advantageously. The tree, vigorous and productive, yields
regular crops. It is cultivated in Isere, within the plateau of Bizoir
from Voiron to Lyons. It is found in all the districts except those of
Saint-Marcellin. It is also cultivated in Savois, in the Drome and in
a few departments in central France.

It is utilized for the manufacture of oil; and especially since the
fresh kernels demand a high price, they crack the nuts and pack the
kernels in cases which are exported to America. According to M.
Rouault, Departmental Professor of Agriculture of Isere, the yield of
oil is 64 per cent or 12 litres (10.8 quarts) of oil to 20 kilograms (44
pounds) of kernels, but in practice they count on one litre of oil to
2 kilograms of kernels. The Chaberte (oil) pays at most from 26 to
32 francs ($5.20 to $6.40) a hectolitre (26^ gallons), a price which is
rarely exceeded; in ordinary years it varies from 15 to 28 francs per
100 kilos ($3 to $5.60 per 220 pounds).

390 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Petite Ronde. — The Petite Eonde, peculiar to the department of
Drome, where it is principally cultivated in the districts of Die, is, as
its name indicates, a nut of small dimensions. It measures on an
average 31 to 32 mm. in length by 30 mm. in width and weighs, dry,
from 6 to 7 grammes. A hectolitre (2.85 bushels) weighs 40 kilos
(88 pounds).

It is almost as wide as it is high, large at the top and slightly
depressed from the shoulder to the point, which is small, but pro-
jecting. The shell is rounded in the region of the base, which makes
it rather unstable on its base. The shell projects a little along the
line of suture of the valves in the upper half.

The Petite Ronde is of a beautiful dark yellow color; it is culti-
vated for sale fresh (for confectionery) and for sale of the fresh
kernels. There are 3 kilograms (6.6 pounds), 500 green kernels, in a
double decalitre (2J pecks) of walnuts. The tree blossoms late. It
yields large crops.

NUTS OF CENTRAL FRANCE.

Car erne. — The Careme is a little elongated, having a medium point
and a shell flattened and also slightly and irregularly depressed at the
base. The shell is projectile along the suture of the valves extending
from the middle. It is thin, tender, with a dull, very wrinkled sur-
face. It is of average size, 36 mm. in length by 32 mm. in width.
The average weight of a dry nut is 8J grammes and the weight of a
hectolitre (2.85 bushels) varies from 34 to 36 kilos (75 to 80 pounds).

The Careme is principally cultivated in the department of Aveyron,
particularly in the district of Villef ranche-de-Rouergue ; the greater
part of the walnut trees of the department are of this variety, which
has for its origin an old and magnificent tree situated on the route from
Capdenac, one kilometer to the north of Yilleneuve. This old tree
has a trunk measuring only 2 to 2J meters in height, and strong limbs
which extend laterally through a radius of from 10 to 12 meters; it
has formerly yielded as much as 6 hectolitres (17 bushels) of nuts. It
is this which has furnished grafts for nearly all the trees in the country.
The tree is spreading and bears well.

The Careme is sometimes sold for the table. It is very much valued
for the sale of the green kernels. Its shell is thin and the kernel fills
it well, with no waste space, the kind of nut which has little waste in
breaking. To-day they do not manufacture much oil, but formerly,
when the price of nuts was lower, preference was given to the Careme
nut for the manufacture of oil. They obtained, with the primitive
presses, a dozen litres of oil from 2 hectolitres of nuts. The nuts were
sold in 1910 for from 20 to 25 francs a hectolitre ($4 to $5 per 2.85
bushels).

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 391

Gourlande. — The Gourlande nut is very large, elongated, oval, with
shell deeply and irregularly sinuate, pointed at the apex. This shell
is extremely fragile and when dry it breaks and shatters with the least
shock. Therefore, the Gourlande is difficult to preserve dry. The
handsome nut measures 48 mm. in length by 40 in width and weighs,
dry, from 13 to 14 grammes. The average weight of a nut is 11
grammes.

The Gourlande is cultivated only in the department of Puy-de-Dome.
It is found in the townships of Chamalieres, Cebazat, etc. It is much
sought by confectioners. It is harvested when the kernel is still
white and the shell gelatinous. They pick them partly green and
preserve the kernel. The green nuts sell for from 25 to 40 francs
per 100 kilos ($5 to $8 per 220 pounds). A mature tree furnishes
perhaps 150 kilos (330 pounds) of green nuts for the confectioners.

They never keep the Gourlande nut to eat dry; nevertheless, it is
frequently sold fresh in August or September as a table nut. It is
rarely kept for the manufacture of oil; moreover, the crop is less by
one tenth that of the ordinary nut (noix commune).

The seed bed is the only method of propagation in use ; in no prac-
tice, it appears, has the Gourlande been propagated by grafting. Those
who have tried various systems of grafting have been disappointed.
By means of the seed bed, they obtain trees of which two thirds are
degenerate and ought to be rejected; there is, in consequence, a great
waste.

Corne.— The Corne nut, still called Coutras, Corne-de-boeuf, has a
half -hard shell. It is elongated, of ovoid form, of average size and very
pointed at the apex. The shell is of clear color with surface irregular
and deeply sinuate; it is depressed in the upper half along the line
of suture of the valves. The two valves are solidly sealed which qual-
ifies it for a good dessert nut, easy of transportation and of long preser-
vation. The kernel is fine and white. The average dimensions are
as follows: length 39 mm., width 30 mm. The average weight of a
dry nut is 8 to 9 grammes and the average weight of a hectolitre (2.85
bushels) 37 to 39 kilos (81 to 86 pounds).

The tree is vigorous and very productive; it blossoms generally at
the end of May.

The Corne nut is very popular in Lot. It is found in the environs
of Montvalent, Eocamadour. They cultivate it as well in Dordogne
(Sarladais) and also in Aveyron. Very choice in commerce, by reason
of the hardness of its shell and fineness of its kernel, it is spreading
(in commerce) to the detriment of other varieties. In 1910 it sold
for from 45 to 50 francs for 50 kilos or 90 to 700 francs per quintal.

392 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

Nave or Noix du Lot. — The Nave or Noix du Lot resembles the
Corne both in shape and in appearance. The shell is clear, ovoid, quite
pointed, slightly projecting along the line of suture of the valves in
the upper half ; the shell is tough and hard to crack ; it is less wrinkled
and more uniform than the Corne; it is much less elongated at the
apex and more flattened in the region of the point. The Nave is of
average size; it measures 39 to 40 mm. in length, 29 mm. in width.
The average weight of a dry nut is 8J grammes and the weight of a
hectolitre 36 to 38 kilogrammes in a good year; in 1910 the weight
was only 34 to 35 kilogrammes. The nut of Lot is very precocious and
always comes in a dozen days before other varieties. It is much
appreciated for commerce and exportation for the two following
reasons: Because the hard shell allows it to sustain handling without
breaking and arrive intact in America; because it is harvested early,
which permits the commencing of shipping about the 15th or 20th
of October, while the other varieties are not ready for exportation till
in November. They cultivate it in the environs of Cahors and in the
south of the department of Lot.

The Noyer du Lot blossoms late, May or June; they harvest the
nut to the end of September; the merchants buy the dry nuts from
the producers. Discarding the culls, they sulphur the nuts and send
them to Bordeaux and to Germany.

Lelande. — The Lelande is elongated, terminating at the apex in a
very pronounced point; the shell, very irregular and deeply sinuous,
is unsymmetrical at the base and a little flattened. The line of suture
of the valves is very projectile, especially in the middle. This nut
has a shell of clear color, thin and very tender, breaking easily; it is
unsuitable for transportation. The fact that its kernel is fine and
plump makes it a choice nut for commerce, put up in boxes and for
sale as green kernels. The average dimensions are as follows: length
41 mm., width 30 mm. The average weight of a dry nut is 9 grammes
and a hectolitre of dry nuts weighs from 35 to 36 kilogrammes.

The Lelande is cultivated principally in Correze and Dordogne. In
certain parts of Correze this variety is replaced by the Marbot, which
is more productive, larger, having a shell a little harder which can
stand transportation ; the Marbot also sells for a little more.

The tree attains an average size; it is very vigorous but it blossoms
early which makes the crops irregular. The yield is large when the
late frosts do not destroy the flowers. The Lelande nut sells on an
average of from 15 to 20 francs per hectolitre; in 1910 the price
reached 37 to 40 francs ; in 1900 it was worth from 10 to 12 francs and
in 1909 from 20 to 22 francs. A hectolitre (2.85 bushels) of nuts
makes from 15 to 16 kilogrammes (33 to 35 pounds) of kernels con-
taining 50 to 55 per cent oil.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 393

Marmot. — The Marbot is large or very large, terminating in the upper
part in a projecting point small and very sharp. It is flattened at
the base and stands perfectly upright. The shell, irregularly sinuate,
is depressed along the line of suture of the valves extending from the
lower third to the top. It is a nut with a tender shell, but sufficiently
firm to bear transportation.

The Marbot is especially cultivated in the department of Lot and
particularly in the environs of Vayrac, Gramat, Saint-Cere, and in the
entire north of the department. It is likewise cultivated in Correze
and in the environs of Maysac. It is larger than the Noix du Lot.
Its average dimensions are as follows: Length 43 mm., width 38 mm.
The average weight of a dry nut is 12 grammes and the average weight
of a hectolitre from 32 to 33 kilogrammes.

It is very valued in commerce as a dessert1 nut. The tree blossoms
from the end of April through May; it produces very regular and
satisfactory crops.

Gros Jean. — Likewise called Noix de Figeac. The fruit is large or
very large, having thick, hard shell from which the meat is with some
difficulty detached. The nut is a little elongated, oblong, slightly flat-
tened at the base, but it does not stand upright very evenly. At the
apex it terminates in a point, strong and sharp. The shell is hard and
wrinkled ; the line of suture of the valves is projectile, extending from
the lower third to the region of the point. The average dimensions
are as follows : length 42 mm., width 32 mm. The average weight of a
dry nut is 9J grammes and the weight of a hectolitre from 38 to 40
kilogrammes. The best nut weighs from 11 to 12 grammes. The kernel
is of good quality.

The tree attains large dimensions ; it is vigorous and very productive,
but it takes the original fertility from the soil. The nut, by reason
of the hardness of the shell which makes it difficult to break, is less
suitable than other varieties (Candelon, Lelande, Grand Jean) for
the production of the green kernel; on the other hand, it is excellent
for sale in 'the shell. It is cultivated in Lot in the neighborhood of
Souillac and in the district of Sarlat (Dordogne). It is cultivated also
in the environs of Figeac where it is propagated under the name Noix
de Figeac.

Grand Jean. — This variety is a little elongated, flattened at both
ends, terminating in the upper part in a point almost imperceptible.
It stands perfectly upright upon the base. The shell, projecting from
the lower third along the line of suture of the valves, is thin and tender
and well filled with a delicate white kernel. The average dimensions
are as follows : length 37 mm., width 30 mm. The dry nut weighs on
an average of 9 to 10 grammes and the weight of a hectolitre varies
from 35 to 37 kilogrammes.

394 UNIVERSITY OP CALIFORNIA — EXPERIMENT STATION.

i

The tree is vigorous and very precocious. By reason of its early
flowering it requires a warm exposure. It grows well in sandy soil.
The Grand Jean is very desirable for the sale of green kernels; it is
a variety much sought by the markets of Sarlat (Dordogne), Souillac
and Gourdon. It is cultivated in the districts of Sarlat. It yields
abundantly in the canton of Saint-Cyprien extending from Buisson
to Domme ; it is found, likewise, in the highest canton.

Candelou. — The Candelou is a small, slightly elongated nut with
thick and very pronounced point; the shell is irregularly flattened at
the base in a manner which does not permit it to stand upright.
The line of suture of the valves is a little projectile, extending from
the middle to the top. The shell, tender and thin, is very uniform
and does not adhere to the green kernel, which makes breaking easy
and rapid. The kernel is sightly and of good quality. The average
dimensions are as follows : length 34 mm., width 30 mm. The average
weight of a dry nut is 8 grammes and the average weight of a hecto-
litre is from 35 to 36 kilogrammes.

The Candelou is especially cultivated in the department of Lot
and particularly in the region of Gourdon and Souillac; it is also cul-
tivated a little in Dordogne in the part neighboring on the district
of Gourdon.

The tree blossoms very late. The kernels are especially suited to
be packed green in boxes. It is too small for the table. In 191C
it brought from 36 to 38 francs per hectolitre.

Noix de Brantome. — The Brantome nut is originally from Bran-
tome in the district of Perigueux (Dordogne), where it is considerably
cultivated.

It is a small walnut, a little elongated, having a tender shell of amber
color whose surface is a little wrinkled. It is slightly flattened at
both extremities. The point is almost nil and the line of suture of
the valves is slightly projecting. The average dimensions are as fol-
lows : length 35 mm., width 28 mm. The average weight of a dry nut
is 8 grammes and a hectolitre weighs from 37 to 38 kilos.

It blossoms early (commencing in May) and the trees are rather
exposed to late spring frosts.

In localities where the Noix de Brantome is cultivated, it is still
used for the manufacture of oil. Every cultivator ordinarily lays by
three hectolitres of nuts to make a pressful of kernels, from 35 to 40
kilos. The yield is 50 per cent oil.

The grafted nut of Brantome is very productive when the year
is favorable ; because it is precocious, it is sent off fresh in good time
for the markets of the large cities of France or foreign parts. They
sell it for dessert and for the green kernels. The green kernel of the
Noix de Brantome is from 38 to 40 per cent of its total weight.

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 395

Its culture has a tendency to diminish. They plant in "preference,
the Corne, which produces more regularly and gives a fruit selling at
least 8 to 10 francs more per quintal.

Redon de Montignac. — This variety is peculiar to the department
of Dordogne; it is cultivated in Montignac and surrounding district
of Sarlat. It is a small nut having half hard shellj of a dark color.
The line of the suture of the valves is projectile, extending from the
middle to the point. The shell is rather smooth and slightly flattened
at both extremities. The average dimensions are as follows: length
30 mm., width 26 mm. The dry nut weighs about 7 grammes and the
weight of a hectolitre of dry nuts reaches 38 kilos.

The Eedon de Montignac is a variety which blossoms early; the
flowers are in full bloom in April and May and are exposed to the late
frosts. Some years ago this nut was almost exclusively used for the
manufacture of oil and by reason of its yield it was preferred to other
varieties. To-day the nuts are cracked on the place and exported in
the form of green kernels, which tends to replace the Redon with the
Lalande, a nut of greater value and larger size. Nevertheless, at the
present time the Redon de Montignac is still very popular.

Anguleuse. — -The Anguleuse (angular), being a nut with a hard shell,
is the fruit of the Juglans regia angulosa (J. r. dura). It is a nut
of average size, having a very hard, thick shell presenting angles
parting at the middle and rejoining at the apex to form a sharp point.
It contains a kernel rather hard and difficult to extract whole on account
of the hardness of the shell. The dry nut weighs about 10 grammes
and the weight of a hectolitre is from 34 to 35 kilograms.

This variety, which is found in Dordogne and Lot, yields fruit
utilized for the manufacture of oil. The wood is of good quality and
often veined.

Noix a Grappes. — It is the fruit of Juglans regia racemosa. The
variety is very curious, for the nuts are collected in a bunch, compris-
ing 12, 15 and even 20 or 24 fruits. They are small and weigh about
6 grammes dry.

The Noyer a Grappes is found here and there in Indre, Vienne, etc.
The variety is very productive. A single tree produces from 3 to 4
hectolitres of nuts (8-J to 11 bushels). The Noyer a Grappes is a
spreading tree, slightly exacting and suited for the production of nuts
intended for the manufacture of oil.

Noisette. — The Noisette nut is produced by a tree having small fruit
(Juglans regia avellana, J. r. microcarpa). The fruit is, as the name
indicates, very small, globular, having hard, full shell containing a
white kernel, delicate and very rich in oil. Notwithstanding the small-

396 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

ness of the fruit, the tree is productive. It is. cultivated a little
everywhere in the department of Dordogne.

Nogarelle. — The Nogarelle or Petite Impente is a variety rather
recently brought to attention and still slightly known in cultivation.
It is found in Dordogne extending from Buisson and along Dordogne
to Lalande. It is of average size, a little smaller than the Grand
Jean and having a tender shell. It is recommended for agriculture
because of the large crop of green kernels.

VARIETIES OF VARIOUS REGIONS.

Commune. — The Noix Commune has distinct characteristics. It is a
small nut having hard or half-hard shell, somewhat flattened at the
base, slightly pointed at the apex, containing a kernel fine and rich in
oil. The average weight of a dry nut is from 6 to 8 grammes and the
weight of a hectolitre about 40 kilos. One hundred kilos of nuts make
on an average 40 kilos of kernels and 100 kilos of kernels yield, by
pressing, 50 kilos of oil.

The Noyer Commune blossoms in April or the beginning of May,
before its leaves commence to push through. As a result of its early
blossoming, it is exposed to the attacks of spring frosts and its crops
are very irregular. It is propagated exclusively from seed and as
the selection of the nut is rarely practiced, the trees obtained present
great differences as regards crops. It is cultivated in all departments ;
it is an oil nut par excellence. In places it could be advantageously
replaced with good varieties which blossom late and which could be pro-
pagated by grafting.

Noix de la Saint-Jean. — This variety is thus named because the tree
does not blossom until the month of June, much later than other varie-
ties, which permits the tree to escape spring frosts.

The nut is small, round, of a dark color, having a tender shell
enclosing a kernel rich in oil. The kernel instead of being white, as
in good varieties, is of a yellow color. The line of suture of the valves
is very much projected in the whole circumference and especially in the
region of the point and base ; the shell is very wrinkled. The average
dimensions of this nut are as follows: length 37 mm., width 34 mm.
The average weight of a dry nut is from 7 to 8 grammes and the
weight of a hectolitre from 38 to 40 kilos.

Because it blossoms late, the Noix de la Saint- Jean is recommended
for the parts of the country subject to frost (north and central). The
fruit is especially suited for the manufacture of oil. It produces
regularly and abundantly. The tree grows rapidly ; its wood is some-

BULLETIN 231] WALNUT CULTURE IN CALIFORNIA. 397

times veined with black, often presenting rings which add greatly to
its value ; the bark is brown and deeply fissured.

Noix a Bijoux. — The Noix a Bijoux or Noix de Jauge is the fruit of
the " walnut tree having large fruit" {Juglans regia maxima). It is
a nearly square nut, having wrinkled shell, flattened at the sides, with
the line of suture of the valves slightly projecting; it is somewhat
pointed at the apex and depressed at the base, which permits it to
stand resting on the base. Its shell, thick, breakable, contains a kernel
of ordinary quality which never fills the cavity well. The dimensions
of the nut, in general, are 4 to 5 centimeters in length with equal width.
Its average dry weight is 15 grammes.

This variety is curious in the exceptional dimensions of its fruit,
but from the culture point of view it is of slight importance. Its
fruits are generally distributed in clusters of two or three; they are
much sought by jewelers for making jewel boxes. The tree requires
a fresh and fertile soil; it grows rapidly and its wood is of inferior
quality to that of the Noyer Commune.

Fertile. — This variety was found by M. L. Jamin about 1838, on
the grounds of M. Louis Chatenay, nurseryman of Duoe-la-Fontaine
(Maine et Loire).

In size it is medium or small, having roundish oval form, with soft,
well filled shell. The tree is rather vigorous and remarkable because
it bears the third year; unfortunately it blossoms early, often expos-
ing the crop to frosts.

The Fertile nut comes sufficiently true from seed.

Noix a Coque Tendre. — The nut with tender shell, also called the
Noix a Mesange (titmouse) and the Noix de Mars, is small, elongated,
pointed, tapering at both ends. The shell is very delicate and breaks
with the least shock; birds, often by hundreds, feed upon the kernels,
whence its name Noix a Mesange. The shell is well filled and con-
tains a good and very oily kernel. The average weight of a dry nut
is 8 grammes and the weight of a hectolitre from 40 to 44 kilos.

The early blossoming exposes it to spring frosts; it should be in a
sheltered place and well exposed to the sun. When the year is favor-
able it yields large crops. The tree is very large and vigorous ; it has
the fault of sending out a great many shoots before bearing. Its
bark is white and delicate and the wood often veined in black. The
nut is harvested early, a part being on sale fresh for the table. The
greater part is utilized for the manufacture of oil and for packing in
boxes for green kernel sale.

Barthere. — This variety was obtained in 1860 by a nurseryman,
Barthere. of Toulouse. The characteristics of this nut are its long,

398 UNIVERSITY OF CALIFORNIA EXPERIMENT STATION.

flattened appearance, half-hard shell of clear color. The shell is well
filled and its kernel of good quality. The tree is vigorous, fruitful,
portly and erect. The nuts mature late ; they are harvested in October.

Noix a Cerneau Rouge.— The Noix a Cerneau Rouge (Juglans regia
rubra) is an old variety. It is mentioned for the first time (1763)
by the Dutch pomologist Knoop and afterwards pointed out by various
others. This variety was completely lost sight of. It has been recog-
nized after twenty years at Gratz (Styrie), where there is a good
specimen.

The nut is rather large, of ovoid form, having a shell half -hard,
very dented and well filled. The kernel, as in many varieties of
hazelnuts, is covered with a blood-red or carmine-red membrane ; it is of
good quality.

The tree is identical with the Noyer Commune and possesses the same
vigor. It is reproduced sufficiently well from seed and bears before
the eighth year. This information was obligingly furnished by M.
Jouin, director of the Simon-Louis nurseries at Plantieres near Metz.
This is established by noting down information from those who have
grown the Noix a Cerneau Rouge.

ACKNOWLEDGMENT.

In the eight or nine years, during which the observations and investi-
gations reported in this bulletin have been under way, numberless
suggestions, ideas, and bits of information have been obtained from a
great many different people, some of whom have been mentioned in
the body of the publication in connection with various subjects. It
is impossible, however, to give full individual credit for everything of
this sort. We can only say, in general, that almost all of this informa-
tion is the result of continued observation, correspondence, and con-
versation carried on from year to year in all parts of the State where
we could learn of any possible source of information concerning wal-
nuts. To all of those who have so willingly helped us during this work
we wish to express our most sincere appreciation. To Messrs. S. F.
and Frank A. JJeib, of San Jose, W. W. Fitzgerald, of Stockton, and
J. B. Neff, of Anaheim, we feel especially indebted for many sugges-
tions and ideas which could not be individually credited in the bulletin.
Special mention is also due to Mr. Edgar A. Metcalfe, our expert propa-
gator, who has worked out many of the ideas contained in the bulletin,
especially those upon budding the walnut. The majority of our sug-
gestions upon propagation have come from the work of Mr. Metcalfe
and that of Mr. George Weinshank, of Whittier.

STATION PUBLICATIONS AVAILABLE FOR DISTRIBUTION.

REPORTS.

1896. Report of the Vjticultural Work during the seasons 1887-93, with data regard-

ing the Vintages of 1894-95.

1897. Resistant Vines, their Selection, Adaptation, and Grafting. Appendix to Viti-

cultural Report for 1896.

1902. Report of the Agricultural Experiment Station for 1898-1901.

1903. Report of the Agricultural Experiment Station for 1901-03.

1904. Twenty-second Report of the Agricultural Experiment Station for 1903-04.

BULLETINS.

No. 128. Nature, Value and Utilization of

Alkali Lands, and Tolerance of

Alkali. (Revised and Reprint,

1905.)

133. Tolerance of Alkali by Various

Cultures.

147. Culture work at the Sub-stations.
"" 162. Commercial Fertilizers. (Dec. 1,
1904.)

164. Poultry Feeding and Proprietary

Foods.

165. Asparagus and Asparagus Rust

in California.

167. Manufacture of Dry Wines in

Hot Countries.

168. Observations on Some Vine Dis-

eases in Sonoma County.
' 169. Tolerance of the Sugar Beet for
Alkali.

170. Studies in Grasshopper Control.

171. Commercial Fertilizers. (June

30, 1905.)
174. A New Wine-cooling Machine.

176. Sugar Beets in the San Joaquin

Valley.

177. A New Method of Making Dry

Red Wine.

178. Mosquito Control.

179. Commercial Fertilizers. (June,

1906.)

181. The Selection of Seed-Wheat.

182. Analyses of Paris Green and

Lead Arsenic. Proposed In-
secticide Law.

183. The California Tussock-moth.

184. Report of the Plant Pathologist

to July 1, 1906.

185. Report of Progress in Cereal In-

vestigations.

186. The Oidium of the Vine.

187. Commercial Fertilizers. (Janu-

ary, 1907.)

188. Lining of Ditches and Reservoirs

to Prevent Seepage and Losses.

189. Commercial Fertilizers. (June,

1907.)

191. California Peach Blight.

192. Insects Injurious to the Vine in

California.

193. The Best Wine Grapes for Cali-

fornia ; Pruning Young Vines ;
Pruning the Sultanina.

194. Commercial Fertilizers. (Dec.,

1907.)

195. The California Grape Root-worm.

No. 197.

198.
199.
200.

201.
202.
203.
204.
205.
206.

207.
208.
209.
210.

211.

212.
213.
214.
215.

216.

217.
218.
219.

220.
221.

222.
223.
224.
225.

226.

227.
228.

229.
230.

Grape Culture in California ; Im-
proved Methods of Wine-mak-
ing ; Yeast from California
Grapes.

The Grape Leaf-Hopper.

Bovine Tuberculosis.

Gum Diseases of Citrus TreesTn
California.

Commercial Fertilizers. (June,
1908.)

Commercial Fertilizers. (Decem-
ber, 1908.)

Report of the Plant Pathologist
to July 1, 1909.

The Dairy Cow's Record and the
Stable.

Commercial Fertilizers. (Decem-
ber, 1909.)

Commercial Fertilizers. (June,
1910.)

The Control of the Argentine Ant.

The Late Blight of Celery.

The Cream Supply.

Imperial Valley Settlers' Crop
Manual.

How to Increase the Yield of
Wheat in California.

California White Wheats.

The Principles of Wine-making.

Citrus Fruit Insects.

The House Fly in its Relation to
Public Health.

A Progress Report upon Soil and
Climatic Factors Influencing
• the Composition of Wheat.

Honey Plants of California.

California Plant .Diseases.

Report of Live Stock Conditions
in Imperial County, California.

Fumigation Studies No. 5 ; Dos-
age Tables.

Commercial Fertilizers. (Oct.,
1911.)

The Red or Orange Scale.

The Black Scale.

The Production of the Lima Bean.

Tolerance of Eucalyptus for
Alkali.

The Purple Scale.

Grape Vinegar.

Pear Thrips and Peach Tree
Borer.

Hog Cholera and Preventive

Serum.
Enological Investigations.

CIRCULARS.

No. 1. Texas Fever.

7. Remedies for Insects.
9. Asparagus Rust.

10. Reading Course in Economic

Entnology.

11. Fumigation Practice.

15. Recent Problems in Agriculture.

What a University Farm is For.

29. Preliminary Announcement Con-
cerning Instruction in Practical
Agriculture upon the University
Farm, Davis, Cal.

32. White Fly Eradication.

33. Packing Prunes in Cans. Cane

Sugar vs. Beet Sugar.

36. Analyses of Fertilizers for Con-
sumers.

39. Instruction in Practical Agricul-
ture at the University Farm.

46. Suggestions for Garden Work in
California Schools.

50. Fumigation Scheduling.

52. Information for Students Con-
cerning the College of Agricul-
ture.

No. 55. Farmers' Institute and Univer-
sity Extension in Agriculture.

60. Butter Scoring Contest, 1910.

61. University Farm School.

62. The School Garden in the Course

of Study.

63. How to Make an Observation

Hive.

64. Announcement of Farmers' Short

Courses for 1911.

65. The California Insecticide Law.

66. Insecticides and Insect Control.

67. Development of Secondary School

Agriculture in California.

68. The Prevention of Hog Cholera.

69. The Extermination of Morning-

Glory.

70. Observations on the Status of

Corn-growing in California.

74. Rice.

75. A New Leakage Gauge.

76. Hot Room Callousing.

77. University Farm School.

78. Announcement of Farmers' Short

Courses for 1911.

79. List of Insecticide Dealers.

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