TI HE KN APP :
METHOD of a

Cy) ROWING

COTTON: |

—HESavely &

WB.Mercier -

Sa |
‘Cass SH 249 —
PR 3 Bc
Copyright N°__

COPYRIGHT DEPOSIT.

Dr. Seaman A. Knapp

| THE
KNAPP METHOD
OF
GROWING COTTON

By
W: B. MERCIER
Agriculturist and Field Agent, U. S. Department of Agriculture
and

Hr i SAVELY

Agriculturist and Field Agent, U. S. Department of Agriculture

Illustrated

GARDEN CITY New York
DOUBLEDAY, PAGE & COMPANY
1913

SBxu4q

Copyright, 1913, by
Dovus.epay, Pace & CoMPANY

All rights reserved, including that of
translation into foreign languages,
including the Scandinavian

©ClA857105

TO THE LATE
DR. SEAMAN A. KNAPP
THIS WORK IS DEDICATED IN APPRECIATION OF

HIS GREAT SERVICE TO THE COTTON
FARMERS OF THE SOUTH

rv
4 tat Pa oa iia ap

PREFACE

In the preparation of this book it has been
the aim of the authors to give in concise form a
practical treatise on Cotton, instructive to the
cotton grower.

The authors desire to express their thanks
to the many friends who have assisted them
in this work, and especially to the following:
Messrs. B. L. Moss, J. A. Evans, and E. C.
Ewing in reading the manuscript of certain
chapters. In the preparation of this manu-
script, we have consulted freely the publications
of the State Experiment Stations and the U.S.
Department of Agriculture; “Cotton,” by
Burkett and Poe; “Southern Field Crops,” by
J. F. Duggar, and “Cyclopedia of Agricul-
ture,” Bailey.

In the list of illustrations credit is given in
detail to the U. S. Department of Agriculture,
and to State Experiment Stations and others
that contributed photographs for this volume.

vil

VIII.

CONTENTS

Introduction. History of Cotton

Description of Cotton Plant

Climate and Soils

Cotton Culture

Fertilizers for Cotton ‘

Improvement of Cotton by Seed
Selection

Varieties of pinetican ‘Unload
Cotton

Some Cotton Biceaces wad basect
Pests — With Suggestions for
Their Control ae

Harvesting and Marketing Gorton

Cost of Cotton Production

Equipment in Teams and Tools
for Cotton Farms

Cotton By-products

Soil Improvement on Cotton
Farms

Outlook for the Cotisn eae

The Supply and Distribution of
Cotton

Supplement

I2I

145
151

161
181

Ig]
197

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A)

ress blk
a
is :
yee { 4 mie

.
Rr
p

LIST OF ILLUSTRATIONS

ereceamian AKnApp ww oe wl Frontispice \/
FACING PAGE

Cutting Down the Expense of Making a Cotton Crop
by Harrowing Young Cotton Across the Rows ._ 18

(Courtesy of W. F. Haden)

Breaking Three Acres a Day with Moldboard Plow 19 \
(Farm Management, U. S. Department of Agri-

culture)
A Weeder in Use for Early Cultivation . . . . 19
(W. F. Haden)
BioSC COLLIN A GOR. 2c) "o0), ai) ee 2 Glee! 8) Sy
The Modern Way—Ten Acres a Day . . 35

(Farm Demonstration Work, B. P. I., U.S. Debate:
ment of Agriculture)

The Way to Get a Deep Seed Bed . . 36 \
(Farm Demonstration Work, B. P.I., U.S. neste:
ment of Agriculture)

Po terraced! Field 2. v.. 37
(Farm Management U. S. Denaroment of ye
culture)
Method of Making Broad Terrace . . 37

(Farm Management, U. S. Department af Meret:
ture)

xi

xii LIST OF ILLUSTRATIONS

FACING PAGE

Cultivating Cotton with a Spring Tooth Cultivator

(Farm Demonstration Work, U. S. Department of
Agriculture)

Cultivating Cotton with a Two-horse Cultivator
(Farm Demonstration Work, U. S. Department
of Agriculture)
Young Cotton Plants

(Fiber Investigations, B. P. i U. Ss. Detahaien
of Agriculture)

Cotton Bolls . .
(Fiber Lavesigatises:. B. P. ié U. Ss. Department
of Agriculture)

Open Bolls of Cotton .
(Fiber Investigations, B. P. rE U. S. ‘ Depantnons of
Agriculture)

Varieties of Cotton: Sea Island, Rio sugar Upland
Long-staple, Upland . :
(Fiber Investigations, B. P. a U. S. ‘Deparonens ee
Agriculture)

Varieties of Cotton: Bill Boll Group, King-like or
Early Group, Cluster Group, Semi-cluster Group .
(Fiber Investigations, B. P. I., U. S. Department
of Agriculture)
American Upland Cotton. .
(Fiber Investigations, B. P. 1., U. S. Deiamen
of Agriculture)
Cotton Boll with Anthracnose
(Office of Plant Pathology, B. P. I., ue ‘Ss. Donan
ment of Agriculture)
Root-knot on Cotton Plant .

(Office of Plant Pathology, B. P. I., U. S. edadment
of Agriculture)

48 ,

48.

49°

82°

83°

88

89

92

93

93 '

LIST OF ILLUSTRATIONS

Xill

FACING PAGE

Map Showing Spread of Cotton Boll Weevil from 1892
tanGi2

(Bureau of Paoioliey: U. S. Desaroment i; Ver
culture)
A Young Cotton Plant Dying from Wilt :
(Office of Plant Pathology, B. P.I., U.S. Deseren
of Agriculture)
A Typical Plant of Dillon Wilt-resistant Cotton
(Office of Plant Pathology, B. P. I., U. S. Depart-
ment of Agriculture)
A Field of Upland Cotton in South Carolina Destroyed
by Wilt)...
(Office of Plant Patholoay: B. Ap 73 eh ‘Ss. Depart.
ment of Agriculture)
Wilt-resistant Dillon Cotton on eae Land Badly
Infected with Wilt. .
(Office of Plant Paskalogy, B. POP: oe, is, ‘Degare
ment of Agriculture)
Moths of Cotton Boll-worm .
(Bureau of Entomology, U. S. Dejavincns of aves
culture)
Pupa of Boll-worm in Its Underground Burrow .
(Bureau of Entomology, U. S. Department of Agri-
culture)
Stages and Work of the Cotton Worm or Cotton Cater-
pillar
(Bureau of Pnsomoloey’ U. S. Dedartinen: of yes
culture)
Cotton Plant Attacked by Boll Weevil

Cotton Boll-worm on Outside and Inside of Cotton Boll

(Bureau of Entomology, U. S. Department of Agri-
culture)

97 |

ss,

$9

102

102

103

103

104

105
108

XIV LIST OF ILLUSTRATIONS

FACING PAGE
Partly Opened Cotton Bolls Showing Effects of Boll-
worm Damage .. err Brrr

(Bureau of Fiionialons: U. S. Department of Agri-
culture)

Injury by Boll Weevil to Bolls nes 109,

(Bureau of Entomology, U. S. Divgwnen a Pres
culture)

Effects of Boll-weevil Attack on Leaf and Squares 112,
(Bureau of Entomology, U. S. Department of Agri-

culture)

Poisoning Cotton by Poleand Bag Method . . 113 v

(Bureau of Entomology, U. S. Department of Aisi:
culture)

Poisoning Cotton by Use of Spray Pump . 113

(Bureau of Entomology, U. S. Department of ane
culture)

A Farmer Comparing His Cotton with the Government
Standard Grades. < 40.) as oo snh ee ee oee

(W. T. Payne)

Round Bales Showing Method of Opening . . 128
(Cotton Marketing, U. S. Department of Anielina

Gin-compressed Bales Ready for Shipment .. 128
(Cotton Marketing, U. S. Department of Wein

Gin-box, Egyptian, Gin-compressed and Recompressed
Cotton Bales. . 129 »

(Bureau of Foreign and Domédte Commerc Bid
ment of Commerce and Labor)

Transverse Section of a Cotton Gin. . . . . 136
(Continental Gin Company)

LIST OF ILLUSTRATIONS XV

FACING PAGE
Section from a Ginnery enemne: Box Press and Gin
Stands : et rice tig ES a
(evntinental Gin Canaan)

Ordinary Equipment of One-horse Cotton Farm 146:
(Farm Management, U. S. Department of deeiad
ture)
Ordinary Equipment of Two-horse Cotton Farm 146
(Farm Management, U. S. Department of Abreal:
ture)

Up-to-date Equipment for a Cotton Farm . 147
(Farm Management, U.S. Department af Aaeieubire)
Srmson Clover in Central Alabama = . . . |. 1976
Corn and Velvet Beans .. : Pare ue te ios oer
A Yield of Two and One Half Bales Per Acre . . 177.

(Farm Demonstration Work, B. P. I., U. S. Depart-
ment of Agriculture)

listory of Cotton ©

cat

CHAPTER I
INTRODUCTION
HISTORY OF COTTON

OTTON is the world’s greatest fiber

crop. History records nothing that

compares to it as a cash crop. The
cotton crop is extensively grown in but
twelve of the Southern States, and exceeds
in total value any other crop in the United
States, except corn, which is produced in each
of the forty-eight states of the Union. The
spinners of Europe are much more concerned
about the size of the American cotton crop
each fall than about the peace of nations. The
cotton plant furnishes the raw material for
the greatest textile industry of all times. The
volume of the export trade it supports is enor-
mous.

Cotton has been known and perhaps used as
fiber since the earliest civilization. The im-
portant part it was to play in the economic

3

4 KNAPP METHOD OF GROWING COTTON

adjustment of the world’s products and finances
was not realized until after the American
Revolution. Silk, flax, wool, and cotton have
always been the staples to furnish mankind
with clothing. By reason of the cheapness
of production, the ease of manufacture, and the
general excellence of the manufactured goods
for wearing apparel, cotton is rapidly taking
place of the other three materials.

HISTORY

The original home of the cotton plant has not
been definitely established by historians, but
from the best data at hand was probably the
East Indies. Hindoo history, 4,000 years old,
speaks of a fiber, evidently cotton, and leads us
to believe it was manufactured into fabrics at
this early period. Cotton has been known in
the countries of southern Europe for several
centuries. The early fragmentary history of
various countries mention some plant bearing
a wool-like fiber, which was undoubtedly cotton.
Some species of cotton have been found growing
wild in practically all countries lying between
the 37th degree of latitude north and south
of the equator except the present cotton area

HISTORY OF COTTON 5

of the United States. Magellan found the
Brazilians using cotton for beds and fabrics
in 1519.

The first record of its being grown as a fiber
in the United States was in 1621, and then only
in small quantities. Cotton seed was brought
from the Barbadoes to South Carolina in 1680.
The first foreign shipment of cotton from this
country was from Savannah in 1747 — only
three bags. ‘There seems to have been so little
grown that no authentic record of the crop was
kept'until 1791, at which date the entire Ameri-
can crop was 8,889 bales weighing 225 pounds
each. The lint had to be separated from the
seed by hand, which was a tedious and difficult
task.

The cotton gin was invented by Ely Whitney
in 1793. The first saw gin was erected in
South Carolina in 1795, and from this dates
the beginning of an industry which, for rapidity
and volume of growth, has no parallel in the
world’s history.

The total crop of the United States in 1850
was, in round numbers, 2,500,000 bales. In
1860 it reached 4,500,000 bales. ‘Then the
Civil War came on and so paralyzed all the

6 KNAPP METHOD OF GROWING COTTON

business industries of the South that it took
almost two decades to get back to the produc-
tion of 1860. Since 1880 the increase has been
continuous and rapid. The average yearly
production, for the twenty-six years ending
1904 was 7,500,000 bales. ‘The average for the
past ten years has been 12,300,000 bales. The.
crop of I9II was over 16,000,000 bales, the
largest of any yet grown. The highest average
prices for thirty years have been paid for the
last five crops, averaging more than 12,000,000
bales each. The cotton mills of the world now
handle more than 15,000,000 bales of cotton
annually. Even with this enormous supply,
it is claimed that half the people on the globe
know nothing of modern-made cotton goods.
One statistician has estimated that if all the
people in the world used as much cotton goods
as the civilized nations, it would take more than
40,000,000 bales to supply the demand. The
progress of some of the most populous countries
toward higher standards of living will doubtless
cause the demand to grow faster than the
supply unless there is some readjustment of
labor conditions in cotton-producing countries.

The United States has special advantages

HISTORY OF COTTON 4

for cotton growing that perhaps are possessed
by no other country. There exists a peculiar
combination of soil and climatic conditions
found in no other country, even where situated
in the same degrees of latitude. Not all the
lands lying between the 37th degrees of north
and south latitude will produce cotton success-
fully. Profitable production of cotton in any
country is largely determined by conditions of
soil, climate, labor, and management.

America now furnishes about 75 per cent.
of the cotton used by European spinners.
Egypt, India, and Brazil, in the order named,
supply the rest. Several other countries
grow limited amounts, but unless better
methods are used and a more rapid progress
made, these countries will hardly produce more
than enough for home consumption. The only
chance of an early increase in supply for Euro-
pean spinners must come from Egypt, and under
the most favorable conditions the increase from
this source must be limited. All other cotton
countries except America have found other
crops more profitable, and it is hardly probable
that they will change to cotton merely to accom-
modate the spinner.

8 KNAPP METHOD OF GROWING COTTON

There are vast possibilities for the extension
of the cotton industry in the Southern States.
In the strictly cotton-producing states there are
303,000,000 acres of land. Of this not over
100,000,000 have been put into cultivation.
In recent years 28 to 36 million acres, or about
one third, have been planted to cotton. This
is about 9 per cent. of the total area of the
cotton states. There are still vast areas avail-
able for cotton production.

It would appear from the above figures that
the quantity that could be produced might be
greatly increased by the utilization of all avail-
able lands. ‘There are, however, certain im-
portant factors that will limit production.
The problem of maintaining soil fertility; the
adjustment of the labor problem, now a most
serious one; and the increasing population with
constantly advancing prices for other farm
products will have a tendency to limit the
acreage devoted to cotton. Again, it must be
remembered that cotton is one of the most
tedious and difficult crops to grow and harvest.
It will always be hard to get those accus-
tomed to growing other crops less troublesome
to adopt cotton farming. This will be the case

HISTORY OF COTTON 9

so long as present high prices for other products
exist. The present practice of growing cotton
and buying from the proceeds the necessary
supplies to run the farm is seldom profitable.
_ About one third of the American crop is
consumed in the United States, the remainder
being exported. The estimated total value of
the last two crops, including seed, is $1,000,-
000,000 each. This is a vast sum of money
and should the Southern farmers make up
their minds to grow this amount of cotton and
in addition all the food supplies for man and
teams, a thing that could easily be done, it
would be only a question of a few years until
the cotton farmers of the United States would
be the most prosperous and independent of
all men.

Description of Cotton Plant

CHAPTER II

DESCRIPTION OF COTTON PLANT

‘To: cotton plant belongs to what is
known as the mallow family. The
okra, hollyhock, althea, some weeds
and trees belong to the same family. Cotton
is a tropical plant and is found growing wild
in most tropical countries. It is an annual
in the United States; but after warm winters
occasional stalks of the old crop start new
growth, indicating the perennial nature of
the plant. In this country it is usually a
shrub-like plant, ranging from two to seven
feet in height. The extent of growth naturally
depends on soil, climatic conditions, variety,
and general treatment.

A peculiarity of the mallow family is that all
plants in it have flowers with five petals with
numerous stamens that form a tube about the
pistil. There are usually several leaf-like parts
below and around the flower. In cotton there

13

I4 KNAPP METHOD OF GROWING COTTON

are three of these, which, with the inclosed bud,
form what is termed the “‘square.” The leaves
are alternate, lobed, with veins all beginning at
a common point near the base.

The genus or general subdivision of the
family to which cotton belongs is Gossypium.
A number of species are classed under this sub-
division, but only two of these are of special
interest to the American cotton grower. The
first, and one of the greatest importance, is
Gossypium Hirsutum, which includes all the
upland cottons both long and short staples.
The second, Gossypium Barbadense, includes
all the Sea Island and Egyptian cottons. As
indicated above, American upland cotton
may be divided into two distinct classes: (1)
short staple, and (2) long staple varieties.
The chief distinction between the two is in
the length and strength of staple. The short
staple ranges from three fourths to one and
one eighth inches, while the long staple ordi-
narily runs from one and three sixteenths to one
and five eighths inches in length. There are, of
course, several intermediate classes. ‘The buy-
ing and selling prices of long staple cotton are
largely determined by the length of staple; the

DESCRIPTION OF COTTON PLANT I5

highest price, of course, being paid for the
longest.

Cotton seed when planted germinate quickly
under favorable conditions. The first stage in
the growth of the young plant is the formation
of astem and tap root. When the young plant
first appears above ground it has two leaves.
With warm weather, plenty of plant food, and
good treatment the plant develops rapidly.
The plant has a central main stem from which
are put forth limbs or branches. ‘This stem and
the branches are woody in nature and possess
considerable strength. The first or base limbs
are the largest and in many varieties assume
the stalk-like qualities of the parent stem.
The other branches decrease in length and
size toward the top of the plant. When fully
developed the plant usually presents a very
symmetrical and pleasing appearance. The
main stem and the larger base limbs produce
only leaves and smaller sub-branches on which
the bolls are found. One peculiarity of the
cotton plant is that two limbs start from the
axil of each leaf on the main stem. One con-
tains the bolls and the other is barren; fre-
quently, however, only one develops, and

16 KNAPP METHOD OF GROWING COTTON

fortunately this one is more often the fruit-
bearing branch.

The varieties or plants developing fruit limbs
nearest the ground having short joints or
nodes are found to reach maturity first; the
long-jointed, straggling plants being invariably
late in maturing. The stalks and stems are
covered with a rather strong, tough bark,
usually of abrownish color. This bark contains
a coarse fiber, but it has never attained any
commercial importance.

Cotton leaves appear alternately on the stem
and may vary in size or shape in the same
variety and even sometimes on the same stalk.
The upland cottons usually have leaves with
three lobes, sometimes more. The big boll
varieties have large heavy leaves with slight
indentations and short lobes. The very small
boll varieties have small, light leaves with
deeper indentations and sharp, pointed lobes.
Sea Island and Egyptian cottons have very
deep indentations and slender lobes. There are
usually three or more prominent veins in each
leaf starting out from a common point at the
leaf stem. The leaves and small stems of
upland cottons are covered with short hairs

DESCRIPTION OF COTTON PLANT Live

which are not found on the Sea Island vari-
eties.

A small flower stem of varying length appears
along the larger branches to support the bolls.
The square is the first stage of the fruit. It
consists of three bracts or leaves with the
inclosed flower bud and appears, on an average,
twenty-one days before the bloom opens. The
blooms of upland cotton are cream colored the
first morning, changing to pink the second day,
and fall to the ground the third or fourth day.
The flowers open up beautifully early in the
morning, but begin to close and change color in
the afternoon of the first day. Blooms of other
species vary in size and color. The cotton bloom
is self fertile. When the bloom drops, it leaves a
small pod about the size of a pea which develops,
on an average, in from forty-five to fifty days
into the full grown boll. This boll is similar in
size and shape to a small hen’s egg and contains
the lint and seed. The boll of upland cottons
has four to five divisions, each containing
a lock consisting of seed and lint. Each lock
has from six to twelve seeds. Sea Island
bolls are smaller and contain three or four
locks,

18 KNAPP METHOD OF GROWING COTTON

The number of bolls may vary from a very
few to several hundred to the stalk. The num-
ber depends largely on the variety, soil, moist-
ure, and climatic conditions while growing.
The number of blooms appearing does not
signify how many bolls will reach maturity, as
insect pests, excessive rains, dry weather, or
lack of fertility may cause a large per cent. to
shed. An average of thirty to fifty mature
bolls to the stalk over a field with a good stand
should give a yield of three quarters to one bale
per acre. The size and shape of the boll varies
with the varieties, class of soil, and weather
conditions. The small boll cottons require
from one hundred to one hundred and twenty
bolls to make a pound of seed cotton, while some
of the large boll varieties require only forty to
sixty to the pound. The manner of opening of
bolls differs greatly with the varieties; some
yield their locks freely, while others open in
such a way as to cause the lock to adhere
closely. The latter kinds are preferred in a
windy country or where the harvesting is not
done promptly.

The seed cotton produces about two thirds
seed and one third lint or fiber when ginned.

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DESCRIPTION OF COTTON PLANT 19

Five hundred pounds of lint is a bale. A
bushel of seed weighs thirty-two pounds. The
seed are rich in oil and nitrogen, and are usually
worth about one sixth as much as the lint.

CHAPTER III

CLIMATE AND SOILS

HAT is commonly known as the

W cotton belt of the United States
lies below latitude 37 degrees. This

embraces the larger part of the following
states, viz: Arkansas, Alabama, Florida,
Georgia, Louisiana, Mississippi, Oklahoma,
North Carolina, South Carolina, Texas, Ten-
nessee, and small portions of Virginia and
Missouri. The climatic conditions of this
particular region are perhaps more thoroughly
adapted to the successful growing of the culti-
vated varieties of cotton than any other yet
known. The summers are long and the tem-
perature relatively high. ‘The average annual
rainfall is between forty and fifty inches over
the larger part of the cotton territory. Cotton
being naturally a tropical plant, it does best
in a warm, humid climate; but, on the other
hand, can be grown profitably under semi-arid
conditions. ‘To reach full development, the

23

24 KNAPP METHOD OF GROWING COTTON

cotton plant must be grown where there are at
least six months warm sunshine. ‘The dates of
killing frost in spring and fall are every impor-
tant with the cotton grower. While the picking
sometimes extends into the winter months, a
killing frost stops all growth and frequently
spoils considerable quantities of immature bolls. |
If the temperature is uniformly high, day and
night, the young plant develops rapidly. On
the other hand, should there be cold nights or a
sudden drop in the temperature, the growth of
the young plant is seriously checked and the
stand may be so injured that replanting is
necessary. The extreme sensitiveness of the
cotton plant to cold makes it important that
planting be delayed for seasonable weather.
There is nothing gained by planting before the
ground and air have been sufficiently warmed
to insure quick germination; besides, there is
danger of losing the choicest seed if planted too
soon. With warm weather, good cultivation,
and a normal amount of moisture, the plant
should reach maximum stalk growth by the
first of August. After this the principal busi-
ness of the plant should be to develop and
mature fruit.

CLIMATE AND SOILS 25

The best cotton seasons are the ones during
which there is an absence of abnormally heavy
rainfall, but where showers and occasional rains
are frequent enough to supply moisture for con-
tinuous but not excessive growth. Such sea-
sons permit the plant food to be assimilated
gradually, and also causes a sufficient setting
oi yearly fruit: to. insure a fair yield: These
conditions distribute the bolls in such a manner
as to make the plant more symmetrical and give
a more extended opening period, resulting in a
better grade of lint, especially where pickers are
limited during harvest season. A cold, wet
spring is unfavorable, interfering with prepara-
tion, retarding planting operations, and early
cultivation. While such conditions materially
lessen the chances for a good yield, the cotton
plant is so adaptable to conditions of climate
and soil that fair crops have been made when
the early outlook was quite gloomy. Frequent
heavy rains during June, July, and August,
sometimes occur and seriously damage the crop.
Such seasons interfere with proper cultivation,
promote excessive plant growth at the expense
of fruit, and encourage the multiplication of
insect pests and fungous diseases that prey upon

26 KNAPP METHOD OF GROWING COTTON

cotton. ‘The territory is so extensive, however,
that there is wide variation in the weather con-
ditions. Some sections may have favorable
conditions, while the opposite may be true of
others. No two states have the same weather
conditions, and often in the same state there is
a wide variation. There is, consequently, little
probability of having an ideal season over all -
the cotton belt the same year. Under the
present system and with the large acreage
planted, it is doubtful whether an ideal season
over the entire cotton area would be best for
the industry. Under the most favorable con-
ditions such a large crop might be grown from
the present acreage that the price would per-
haps be reduced below the cost of production.
It will be noted by taking the averages for ten,
twenty, and thirty years that the cotton crop
will show a more uniform yield per acre than
any other American farm crop.

SOILS

Cotton may be planted on almost any well-
drained soil in the cotton region. It will be
found growing readily on all kinds of soils
from the stiff clays to the lightest sands, The

CLIMATE AND SOILS 27

vigor of growth and yields vary widely on diff-
erent soils. A profitable crop can be produced
on almost any class of land, provided suitable
plant food is present or is furnished by applica-
tions of fertilizers.

The system of cropping practised in the
cotton states has so reduced the fertility of
some soils that crops cannot be grown on them
ata profit. The use of so much of these poor,
depleted lands accounts for the low average
yields. Some of the cotton lands are naturally
poor; and the constant cropping to cotton, with-
out returning enough vegetable matter to retain
fertility and protect from washing has made
vast areas of once rich soils almost worthless.

On the other hand, there are some extremely
rich bottom lands and some newly cleared
fields not in bottoms that have too much moist-
ure and plant food for successful cotton raising.
These should be devoted to corn, meadows or
pastures. If planted tocotton the plant growth
is too rank and the fruit will often be scattering.
There is also an additional danger of serious
damage from the rotting of the bolls, insect
depredations, and fungous diseases on these
rich lands,

28 KNAPP METHOD OF GROWING COTTON

The most satisfactory of all lands for cotton,
taking it through a long series of years, is a
medium sandy loam with a clay subsoil. The
nearest approach to ideal conditions can be
maintained on such soil in all seasons. The
plant growth in a normal year will neither
be too rank nor too small. There is a com-
paratively small percentage of typical loam soils
now in cultivation. Some of the best of these
have been cropped with cotton so continu-
ously that much of the plant food has been
exhausted and leached out.

The per cent. of sand or clay in soils has an
important bearing on both their mechanical
texture and production. The texture of the
soil means more to the average farmer than its
chemical composition. Long experience and
practice have taught him to determine the best
cotton lands from observing the native growth
and the texture of the soil, rather than from
chemical knowledge of its contents. The tenant
farmer soon learns the fields that are best suited
to the crop, and this accounts largely for their
continuous cropping in cotton.

About 50 per cent. of all space in soils is
occupied by air and water. Sandy soils are

CLIMATE AND SOILS 29

composed of larger particles and naturally are
less retentive of water; clay soils are composed
of very fine particles and are more retentive of
moisture. Under very dry conditions sandy soils
do not retain moisture sufficient for cotton;
while, on the other hand, clay soils are equally
objectionable during wet or rainy periods
for the opposite reason. The most reliable
cotton lands are therefore loams and sandy
loams, well drained, but with sufficient clay to
make them retentive enough to insure a uniform
moisture supply during the growing season.
When such soils have had proper preparation
and the early rains have been stored and re-
tained by later shallow and frequent cultiva-
tion, the yield may be expected to turn out
satisfactorily in all seasons.

The mechanical condition of all soils are
greatly improved by keeping them well supplied
with vegetable matter.

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Cotton Culture

CHAPTER IV
COTTON CULTURE

REPARATION of Seed Bed.— Where
Pp possible to do so, break the land in the
early fall or winter. This breaking should

be done on most soils before December first.

If an ordinary turning plow is used, break
one or two inches deeper than usual, cutting
a narrow furrow slice in order to set the furrow
on edge to prevent bringing the subsoil to the
surface.

The disk breaking plow is especially suited
for this fall breaking as it brings but little of
the subsoil to the surface. Ifa disk plow can
be secured, use it and go down as deep as
possible.

On well-drained lands the fall breaking may
be done broadcast. On poorly drained lands
it is better to throw up in high beds or ridges in
order to give drainage and to thoroughly aerate
the soil during the winter.

33

34 KNAPP METHOD OF GROWING COTTON

The object of deep fall plowing is mainly to
increase the supply of available plant food and
the storage of moisture in the soil. The parti-
cles of the soil are separated by this tillage,
allowing frost to penetrate deeper and the air
and moisture to circulate freely, and the winter
rains are stored up for use in the spring and
early summer. When the subsoil is first
brought to the surface it is a dead inert mass,
and the soil particles must be acted on by the
oxygen of the air, the frost, and the rains to
make plant food available. Every farmer has
observed that when a ditch is dug and dirt is
thrown out from the bottom nothing will grow
on it for several months. The second year the
rankest growth is found on this soil. An
additional advantage of fall breaking is that
it destroys some injurious insects, which pass
the winter in the soil. Deep fall plowing is of
great value in fields long in cultivation where
the plant growth is medium or less. On very
rich, moist soils where there is too much avail-
able plant food for cotton, a condition that
makes an excessive growth of the stalk and a
consequent decrease in fruitage, it is best not

to do fall breaking. Such lands should be

doid 94} SutyeAryno
pur paq peas oy} surredaid ut [003 ajqenyea e — 10zeATINO dsIp ou],

The modern way — ten acres a day

COTTON CULTURE 35

broken shallow in the spring. Deep, light,
sandy soils should not be broken in the fall
unless covered with a heavy crop of vegetation
or where a winter cover crop is to be planted
to utilize available plant food and prevent
leaching.

Where land was broken deeply in the fall,
rebreak in the spring from three to four weeks
before time to plant, and throw in slight beds
or ridges the desired width of the cotton rows.
This will give sufficient time for the beds to
become firm before planting. This spring
rebreaking or bedding can be very rapidly and
satisfactorily done with a disk cultivator by
adjusting the disks so as to throw up a slight
bed. Just before planting, freshen and thor-
oughly pulverize the surface of the beds to a
depth from one to one and one half inches.

The cotton plant first throws out its feeding
roots in the moist, warm, surface soil, and it is
best, therefore, immediately before planting,
to use freely the section, disk or some other
harrow. Time spent in making a good seed
bed in not wasted. Go over the field several
times with the harrow if necessary.

Where it is not possible to break the land in

36 KNAPP METHOD OF GROWING COTTON

the fall or early winter, break broadcast as early
in February or March as soil conditions will
permit, as deep or slightly deeper than it has
been previously broken.

It is seldom advisable to turn the subsoil in
the spring. It is usually too full of water and
it is too late for much effective action of the air.
upon the soil and for the rains to firm the sub-
soil before planting.

Even where the land is not plowed until
spring it is found profitable to rebed before
planting. Freshen and thoroughly pulverize
the surface of the beds immediately before
planting. It is usually better to plant cotton
on a firm seed bed. If the land cannot be
broken or bedded in the spring in time to be-
come firm by rains, then a heavy drag or roller
should be run over the loosely plowed land to
firm it before planting. A poor stand often
results from planting cotton on a locse bed on
account of lack of sufficient moisture to insure
germination. It is also difficult to plant seed
the proper depth on a loose seed bed.

Whether it is best to plant cotton flat or on
beds is a question that is wholly determined by
local conditions. On level, well-drained lands

daap soyour use}1n0y Suryvorg “peq pases daap v yas 07 ABA oy,

A terraced field
Method of making broad terrace

COTTON CULTURE a7

flat planting is practicable, and it will be easier
to cultivate than where cotton is planted on
ridges. Cotton is planted on beds as a pre-
caution against heavy rainfall after planting.
Seeds require moisture for germination, but
must be kept out of standing water in the soil.
Where conditions are such that cotton can
be flat planted, it may also be planted in check
rows which insures easier and more economical
cultivation. Even where cotton is planted on
beds or ridges the beds should be dragged down
with the harrow so that they have only a slight
elevation above the level surface.

In semi-arid sections cotton is frequently
planted in the bottom of a freshly opened
furrow between beds in order to get the seed
into moist soil.

Width of Rows. —'The proper spacing of the
rows for cotton is important. The general rule
for spacing is that the distance between the
rows shall be a little more than the height of the
plant in average years. Where cotton usually
grows two or three feet high, the rows should
be from three and one half to four feet apart.
Where cotton normally grows three and one
half feet high, plant in four foot rows. Where

38 KNAPP METHOD OF GROWING COTTON

it grows from four to five feet high, space the
rows four and one half to five feet apart. It is
better to have the rows a little too wide than
too narrow. Air and sunlight are of great im-
portance in pushing the crop to maturity.

Date of Planting. — Cotton should be planted
as soon in the spring as danger from frost is
past and the soil becomes sufficiently warm to
quickly germinate the seed and insure healthy
and vigorous growth of the plant. The best
time for planting cotton along the Gulf Coast
is probably between the dates of March 25th
and April 25th. In the central part of the
Gulf States planting should be between April
toth and May tst. In the northern part of the
cotton belt planting should be between April
2oth and May 15th. ‘The largest part of the
cotton crop is planted before the first of May
in the central part of the cotton belt, but fre-
quently fields of cotton are planted as late as
the middle or last of May and produce good
crops. On the rich alluvial lands of the Mis-
sissippi Valley, following overflows, cotton some-
times produces a fair crop even when planted
late in June. Extra early or extra late plant-
ing is not recommended. Extremely early

COTTON CULTURE 39

planting increases the labor of cultivation, and
the young, tender plants are frequently injured
by the frost. Very late planting lessens the
labor of cultivation, but the crop is liable to be
cut short in the fall by early frost, which
destroys immature bolls.

Cotton Planters. — Where cotton is planted on
ridges the most satisfactory planter to use is the
one-horse walking planter. There are a num-
ber of these planters on the market. The
principal features to be desired in a planter are:
regular and uniform distribution of the seed,
and uniform depth of planting. Some of the
planters have adjustments for dropping the
seed in hills instead of in continuous drill.
With these planters it is often necessary to
dampen the seed and roll them in dust, lime
or ashes to temporarily paste down the fuzz
in order to get regular distribution of the
seed.

Seed planted in hills require less work with
the hoe in thinning to a stand, but the extra
care in preserving the stand about offsets any
advantage to be derived by planting in hills.

Depth of ‘Planting. — Cotton should be
planted shallow, not over one inch deep, pro-

40 KNAPP METHOD OF GROWING COTTON

vided that depth reaches moisture, in which
case plants will be up in a few days.

In sections of light rainfall or when planting
late in the season, it will be necessary to plant
deeper than one inch. More stands of cotton
are lost from planting too deep than from
planting too shallow.

Amount of Seed Per Acre. — Where seeds are
distributed in continuous drill, three pecks of
good seed per acre is ample. A stand may be
secured with half this amount of seed when
planted the proper depth on a good seed bed,
but it is an advantage to have more plants on
the land than necessary, so that if a few of
them are destroyed in the first cultivation the
stand will not be injured.

First Cultivation. — Begin the cultivation as
soon as the seeds are planted by running once
or twice across the rows with a section harrow.
When cotton is up to a stand, run diagonally
across the rows with a section harrow with the
teeth slanted backward at an angle of forty-five
degrees. One week later go over the cotton
again with the section harrow, diagonally
across the rows in the opposite direction. This
will destroy a few of the plants, but if three

COTTON CULTURE 4!I

pecks of good seed per acre have been planted,
not enough plants will be destroyed to injure
the stand. The weeder is better for this early
cultivation than the harrow on very loose soil,
and should always be used instead of the harrow
on sandy soils.

“Chopping” or Thinning. — This early culti-
vation with the section harrow or weeder de-
stroys young grass and weeds and leaves the
cotton in fine condition for “‘chopping” or
thinning. The common practice of “‘barring
off,’ leaving the plants on a narrow ridge to
save labor in thinning, is unnecessary if the
harrow has been used to keep the rows free of
weeds and grass. If it should be found neces-
sary to run around the cotton to destroy grass
and save labor with the hoe in thinning, this
work can be done more satisfactorily with a side
harrow than with the turning plow. The
turning plow should never be used in cultivation
unless the crop has become so foul with weeds
and grass that it is impossible to clean it with
other implements.

Where planting was rather early it is better
to thin twice, leaving two or three times the
number of plants needed at the first thinning,

42 KNAPP METHOD OF GROWING COTTON

and about three weeks later thin to a stand.
Where planting is done toward the latter part
of the planting season it is advisable to bring
to stand at first thinning.

The distance apart of plants in the drill will
depend upon the fertility of the soil. On
medium soils where plants grow about three
feet tall, leave plants from fifteen to twenty
inches apart in the drill. Where cotton nor-
mally grows four to four and one half feet tall
thin from twenty to twenty-four inches in the
drill.

Later Cultivation. — The first cultivation after
using the section harrow or weeder, may be
given with some form of cultivator. Among
the implements used for this cultivation and
with which satisfactory results are obtained
are the following: the fourteen-inch heel sweep
and short bull-tongue point on one-horse
Georgia stock; one-horse spring-tooth culti-
vator; five shovel, one horse cultivator; and
the sulky cultivator with short, narrow, dia-
mond point shovel attachments, or with spring-
tooth attachments. If the land has become
hard and compact from rains since plant-
ing, the first cultivations may be rather deep.

COTTON CULTURE 43

This will not be likely to occur, however, if
the section harrow has been run as often
as recommended. All later cultivation should
be shallow. During periods of excessive rains
it may be necessary to cultivate deeper to
clear the crop of weeds and grass, but after
this is done continue the shallow cultivations
as before. If the land is clear of stumps the
cultivation can be done more economically
with a two-horse cultivator that will cultivate
the entire row at one trip. Any form of attach-
ment may be used on the sulky cultivator which
will give a loose dust mulch about one to two
inches deep. If from any cause it is not practi-
cable to use the sulky cultivator, excellent work
can be done with a one-horse cultivator or with
a one-horse Georgia stock, with broad narrow-
winged sweep (heel sweep) if the dirt is allowed
to fall loosely over it. Care should be exercised
in cultivating cotton not to allow the cultivator
to go deep enough to break the feeding roots
of the plant. On very rich, moist soils, where
cotton has a tendency to grow an excessive
stalk with consequent decrease in fruitage,
it is often helpful to cultivate deeper than above
recommended in order to check the growth of

44 KNAPP METHOD OF GROWING COTTON

the plant and encourage fruiting. Usually
this should be done early in the season and dis-
continued when plants begin to set fruit freely.
Cultivating every seven to ten days, weather and
soil conditions permitting, will be best. This
will allow, on an average, seven to nine culti-
vations. The general practice is to stop culti-
vation too early. In most sections it will pay
to continue cultivation until the crop is prac-
tically matured.

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CHAPTER V
FERTILIZERS FOR COTTON

OMMERCIAL fertilizers were not used
4 : for cotton until about 1860. At this
early date wonderful results were at-
tributed to their use in increasing the crops.
For several years the increase in the use of
them was followed with good results, but
after a time the idea began to spread that
the stimulating effect gave out and the soils
really became poorer. The truth of the mat-
ter was that with their continued use and with
the clean cultivation, all the vegetable matter
and humus became exhausted. A _ natural
consequence was poor land and decreased
yields. The alluvial bottoms along the streams
and some of the rich uplands will produce
profitable cotton crops without the aid of
manures of any kind.
Commercial fertilizers, when wisely used,
have been profitable to the cotton grower,
47

48 KNAPP METHOD OF GROWING COTTON

but an extravagant and often unintelligent use
has been too common.

The one-crop system of the cotton states
has been followed until much of the best lands
have become unprofitable without the use of
artificial plant food. There are vast areas
where the natural fertility is too low to produce
paying yields without the application of fertil-
izer. ‘These facts, with the demand for a quick
cash crop, the prevalence of the credit system,
the indifferent nature of the negro laborer, and
the necessity for hastening maturity to avoid
insect pests has led up to a general use of com-
mercial fertilizers in recent years. A sort of
fertilizer craze has swept over the Atlantic and
Gulf States, only that portion of the cotton
region west of the Mississippi escaping. The
farmers have bought it and used it extrava-
gantly and unwisely, thereby bringing upon
themselves and their states a fertilizer debt,
much of which is an unnecessary drain upon the
resources.

The following figures show the value of
commercial fertilizers consumed in cotton
states in 1910 based on inspection and tax
laws as reported by state officials: North Caro-

Cultivating cotton with a spring-tooth cultivator

Cultivating cotton with a two-horse cultivator

Young cotton plants

FERTILIZERS FOR COTTON 49

lina, $14,368,100; South Carolina, $20,104,305;
Georgia, $22,719,760; Florida, $3,523,390; Ala-
bama, $8,200,000; Mississippi, $4,055,540; Ten-
nessee, $1,172,240; Louisiana, $1,820,200; Texas,
$860,000.

The above figures represent the value of
commercial fertilizers and cotton seed meal
used. No report was given of the amount of
cottonseed meal used in Alabama, Tennessee,
Louisiana, and Texas. The above table does
not take into account a large amount of cotton
seed and other fertilizing materials of which no
official record was kept. While all of this
fertilizer was not used for cotton, it was paid for
out of the proceeds of the cotton crop.

Until recent fertilizer laws were passed in the
states requiring a guaranteed analysis to be
stamped on the package, unscrupulous manu-
facturers and dealers sold much cheap, inferior
goods to the farmers at high prices. The law
does not prevent making cheap grade fertilizer,
but it must be branded so that the purchaser
will know just what he is buying. The average
farmer wants a cheap grade article notwith-
standing the fact that the plant food in a high
grade is cheaper and more satisfactory. It is

50 KNAPP METHOD OF GROWING COTTON

a matter of record that in the early days of
commercial fertilizer the foulest smelling and
the most repulsive looking brand was considered
most effective. This idea no longer prevails
among intelligent farmers. The first thing
they look for is the tag showing available
elements in each package. But the mass of
farmers have not been sufficiently educated
along this line. They still buy on credit and
consequently take what the dealer offers, re-
gardless of price or grade. We hope this book
will be of value in aiding purchasers to buy and
use fertilizers with more intelligence and profit
in the future.

The chief object in the use of any fertilizer is,
of course, increased yield, and to bring this
about it must supply available plant food, or
make available some of that already tied up
in the soil. Usually artificial fertilizers per-
form both of these offices.

Most soils contain all the elements that enter
into the plant growth except three — nitrogen,
phosphoric acid, and potash. There is enough
potash found in the soils in nearly all the South-
ern States. This is especially true on the red
clays if a proper rotation is followed.

FERTILIZERS FOR COTTON SI

Commercial fertilizers cannot be bought in
a pure state, but in combination with other
substances which are of no value except to
increase the bulk and make it easier to dis-
tribute. The farmer should, by all means,
know that the value of a fertilizer depends
not on gross weight, but on the amount of
available plant food contained. No fertilizer
should be purchased that does not have the
guaranteed analysis printed on the package.
The composition is given in percentages, and
in each hundred pounds there should be so many
pounds of the particular element mentioned.

For example, a fertilizer is offered for sale
branded as follows:

Nitrogen . Se a euper Celt.
Water-soluble phosphoric eid ME ee | OG per cent.
Citrate-soluble phosphoric acid . . . 2 per cent.
Total available a ea HeidN ce be Oia) pEOL per Cent.
Botan: ) 7. -. Spent ee | 2) Der cent.

Translated into terms of pounds this means
that in a sack weighing 100 pounds there are:

2 pounds of nitrogen.

8 pounds of water-soluble phosphoric acid.
2 pounds of citrate-soluble phosphoric acid
10 pounds of available phosphoric acid.

2 pounds of potash.

52 KNAPP METHOD OF GROWING COTTON

This gives a total of 14 pounds of plant food
in a 100-pound sack. When a ton of such fertili-
zer is bought, the purchaser receives nitrogen,
40 pounds; water-soluble phosphoric acid, 160
pounds; citrate-soluble phosphoric acid, 40
pounds; potash 4o pounds. Notice that what
is called ‘‘available” is the sum of the water-sol-
uble and the citrate-soluble phosphoricacid. In
this fertilizer we get three things that are of use
—2 pounds of nitrogen, 10 pounds of phosphoric
acid, and 2 pounds of potash to the 100 pounds.

If cotton seed meal, acid phosphate, and kainit
are used to make this fertilizer, it will require the
following quantities for one ton of the mixture:

TaBLeE I.— PROPORTIONS AND VALUE OF COTTON SEED MEAL,
ACID PHOSPHATE, AND KAINIT REQUIRED FOR A TON OF
FERTILIZER OF A 2—I0-2 COMPOSITION

FERTILIZING MATERIAL POUNDS VALUE

Cotton seed meal (6.4 per cent. Ni-

tropenyot UG 0 OF BR es ee $ 8.00%
Acid phosphate (16 per cent. avail-
ANE nec 42, AC Nia Veale 1,140 10.00
Kainit (12.5 per cent. potash) . . 235 2.00
Total VQ oki ah ee Se eee oe $20.00

a

*The value of fertilizing materials is calculated on the basis of
20 cents a pound for nitrogen and 5 cents a pound each for phosphoric
acid and potash.

FERTILIZERS FOR COTTON 53

The figures quoted express the actual cost
of the materials, so by the time such a fertilizer
reaches the farmer it will cost him nearer $25
perton. The difference between the value of
materials and the price the farmer pays repre-
sents the cost of mixing, and bagging, and the
profits.

It will be found that all materials used
in mixing fertilizers vary in the amount
of plant food contained in them. ‘Taking
acid phosphate for example, we find some
running as low as 10 pounds of available
phosphoric acid per 100 pounds, while the
best grade runs as high as 16 pounds or
more per 100 pounds. On this basis, val-
uing phosphoric acid at 5 cents per pound,
the first would cost 50 cents, whereas the
latter would cost 80 cents. Even greater
differences will be found in the grades of cot-
tonseed meal.

Samples of cotton seed meal can now be found
ranging from 3.5 per cent. to 7 per cent. of
nitrogen. Basing the values on the nitrogen
contained, Table II shows the relative values
of cotton seed meal of the different grades. It
is assumed that cotton seed meal containing

$4 KNAPP METHOD OF GROWING COTTON

6.5 per cent. of nitrogen can be bought for
$28 per ton.

TABLE II]. — VALUES PER TON OF COTTON SEED MEAL OF
DIFFERENT GRADES

VALUE

$28.00] 6.3 |$27.13
27,671 6.2) 2071

670°) 625.8454

The average sample of cotton seed meal con-
tains approximately the following percentages
of plant food.

Nitrogen. a) ee VB c a percents
Phosphoric Midge tae Me eye per rene
Potash): cy. ) =) seed peices tle Sper deem

A 100-pound sack will therefore contain the
following quantities of plant food.

Nitrogen : So at a a NGAP ais
Phosphoric eey MA hehe ee
POA Sh) oo acy sh rsieriestt cee oak A ee

The results following the use of cottonseed
meal indicate that decomposition makes the
phosphoric acid in the meal available. In
buying materials for mixing fertilizers it is

FERTILIZERS FOR COTTON 55

always economy to use only high-grade goods,
even though they cost a little more.

How to Use Commercial Fertilizers. — lf fer-
tilizers are used, the following general rule
should govern: On rich lands use mainly fer-
tilizers that will stimulate the fruit and not
stalk growth. On lighter lands use more of the
elements to force growth, combined with others
which will mature the fruit. High-grade acid
phosphate may be considered a basis for in-
creasing the fruit and hastening the maturity
of crops. Even on the richest land it has been
demonstrated that a small percentage of ni-
trogen added to the acid phosphate gives better
results.

Nitrogen. —'The chief function of nitrogen
is to promote plant growth, but it is also of very
great importance in the production of fruit.
Nitrogen enters largely into the composition of
plants, and it follows that everything of vege-
table origin is a valuable source of this sub-
stance. When vegetable matter is burned the
nitrogen is released from its combination,
escapes into the atmosphere, and is _ lost.
Hence, it is bad practice to burn off fields and
destroy vegetable matter; it is better to turn it

56 KNAPP METHOD OF GROWING COTTON

under. The humus in vegetable matter has a
value in soil renovation frequently greater
than its value as a plant food. The most
important sources of nitrogen used in com-
mercial fertilizers are as follows:

Tas Le IIIJ.— NitrroGEN CONTENT OF IMPORTANT FERTIL-
IZER MATERIALS

SOURCE OF NITROGEN PER CENT SOURCE OF NITROGEN PER CENT
Cotton scedimeal 6 to':7°'| Fishiscrap . .. . 7 tews
Dried blood . .12 to 14 | Sulphate of am-

monia, “| . -1Sitewo

Tankage Nitrate of soda .14 to16

Phosphoric Acid. — Next in importance asa
plant food is phosphoric acid. It is largely
required by the plant for growth, but it is
absolutely essential in promoting fruitage and
is a great factor in hastening the maturity of
the crops. The principal commercial sources
of phosphoric acid are as follows:

Table IV.— PHospHoRIC ACID CONTENT OF IMPORTANT
FERTILIZER MATERIALS

SOURCE OF PHOSPHORIC ACID PERCENT | SOURCEOF PHOSPHORICACID PERCENT

Rock phosphate: Bone meal:
Dissolved . .12 to 16 Dissolved . .15 to17
Ground:.) ... =24 tog2 Ground)... ». -:20:t022

Thomas slag . .15 to 20

FERTILIZERS FOR COTTON 57

Potash. — Potash is more directly effective
in developing the fruit and adds to the vigor of
the plant. It is seldom deficient in soils and
especially in the soils of the Gulf States. It is
obtained from the following sources:

TaBLE V.— PoTAsSH CONTENT OF IMPORTANT FERTILIZER
MATERIALS

SOURCE OF POTASH PER CENT SOURCE OF POTASH PER CENT
Manteo. . . £25) Sulphate of potash 53
Muriate of potash . 50.0] Woodashes . . 5 to 20

It should be understood that the fertilizing
content of all the above-named materials are
not readily available for the use of the plant.
The amounts available should always deter-
mine the value of the material. An example to
illustrate may be found in acid phosphate.
The total content of the ground rock is twice
that of dissolved rock, but such a large per cent.
of the ground rock is unavailable that it might
be cheaper to buy the dissolved rock at twice
the price per ton. The same principle applies
in a greater or less degree to all the other
materials used in making commercial fertilizers.

What Fertilizer to Buy. — Since the elements
of plant food already mentioned are required in

58 KNAPP METHOD OF GROWING COTTON

different quantities and since the soils vary in
their supply, it is well for the farmer to know
what his soil and plants need before investing
his money in fertilizers. ‘The practical way for
the farmer to determine these facts is to observe
the growth of the plants on his land. If the
plants grow rapidly and make an abundance of .
leaf and stalk*it is evidence of a good supply
of nitrogen. If there is not a proportionate
amount of fruit it is a sure indication that the
soil needs phosphoric acid. On the other hand,
if the plant does not have a good color and tends
to drop its fruit before it reaches a fair size it
indicates that the soil requires potash.

Most of the soils in the South are deficient
in both nitrogen and phosphoric acid, and
some in potash, so when commercial fertilizers
are bought their value depends upon their
content of these substances. If the farmer has
saved all manures and has grown cowpeas or
other legumes abundantly, he will rarely have
to buy nitrogen.

For rich soils, or soils where a heavy crop of
peas, beans, or clover was grown the previous
year, use one part of cotton seed meal and three
parts of acid phosphate for cotton. For me-

FERTILIZERS FOR COTTON 59

dium soils use one part of cotton seed meal and
two parts of acid phosphate. On thin soils use
one part of cotton seed meal and one part of
acid phosphate. These proportions are for
soils rich in potash, but deficient in nitrogen
and phosphoric acid. Experiments have shown
that most of the clay soils in the cotton states
do not need potash for growing field crops.
On soils showing a need of it potash should be
added. On some soils experiments have shown
that neither acid phosphate nor potash is
needed; examples of such soils are found in the
black waxy lands of west Alabama, east Mis-
sissippi, and Texas, and the stiff alluvial lands
of the Mississippi Valley.

On these soils nitrogen and humus seem to be
all that is needed. Deep sandy lands such as
are found in Florida and along the coastal
plains are in many cases deficient in potash, as
well as in phosphoric acid and nitrogen. On
such soils a complete fertilizer or one containing
nitrogen, phosphoric acid, and potash should
be used.

Amount of Fertilizer to Use Per Acre. — No
definite instructions in regard to the use of
fertilizers can be given to fit all conditions and

60 KNAPP METHOD OF GROWING COTTON

soils. This question must be settled by tests
on individual farms. The following formula
will serve as a guide in mixing fertilizers to be
used under the conditions mentioned:

TaBLeE VI.—PROPORTIONS OF FERTILIZER FOR COTTON

POUNDS OF FERTILIZER PER ACRE

On deep sandy

On sandy loam or clay soils when

Fertilizer to be used. Poor \ Medium Rich ted es I
Cotton seed meal] 150 100 75 150
Acid phosphate 150 200 225 150
Kainit — a — 150

Where it is found that potash is needed on
clay lands, one hundred pounds of kainit or its
equivalent in muriate or sulphate of potash
may be added.

Where the land has grown a heavy crop of
peas or beans the year before, half the amount
of cotton seed meal may be used.

On the black waxy lands of Alabama and
Mississippi and the stiff alluvial lands of the
Mississippi Valley that have been planted to
cotton for a long period of years and have be-
come deficient in vegetable matter, 200 to 300
pounds of cotton seed meal or 100 pounds nitrate
of soda per acre have given profitable returns,

FERTILIZERS FOR COTTON 61

The amount of fertilizer to use depends on
several factors. The cost of the material used
in the fertilizer, the value of the land, the need
and condition of the soil, and the money value
of the crops to be grown must each be considered.
The greater the money value the crop represents
the larger the quantity of fertilizer that can
be used with profit. Large applications of
fertilizer never pay on thin, poorly prepared
soils. The amount of fertilizer to use is a
question of economics as well as of crop culture.
With 12-cent cotton the farmer can realize
large returns from 600 to 800 pounds per acre
on soils in good condition.

Different Forms of Fertilizing Materials. —
Elsewhere we have suggested some of the most
common sources of nitrogen, phosphoric acid,
and potash. In the formula given acid phos-
phate and cotton seed meal have been used.
They are the most commonly known and more
generally used. If for any good reason it is
desirable to substitute other materials in the
mixture, it can be readily done. Simply sub-
stitute in proper porportions. Ordinarily
nitrate of soda should not be used in making
mixed fertilizers. It is better to use it as a top-

62 KNAPP METHOD OF GROWING COTTON

dressing for growing crops. Where nitrate of
soda is used for cotton, apply it about the time
the plant begins to fruit. If more than 100
pounds per acre is used make two applications
fifteen days apart.

Methods of Mixing. — The mixing of fertili-
zers on the farm can be done very satisfactorily
by emptying the raw materials on a tight floor
of wood or concrete; or if more convenient
it may be done on a hard, dirt floor under a shed
or outhouse.

It is better not to empty over 400 to 600
pounds at one time, as it can be more readily
and thoroughly mixed in small quantities. The
mixing can be done with hoes and shovels by
turning over two or three times and continu-
ing this process until the desired quantity is
ready for use. This method of home mixing
is very desirable where the farmer wishes to
leave out any element or in any way change
the proportion to better suit special conditions.

How to Apply Commercial Fertilizers. —
Before applying commercial fertilizers prepare
the soil thoroughly. Where 500 pounds of
fertilizer or less is used for cotton put it all out
in one application in the furrow about ten days

FERTILIZERS FOR COTTON 63

before planting and mix well with the soil. On
deep sandy soils it may be best to make two
applications; one half at planting and remainder
at second cultivation. Where 600 or more
pounds per acre are used two applications
may be made, one half in the furrow before
planting and the remainder as side applications
at the second working of the crop. When
using 1,000 pounds or more, make two or more
applications or broadcast the entire amount
before planting.

The depth to which the commercial fertilizer
is applied is important. Experiments have
shown that about three inches is the proper
depth in all except semi-arid regions, where it
should be put deeper. It has been a common
practice among farmers to apply fertilizers too
deep.

The following facts regarding fertilizers
should be kept in mind by the cotton farmer:

I. Never allow the waste of barnyard
manure.

2. All waste and by-products from the
farm should be returned to the land.

3. Rotation of crops is essential for per-
manent soil building. Legumes and green crops

64 KNAPP METHOD OF GROWING COTTON

should be grown liberally and turned under
to furnish humus, and keep the soil in good
mechanical condition.

4. The greatest benefit to be derived from
commercial fertilizers is in combination with
farm manures and green crops turned under.
A much more liberal application can be made
profitable under these conditions.

5. A general and rather liberal use of
commercial fertilizer can be recommended
if intelligence and good judgment is displayed.

6. Excessive and reckless use of commercial
fertilizer should be avoided. Beyond a certain
limit profits are much more uncertain.

7. One application on clay soils has been
found as satisfactory as more where less than
soo pounds per acre were used. Quickly
available substances, such as nitrate of soda,
should be applied to growing crops. When
large amounts of fertilizer are used, and
on special soils, two applications are sometimes
more profitable.

8. Where all the benefits from fertilizers
are desired the first season, only readily avail-
able materials should enter into its composition.
For permanent improvement of the soil more

FERTILIZERS FOR COTTON 65

slowly available materials may be used and
these are usually cheaper.

g. The effect of fertilizers on crops after
the first year depends on season, soil condition,
and materials used.

10. Fertilizers give best results when not
applied more than two or three inches deep, ex-
cept when used on dry land, then they should
be deeper.

11. Organic nitrogen such as cottonseed
meal, dried blood, tankage, and fish scrap
have been found preferable in mixed fertilizers
where only one early application is made.

12. Potash is not needed on much of the
cotton soils as a fertilizer, but kainit has been
found greatly beneficial on soils subject to ¢ot-
ton rust.

13. Home mixing is profitable. A better
grade of materials can be had, and the mixing
can be done to suit special soils or crops.

14. A judicious use of fertilizers will increase
yields on any soil. It hastens maturity so
that cotton may be grown farther north, and
also makes it possible to offset insect damage.

15. Rotation of crops is very beneficial on
the cotton farm, especially if all the crops are

66 KNAPP METHOD OF GROWING COTTON

fertilized. In this way the benefits from the
fertilizers will be cumulative.

16. If nitrogen-gathering crops are grown
and manures and waste matter about the farm
plowed under and incorporated with the soil,
the mechanical condition will be greatly im-
proved and little nitrogen (the most expensive
element in fertilizers) will have to be purchased.

17. Where cotton has been grown exclu-
sively on lands for a long period, a complete
fertilizer is necessary, but where rotation has
been practised only two of the elements and
sometimes but one will have to be purchased.
The actual field experiments of the individual
farmer will be necessary to determine what
elements are required. A close study of these
problems by the farmer will save money now
uselessly squandered on commercial manure.

Improvement of Cotton by Seed Selection

CHAPTER VI
IMPROVEMENT OF COTTON BY SEED SELECTION

HE careful selection of the best seed is
a matter of importance to the cotton
farmer. It has been a too common
practice to plant inferior mixed seed from the
gin or oil mill, no attention having been given
to seed selection. ‘Tests show conclusively that
by selecting the best seed from the most desir-
able stalks the yield will be from 10 to 20 per
cent. more than where gin run seed, even of the
same variety, are used. At the present price
of cotton the loss to the farmer who plants poor
seed will be from $5 to $15 per acre.

Cotton is a plant which is very susceptible to
improvement by seed selection, and can be
greatly modified in form and habit in a very
few successive crops. The bloom is large
and open and cross fertilization is constantly
taking place by means of insects and other
causes. ‘The cotton plant sports easily and

69

70 KNAPP METHOD OF GROWING COTTON

responds quickly to differences in environment,
soil, climate, treatment, and fertilization. This
is an aid to the farmer if he uses care in selecting
his seed, but if no attention is given to seed
selection, the plant will show deterioration year
after year.

The main points to be considered in improv-
ing cotton seed are — variety or type, selec-
tion, ginning, and storage. By type is meant
the kind of stalk, bolls, lint, and general char-
acteristics. There are but few botanical va-
rieties, but there are a large number of what
might be called “Agricultural varieties” and
these agricultural varieties have a great many
more names than there are recognizable forms.
There are a great many varieties that have
been developed by the careful work of the most
progressive farmers through years of seed
selection. Each farmer should decide which
type or variety is best suited to his conditions,
should grow it exclusively and continue to
improve it. In choosing a variety, too little
attention is often given to some qualities and
too much to others. In making a choice
of a variety the following points should be
given careful attention and _ consideration:

SEED SELECTION 71

adaptability, productiveness, earliness, habit of
growth, length and strength of fiber, size of
seed, and susceptibility to disease. A desir-
able type of upland cotton is one having a
strong, vigorous, short-jointed stalk with plenty
of fruit limbs on the lower half; fruit limbs
short-jointed and extending to the outer
border of the plant and fruiting to the end;
large bolls, storm resisting; a high percentage
of lint; medium-size seed; staple at least one
and one eighth inches, and strong: plant
hardy, early, and prolific.

Simplest Method of Seed Selection. —'The
simplest method of seed selection is for one
careful hand to go ahead of the pickers at
the first or second picking and take the best
bolls, from near the heart of the stalk, from
such plants as nearest approach the type
for which the grower is selecting. Store this
selected seed cotton in a dry place and wait until
the gins are not crowded, then carefully clean
the gin, put down a sheet to catch the seed,
and run the selected cotton through. Store
these seeds in a dry place until it is time for
planting. This kind of seed selection will
aid in maintaining the excellence and purity

72 KNAPP METHOD OF GROWING COTTON

of a good variety and is practicable for farmers
who cannot devote much time to cotton
breeding.

Plant-to-the-Row Method. — A much better
plan and one that should be adopted by the
farmer who wants to do careful seed breeding
is to have a breeding patch, separated as far.
as possible from any other cotton to avoid
cross fertilization. It will be best to have
this breeding patch at least one fourth of a
mile from any other cotton. Select a plat
of ground for this purpose having uniform
character and fertility of soil. From the best
field of cotton each year select one hundred
stalks, or as many as can be conveniently
handled, and gin the cotton from each stalk
separately. A specially constructed small gin
will be best for this purpose, but if this cannot
be had the seed can be planted without ginning.

Lay off the seed patch in rows of equal
length and uniform width and plant the seed
from each stalk in a separate row. Mark
the rows off in checks of equal width and plant
the seed in hills. Plants may show marks of
excellence due to favorable environments but
by keeping the seed from each plant separate,

SEED SELECTION 73

and planted in separate rows, the good qualities
inherited from the parent plant will be easily
determined, and it is reasonable to suppose
that these plants will transfer their good
qualities to their offspring. From the rows
showing that the plants have inherited the good
qualities of theirparent plant, select one hundred
plants to be planted in the plant-to-a-row
patch the second year. The remainder of the
seed from the best stalks in the rows showing
the most excellence may be selected and planted
in a larger field from which seed can be grown
to plant the entire crop the year following.

The following diagram by Webber illustrates
seed breeding by the plant-to-a-row method:

Ist Year 2nd Year 3rd Year 4th Year 5th Year

Select Plant (1) | 500 { 5 \ ee { \
Plants Acres Crop
Select Plant (1) { 500 \ ure ; eel
Plants Acres Crop

j
Select Plant (1) ee Plats i | Kes
}

Select Plant (1) 1 500
Stray

Select Plant cd

74. KNAPP METHOD OF GROWING COTTON

Cross Fertilization. — When it is desired to
combine the good qualities of two varieties
in a single stock, this work can be best ac-
complished by cross fertilization. It is quite
probable that most of the varieties which have
been developed from single plants have really
originated by means of accidental crossing of.
different varieties.

While cross fertilization is the surest method
for the production of new varieties, it is largely
work in the dark, as plants resulting from the
crosses may inherit the weak qualities of both
parents without showing the good qualities
of either. It is often necessary to make a
hundred or more crosses before producing a
plant showing the desired combinations. Even
after a plant has been secured showing the
desired qualities the majority of its offspring
will not inherit these qualities. After the
cross is made and a plant of desired type
secured it is then necessary to practise care-
ful seed selection for a number of years before
there is much uniformity between the different
plants.

While there is much variation between in-
dividual plants resulting from a single line

SEED SELECTION 75

of crossing, still, as a general rule, the character
of stalk and the habit of growth in the future
plant will be more like the female parent, while
the fruit of the plant will be more like the male
parent.

It will not be found very difficult to artifi-
cially cross fertilize flowers of the cotton plants.

Near sunset select a large, well-developed
flower bud that would be open the next morning,
and carefully remove the anthers from the
flower by means of a small pair of scissors or
a sharp, thin bladed knife, using care not
to bruise the pistil of the flower. As soon
as the anthers are removed tie a paper bag
over the mutilated flower to keep out insect
visitors.

Next pick out a large, well developed bud
on the plant that is to furnish the pollen and
tie over the; bud) a paper bag to keep out
the insects. The following morning the pistil
will be fully developed and ready to receive
pollen. Pull the entire flower that is to furnish
the pollen and rub its anthers lightly over the
stigma of the flower from which the anthers
were removed. Again place the paper bag
over the cross pollenated flower and leave

76 KNAPP METHOD OF GROWING COTTON

until the young boll is developed, which will
be in four or five days. The paper bag should
then be removed and the boll carefully labelled
with a small tag so that it can be readily
identified at harvest time.

Varieties of American Upland Cotton

CHAPTER VII

VARIETIES OF AMERICAN UPLAND COTTON

r ie American upland varieties of cotton
are commercially divided into two
groups — short staple or those having

a fiber three fourths to one and one eighth inches

in length, and long staple or those having a

fiber from one and three sixteenths inches to

one and five eighths inches.

Short staple varieties when grown on moist
alluvial soils frequently produce a staple
slightly longer than one and one eighth inches,
but hardly long enough to be classed in the long
staple group. This grade of cotton is known
commercially as rivers or benders.

Varteties of American Upland Cotton. — There
are several hundred so-called varieties of cotton,
but a large number of these are practically
identical. This multiplication of names has
been brought about largely by farmers who
secure seed of some standard variety and

79

80 KNAPP METHOD OF GROWING COTTON

after growing it for one or two seasons, give
it their own name or some local name for
commercial purposes.

Classification of V arieties. —'There are several
methods of classification of American upland
cotton. They may be classified according to
conformation of stalk, length of staple, earli-

ness, size of boll, and percentage of lint.
J. F. Duggar, Director of Alabama Experi-

ment Station, Bulletin 140, divides American
upland into eight groups. His classification
with description of each group is as follows:
(1) Cluster varieties, or Dickson type.
(2) Semi-cluster varieties, or Peerless type.
(3) Rio Grande varieties, or Peterkin type.
(4) The King-like varieties, or King type.
(5) Big Boll varieties, or Truitt type.
(6). Long Limb varieties, or Petit Gulf
type.
(7) Intermediate varieties, or various types.
(8) Long Staple Upland varieties, or Allen

type.

The lines of demarkation between these
groups are not always clear and distinct; one
group often merges into another by almost

AMERICAN UPLAND COTTON 81

imperceptible gradations, just as is the case
with related varieties.

Below is given a list of the varieties which
are included under these several groups, and
also a general description of the varieties
composing each class. Some varieties are not
classified, either because of insufficient data,
or more frequently because badly mixed.
In cases of a medium degree of impurity, or
variation, description has been made of the
predominant type.

Group I: Cluster Varieties, or Dickson
Type. — The most striking characters are (1)
the extreme shortness of the fruit limbs, and
(2) the tendency of the bolls to grow in
clusters, often two and even three from the
same node. The plants are often tall and
always slender and normally erect, though
often bent down by the weight of bolls growing
near the upper end of the main stem. The
few base limbs are often long, or there may be
no wood limbs, especially when these varieties
are closely crowded or grown on poor land.
The bolls and seed are usually small, but
may be of medium size; the seed are thickly
covered with fuzz, which is usually whit-

82 KNAPP METHOD OF GROWING COTTON

ish, with little or no brownish or greenish
tinge.

As to the time of maturity these varieties
must be classed as early, even though they
sometimes make a second growth of bolls in
the top of the plant which may fail to mature.
In earliness they are surpassed by the varieties
of the King type (Class IV).

In percentage of lint they are variable, some
of them equalling in this respect the Rio
Grande group.

Dickson, Jackson (also called Limbless or
African), U.S. Dept. Agr., No. 128, and Wel-
born, belong to this group.

Group II: Semi-cluster Varieties, or Peer-
less Type.— These varieties have in less
marked degree some of the qualities which
distinguish Class I, being erect and having
bolls borne singly very near together. Along
the main stem are short fruit limbs increas-
ing in length toward the bottom of the stem.
The two to five base or wood limbs are usually
of medium length. In size of bolls and size of
seed and percentage of lint there is considerable
diversity among these varieties. ‘The seeds are
usually well covered with fuzz of many shades,

u0}}09 UeIpUy ‘7YSII UO pur fpurysy vas ‘ar}Ua9 UI {pur[dg uLoTIEUY ‘Jo, UD
s][oq U01}09

U0}}09 yoordur110}s [[Oq 3Iq purldy
Q uroeuy ‘pe +0309 IRIS ‘pz {u0}}09 uendésy 4s1 ‘qjJe] 243 UO

* uojoo jo s[joq uedO

uvoueauy ‘yyb tajdeqs suo] puejd

AMERICAN UPLAND COTTON 83

whitish, greenish, or brownish. Most of these
varieties are early or medium, but some that
belong in both the semi-cluster and big boll
groups are late in maturing. The following
varieties are included in the semi-cluster group:
Barnett, Berryhill, Blue Ribbon (L. S.), Cum-
mings, Defiance, Dongola (B. B.), Feather-
stone, Garrard, Haralson (B. B.), Hardin,
Hawkins, Herndon, Hilliard, Lealand, McCall,
Minor, Montclare (B. B.), Norris, Peerless,
Pullnot, Rogers (B. B.), Sterling, Tyler, and
Woodfin.

Group III: Rio Grande Varieties, or Peter-
kin Type.— The characters which most dis-
tinctly mark this class are:

(1) The large proportion of lint, usually
35 per cent. or more, of the weight of seed
cotton, and

(2) Seeds of which many are bare of fuzz,
except at the tip end, or so scantily covered
with fuzz that the dark seed hull shows through.

The plants are well branched, and usually,
on upland soils, of medium size. On many
plants the stems and branches are of a deep
red color. The bolls are small to medium
and the seeds are quite small. In time of

84. KNAPP METHOD OF GROWING COTTON

maturing these varieties are usually neither
very early nor extremely late.

The varieties included in this group are
conveniently divided into two sub-groups ac-
cording to the presence or absence of naked,
smooth seed. The following Rio Grande vari-
eties have a considerable proportion of naked
seed: Ansom Cream, Bates, Braddy, Brannon,
Cameron, Carolina Queen, Champion, Combi-
nation, Crossland, Dixie Wilt-Resistant, Moss,
Parker, Peterkin, Pinkerton, Ptomey, Shine
Black Seed, Sistrunk, Texas Oak, Texas Wood,
Victor, and Wise.

Rio Grande varieties having practically no
naked seed, but having many seeds so scantily
clothed with fuzz that the dark seed coat
shows through, giving a brown color, are the
following:

Berryhill, Borden, Dearing, (probably)
Eureka Favorite, (probably) Gregg, Layton,
Park’s Own, Speight, and (probably) Toole.

Group IV: King-Like Varieties, or King
Type. — The varieties of this group are the
earliest of American cottons. The plants are
usually small but may be of medium size.
The limbs are numerous and the fruit limbs

AMERICAN UPLAND COTTON 85

are rather long in proportion to the height
of plant. The fruit limbs are often crooked
at the joints, reminding one of the crooked
twigs of a black jack oak. The base limbs
are short and sometimes replaced by fruit
limbs bearing a number of bolls on each.
King is essentially a short-jointed, compact
plant with an abundance of slender, rather
crooked limbs. The bolls of this group are
small; the seeds are usually small and thickly
covered with fuzz which is usually brownish,
with an occasional seed showing a greenish
tint: The percentage “of lint’ is’ usually 33
to 35, and sometimes higher. King and its
synonyms have on many blooms a red spot
near the base of the inner portion of each petal.
The varieties of this group are: Dozier, Grier,
Golddust, Hodge, King, Simpkins, Lowry,
Mascot, Missonary, and probably Shine Early.

Group V: Big Boll Varieties or Truttt
Types. — The character which especially dis-
tinguishes this class is the large size of bolls,
of which only 45 to 68 are required to yield a
pound of seed cotton. Other specially nota-
ble qualities are late maturity and vigorous
growth of:stalk. The seeds are large or very

86 KNAPP METHOD OF GROWING COTTON

large, and covered with a thick fuzz, generally
brownish white or whitish, a part of the seed
of many of these varieties being covered with
a deep green fuzz. The per cent. of lint often
runs rather low and is usually between 31 and
35. The bolls are not closely clustered; in
some varieties the upper limbs are so short
as to give the top of the plant the erect, slen-
der appearance which is common among semi-
cluster varieties. In typical plants the base
limbs are of short or medium length, the num-
ber of fruit limbs and bolls relatively few,
and the main stem is rather short. However,
a number of varieties are included here that
have all or many of their plants of the semi-
cluster form.

The following varieties belong in this group:
Alex. Allen, Anderson, Bancroft, Banks, Berry,
Bohemian, Cheise, Christopher, Cleveland,
Cliett, Cook Improved, Coppedge, Culpep-
per, Diamond, Double Header, Dongola,
Drake (Ala.), Duncan, Ellis, Grayson, Gunn,
Haralson, Hunnicutt Big Boll, Hutchinson,
Jones, Langford, Lee, Maddox, Montclare,
Mortgage Lifter, Ozier Big Boll, Reliable,
Rogers, Rowden, Ruralist, Russell, Scogin,

AMERICAN UPLAND COTTON 87

Sewell, Schley, Smith Improved, Smith Stand-
ard, Southern Wonder, Spearman, Strickland,
Tatum, Texas Bur, Texas Storm Proof, Thrash,
Todd, Triumph, Truitt, Webber-Russell, Whit-
ten, and Wyche.

Group VI: Long Limb Upland Varieties,
Petit Gulf Type.— The varieties in this class
grow to large size and have long limbs and
long joints, the plants presenting a straggling
appearance or want of compactness. ‘The
bolls and seeds are both of medium to
large size, the latter covered with fuzz of
various shades. The per cent. of lint is
usually low. The long limb form is usually
accompanied by unproductiveness on average
upland soil.

The following varieties are included in this
group: Hagaman, Louisiana, Peeler, Petit
Gulf, and probably Red Leaf.

Group VII: Intermediate Varieties or Vari-
ous Types. — This group is here added to the
scheme of classification published by the
writer in 1899, primarily to include varieties
having limbs a little too long to bring them
within the semi-cluster class. It is also made
to include a few other varieties that are inter-

88 KNAPP METHOD OF GROWING COTTON

mediate between any two of the other seven
groups.

To this division are assigned, Breden, Boyd,
Edgeworth, Eureka, Excelsior, Gold Standard,
Hunnicutt (J. B.), Lewis, Meredith, Roby,
Rosser, (probably) Shine Early, Sprueill, (pos-
sibly) Toole, Tucker, and Webber-Russell.

Group VIII: Long Staple Varieties, or Allen
Type. — The length of staple is the distinguish-
ing characteristics. ‘The lint usually measures
1; to 13 inches in length. An almost invari-
able accompaniment to great length of staple
is a low proportion of lint.

The plants grow to large size, have limbs of
great length, and usually present a straggling
appearance, though in some varieties only the
base limbs are long, the upper limbs bearing a
number of bolls close to the main stem, and
giving the upper portion of the plant the
appearance of great prolificacy.

The bolls are not very large, but are long,
usually slender, tapering to a sharp point.
Most of these long staple varieties are late in
maturing a crop.

The seeds are mostly of medium to large size,
usually densely covered with fuzz, from which

Varieties of cotton

Cluster group: Jackson limbless
variety

Semi-cluster group: Hawkins
variety

Big boll group: Truitt variety
The King-like, or Early group:
Shine variety

Varieties of cotton

Upland long-staple group: Allen
variety
A stalk showing desirable type of
Upland cotton

Sea Island
Rio Grande Group: Peterkin
variety

AMERICAN UPLAND COTTON 89

all trace of green is absent, the color being
almost pure white, or in some varieties of a
brownish tint. In some varieties the seeds are
bare. In the long staple group are included:
Allen Long Staple, Allen Hybrid Long Staple,
Black Rattler, Blue Ribbon, Cobweb, Cook
Long Staple, Colthorp, Davis, Florodora,
Gholson, Griffin, Keno, Laclede, Ozier Long
Staple, Simms, Sunflower, and Wonderful.
Relative Value of Varieties. — The relative
valueof the different varieties can be determined
only by the number of dollars per acre each
will bring. Each section of the cotton growing
belt should secure varieties specially adapted
to the particular conditions by which they are
to be surrounded. W.R. Perkins, of the Mis-
sissippi Experiment Station, in a test of sixteen
well-known varieties, under the same conditions
and with the same cultivation found the differ-
ence in value per acre of the best over the poor-
est was $19.25 one year, and $26.81 another
year. This wide range of values would certainly
indicate that ascertaining the proper variety
to be grown was necessary for success. A
variety may succeed well in one locality and
when transferred to another section and planted

go KNAPP METHOD OF GROWING COTTON

on a different soil may not maintain its good
qualities. Some varieties are more liable to
suffer from insects than others; some are more
susceptible to certain diseases than others;
some produce fairly well under almost any
condition while others produce well under
favorable conditions, but fail miserably on
unfavorable soils or with unfavorable cli-
matic conditions. Some of the long staple
varieties which produce a long, strong, silky
fiber on moist rich alluvial river bottom soil,
fail to produce as good quality of lint or as
satisfactory yield per acre when planted on
high dry uplands.

The yield of lint per acre of long staple cot-
ton on the same land and with the same treat-
ment will be from 30 to 4o per cent. less than
short cotton. Long staple cotton is more ex-
pensive to harvest on account of the size and
shape of boll, making it harder to pick and
requires more care and expense in ginning.
For the farmer to be justified in growing long
staple cotton he should receive at least
a premium of 40 per cent. over the price
of short cotton. In other words, when
short cotton is selling at ten <cents jper

AMERICAN UPLAND COTTON gI

pound long staple cotton will have to sell
for about fourteen cents per pound for the
farmer to realize as much per acre from
it.

On lands suitable, the big boll cottons are
preferable for the following reasons: The
plants are stronger and more vigorous, it is
much easier to harvest, and not so liable
to damage from rain or storm when harvesting
is delayed.

In purchasing seed of the chosen variety
attention should be given to the care that has
been exercised in seed selection by the grower
and not to advertisements of extra large
yields. It is also best to procure seeds that
were grown near by, if possible, as they are
already acclimated and adapted to local
conditions.

The following varieties of small boll early
short staple cottons have taken high rank in
yield of lint per acre at experiment stations
in recent years:

Toole Trice
Simpkins Hawkins
King
The following big boll short staple cottons

92 KNAPP METHOD OF GROWING COTTON

have taken high rank in yield of lint per
acre:

Triumph Russell
Cleveland Cook’s Improved
Truitt

Triumph, Cleveland, and Cook’s Improved ~
are medium early, Truitt and Russell are late
maturing.

The following long staple cottons have
taken high rank:

Columbia _ Griffin
Hartwell Allen
Sunflower
Sea Island Cotton. — Sea Island cotton is a

native of the West Indies and Central
America and is grown only in a limited
area in South Carolina, Georgia, and Flor-
ida, and off-lying islands. It is seldom
profitable when grown more than one hun-
dred or one hundred and twenty-five miles
from the seacoast.

The plant grows rather tall, has long, slender
branches, leaves with long slender lobes, the
bolls are small, slender and sharp pointed
having usually only three locks, and the fiber

American Upland cotton

Leaves: flower opening creamy white in the morning, closing arid
changing to rose pink in the afternoon; unopened bolls; mature open
bolls with cotton ready for picking

Cotton boll with anthracnose

Root-knot on cotton plant

_ AMERICAN UPLAND COTTON 93

is fine and silky, ranging from 13 to 2 inches
in length.

Sea Island cotton produces the finest staple
of any cotton grown and is used to manu-
facture thread and the most expensive cotton
fabrics.

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CHAPTER’ Vii

SOME COTTON DISEASES AND INSECT PESTS WITH
SUGGESTIONS FOR THEIR CONTROL

HE cotton plant is subject to more dis-
eases and insect enemies than any of
the farm crops of the South. This is

to some extent due to the delicate nature of
the plant in its early life. It is also partly due
to the fact that cotton has been forced to adapt
itself to more or less artificial conditions; it is
naturally a tropical plant. While cotton has
its origin in tropical climates, it is very largely
grown commercially in semi-tropical countries,
and under entirely changed conditions. It is
probably better for the average cotton producer
that the cotton plant has its enemies, for with
nothing to check its growth and production
_ the supply would be largely in excess of demand.

Anthracnose or Pink Boll Rot.— This is a
fungus which causes the bolls to rot and is more
or less prevalent in all parts of the cotton

97

98 KNAPP METHOD OF GROWING COTTON

belt. No variety of cotton is entirely free
from this disease, but some varieties are more
subject to it than others.

This discase first appears on the bolls as
very small, dark spots, which enlarge and
become somewhat sunken in the centres,
which are pink or reddish brown.

The disease is spread by spores formed on the
diseased areas and is carried over winter in
infected seed and possibly in old cotton plants.
Anthracnose is worse in wet than in dry sea-
sons. By giving the cotton plenty of space
to let in sunlight and air the disease will be
less prevalent.

It is claimed by some farmers and investi-
gators that deep breaking the land in the fall
completely burying all old cotton plants has
a tendency to lessen the damage from this
disease.

In selecting seed be careful to avoid selecting
from plants affected by anthracnose.

Cotton Wilt.— This is a fungous disease
which attacks the roots and stems of the
plant. It enters the roots from the soil and
plugs up the water carrying vessels of the
roots and stems.

A young cotton plant dying from wilt

A typical plant of Dillon wilt-resistant cotton

SOME COTTON DISEASES > 9G

This disease first makes its outward appear-
ance in a cotton field by a sudden wilting of
the leaves which turn yellow and fall without
apparent reason.

An examination of the roots of a freshly
wilted plant that has been attacked by the
wilt fungus always shows a blackened condi-
tion of the inner wood of the root or stem.

So far as known cotton and okra are the only
plants the cotton wilt fungus lives on as a
parasite.

This disease cannot be controlled by the
application of potash as some farmers suppose.

The wilt fungus lives in the soil and is
spread by the plow, by drainage water, by
cattle, by manure, and other means of carry-
ing the spores from one place to another. No
direct proof is available that this disease has
been spread by planting seed from infected
fields, but many cases have been reported
which indicate that the disease may be spread
in this way.

In every field attacked by wilt there will be
found a few plants not affected by the disease.
By selecting seed from these plants a strain
of cotton may be secured practically immune

I0O0 KNAPP METHOD OF GROWING COTTON

to the disease. Another means suggested
for the control of this disease is by practising
crop rotation, using in the rotation crops that
are not affected by the wilt fungus and the
nematode worm —a very small worm which
attacks the roots of plants causing root knot.
It is claimed that the attack of this worm on
the cotton roots makes it easier for the wilt
germ to enter. The plants that may be used
in a rotation to free the land of wilt are: corn,
wheat, oats, rye, iron cowpea, Brabham cow-
pea, velvet bean, beggar weed, and grasses.

The United States Department of Agri-
culture has developed two varieties of cotton
which show great resistance to wilt, viz.,
Dixie and Dillon.

Cotton Rust. — Cotton ‘‘rust”’ first makes an
outward appearance by a mottled yellowish
color of the leaves in dry weather or a sudden
blackening and shedding of the foliage in wet
weather. This disease is probably due to a
poor mechanical condition of the soil and the
lack of some plant food element, usually potash.
Soils affected with rust are greatly benefited by
turning into them heavy crops of vegetable mat-
ter, and by a rather liberal application of potash.

SOME COTTON DISEASES IOI

The Cotton Boll-Worm. — Perhaps the earliest
insect to do serious damage to the cotton crop
was the boll-worm. It also attacks the corn
and tomato plant. It is known in corn as
the common ear-worm, getting its name from
the fact that the moth, laying the eggs, deposits
them on the silk of the young ear of the corn.
Here they hatch out and go into the ear and
feed on the tip end grains as they reach the
roasting ear stage.

The cotton boll-worm is a large green to dark
brown worm that destroys the partially grown
cotton bolls by eating into them.

They will invariably attack corn if in reach
before going to cotton. The best way to
combat this enemy in the cotton plant is to
use corn as a catch crop for them. When
corn is used for a catch crop, several plantings
should be made so that it will give the worm
something to feed on continually, without
resorting to the cotton patch. This may be done
by planting a few rows of corn around the
cotton patch, or if preferred, two or three rows
may be planted at intervals through the fields.
Some good may be done by the use of poison.
For poison to be effective it should be applied

102 KNAPP METHOD OF GROWING COTTON

several times during the season. The poison
generally used for this purpose is dry Paris-
green, which is sprinkled over the plants,
preferably in the early morning while the dew is
still on them. The boll-worm never attacks
nor injures cotton except in the bloom and
small boll.

A single moth may lay as many as one thou-
sand eggs. ‘The eggs are laid on all parts of
the plant, but especially on the leaves. After
the worm hatches it feeds on the tender leaves
until strong enough to cut into a boll. Each
worm will destroy the contents of one or more
bolls. When full grown the worm drops to
the ground, and burrows two or three inches
below the surface, where it remains until it
emerges as a full grown moth. There will
usually be from four to five generations in a
season.

The boll-worm passes the winter in the ground
in the pupa stage. Many of these insects can
be destroyed by breaking the land deep in the
fall or early winter.

The Cotton Caterpillar. — This is one of the
earliest insect enemies of cotton in the United
States. It is sometimes known as the ‘‘web-

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A field of Upland cotton in South Carolina destroyed
by wilt

Wilt-resistant Dillon cotton on adjoining land badly

infected with wilt

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Moths of cotton boll-worm

Pupa of boll-worm in its underground burrow

SOME COTTON DISEASES 103

worm,” or ‘

‘army-worm.”’ It appears almost
every year to a limited extent. It has proven
disastrous to the cotton crop only a few times in
the United States. Its ravages do not extend
over a very considerable amount of territory
during any one season.

There are four stages in the life of the cotton
worm: the egg, the larva, the pupa, and the
adult. The adult cotton worm is a brownish
yellow or grayish colored moth, the wings of
which expand from one and one eighth to one
and one half inches. ‘The moth deposits its
eggs on the under side of the leaf of the plant,
where it hatches out in very hot weather in
about three days.

The worm or larva feeds upon the leaves of
the plant, and when very numerous will attack
the squares and the outer surface of the bolls
and even the twigs. It has been known to
destroy a whole field in a few days and then
move to another field in such numbers as to
derive the name of “‘army-worm.”’

The cotton leaf worm or caterpillar transforms
to the pupal stage on the cotton plant. The
beginning of this stage is known as ‘“‘webbing

99

up.’ The time required from the hatching out

104, KNAPP METHOD OF GROWING COTTON

of the larva or worm to the “‘webbing up” or
pupal stage is about fifteen days. Usually
the caterpillar spins a crude web or cocoon
using a portion of the leaf for the purpose,
but in many cases no web whatever is formed,
and the naked pupa hangs from the cotton
plant by means of a thread spun by the cater- -
pillar. The time required from the ‘‘webbing
up” to the hatching out of the moth is in very
hot weather from seven to ten days. The
complete life cycle from eggs to moth will be
completed in hot weather in from three to
four weeks. A single moth lays from four to
six hundred eggs in a week or ten days and
then dies.

From the fact that the worm feeds on the
foliage of the plant, it may be effectively
controlled by the use of poisons; Paris-green,
arsenate of lead, London purple, or any of the
arsenical poisons may be used for this purpose.
The most common method of poisoning is by
applying Paris-green mixed with one or two
parts of flour or lime.

The most practical method of application is
the one commonly adopted, of sacks attached
to the ends of poles and carried on horseback

Stages and work of the cotton worm or cotton caterpillar

Cotton plant attacked by boll weevil

a, Hanging dry square infested by weevil larva; 6, flared square,
with weevil punctures; c, cotton boll, sectioned, showing attacking
weevil and weevil larva in its cell

SOME COTTON DISEASES 105

through the fields. Take a pole about one
foot longer than the width between the cotton
rows, and six inches from each end of the pole
attach a sack or bag containing the poison.
Cheesecloth will be found a satisfactory
material for making the sacks. By the above
method one hand on horseback can poison two
rows at a time and cover twenty acres a day.
The poison should be applied at the first
appearance of the worm. It is best to make the
application early in the day when the leaves are
moist with dew. If the poison is applied on a
calm day there will be less loss from the poison
drifting to the ground. .

The Cotton Boll Weevil. —'The most destruc-
tive of all insects that have attacked the cotton
plant is the boll weevil, which has only been
in the United States for the past seventeen or
eighteen years. It has rapidly spread each
year since its first appearance and is destined
within the next decade to cover the entire
cotton-producing part of the United States.
The ravages of this enemy are so great that the
total production of some counties has been
reduced to less than Io per cent. of the normal
production. However, a few years’ experience

106 KNAPP METHOD OF GROWING COTTON

with it has overcome the ravages to some degree
in most sections, and in some cases the farmers
have almost reached the original production.

The cotton boll weevil is a member of the
beetle family. In size it varies from one
eighth to three eighths inches in length and
the breadth of its body is about one third its -
length. The color varies from a light yellow-
ish brown to a chocolate brown.

The members of the group of insects to which
the boll weevil belongs are characterized by
having part of the head in front of the eyes
greatly extended to form a long slender snout.
The snout of the boll weevil is slightly curved
and is about one half as long as from the head
to the tip of the body. The distinguishing
feature of the cotton boll weevil is two tooth-
like projections on inner side of the fore-legs,
at the lower end of the thigh, the inner or one
nearest the body being longer than the other.
There are four stages in the life of the weevil,
the egg, the larva, the pupa, and adult weevil.

Three of these stages, egg, larva, and pupa
are passed inside the cotton square or boll.
The egg is deposited by the female weevil in a
cavity formed by eating into a square or boll.

SOME COTTON DISEASES 107

From the egg there hatches in a few days a small,
white footless grub or worm which begins to
feed, making a larger place for itself as it grows.
During the course of its growth the grub or
larva sheds its skin and the pupa appears. In
this stage it is inactive and takes no food. Ina
few days the pupa sheds its skin and the full-
grown weevil appears and in two or three days
eats its way out of the square or boll and about
one week later is ready to start another gene-
ration.

The time required from the laying of the
egg to the emergence from the square or boll
of the full-grown weevil is from fifteen to
twenty-five days, depending on the season—
the shorter time being required during very
warm weather.

In the extreme southern part of cotton belt
there will be as many as five generations of
weevils in one season. In the central part of
the cotton belt there will be from three to four
generations.

The weevil is a very prolific insect, each
female weevil laying during a lifetime about
one hundred and forty eggs, so during a season
it is estimated that one pair of weevils may have,

108 KNAPP METHOD OF GROWING COTTON

under favorable conditions, a living offspring
of two hundred and fifty thousand.

The weevil feeds by sucking out the juices
from the inner portion of the plant, which makes
it impossible to use poisons effectively in its
control, as is done with insects which feed upon
the foliage of the plant. This renders the
weevil very difficult of control.

The only way of combating the ravages of
this insect is by using all means possible to
hold the weevils in check and by practising
better cultural methods in producing the crop.
There are at present no known methods of
completely destroying the weevil, so it will
most likely be a factor in all future cotton pro-
duction in the United States.

The Bureau of Entomology, U. S. Depart-
ment of Agriculture, has established the follow-
ing facts regarding the life history of the
weevil which are important in outlining methods
for its control:

1. The cotton boll weevil feeds upon nothing
but cotton.

2. It goes into winter quarters mainly in
or near the field of its depredations.

Cotton boll-worm on outside and inside of cotton boll

Partly opened cotton bolls showing effects of boll-worm
damage

Injury by boll-weevil to bolls
a, Three larve in boll; }, emergence hole in dry unopened boll;
c, two larve in boll; d, weevils puncturing boll; e, opened boll with
two locks injured by weevil; f, large bolls severely punctured

SOME COTTON DISEASES 109

3. That a comparatively small per cent.
of the total weevils survive the winter
and emerge in the spring.

4. That the overwintered weevil feeds upon
the terminal bud of the young cotton
plants until the forms or squares de-
velop, then the female deposits her
eggs in the squares exclusively at first,
but later may deposit them in the bolls.

5. That the life of the adult weevil, when
supplied with food, is about seventy
days. If deprived of food it lives
only six or seven days except in hi-
bernation,

6. For a period after emergence from winter
quarters it is comparatively sluggish
and while feeding upon the cotton
plant may be picked or poisoned.

7. The weevils remain in the field where
they appear in the early spring until
they become very numerous. Their
principal period of migration is in the
fall.

Based upon these life habits of the weevil Dr.
S. A. Knapp, Bureau. Plant Industry, U. S.

IIO0 KNAPP METHOD OF GROWING COTTON

Department of Agriculture, outlined the fol-
lowing plan for the production of cotton under
weevil conditions:

(1) Under boll-weevil infestation the fields
selected for cultivation should be well drained,
because a successful crop will then depend upon
the possibility of cultivating them at the proper
time. The poorly drained lands should be
devoted to other crops. They have always
been an uncertain factor in cotton production.
It is not the intention to state that well-
drained alluvial lands should not be planted
to cotton.

(2) The early destruction of the cotton
stalks before frost and the burning of all rubbish
in and about the infested field are imperative.

(3) Break the field deep as early in the fall
as possible with an implement that does not
bring too much of the subsoil to the surface.
Some winter cover crop should be grown if
practicable; if not, harrow occasionally during
the winter. Before planting, thoroughly pul-
verize the soil and make the best seed bed
possible.

(4) Care must be taken to secure seed of an
early-maturing variety and of the highest

SOME COTTON DISEASES Ill

vitality — not necessarily a small-boll variety,
for on uplands we have been more successful
with some large-boll varieties.

(5) Plant reasonably early. Planting
should be delayed until all danger from frost
is past and the soil is warm enough to produce
rapid germination and growth.

(6) The use of the section harrow before
planting and after planting, and again just as
soon as the plants are well up, is advised.

(7) Use intensive, shallow cultivation of the
crops and never lay by the cotton till picking
commences. Late cultivation is very important.

(8) Incase it is evident that a large number
of weevils have been overwintered, it is advis-
able to hand-pick the early appearing weevils
from the buds of young cotton plants before
squares begin to form.

(9) As soon as the weevil commences to
work, as evidenced by the punctured squares
attach a pole or brush to the handles of the
cultivator so as to knock the squares off.
Most of them will fall of their own accord in a
few days after they are punctured.

(10) Persistently pick up and burn the fallen
squares.

II2 KNAPP METHOD OF GROWING COTTON

This battle against the weevil is in two di-
visions:

The first division of the work consists in
reducing the number of weevils just as much as
possible so that a crop can be made.

The second division is to push the cotton
plant to maturity as fast as possible and by |
extra cultivation and fertilization cause it to
put no more forms or squares than it can mature,
so that what the weevil takes is only a surplus
— of no consideration in making the crop.

The burning of the stalks is very destructive
to the weevils in the field, but its value depends
considerably on when and how it is done. It
must be done early and before frost. Demon-
strations have been made showing that it
caused the destruction of as many as 97 per
cent. of the weevils if done early and properly,
but if delayed it might allow as many as 45
per cent. to escape.

There are several methods of destroying the
stalks. First, every third or fifth row may be
allowed to stand and the rows on each side
uprooted and thrown against it. Second, all
the stalks may be cut and thrown into piles
of convenient size. In either case, some of

Effects of boll-weevil attack on leaf and squares

a, Cotton leaf much fed upon by adult weevils; 6, square with
two egg punctures; c, flared square with many feeding punctures; d,
square prevented from blooming by puncture; e, bloom injured by
feeding puncture; f, poor blooms caused by feeding punctures.

Poisoning cotton by pole and bag method

Poisoning cotton by use of spray pump

SOME COTTON DISEASES 113

the adult weevils will collect in the windrows
or piles and be destroyed when the stalks are
burned.

Another plan practised is to turn cattle in
the fields to eat the foliage and immature bolls.
This plan, however, should not be followed
except by those farmers who can turn in
enough cattle to completely clean up the
field in a week’s time.

The object in destroying the stalks is a
twofold one: (1) ‘To deprive the adult weevil
of food and breeding places; (2) to kill the
vast numbers of weevil eggs, larve, and pupe
contained in the squares and immature bolls
at this time. To make this destruction com-
plete, the stalks should be burned as soon as
possible after being cut and piled. As soon
as the foliage will burn readily fire should be
applied, although the main stem and branches
may not yet be dry enough to burn. All
rubbish in and about the field should also be
burned and the field immediately broken.

If this single instruction to destroy all cotton
stalks in the fall while still green could be
carried out by every grower, it would practically
solve the weevil problem. The difficulty is

I14. KNAPP METHOD OF GROWING COTTON

that only part of the growers follow the plan.
It requires early maturing cottons and rapid
gathering to get the crop out in time to do this
work to the best advantage.

If delay is made until after a heavy frost and
a large number of the weevils have escaped from
the field, either to hibernate or to go elsewhere
then to cut and burn stalks may be of little
value, and the better practice is to thoroughly
cut the stalks and plow them under.

It is seldom practicable for farmers in the
northern portion of the cotton belt to cut and
burn stalks early enough to be of value.

The next most important work in eliminating
the weevils is in the spring, when the cotton
plants begin to put on squares and the infesting
weevil punctures them. The grower should
take note of this and immediately attach a
pole to the handles of the cultivator so as to
knock the bush and hasten the falling off of
the squares, and then the squares must be
carefully picked up and burned. In one sense
this picking up of squares goes to the root of
the matter more than early fall destruction of
the stalk, because in the fall destruction only
a small percentage of the weevils would live

SOME COTTON DISEASES 115

through the winter anyway, while we can
rest assured that practically every square not
picked up and destroyed, at least in cloudy
weather, will result in furnishing a boll weevil
to infest the crop. We know of hundreds of
instances where fields were located in the best
situation for weevil depredation, on bottom
lands surrounded by heavy timber, with a
rank growth of cotton and no previous prepara-
tion or burning of the stalks or destruction of
the rubbish, and yet by picking up the squares
and intensive cultivation a large crop of cotton
was made. If care is taken that every punc-
tured square is destroyed, a whole generation
of weevils will be wiped out in two or three
weeks. The old weevils will die and we can
go right on making the crop. Of course, in
sections where there is very slight rainfall and
on sandy upland soils anywhere during periods
of dry and very hot weather, dependence may
be placed on the heat to kill the weevil larve
in the squares.

It will seldom be safe to depend on this on
alluvial soils and never on any kind of soil
except under the conditions of drought and
heat above noted.

116 KNAPP METHOD OF GROWING COTTON

We therefore wish to emphasize the two
points, the early destruction of the stalks in the
fall and the picking up and burning of the
squares, as of primary importance in making a
successful crop of cotton. The early destruc-
tion of stalks in the fall has a double advantage.
It not only kills a vast number of the weevils, |
but it destroys all their supply of food so that
such as are not killed by fire mostly perish for
lack of food before winter.

The crop must be worked regularly and the
period of cultivation extended until the early
maturing bolls begin opening. It has been
found by actual experience that a profitable
crop may be made under the heaviest infesta-
tion of the boll weevil if the weather is fairly
seasonable, that is, if there is not too much rain.
It is utterly impossible for the farmer to make a
profitable crop of cotton with the boll weevil
present under the old system of farming. The
system of farming has been materially changed
in every section where the weevil has yet
appeared. The people have been forced to
abandon the all-cotton system and to adopt the
method that will enable them to produce all of
the home supplies. The first few years have

SOME COTTON DISEASES 117

usually brought about a demoralization of
conditions, which almost ruins business in the
community. After the third year, the people
begin to adapt themselves to the changed
conditions and it is frequently the case that in
four or five years after the weevil has en-
tered a section the people are in really better
financial condition in every respect than they
were before the weevil came.

Other Cotton Insect Enemies. — Other insect
enemies of the cotton plant are the red spider,
the plant louse or aphis, and the cut worm.
The damage from these is never very serious
and is always confined to local territory.

COTTON BOLL WEEVIL

a. Beetle from above; b. same, from side (five times natural size).
Note the two tooth-like projections on the inner side of first joint of
the front legs.

Harvesting and Marketing Cotton

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CHAPTER: «Lx

HARVESTING AND MARKETING COTTON

NDER harvesting comes cotton picking,

| ginning, and baling. Picking is the
most expensive item in the production

of the crop. No machine has yet been per-
fected that will satisfactorily do this work, and
it must necessarily be performed by hand. The
prices for picking cotton range from thirty-five
cents to a dollar per hundred pounds of seed cot-
ton, varying with the localities and the season in
which the picking is done. Hence, the cost of
picking a bale of 1500 pounds of seed cotton
ranges from $5.25 to $15. Picking begins usu-
ally in the latter part of August and extends to
the first of December, and in some instances to
the first of January. At least three pickings
should be made to gather crop in the best
condition. The heaviest picking comes in
October. One man can cultivate from twenty
to thirty acres of cotton very readily, but it

121

I22 KNAPP METHOD OF GROWING COTTON

will take four to five good pickers to gather the
crop fast enough to keep it from being damaged
by the weather. An experienced picker can
pick from 150 to 200 pounds per day. The
average, however, is much less than this.
Under favorable conditions and with some
special inducements, a few pickers have gone
as high as four or five hundred pounds a day.

Cotton is seldom gathered under the most
favorable conditions. It should be picked as
soon as enough bolls open to justify going over
the field. From three to five bolls per stalk
make a fairly good picking. If the crop is
kept up with closely and never allowed to take
the weather, the standard of the grades is much
higher and commands better prices. Fre-
quently, faulty, yellow locks, or dirty cotton is
picked and thrown in with the good. A few
bolls of this damaged cotton will injure the
grade of the entire bale and lessen the value
from one half to one and one half cents per
pound. Cotton should not be picked when too
green as the lint continues to grow and mature
until the seed have fully dried out. Cotton
that is blown out on the ground and damaged
by dirt, if picked should be put in separate

HARVESTING AND MARKETING COTTON 123

bags and ginned separately. This will insure
not getting mixed cotton in the bales. The
exercise of more care in this direction would
result in an annual saving of many thousands of
dollars to the farmers of the South. Until
recent years the common practice was to
pick almost the entire crop and store it in the
house for several weeks and haul it to the gin
after the rush of picking season was over.
In many respects this custom was a good one
from the fact that it allowed the cotton to ripen
up and become thoroughly dry, thus improving
the staple. It is true that there is some loss in
the weight of the seed, but this is more than
made up by the increased price from the im-
proved quality of the cotton.

There have been many machines patented
for the mechanical harvesting of the cotton
crop, none of which have as yet been entirely
satisfactory. It is possible that a machine may
be perfected that will harvest the crop on fields
favorably situated; but on small farms and
rough lands it is doubtful whether it will
be practicable to ever use mechanical contriv-
ances for gathering the crop. A light ma-
chine, of moderate cost, adjustable to small

I24 KNAPP METHOD OF GROWING COTTON

farm conditions, would go far toward solving
the harvesting problem. With a successful
mechanical picker the cotton acreage could be
enormously increased and the whole system
placed on a changed economic basis.

Ginning. — The second process in harvesting
cotton is the ginning or separation of the lint -
from the seed. In the early days of cotton
ginning in this country this was done by hand,
a man separating from the seed about one
pound of lint per day. The cotton gin was
invented in 1792 and since then has been so
perfected as to entirely revolutionize the
cotton industry and make it one of the greatest
in the world. The modern seventy-saw gin
stand will gin from ten to fifteen bales a day.
In big ginneries several stands are connected,
all arranged for conveying the lint to the same
press. The lint is carried by conveyors from
the gin stand to the press, where it is packed into
bales, varying in weight from 300 to 600 pounds.
The average commercial bale is rated at 500
pounds.

These big plants take care of the crop for a
considerable territory. The saw gin is used
for the short and medium staple cottons.

HARVESTING AND MARKETING COTTON 125

When long staple cotton is ginned on the saw
gin it should be run at a low speed, not over
300 to 400 revolutions a minute. It is a very
common practice to run a gin too fast and to
injure the staple of any kind of cotton. This
is especially true in the busy season, when the
ginning plants are more or less crowded. For
ginning very long staples, such as Sea Island,
what is known as a roller gin is used. This is
done to prevent cutting the fiber, which may
occur with the saw gin.

Before shipment to distant markets, the
bale is compressed to one half its size. The
round bale is compressed at the gin. The
square bales are covered with what is known as
bagging, which is made of jute in most cases
and is usually a very poor covering. The
bale is bound by six steel ties. The average
American cotton bale presents a very ragged
appearance. Some sections are using bet-
ter coverings for their cotton bales, and especi-
ally is this true where the round bale press is
used. The round bale is a much neater
package, and is completely protected from
damage by handling, dirt, or weather. The
farmer should demand a better wrapping for

126 KNAPP METHOD OF GROWING COTTON

his cotton, requiring the ginner to completely
cover the bale. The round bale is perhaps the
most satisfactory way of putting up cotton.
This method has never been popular for various
reasons: mainly from the fact that there is so
much money invested in the old style press.
and compress that it is difficult for the round
bale companies to compete with the old con-
cerns. ‘Thousands of dollars can be saved
for the cotton states by a better method of
packing, wrapping, and handling the crop.

Much loss is sustained by allowing the bales
to be exposed to the weather after ginning.
The cotton bale, when exposed to the weather,
absorbs moisture, and the outer edges of the
bales will become discolored and the grade
injured ‘The poor covering now used on the
American cotton bale is usually torn off by
rough handling before reaching the mills.
This allows the outside of the bale to become
dirty, thus lowering the grade of the outer
portion of the bale.

Marketing. —'The common practice on the
small farm is to haul the cotton bales directly
to the warehouse or small town market and sell
to the local merchant. This system, perhaps,

HARVESTING AND MARKETING COTTON 127

has some advantages, but there is much room
for improvement. There should be some uni-
form system of grading and storing cotton in
warehouses until a sufficient amount is collected
to justify the large buyer to classify and bid on
the entire lot. The average farmer and local
merchant know but little about grading cotton,
consequently, nearly all the cotton in smaller
markets is sold at about the same price, re-
gardless of staple or grade.

The following table shows the official classi-
fication of cotton grades established by the
Bureau of Plant Industry, U. S. Department
of Agriculture, with the approximate difference
in value per pound between grades:

Middling fain (3220/2. 1c above middling
Strict good middling . . gene >
Good middling —.-—.—_.—: Fo AN of tan 5
Strict middling arabes tod ead "
Middling oN ENG Se ae Basis

Strict low middling . . tc below middling
Low middling . . . . 4 tose. \* es
Strict good ordinary . . tere: \.3* &
Good ordinary’. . . . Ig totic “ i

Mr. D. E. Earle, expert in cotton grading,
U. S. Department of Agriculture, in an address

128 KNAPP METHOD OF GROWING COTTON

before the South Carolina Farmers’ Institute,
spoke as follows about the work of cotton
standardization of the department:

“The official cotton grades have met with
the approval of most of the Southern cotton
exchanges and have been formally adopted at
the following places:

“New Orleans, Memphis, St. Louis, Little
Rock, Natchez, Mobile, Macon, Galveston,
and Charleston.

“The New England, the Texas, and also
the Southern Cotton Buyers’ Association have
agreed to make the official grades the basis
of their operations.

“For any grower who desires the grades and
feels that he cannot afford a complete set,
the Department has afranged to fill orders
for any three grades. Low middling, middling,
and good middling, for instance, usually cover
the bulk of the crop and for white cotton these
three boxes would indicate the grade fairly
close.

“The price of the nine official cotton grades
has been reduced from $30 to $25, and the
price of the fractional sets have been reduced
to $9 that is, $3 per box or grade.”

wire
il MLLER wa Hi}

sd “. my

1. A farmer comparing his cotton with the Government
standard grades in a Farmers’ Union warehouse
2. Round bales showing (in centre) method of opening.
3. Gin-compressed bales on a Mississippi plantation

ready for shipment to Germany

sa[eq uo0}}09 passaidurosai ‘by Spassarduioo-uts ‘€ fuendAsy ‘2 fxoq-urny ‘1

HARVESTING AND MARKETING COTTON 129

If some working system of warehouses could
be organized and maintained on a business
basis, it would perhaps be the most economi-
cal way of handling the cotton crop. Mana-
gers of these houses could collect and classify
cotton and sell direct to the large buyer. This
would enable the manufacturer to pay more
on an average for cotton, since he is thus assured
of getting large quantities of a product uniform
in grade.

The custom of holding cotton for a_bet-
ter price, in the meantime leaving it out
of doors and unprotected, is not profit-
able. The actual damage to the cotton is
often greater than any increase in price that
may be obtained.

The old custom of marketing the cotton crop
through the commission merchants has almost
been discontinued. This method always placed
the farmer at the mercy of the buyer, and by
the time commission, storage, insurance, and
other fixed charges were deducted, less was
realized for the cotton than if it had been sold
in the local market.

In some places the farmers market their
cotton by selling in the seed to the public ginner,

130 KNAPP METHOD OF GROWING COTTON

instead of having the crop ginned at so much
cash per bale. The usual cash price for ginning
and covering in recent years has ranged from
$2.50 to $3.50 per bale. Selling seed cotton is
a bad practice from the farmer’s standpoint.
It puts the farmer at a disadvantage since the
price is based on a certain grade, and no al-
lowance is made for advance in prices or for
premiums on better grades.

A mutual agreement on some improved
method of marketing the cotton crop would be
beneficial alike to producer and spinner. Such
a system would tend to prevent violent fluctua-
tion in prices. This reform can only be brought
about by a closer understanding between grower
and spinner. The multiplicity of middlemen
has become an immense burden, not only in
the cotton business but in the handling of
all farm crops.

In the past the entire crop has been thrown
upon the market in three or four months, when
it should have been distributed throughout
the year. The high price of cotton in recent
years has bettered the financial condition of
the Southern cotton grower to such an extent
that in the future the crop can be held and

HARVESTING AND MARKETING COTTON I3I

marketed through the year. This should result
in a more equitable adjustment of values
between all parties concerned, and at the
same time eliminate the drain in the form
of fixed charges that exist under the present
system.

Cost of Cotton Production

CHAPTER X
COST OF COTTON PRODUCTION

NE of the hardest problems for the cot-
ton farmer to solve with any degree of
accuracy is cost of production. ‘There

are so many factors to be dealt with which are
beyond man’s control that no real basis for esti-
mating the cost of the year’s operations can be
made. In nearly every other business there are
some known quantities upon which to base cal-
culations. To the farmer nothing is absolutely
sure, especially is this true with the cotton
farmer. Climatic conditions perhaps mean
more to him than to any one. The returns
for his year’s labor must of necessity depend
upon the caprice of the rain, the wind, the
frost or the depredation of numerous insect
pests. Any one or all of these may in a very
short period turn a flattering prospect for a
bountiful crop into almost a complete failure.

We may take the statistics showing total

139

136 KNAPP METHOD OF GROWING COTTON

production of the cotton or the yield per acre
for a series of years and the variations or
fluctuations will be quite noticeable. These
rather wide differences are due largely to
causes over which the farmer has no control.
The same general plan of crop management on
the same land with the same amount of fertil-
izer, teams, and labor may have been used
each year and still the yields vary a great deal.
The total crop production on the same acreage
with practically the same expenses frequently
varies as much as 25 per cent. in two successive
seasons. ‘These extreme fluctuations make a
wide margin between the cost of production and
the selling price necessary for the farmer to
come out with an average profit in the crop.
The elements of uncertainty which enter into
the production of every crop, make it impossible
to estimate the cost.

The business man or the manufacturer can
figure with some degree of certainty as to what
his running expenses will be. He can also
make a pretty close estimate of what the out-
put of his factory or business will reach during
the year. It often happens that the manu-
facturer knows just what he is to receive for his

gin

a cotton

f

section oO

Transverse

spuvjs uid pur ssoid xoq Sutmoys AJOUUIS & WOIJ UOT}IIG

COST OF COTTON PRODUCTION 137

products before they are made. At all events
there is not the degree of uncertainty about it
that the farmer has to meet.

We have mentioned some of the natural
causes or climatic conditions which may cause
wide variations in yields and profits, but
the farmer himself must be taken into account
as one of the greatest factors. One man can
manage his cotton farm so as to make handsome
profit, while another under the same natural
surroundings, but with a less degree of business
ability, agricultural knowledge, or industry,
would produce the crop at a net loss.

To get out of cotton farming under the new
order of things more than a mere existence a
man must use brains and incessant industry
along with his physical labor. The days of
profitable farming along the old trodden paths
are numbered. By this we do not mean that
there is no place for cotton on the small farm,
for, if properly managed, there is a possibility
of greater profits than on the larger farms.
The ordinary methods followed on both the
one-horse and the larger farms must give way
to more up-to-date management. Under a dif-
ferent system two horses can be used profit-

138 KNAPP METHOD OF GROWING COTTON

ably 'where one has been deemed sufficient
before. The plan of crops can be changed so
as to furnish labor for team and help for a
longer period than where cotton alone is grown.
At the same time the better teams and imple-
ments will easily double the yield which
would give as much cotton as before, and allow
half the land for other purposes.

To break the land properly, to do the hauling
and cultivation at least expense, two horses
or mules are necessary on any farm. The
all-cotton system of farming-was never really
successful. under any conditions. Statistics
from any section of the cotton territory, whether
taken for the present or fifty years ago, will
show that the only farmer who had money to
lend and supplies to furnish the entire farm was
the man who did not grow all cotton. The
actual time devoted to making and gathering
the crop on an all-cotton farm is not more than
six months. This leaves hands and teams
practically idle for the other six months. The
expenses for subsistence for both labor and
teams for this idle period must be about the
same that it is for the other six months, but
unless there is some profitable labor furnished

COST OF COTTON PRODUCTION 139

them during this time, this additional expense
must necessarily be taken from the proceeds
of the cotton crop. Such management as
this accounts for the higher cost of cotton pro-
duction. Under a better planned system just as
much cotton can be grown and, besides, all the
foodstuff necessary for the labor and the teams.

Cotton farmers often claim that it is more
economical to grow cotton exclusively and
buy all the supplies for the farm. Practical
experience and close observations and inquiry
into the subject do not confirm the correctness
of their claims. Even at the rather phenom-
enally high price of cotton for the past few years,
the man who actually grew it made little clear
profit unless he also grew his supplies. The
landlord who furnished the land at high rentals
and supplied his tenants at enormous credit
prices, no doubt gets big profit from the all-
cotton method, especially in the good years.
The small farmer and tenant has not nor will
he ever be able to get much more than a poor
living out of cotton farming, when he buys
everything else used on the farm from the
proceeds of the crop. It is difficult for a man
who has been accustomed to figure expenses,

I40 KNAPP METHOD OF GROWING COTTON

incomes, and profits in an ordinary business
to realize why the same methods of accounting
cannot be applied to farm operations. The
elements of risk and uncertainty met on the
farm due to natural causes over which man has
little control, but which so greatly effects
expenses and yields, are lost sight of in making
calculations. Here is where so many who know
nothing of the practical side of farming are
led into trouble. Certain fixed expenses and the
climatic changes are left out of the calculations.

The following is given as an example which
serves to illustrate the differences in good and
poor farming. The first column represents
results from good farming on fair land with
good teams and tools, allowing a yield of
1,500 pounds seed cotton per acre. ‘The second
column is the results from ordinary farming on
average cotton lands with insufficient teams and
tools. Yield per acre 600 pounds of seed cotton:

Good Poor

Choppisiecstallke) 3) SoS Gr ce) Bea gO $ .50

Breaking land 2020414. ears tier eee 1.50

Harrowing . : .50 .50
Opening furrows aaa deensaeine fee

talizer <: é .50 1.00

Bedding and dames for pleniine 75 1.50

COST OF COTTON PRODUCTION 14!

Good Poor
Piagatne |... RED Mi Wines ee By
Chopping and hosting LE SAR IS 1.50
eiuinciniatie it yoke Ve slilic peat’ atthe, 5506 4.50
Fertilizer . . WRENS SEU rr een do Ae 8 3.00
Seed (for plantings Zr Ne MM AN! avi fo 2m
Picking ate NE 3 g.00 3.60
Ginning and baling enter iui aioe can (ally rac IO 1.20
Hauling to gin and to market. . $1.50 $ .60
Rent of land 5.0Cc 3.00

Less value of seed @ $18 perton. . 9.00 3.60

$23.50 $19.80
Sale of lint @ 10 cents nike a) SSOCGO'. ' $20\500
Net profit . Seater see dlileey Lr SOL SO .20
Most per pound: sie) 7) 2) .047 .099

These figures do not allow anything for wear
and tear on teams and implements nor is there
anything accounted for supervision. There are
several other legitimate expenses which must
be made which would add to the total cost.
Unless the labor and teams are profitably
employed during the period when they are not
needed for the cotton crop the cost of subsist-
ence must be added as an additional item.
Some of the items might be reduced by excep-
tional management. For instance, the fertil-

I42 KNAPP METHOD OF GROWING COTTON

izers can be reduced by a saving of farm manures
and rotation of crops. The cost of food and
farm supplies could possibly be reduced, if
grown intelligently on the farm. A fair profit
may be expected under average conditions
where the crop is produced upon a cash basis
and where a reasonable degree of knowledge
is used in producing it.

Equipment in Teams and Tools for Cotton
Farms

CHAPTER XI

EQUIPMENT IN TEAMS AND TOOLS FOR COTTON
FARMS

important part in the economy of pro-

duction of any crop. As liberal an
assortment of labor-saving tools is required in
cotton farming as in any other type of farming.
The principal difference in the equipment for a
large or a small cotton farm, under the old one
crop system, was mainly in the number of tools
rather than in the kind. The cotton farmer
has been slow in bringing to his aid labor-
saving implements in the production of crops.
This has been partly due to the fact that such
a large per cent. of farm labor in the cotton
belt was uneducated and unskilled in the use
of machinery, and partly due to the fact that
one man, under the one crop system of cotton
farming, could, with one horse and with small
one-horse plows or cultivators, produce as

145

] spores par machinery plays an

146 KNAPP METHOD OF GROWING COTTON

much cotton as three or four laborers could
harvest.

On a 160-acre cotton farm, where one third
of the area is devoted to corn and two thirds
to cotton, the ordinary equipment in the past
has consisted mainly of the one-horse, seven-
inch moldboard plow; the small Georgia plow
stock with sweep and shovel attachments;
a one-horse cotton planter; the 14-tooth V-
shaped harrow, and the hoe. The entire
equipment for a 160-acre farm, under the old
system, has been about as follows:

8 mules... . .. |@ $i50.00 =, S1-2a0
87-inch meldenar Blows . @ 7. Cot 56
8 1-horse plow stocks, with sweep

and shovel attachments @ 4:00 = 32
8 V-shaped spiketooth harrows @ £08 == 32
4 I-horse cotton planters . @ 5.00 = 20
24 hoes @ [os 12
I farm wagon @ 60
1 set of double wagon Tigehiens 30
8 sets single plow harness. @ If eee 40
i set of ‘repair ‘tools, ss fe)

Total a egies eT 2) Baan Be $1,492

The cotton farmer is beginning to diversify
his crops and is rapidly discarding light mules
and one-horse implements for heavier teams

pk

Ordinary equipment of implements ona one-horse cotton
farm

Ordinary equipment of implements on a two-horse cotton
farm

wey uo0}j09 & Joy yuaUIdmMba 9}ep-03-dy

EQUIPMENT IN TEAMS AND TOOLS 147

and improved farm machinery. The two,
three, and four horse breaking plows, the sulky
cultivator, disk harrow, section harrow, the
weeder and the mower are fast coming into
use on the cotton farms.

The mule has been the principal work anima
on the cotton farm in the past. In recent
years many progressive farmers have substi-
tuted heavy draft mares in the place of mules
and have found them just as satisfactory as
the mule except for the very rough work.
These mares will do any ordinary farm work
and will raise a valuable colt each year.

The necessary equipment in teams and tools
for a 160-acre cotton farm, where one fourth of
the area is devoted to pasture, one fourth to
cotton, one fourth to corn and one fourth to
small grain and hay, is as follows:

PEI ite Wa yal) a |e)" @S200 ==. $ 400
Reema eal 4! ah) a!) BY, 200, == 800
MePIEWACON ke we 60
memower and rake . ... « . 60
@reombination planters . . . . @ 15 = 30
auizg-inch moldboard plows . .<. @ 12 = 36
I 24-inch disk breaking plow . . 35
I 20-inch 8 disk, disk harrow . . 25
endme sulky cultivators . .. @ 35 = 70

148 KNAPP METHOD OF GROWING COTTON

TP) BeCtOn, Array nw ta ere $25
4 springtooth*cultivatora:..) 5. <F @)\ 5 == 20
2 one-horse, 5-shovel, cultivators . @ 12 = 24
¥ Set of repair tools: £ .°%. <a 25
Pxtraemallitoots.n co. 8b tle May oe 25
[ reaper and binder) i<; < -. 4 150
4) sets) double*harhess. 400.0) 3) -f (@ gots go
i manurexspreader, . 20s). we Ge 125

MICE Fak Wess FR TE Cran ica erates eek UO er eee $2,000

Dr. S. A. Knapp, of the U. S. Department of
Agriculture, estimated that there is a possible
increase of 300 per cent. in the productive power
of the farm laborer in the average Southern
state by the use of more and better teams and
farm machinery.

Dotton By-Products

CHAPTER -XiI

COTTON BY-PRODUCTS

CARCELY more than a quarter of a cen-
tury ago cotton seed, the chief by-product
of the cotton crop, was considered worth-

less except for planting purposes. A common
practice among the ginners and large planters
was to dump the seed into waste places, into
the streams or anywhere to get them out of the
way. Contamination of the water supply in
the streams and the odor given off by the
decomposition of the seed became a nuisance,
and in some places steps were taken by the
health authorities to prescribe the manner
of disposing of them. The planters as well as
the country in general little realized the immense
value of the seed as a fertilizer and stock feed.

History of the O1l Mill. — The first manu-
facture of cotton seed products on a commercial
scale did not begin in the United States but
in England where no cotton is grown. In

I5I

152 KNAPP METHOD OF GROWING COTTON

1870 that country had an annual crush of
about 200,000 tons and was leading the world
in the manufacture of cotton seed products.
All of this supply had to be shipped across the
ocean and there was much loss from the seed
heating and decomposing in transit; so it was
not long before it was found necessary to
move the manufacturing industry nearer to
the field of production.

The increased uses made of the seed prod-
ucts and the difficulty of getting the seed to
the foreign mills in good shape led to the
establishment of a great milling industry in the
United States. The annual consumption by
American oil mills is now more than 4,000,000
tons. The first cotton seed oil mills were built
in the United States in 1840. As late as 1860
there were only seven. In 1gr1o this number
had been increased-to 841. The number of
laborers employed in oil mills increased from
12,600 in 1899 to more than 22,000 in IgI0.
The total value of the seed delivered at the
mills in 1910 was about $142,710,000, an increase
of more than $100,000,000 over 1899. In 1910
the average cost per ton of seed was $27.40,
more than 2} times that of 1899. The total

COTTON BY-PRODUCTS 153

value of the products manufactured from the
seed in I910 amounted to $152,710,000 as
compared with $46,100,000 in 1899. This
large rise in value was brought about by the
increased consumption of mill products, and
is shared by every state which grows cotton.
The value of the products manufactured from
a ton of seed in 1899 was $17.75 and that
of I910 was $32.50. The total value of oil
mill products in 1910 was as follows: oil,
$80,430,000; meal and cake, $44,660,000; hull,
$11,370,000; and linters, $6,250,000.

There has been considerable fluctuation
in the price of seed from the beginning. This
is due largely to the fluctuations in the price
of the articles with which the products come in
competition. For instance, the price of oil is
effected quickly by fluctuations in the prices
of such articles as hog lard, soap, and olive
oil; the price of meal, cake, and hulls is governed
largely by the fluctuations in the price of
fertilizer and foodstuff materials with which
they come in competition. The price of
linters, another by-product of the seed, is
governed by the same conditions.

Products of a Ton of Seed, —'There are al-

I54 KNAPP METHOD OF GROWING COTTON

together over fifty useful products made from
cotton seed. The following gives the average
quantity of the chief products from a ton of
seed, with a list of articles made from each:

Batting, stuffing, hats,

eanaters 30 pounds ropes, twines, carpets,
cellulose, paper, and

explosives
Beat talts 840 pounds Feed, fertilizer, paper

and stuffing
3. Cake or meal 730 pounds’ Feed, _ fertilizer

Soap stock, lard, cotto-
lene, butter, salad oil,
olive oil, miners’ oil, lu-
bricating oil and paints

Uses of Cotton Seed Oil. — There was for a
long time considerable prejudice against the
use of cotton seed oils in food products. This
has now been largely overcome, and we find
them used extensively in the manufacture of
compound lard and cottolene; compound butter
and cooking oils; in the manufacture of com-
pound olive oil; and,in fact,nearly all compound
oils now used in this country are composed
largely of cotton seed oil. The cheaper grades
areused largely in making soap, washing powder,
glycerine, candles, and other necessaries which

4. Oil (crude) 280 pounds

COTTON BY-PRODUCTS 155

require a low grade of oil. Some of tlie oil
is also used for medicinal purposes, illuminating,
lubricating, packing fish, and to some extent
for the manufacture of oils for paint.

Uses of Meal and Cake.— The chief use
of cake and meal are for fertilizers and stock
feed. The following table shows the value of
high-grade seed meal as a fertilizer:

FERTILIZING VALUE OF A TON OF SEED

128 lbs. nitrogen @ 20 cents . . . . . $25.60
54 lbs. phosphoric acid @ § cents ce aie 2.70
36 lbs. potash @ 5 cents SYA E RE 2 eee 1.80

Satalewanetin Gaels oa kha a Mey; om 9 £30+50

In 1910 South Carolina used 140,000 tons
of cotton seed meal for fertilizer; Georgia
g1,000 tons, North Carolina 70,000 tons and
Mississippi 56,000; and other states in smaller
quantities. The feed value of cotton seed meal
and cake for fattening stock and furnishing a
concentrated ration to dairy cows is more
than for fertilizer.

The United States Secretary of Agriculture,
Hon. James Wilson, was asked a few years ago
if he thought that the Southern farm lands
could be made to produce as much as the rich,

i156 KNAPP METHOD OF GROWING COTTON

high-priced lands of the Central West, He
said: ‘“‘Why, of course. What is the hindrance?
But the Southern farmer must quit sending his
cotton seed meal over the world to enrich other
lands. He must use the rich fertilizer himself.”
It is deplorable that the Southern farmer has
allowed the larger part of this valuable fertil-
izing and feed product to be shipped from its
native territory to other sections of the United
States andto Europe. The full feed value may
be derived from cotton seed products and at
the same time, if the manures from the stock
are returned to the soil, from 70 to 90 per cent.
of the fertilizing value may be retained on the
farm. 'The combined feed and fertilizing value
of a ton of high-grade cotton seed meal when
fed to animals and the manure carefully saved
and returned to the land is about $50; when
used alone as feed or a fertilizer its value is
about $30. The farmer sustains a tremendous
loss when he fails to get both the feed and fer-
tilizing value from cotton seed meal. When
the Southern farmer appreciates the import-
ance of feeding the meal and returning the
manure to the land, the South will become one of
the greatest stock-raising countries in the world.

COTTON BY-PRODUCTS 157

Southern farmers should keep enough stock
to consume all the cotton seed meal on the
farm, but it will be years before they can
accumulate enough stock to do this. At
present some meal is fed to dairy cows and
animals in the nearby towns, but compara-
tively little of it goes back to the farm except
what is used directly in the form of fertilizer.
Cotton seed meal is one of the most satis-
factory forms of nitrogen that can be used
in making mixed fertilizers for the common farm
crops. It is not only rich in nitrogen but
contains considerable quantities of phosphoric
acid and potash. The fertilizing elements
in cotton seed meal are slowly available, a
quality which makes it desirable for such crops
as have a long growing period. Unless the
cotton farmer has enough stock to consume his
meal, it will pay better to use it as a fertilizer
than to send it away to enrich other sections.

Hulls. — Hulls are used for feed, paper,
fertilizers and packing, but of recent years
almost the entire supply has been utilized
as a stock feed at prices ranging from $3 to
$10 per ton. In addition to the outside cover-
ing of the cotton seed, the hulls contain small

158 KNAPP METHOD OF GROWING COTTON

portions of kernels or hearts which add to
their feeding value. Their feeding value is
about that of cheap grass hay or half that of
good grass hay.

Linters. — The linters or the short fiber
that is taken from the seed in the first process
of manufacture is used in making low grades
of rope, twine, wrappings, and various other
articles requiring a cheap grade of cotton.

Other than a few minor improvements there
has been no changes in oil mill machinery
for the past twenty-five years. The linters
are removed more closely, and several gallons
more oil per ton are obtained than formerly.

Soil Improvement on Cotton Farms

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CHAPTER XIII
SOIL IMPROVEMENT ON COTTON FARMS

AUSES of Depleted Soils on Cotton
Farms.— Good farm lands are now, and
have always been, the greatest asset of

any state or nation. ‘The rapidly increasing
population and the higher standard of civiliza-
tion now spreading over all countries will make
this problem of good lands a more important
one in the future.

Any system of farming that reduces the
fertility of the soil or decreases its crop-pro-
ducing capacity is not only unnecessary but
results in ultimate failure. Extensive investi-
gation and experiments under varied condi-
tions have fully demonstrated that lands
farmed properly can be improved and their
producing capacity greatly increased. There
is no valid excuse for wornout farm lands,
and where they are found it is the fault of
the man or his system and not of the land.

161

162 KNAPP METHOD OF GROWING COTTON

The problem of soil fertility and how to
maintain it has been a very vital one to all
nations. The earliest agricultural literature
mentions the use of manures and other refuse
to make the soil more productive. In all
the old countries the question of keeping up
the soil fertility has been successfully met.
This is evidenced by their being able to feed
from the same lands the constantly increasing
population. There are lands in some of the
European countries that are producing, after
more than one thousand years of cultivation,
larger crops than ever before. The density of
the population and the lack of room for expan-
sion make it necessary to conserve all the re-
sources, and especially that of the soil.

In America there has been a very different
situation. With a sparse rural population and
a seemingly unlimited expanse of fertile virgin
soil, the question of caring for or conserving
the soil was lost sight of for a long time. It
was not until recently that the constantly
decreasing yield per acre of our soils was
seriously considered. While the abuse of farm
lands, idle fields, and tenantless homes are
noticeable all over the country, these are

SOIL IMPROVEMENT 163

even more marked in the cotton states. In
no country or in any age has there been such a
system of soil robbing as that practised on the
Southern farm. The washed and barren hill-
sides are the first things to attract the atten-
tion of all travellers both foreign and native.
Natural causes are, of course, partly responsible
for these conditions. The mild, open winters,
accompanied by frequent heavy rainfalls, with
the naturally sandy loose soil, make washing
easy. lhe prncipali causes are, however,
shallow breaking and the system of clean cul-
ture practised in cotton farming. With little
humus in the soil to absorb the water and hold
the particles together, erosion is the natural
result. Farther north, where the soil is stiffer
and the rainfall lighter, and with a more
diversified system of cropping, soils do not
wash so badly. Here also the surface soils
are frozen for several months which makes
washing impossible for a large part of the year.

In the early days of commercial cotton grow-
ing, when fertile lands were abundant and
cheap and with slave labor to produce the
crop it was considered more profitable to
clear new fields when the old ones became

164 KNAPP METHOD OF GROWING COTTON

exhausted than to preserve the fertility of
the soil. The logical result of such a system was
the wearing out of the most desirable lands.

Any system of cropping which does not
return to the land the larger part of all that is
grown on it, either in the shape of manure from
live stock or by turning under the green crops,
will soon result in unproductive soils. In
some places, cotton has been grown on the
same land for generations. This soil was
evidently very fertile in the beginning or it
would be so exhausted by now that it would not
produce profitable crops. ,

Dr. B. T. Galloway, Chief of the Bureau
of Plant Industry, once said, after visiting
the Cotton States, that ‘‘When the Southern
farmer learned to diversify and feed his soil
by returning to it what it produced, a system
of land robbing would give way to a system of
land building.”

If only the lint were sold from the cotton farm,
less fertility would be removed by it than any
other crop known. By returning the seeds or
their equivalent in manure or fertilizer, with
all the other parts of the plant, there should be
little soil deterioration from cotton farming.

SOIL IMPROVEMENT 165
Five hundred pounds of lint cotton removes
less than two pounds of nitrogen, about one
half pound of phosphoric acid, and two and
one half pounds of potash. The seed from a
bale of cotton, approximately half a ton, con-
tains thirty-one pounds of nitrogen, thirteen
pounds of phosphoric acid, and twelve pounds
of potash. At prevailing prices the seed from
‘each bale of cotton grown removes more than
$7 worth of plant food from the soil. When the
farmer sells his seed without returning their
equivalent in some other form of fertilizer
he robs his land. It has been claimed by many
of the best farmers, and with good reason, that
the rapid deterioration of soils in the cotton
States began with the construction of the oil
mill. Before the day of the oil mill cotton
seed were either fed to stock or used as fertil-
izer. Since the introduction of the oil mill
nearly all the seed are sold. The prices re-
ceived are frequently below the actual fertil-
izing value, and the money received is seldom
spent for plant food to be returned to the soil.
Before the oil mills came, the cotton seed were
used as fertilizer for corn and it was a rare
thing to know of a good farmer who bought

166 KNAPP METHOD OF GROWING COTTON

corn to run his farm. The high prices paid
for seed in recent years have, to a large extent,
robbed the farms of this important fertilizer,
and much of the money received for the cotton
crop has gone to buy corn and other foodstuff.

Analyses show that a ton of meal contains
about as much plant food as two tons of raw
seed; but the feeding value of a ton of cotton
seed is equal to 1,400 pounds of meal. These
facts should be considered when selling seed
or exchanging them for meal.

Methods of Restoring Soil Fertility. — Under
the system of all cotton farming the lands have
greatly deteriorated. The following methods
are suggested for restoring and maintaining soil
fertility on cotton farms:

1. Terrace hill lands to prevent washing, and
drain swamp lands.

2. Grow leguminous crops and winter cover
crops to fill the soil with humus and
check erosion.

3. Adopt a systematic rotation of crops.

4. Keep live stock to consume all grain and
forage crops and return the manure to

the land.

SOIL IMPROVEMENT 167

Drainage. — The first problem in soil build-
ing on cotton farms is to check erosion on the
hill land and drain the swamp land. On
hill lands broad bed terraces are recommended.
On bottom and wet lands, tile drainage, or
some other effective method of ridding the
soil of surplus water should be adopted. Be-
fore any ditching, terracing or tiling is done,
all gullies and rough places should be filled
up and the land put in fair condition. This
will make the work much easier and more
effective.

Before permanent terraces are built, grow
one or two heavy crops of peas, or some other
green crop which can be _ plowed un-
der to add humus to the soil. This will
help to; fake care: ior jpart of: the surplus
water.

Broad embankment terraces of a width of
fifteen feet, with a gradual fall of from four to
six) inches | per one.) hundred. feet, will
carry the surplus water away gradually,
allowing much of it to be taken up by
the soil. These wide terraces will permit
the growing of crops on all the land.
When cultivated crops are planted, lay

168 KNAPP METHOD OF GROWING COTTON

off the rows parallel with the terrace, run-
ning the first rows on top of the terrace and
allowing short rows to come in the centre
or on one side. The terrace bank should
be made high enough in the beginning to
avoid any possibility of overflowing or breaking
while it is new and unsettled. The distance
between the terraces can be determined by the
lay of the land. Shorter distances will be
necessary on steep lands and much wider space
can be left on moderately rolling lands. The
general rule is to allow a three-foot perpen-
dicular fall between terraces. Before start-
ing terraces see that there is a good outlet for
the water.

The laying out of terraces is a very simple
matter, and can be done by almost any farmer
with a little preliminary instruction. The
implements used need not be expensive. A
farm level can be bought for $12 or $15, or
one that will answer the purpose can be
made for $2 by buying a carpenter’s level and
attaching it to a frame made of light wood.
More physical labor will be required to operate
the home-made level, but good work can be
done with it,

SOIL IMPROVEMENT 169

On bottom lands and some rolling hill lands,
tile drainage is the best method for taking care
of the water. ‘This eliminates all ditch banks
and other obstructions.

Green Manure Crops. — The next impor-
tant step in soil building is to get more
humus or vegetable matter incorporated in
the soil. Undoubtedly the quickest and most
effective way of doing this is by means of
growing leguminous crops. If quick re-
sults are desired, the whole of the crop
should be turned under. ‘This, perhaps,
would be advisable for the first year, under
any circumstances. The best crops for this
purpose are cowpeas, soy beans, velvet
beans, and, on land where they will grow,
some of the clovers. The cowpeas will grow
on almost any land in the Cotton Belt. The
velvet bean can be grown anywhere in the
Gulf States. The soy bean will be more
beneficial perhaps in some places on ac-
count of the diseases that affect. the pea.
Lespedeza, bur clover, and crimson clover
can be grown on nearly all soils in the
South. An application of lime will be
helpful to the clovers on nearly all soils,

170 KNAPP METHOD OF GROWING COTTON

By growing legume crops in the summer,
turning them under in the fall, and follow-
ing with a crop of oats, rye, crimson or
bur clover as a winter cover crop, the
land will be fully protected throughout
the year, and if all these crops are turned
under the original fertility will be rapidly
restored. After one or two years of this
treatment the land may be turned over to
the regular crops of cotton and corn. Of
course, this is not specially applicable to
soils that are already in fairly good condi-
tion.

Crop Rotations. — Rotation of crops is the
safest and surest way of maintaining soil
fertility. On every farm a systematic crop
rotation should be adopted. This rotation
will have to be planned to suit the condi-
tions and the location of the farm. What
would be good for one farm might not
be the best for another, even in the same
neighborhood. A few suggestive rotations
are given, so that the farmer may have an
idea of what is meant by systematic crop
rotation.

Following are suggested outlines of two,

SOIL IMPROVEMENT I7I

three, and four year rotations for cotton farms.
The legume crops to be used with these rota-
tions will vary in different sections and on
different soils:

TWO-YEAR ROTATION

FIELD NO. I FIELD NO. 2
(1st year) (1st year)
Corn and cowpeas. Bur | Cotton. Bur clover as win-
clover as winter cover ter cover crop
crop
(2d year) (2d year)

Cotton. Bur clover as | Corn and cowpeas. Bur
winter cover crop clover as winter cover crop

Bur clover can be seeded on the cotton land
from August 15th to October 15th, depending
on the latitude. Seed should be sown in
the bur. The clover will mature seed in the
spring in time to prepare the land for corn.
It will not be necessary to reseed this land
the following fall. The land for cotton will
have to be broken in the spring before the bur
clover seeds, but there will usually be enough
seed remaining in the soil from the past
year to get a good stand of clover after the
cotton.

172 KNAPP METHOD OF GROWING COTTON

Crimson clover is the best of all cover crops
where the soil has been inoculated. If crimson
has not been grown on the farm before, only a
small area should be planted at first, and it
should be inoculated by securing soil from a

THREE-YEAR ROTATION

FIELD NO. I FIELD NO. 2 FIELD NO. 3
(1st year) (1st year) (1st year)
Cotton. Rye or crim- Corn and peas Oats and peas
son clover as winter
cover crop
(2d year) (2d year) (2d year)
Corn and peas Oats and peas Cotton. Rye or crim-
son clover as winter
| cover crop
(3d year) (3d year) (3d year)
Oats and peas Cotton. Rye or Corn and peas

crimson clover as
winter cover crop

crimson clover field and scattering it over the
land, at the rate of from 300 to 500 pounds per
acre at the time of seeding. If soil cannot
be secured from a crimson clover field, fairly
satisfactory inoculation may be obtained from
the nitro-culture bacteria which are prepared
by the U. S. Dept. of Agriculture, and also by
some of the leading seed houses. Unless the
soil has been inoculated, it will be best to plant
the cotton lands to rye for a winter cover crop.

SOIL IMPROVEMENT 173

Lespedeza will make an excellent hay crop
on good land in nearly all parts of the South.

FOUR-YEAR ROTATION

FIELD NO. I FIELD NO. 2 FIELD NO. 3 FIELD NO. 4
(1st year) (1st year) (1st year) (1st year)
Cotton. Rye or | Corn and peas | Oats and les- Lespedeza
crimson clover pedeza
as winter cover
crop
(2d year) (2d year) (2d year) (2d year)
Corn and peas | Oats and les- Lespedeza Cotton. Ryeor
pedeza crimson clo-
ver as winter
cover crop
(3d year) (3d year) (3d year) (3d year)
Oats and lespe- Lespedeza Cotton. Rye or} Corn and peas
deza crimson clo-
ver as winter
cover crop
(4th year) (4th year) (4th year) (4th year)
Lespedeza Cotton. Rye or} Corn and peas | Oats and _les-
crimson clo- pedeza
ver as cover

crop

Lespedeza does not make sufficient growth on
poor land to justify planting it as a hay crop.
It should be sown the last of February or the
first of March on the oat land. Run over the
land after sowing seed with a dragtooth har-
row, the teeth slanted backward at an angle
of 45 degrees. One cutting of hay can be se-

174. KNAPP METHOD OF GROWING COTTON

cured and the lespedeza will reseed itself, and
one cutting can be secured the following year.
Lespedeza is a most excellent plant for im-
proving the soil. In sections where it cannot
be grown other crops can be substituted in
the rotation.

The above outlines of crop rotations are
offered only as suggestions. Each farmer can,
with a little study, plan a system best suited
to his conditions.

Farm Manures.— The last but by no means
the least important factor to be considered
in building up the land and maintaining fertil-
ity is that of farm manures. The practical
and experimental results in the best farming
countries have proven that soil fertility can-
not be most economically maintained without
the use of live stock. The keeping of sufficient
live stock will allow the farmer to get two
values for the heavier rough food products
grown. He may first get the full feed value
through the animal, and second the manure
which can be returned to the land. The neglect
in preserving and increasing the supply of
farm manures has been a great drain on the
American farm, especially in cotton-growing

SOIL IMPROVEMENT 175

sections. The chief difference between barn-
yard manure and other vegetable matter is
that in the process of passing through the an-
imal the fertilizing elements are made more
available for absorption in plant growth.

From 75 to 90 per cent. of the fertilizing value
of the crop is left after it passes through the
animal. Through neglect in caring for manures
about the farm much of their fertility is lost.
The Cornell University Experiment Station
found that as much as 50 per cent. of the
plant food constituents in manure was lost
by leaching and unnecessary fermentation.
The best plan for utilizing manures, where it
can be done, is to haul and spread on the land
regularly as it accumulates. Where there is
no land available, and it is not practicable
to do this at all seasons, some suitable shed or
house should be provided that will thoroughly
protect it from rain or exposure. One of the
best plans for accumulating manures in stables
or barns is to let it remain and be trampled by
the stock. Always supply plenty of bedding
to absorb all the liquids. This treatment will
not only take up the moisture but the continued
trampling of the animal will exclude all air,

176 KNAPP METHOD OF GROWING COTTON

so that the accumulation may go on without
injury to its quality until a convenient time to
remove and spread it on the land.

One can readily see that a large quantity
of valuable fertilizer could be accumulated
during the year with a limited number of
animals when taken into consideration that
each grown horse produces about 12,000 pounds
and each cow about 20,000 pounds per year.
When the straw and other litter is added to this
the amount is largely increased. The actual
plant food contained in one ton of barnyard
manure is worth at least $2.50, and it is safe to
say that the farmer will derive nearly $4 worth
of good from it. It not only furnishes $2.50
worth of plant food but greatly improves the
mechanical condition of the soil and multiplies
beneficial bacteria.

Some farmers prefer composting their ma-
nures, but this, except in rare instances, is an
additional expense without adding very much
to the actual value of the manure. For special
farming the compost heap has been found bene-
ficial and may be made somewhat as follows:

Locate the compost heap in an old shed; or
build a shed, with any kind of cheap material

1. Crimson clover in central Alabama, sown October first,
in cotton middles after first picking of cotton. Clover
in full bloom April fifteenth

2. Corn and velvet beans. The velvet bean is a great
forage and soil improving crop on the cotton farms of the
Gulf Coast country

A yield of two and one half bales per acre by the use of good seed and: modern methods

of culture

SOIL IMPROVEMENT 177

for a roof. Spread on the ground a layer
of stable manure 8 by Io feet, six inches deep.
Over this spread one hundred pounds of acid
phosphate or ground phosphate rock. The
ground phosphate rock answers about as well
as the acid phosphate and costs about half as
much. Continue these layers until all the
manure is used up or until the pile has become
conveniently high. To these layers might be
added straw, leaves, mold, or other litter, add-
ing one hundred pounds of ground phosphate
rock to each ton of material used. Be sure to
wet all thoroughly. When the heap is com-
pleted cover it about four inches deep with
good loam, or with forest mold, to prevent
evaporation of the ammonia and other ele-
ments. ‘This should remain in the heap for
several weeks, thoroughly mixing when cutting
down, and before hauling to the field for ap-
plication.

The judicious use of commercial fertilizers
in combination with barnyard manure and
green crops will aid in soil building, and will
be found profitable in the increased production
of crops.

With the best methods of conserving the

178 KNAPP METHOD OF GROWING COTTON

soil, and the best methods of tillage, the yield
of all crops on the average cotton farm could
be more than doubled. The average small
yield of the cotton farm compared with what
it might be is a heavy tax to pay for ignorance
and careless management. How long shall
we continue such methods? This is a question
that must be answered, not only for our own
good, but for posterity.

Outlook for the Cotton Industry

CHAPTER) XIV
OUTLOOK FOR THE COTTON INDUSTRY

OME apprehension has been expressed con-
cerning the future of the cotton industry
in the United States. The high prices of

recent years and the demoralizing and de-
structive effects on the crop in some sections
by the boll weevil, have created uneasiness
in the minds of the spinners. It is only natural
that the spinner should desire a sufficient supply
of cotton at moderate prices. Several European
countries have spent large sums of money in
efforts to grow cotton in their colonial pos-
sessions that they might become independent
of the American crop. They employed high
salaried experts and expended millions of
dollars; but so far have been unable to produce
cotton of the desired standard and in competi-
tion with the American crop.

The Southern States have had a monopoly
of cotton production, and it is probable that

181

182 KNAPP METHOD OF GROWING COTTON

they will continue to enjoy this distinction.
The Mexican cotton boll weevil threatened
the industry but, after two decades of experi-
ence with this most destructive of all cotton
pests, it has been demonstrated that cotton
can still be grown profitably in the presence
of the! weevil. In fact; the crop has con=
stantly increased during the past five years with
more than half the cotton-producing territory
infested. While there is little doubt that this
troublesome pest will invade every field where
cotton is grown, it is believed that it will
become less destructive in the northern part
of the Cotton Belt. It is also probable that
natural enemies of the weevil and better cul-
tural methods will reduce the damage in
sections already infested. It is doubtful, how-
ever, whether any territory once infested will
ever be entirely rid of the weevil, though the
danger of serious damage may be reduced
except in years of unfavorable climatic con-
ditions.

There is little reason to believe that the
United States will lose its supremacy in the
production of cotton with their rich lands, not
only adapted to cotton but to the greatest

OUTLOOK FOR THE COTTON INDUSTRY 183

variety of useful farm crops; their magnificent
forests of timber for building purposes; the
great deposits of oil, coal, iron, phosphates,
lime, and other minerals; with almost unlimited
water power; and with a mild and healthful
climate; but instead, every reason to believe
there will be expansion and growth.

Mr. Edward Atkinson, a large American
spinner, after trying cotton imported from
various foreign countries, stated that none
of them were satisfactory and that no other
country has a climate so peculiarly adapted
to the growing of cotton as ours. He finally
concluded that the South would perhaps
have the monopoly for a long time. In his
opinion only one section, which is situated in
South America, could ever compete with the
United States in growing the best grades of
upland cotton.

The English Government recently appointed
a commission to investigate the possibilities
of cotton production in Africa, and they
reported in part as follows:

“All efforts to- raise cotton successfully
elsewhere than in the southern part of the

184 KNAPP METHOD OF GROWING COTTON

United States have failed. This is the home
of the cotton plant, and if it will grow and fruit
elsewhere to the extent that the staple will
have a substantial commercial value, the
fact is yet to be demonstrated. It was ex-
perimented with under different suns during
and after the American Civil War and all the
experiments failed. Providence has given the
Southern farmer the monopoly of the indis-
pensable cotton crop and he need not take
fright when the price soars and there are heard
threats of turning Africa, Egypt, and other
countries into cotton fields, and making them
furnish the world’s supply.”

The rapidity with which the industry has
grown in this country can be realized when we
note that the total crop of the South thirty
years ago was only four million bales; twenty
years ago it was six million bales; ten years
ago it was eight million bales, and the past
three crops. have averaged nearly fourteen
million bales. Notwithstanding these three
extraordinary crops, the average price per
pound paid for them has been greater than at
any time in thirty years. A world-wide move-

OUTLOOK FOR THE COTTON INDUSTRY 185

ment toward a higher civilization and higher
standards of living has largely increased the
demand for cotton. It has been estimated that
of the more than fifteen hundred million people
on the earth, only one third are well clothed,
one half are partly clothed, and the remainder
go without clothing. Something like forty-two
million bales would be necessary to clothe all
of the people of the world as we are clothed.
This fact indicates the immense room for
expansion in cotton production. It is believed
that the South can increase the cotton crop
as rapidly as the world’s demand grows. When
we consider that in the cotton states but one
acre in seventeen is devoted to cotton, and
only one acre in eleven in the cotton counties,
there seems to be good reason for this belief.
The average yield per acre is now less than two
hundred pounds of lint cotton; but some of
the best farmers average from their entire farms
from five hundred to eight hundred pounds per
acre. This would indicate the possibility of
immensely increasing the crop, even were
there no increase in acreage.

The low yields in the South may be largely
ascribed to the use of poor seed, run down,

186 KNAPP METHOD OF GROWING COTTON

depleted soils, and inefficient and inadequate
teams and tools. The use of good seed alone
has been known to increase the crop from 30
to 50 per cent., and it is conservative to assume
that with the adoption of the latest methods
in scientific farming the yields on the lands
already devoted to cotton would be doubled.

The acute problem confronting the Southern
farmer to-day is the necessity of caring for
his lands. This can be done by keeping
live stock and rotating crops, and at the same
time producing as much cotton as formerly
on only half the acreage. Under such a sys-
tem all of the supplies will be grown at home,
and the cotton will be a surplus cash crop.
The outlook is very hopeful to the close observer.

Mr. Arthur W. Page, editor of the World’s
Work, in an article analyzing present condi-
tions in the Southern States, said: ‘“‘We are
in sight of the time when the cotton grower
in the old slave states will become the most
prosperous tiller on the earth.”

The late Alfred B. Shepperson, author of
“Cotton Facts,” in an address entitled, ‘The
Sources of Cotton Supply,” before the New
York University a few years ago, went into

OUTLOOK FOR THE COTTON INDUSTRY 187

details as to the future outlook and used the
following in his closing paragraphs:

“‘T am as thoroughly convinced of the utter
futility of the attempts being made to grow
cotton in the new fields of production as I am
of the capacity of our Southern States to
readily meet the increasing requirements of
the spinners of Europe and America. Our
European friends would do well to possess
their souls in patience, and stop squandering
their money in visionary schemes. Blessed
with temperature, rainfall, better adapted to
the successful culture of cotton than any other
country, and with an abundance of land to
meet every possible requirement for expansion
of acreage, the United States will undoubtedly
maintain in the future its present supremacy
in the cotton production of the world.”

The Supply and Distribution of Cotton

CHAPTER XV

THE SUPPLY AND DISTRIBUTION OF COTTON

HE total supply of cotton in the United

States at the end of 1911 was 17,896,226

bales. This represents cotton held over

froma previous crop, and 229,268 bales imported

from various other countries. This is the largest
supply this country has ever accumulated.

The following table shows the production

and distribution of the cotton crop of the

United States from 1855 to I1g9II:

TasBLe VII.— Tora crop, EXPORT, AND DOMESTIC CON-
SUMPTION OF UNITED STATES COTTON CROP FOR SPECIAL
YEARS

TAK T.
YEAR Roage psa a he TOTAL EXPORT RORTEEEN novaaieen
MILLS MILLS
MOSS hee 3,665,557 2,702,863 633,000 138,000
TSO roe 3,849,469 615,032 - 650,000 193,000
ESOS een cece 2,269,216 1,301,146 541,000 127,000
RS 7 Oscar cic 4,024,527 2,922,257 1,072,000 91,000
TS 7.5 a seraets 4,302,818 3,037,650 1,220,000 134,000
MEISE nonce 6,356,998 4,451,495 1,713,000 225,000

MBSE sien elas 6,369,341 4,200,651 1,781,000 381,000
MS8OQONes 2 oes 8,562,089 5,580,319 2,027,000 613,000

IQI

I92 KNAPP METHOD OF GROWING COTTON

TOTAL COMMERCIAL

TOTAL EXPORT

TAKING

NORTHERN

YEAR CROP
Suge tenes 7,146,779
TQOO: esas) 10,266,527
TOOS sca, sie vals 10,804,556
LQOGs separate 13,595,498
TQO7a es pivlsie 11,375,461
LOOB 6c ada 13,587,306
TOOOs sales cis 10,315,382
TOLOS eae 12,005,688
TOUIse sce 16,250,276

4,761,505
6,806,572
6,975,494
8,825,236
7,779,508
8,889,724
6,491,843
8,008,195
10,681,332

1,605,000
1,904,000
2,335,000
2,510,000
1,885,000
2,688,000
2,012,000
1,994,000
2,619,000

2,292,000
2,495,000
2,079,000
2,555,000
2,244,000
2,307,000
2,772,000

Tas_e VIII.— Corron ACREAGE HARVESTED, PRODUCTION
AND YIELD LINT PER ACRE AND PRICE IN THE UNITED
STATES, FOR SELECTED YEARS, 1879-IQII

TOTAL ACREAGE

TOTAL CROP
BALES

YIELD LINT
PER ACRE

| eS | | |

36,045,000
32,403,000
32,044,000
32,444,000
31,311,000
31,374,000
26,117,153
30,053,739
28,016,893
27,114,103
27,220,414
25,758,139
24,275,101
24,967,295
24,319,584
23,273,209
20,184,808
123,687,950
9,525,000
20,175,270
17,439,612
14,480,019

16,109,349
11,965,962
10,386,209
13,432,131
11,325,882
13,305,265
10,725,602
13,697,310
10,015,721
10,784,473
9,748,546
10,245,602
9,507,786
11,189,205
10,897,857
8,532,705
7,161,094
9,901,251
7,493,000
7,472,511
5,682,000
557555359

~
°

-_ -_ ~
C0 ONU ONIN EPNO DOOnWK OOD
ARMNOKRKDODXHHHIUDCOHRANY

8
fe)

SUPPLY AND DISTRIBUTION 193

World’s Production of Cotton (U.S.Census).—
Cotton can be grown over a wide area of the
earth’s surface, but its profitable production
is limited to certain well-defined sections. For
some countries satisfactory data regarding
the production of cotton are not available.
The following table, showing production by
countries, from 1907 to I9II inclusive, is
believed to approximate the facts.

TaBLeE IX.— PRODUCTION OF COTTON FOR MILL CONSUMP-
TION, BY COUNTRIES, 1907 TO IQII

COTTON PRODUCTION (BALES OF 500 POUNDS NET)
COUNTRY

a fe | |
——————

Total
[Ore Pie 9,863,C00 | 13,002,c00 | 10,882,000
British

India... 3,082,000] 3,774,000] 2,953,000] 2,498,000
Egypt 1,506,000] 911,000] 1,275,000] 1,296,000
Russia 900,000 720,000 846,000} 620,000
China 775,000] 600,000] 600,000] 426,000
Brazil 3 10,000 360,000 425,000 370,000
Peruano ns 128,000 107,000 80,000 55,000
Turkey ... 105,000 32,000 89,000 80,000
Mexico. .. 135,000 125,000 140,000 70,000
Persia .. 92,000 90,000 50,000 50,000
All — other

countries 195,000 195,000 185,000 165,000

The average production for mill consumption
during the five years shown in the table was
18,787,000 bales, or 3,510,000 bales less than

194 KNAPP METHOD OF GROWING COTTON

the production of 1911. In addition to the
amounts shown in the table, large quantities
of the fiber are produced in some countries
and consumed in the homes of the people,
without entering commercial channels; but
the amount of such cotton cannot be estimated
with any degree of accuracy.

Proportion of total consumption, by countries (yecr.ending Auguat $x,
1912),

&

Diagram I Diagram II

The relative importance of the several cotton-producing
countries is graphically presented in Diagram I. Of the
total production of commercial cotton in 1911, the United
States contributed 69.7 per cent.; British India, 11.3 per
cent.; Egypt, 6.5 per cent.; and Russia, 5.4 per cent.

The relative importance of the several countries in the
consumption of cotton is shown in Diagram II.

jupplement

SUPPLEMENT

There are many agencies now organized for
the purpose of giving practical and scientific
information to the farmer in helping him solve
his problems. Among these are the State
Agricultural Colleges and Experiment Stations,
the Industrial and Agricultural Agents em-
ployed by the railroads, the U. S. Depart-
ment of Agriculture through its Demonstration
Agents and other employees, and the Editors
of Agricultural Papers.

DIRECTORS OF UNITED STATES AGRICULT-
URAL EXPERIMENT STATIONS IN
THE, COTTON BELT

ALABAMA
J. F. Guggar, Director, College Station, Auburn.
L. H. Moore, Director, Canebrake Station, Uniontown.
G. W. Carver, Director, Tuskeegee Station, Tuskeegee

Inst.

ARKANSAS
C. F. Adams, Director, State Station, Fayetteville.

CALIFORNIA
T. F. Hunt, Director, State Station, Berkeley.

197

I98 KNAPP METHOD OF GROWING COTTON

FLORIDA
P. H. Rolfs, Director, Gainesville.
GEORGIA
R. J. H. DeLoach, Director, Experiment.
HAWAII

E. V. Wilcox (Special Agent in Charge), Federal Station,
Honolulu.
C. F. Eckart, Director, Sugar Planters’ Station, Honolulu.

ILLINOIS
E. Davenport, Director, Urbana.
ISLAND OF GUAM
John B. Thompson(Special Agent Chane): Guam.
KANSAS
W. M. Jardine, Director (Acting), Manhattan.
KENTUCKY
J. H. Kastle, Director, Lexington.
LOUISIANA
W. R. Dodson, Director, State Station, Baton Rouge.
W. R. Dodson, Director, Sugar Station, New Orleans.
W. R. Dodson, Director, N. Louisiana Station, Calhoun,
W. R. Dodson, Director, Rice Exp. Station, Crowley.
MISSISSIPPI
E. R. Lloyd, Director, Agricultural College.
MISSOURI

F. B. Mumford, Director, College Station, Columbia.
P. Evans, Director, Fruit Station, Mountain Grove.

NEW MEXICO
Fabian Garcia, Director, State College.

SUPPLEMENT 199

NORTH CAROLINA
B. W. Kilgore, Director, College Station, W. Raleigh.
B. W. Kilgore, Director, State Station, Raleigh.
OKLAHOMA
J. A. Wilson, Director, Stillwater.
PORTO RICO

D. W. May, (Special Agent in Charge), Federal Station,
Mayaguez.

J. T. Crawley, Director, Sugar Producers’ Station, Rio
Piedras.

SOUTH CAROLINA
J. N. Harper, Director, State Station, Clemson College.
TENNESSEE
H. A. Morgan, Director, State Station, Knoxville.
TEXAS
B. Youngblood, Director, State Station, College Station.
VIRGINIA

S. W. Fletcher, Director, State Station, Blacksburg.
T. C. Johnson, Director, Truck Station, Norfolk.

INDUSTRIAL AND DEMONSTRATION AGENTS
EMPLOYED BY THE RAILROADS

SouTHERN RariLroap — DEPARTMENT OF FARM
IMPROVEMENT WorRK

T. O. Plunkett, Manager, Atlanta, Ga.

ASSISTANT MANAGERS
R. E. Grabel, Charlotte, N. C.
W. D. Clayton, Chattanooga, Tenn.
Roland Turner, Meridian, Miss.

200 KNAPP METHOD OF GROWING COTTON

FIELD AGENTS
Brown, Manassas, Va.

W. M.
R. O. McCord, Danville, Va.
W. E. Perry, Greensboro, N. C.
J. H. Hendricks, Columbia, S. C.
R. A. Stratford, Hazlehurst, Ga.
T. E. Waldrup, Valdosta, Ga.
Frank Shorter, West Point, Va.
George Reese, Atlanta, Ga.

S. A. Miller, Johnson City, Tenn.
B. M. Anderson, Knoxvilie, Tenn.
T. J. Griffith, Danville, Ky.
. C. Prescott, Harriman, Tenn.

. Shepherd, Attalla, Ala.
. Atkinson, Tuscumbia, Ala.

. Draper, Anniston, Ala.

. Culver, Maplesville, Ala.

. Hopper, Tuscaloosa, Ala.

. Malone, Jackson, Tenn.

. Byars, Corinth, Miss.

. Proctor, Itta Bena, Miss.

. Randle, West Point, Miss.

. Burrows, Okolona, Miss.

. Moorman, Lauderdale, Miss.
. Jarrott, Waynesboro, Miss.
. Shand, Thomasville, Ala.
Long, Cuba, Ala.

A Boece! Akron, Ala.

. Birch, Asheville, N. C.

. Chapman, Greenville, S. C.

Co oe ee See
Pape ae Ge Ore Se a

LIVE STOCK AGENT

F. L. Word, Atlanta, Ga.

SUPPLEMENT 201

ASSISTANT LIVE STOCK AGENTS
Dr. Walter Sorrell, Greensboro, N. C.
Dr. C. D. Lowe, Morristown, Tenn.
Dr. Charles J. Becker, Birmingham, Ala.

DAIRY AND POULTRY AGENT
Dr. C. M. Morgan, Atlanta, Ga.

ASSISTANT DAIRY AND POULTRY AGENTS
C. T. Rice, Greensboro, N. C.
Walter W. Fitzpatrick, Atlanta, Ga.
F. H. Denniss, Columbus, Miss.
C. A. Hutton, Knoxville, Tenn.
G. W. Humphrey, Birmingham, Ala.
Carlton Ball, St. Louis, Mo.
MARKET AGENTS
J. M. Seahorn, Atlanta, Ga.
E. M. Lane, Cincinnati, Ohio.
E.. L. Robison, St. Louis, Mo.
M. M. Emmert, Washington, D. C.
CenTRAL oF Georcia RarLway
J. F. Jackson, Agricultural Agent, Savannah, Ga.
T. G. Chastain, Agriculturist, Savannah, Ga.
Atiantic Coast Line Raitway
Wilbur McCoy, Agricultural and Immigration Agent,
Jacksonville, Fla.
SEABOARD Air Line Raritway

J. A. Pride, General Industrial Agent, Norfolk, Va.
H. T. Prosser, Agricultural Agent, Hamlet, N. C.

J. W. Scott, Agricultural Agent, Hamlet, N. C.

E. D. Mays, Agricultural Agent, Jacksonville, Fla.
A. P. Fant, Asst. Industrial Agent, Jacksonville, Fla.

202 KNAPP METHOD OF GROWING COTTON

LOUISVILLE AND NASHVILLE RAILROAD

G. A. Park, General Immigration and Industrial Agent,
Louisville, Ky.

L. H. Lister, Agricultural Agent, Bay Minette, Ala.

T. E. McElroy, Agricultural Agent, Columbia, Tenn.

John Lister, Agricultural Agent, Pensacola, Fla.

Karl R. Wundt, Agricultural Agent, Etowah, Tenn.

William James, Agricultural Agent, Montgomery, Ala.

S. A. Scott, Agricultural Agent, Foley, Ala.

Gur anv Suip Istanp RaILRoapD
F. H. Lister, Ind. and Immigration Agent, Gulfport, Miss.
J. J. Taylor, Agricultural Agent, McHenry, Miss.

Ixttinois CENTRAL RAILROAD
J. C. Clair, Industrial and Immigration Commissioner,
Chicago, IIl.
Charles N. Brumfield, Agriculturist, Memphis, Tenn.

Kansas City SouTHERN RaILway
J. Hollister Tull, Agriculturist, Mena, Ark.

Frisco LInEs
W. L. English, Supervisor of Agriculture, St. Louis, Mo.
E. G. Barnard, Farm Demonstrator, Oklahoma City,
Okla.

N. T. McAlister, Farm Demonstrator, Springfield, Mo.
B. W. White, Farm Demonstrator, Springfield, Mo.

D. C. Cornman, Farm Demonstrator, St. Louis, Mo.

H. H. Harrington, Agricultural Director Kingsville, Texas.
Theo. Kreuz, Demonstration Agent, Kingsville, Texas.

Missourt, Kansas, AND Texas RarLway CoMPANY
oF TEXAS

T. L. Peeler, Industrial Commissioner, Dallas, Texas.

R. W. Hockaday, Industrial Commissioner, St. Louis, Mo,

SUPPLEMENT 203

St. Louis SourHWESTERN Raitway Co.

W. R. Beattie, Agricultural Commissioner, St. Louis, Mo.

P. T. Cole, Assistant Agricultural Commissioner, St.
Louis, Mo.

L. E. Saupe, Assistant, St. Louis, Mo.

C. C. Rockenbach, Assistant, St. Louis, Mo.

Artcuison, ToPpEKA AND Santa FE Rartway Co,

H. M. Bainer, Agriculturist, Amarillo, Texas.

J. D. Tinsley, Agriculturist, Brownwood, Texas.

Missouri Paciric Rattway

G. K. Andrews, Agricultural Commissioner, St. Louis, Mo.

St. Louis, Iron Mountain anp SouTHERN RarLway

L. A. Markham, Agricultural Commissioner, Little Rock,
Ark,

Texas & Paciric Raitway Co. anp INTERNATIONAL
AND Grear NorTHerRN Raitway Co.

R. R. Claridge, Agricultural Commissioner, Longview,

Texas.
Rocx Istanp Lines

H. M. Cottrell, Agricultural Commissioner, Chicago, IIl.
(736 La Salle St. Station).

E. R. Bennett, Horticulturist, Little Rock, Ark.

Sunset CEnTRAL Roure

(Including Galveston, Harrisburg & San Antonio Rail-
way Co., Texas & New Orleans Railroad Co., Hous-
ton & Texas Central Railread Co., Houston, East &
West Texas Railroad Co., Houston & Shreveport
Railroad Co.)

H. P. Attwater, Agricultural Agent, Houston, Texas.

W. P. Young, Agricultural Agent, Houston, Texas.

204 KNAPP METHOD OF GROWING COTTON

New Or.eans, Mosite & Cuicaco RarLroap Co.

L. L. Lawrence, Manager Agricultural and Industrial
Department, Laurel, Miss.

H. H. Bolton, Agricultural and Immigration Agent,
Mobile, Ala.

EDITORS OF AGRICULTURAL PAPERS

G. F. Hunnicutt, Editor, Southern Cultivator, Atlanta, Ga.

R. A. Niven, Editor, Southern Farming, Atlanta, Ga.

J. S. Cates, Editor, Southern Planter, Richmond, Va.

Editor, Farmers’ Union Sun, Columbia, S. C.

L.C. Neele, Editor, Southern Agriculturist, Nashville, Tenn.

Dr. H. E. Stockbridge, Editor, Southern Ruralist, Atlanta,
Ga.

W. C. Stubbs, Editor, The Louisiana Planter, New
Orleans, La.

R. J. Nelson, Editor, Farm and Ranch, Dallas, Texas.

D.N. Barrow, Editor, Texas Farmer, Dallas, Texas.

John Fields, Editor, Oklahoma Farm Journal, Oklahoma
City, Okla.

Edgar A. Wright, Editor, The Florida Grower, Tampa,
Fla.

E. O. Wild, Editor, Gulf States Farmer, New Orleans, La.

Clarence H. Poe, Editor, Progressive Farmer, Raleigh, N.C.

Dr. Tate Butler, Editor, Progressive Farmer, Memphis,
Tenn.

John Small, Editor, Arkansas Homestead, Little Rock,
Ark.

DEMONSTRATION AGENTS OF THE U. S
DEPARTMENT OF AGRICULTURE

The Farmers’ Cooperative Demonstration Work,
organized by the U. S. Department of Agriculture, now

SUPPLEMENT 205

has an Agricultural Agent in nearly every county in the

South. This work is now being carried on by the U. S.

Department of Agriculture in codperation with the State

Agricultural Colleges and the State Departments of

Agriculture.

Farmers desiring information on agricultural subjects
can address communications to:

Mr. Bradford Knapp, Special Agent in Charge, Bureau
of Plant Industry, Washington, D. C.

Mr. J. A. Evans, General Assistant, Bureau of Plant
Industry, Washington, D. C.

Mr. W. B. Mercier, Agriculturist and Field Agent for
the states of Louisiana, Arkansas, and Tennessee,
Bureau of Plant Industry, Washington, D. C.

H. E. Savely, Agriculturist and Field Agent for the states
of Alabama, Georgia, Florida, and Mississippi,
Bureau of Plant Industry, Washington, D. C.

Mr. E. Gentry, Agriculturist and Field Agent for the states
of Oklahoma and Texas, Bureau of Plant Industry,
Washington, D. C.

, Agriculturist and Field Agent for the
states of North Carolina, South Carolina, Virginia,
and Maryland, Bureau of Plant Industry, Washing-
ton, 0. GC:

STATE AND DISTRICT AGENTS IN THE
FARMERS’ COOPERATIVE DEMONSTRA-
TION WORK, U. S. DEPARTMENT
OF AGRICULTURE

ALABAMA
B. L. Moss, State Agent, 701 Bell Building, Montgomery,
Ala.
A. D. Whitehead, District Agent, Greenville, Ala.

206 KNAPP METHOD OF GROWING COTTON

J. T. Watt, District Agent, Talladega, Ala.
W. L. Lett, District Agent, 7o1 Bell Building, Mont-
gomery, Ala.
ARKANSAS
C. W. Watson, State Agent, Little Rock, Ark.
J. C. Barnett, District Agent, Little Rock, Ark.
R. C. Davidson, District Agent, Little Rock, Ark.
W. F. Haden, District Agent, Little Rock, Ark.

FLORIDA

A. S. Meharg, State Agent, Lakeland, Fla.

W. L. Watson, District Agent, Live Oak, Fla.
GEORGIA

. Phil. Campbell, State Agent, Athens,”Ga.

. O. Cornelius, District Agent, Cedartown, Ga.

. M. Cown, District Agent, Union City, Ga.

. V. Cunningham, District Agent, Tifton, Ga.

. W. Hendricks, District Agent, Savannah, Ga.

. G. Oliver, District Agent, Macon, Ga.

LOUISIANA

Mason Snowden, State Agent, Shreveport, La.
L. M. Calhoun, District Agent, Gilbert, La.
L. E. Perrin, District Agent, St. Landry, La.
J. E. Wemple, District Agent, Arcadia, La.

MARYLAND
Dr. Augustus Stabler, District Agent, Bureau of Plant
Industry, Washington, D. C.
MISSISSIPPI

R. S. Wilson, State Agent, Columbus, Miss.
J. W. Willis, District Agent, Grenada, Miss.
P. P. Garner, District Agent, West Jackson, Miss.

SUPPLEMENT 207

NORTH CAROLINA

C. R. Hudson, State Agent, Raleigh, N. C.

T. E. Browne, District Agent, Ahoskie, N. C.
T. D. McLean, District Agent, Carthage, N. C.
E. S. Millsaps, District Agent, Statesville, N.C.

OKLAHOMA

W. D. Bentley, State Agent, Yukon, Okla.
J. M. Daily, District Agent, Muskogee, Okla.
| GA OF Ferguson, District Agent, Minco, Okla.

SOUTH CAROLINA

W. W. Long, State Agent, Clemson College, S. C.
L. L. Baker, District Agent, Bishopville, S. C.

W. H. Barton, District Agent, Simpsonville, S. C
W. R. Elliott, District Agent, Winnsboro, S. C.

TENNESSEE

H. D. Tate, State Agent, 909 Stahlman Building, Nash.
ville, Tenn.

J. M. Dean, District Agent, Columbia, Tenn.

H. S. Nichols, District Agent, Jackson, Tenn.

C. F. Striplin, District Agent, Maryville, Tenn.

TEXAS

W. F. Proctor, State Agent, College Station, Texas.

J. L. Quicksall, Asst. State Agent, 1808 S. 12th Street,
Waco, Texas.

William Ganzer, District Agent, Denton, Texas.

M. T. Payne, District Agent, Temple, Texas.

G. W. Orms, District Agent, Mineola, Texas.

T. O. Walton, District Agent, Livingston, Texas.

208 KNAPP METHOD OF GROWING COTTON

VIRGINIA

T. O. Sandy, State Agent, Burkeville, Va.

F. S. Farrar, District Agent, Jetersville, Va.

W. P. Moore, District Agent, Forest Depot, Va.
W. C. Shackleford, District Agent, Proffit, Va.

THE END

L — =. mT

O0009317946