a

THE WATER RELATIONS
OF PLANTS

THE BRITISH ECOLOGICAL SOCIETY

SYMPOSIUM NUMBER THREE

THE WATER RELATIONS
OF PLANTS

A Symposium of
THE BRITISH ECOLOGICAL SOCIETY

London, ^—8 April ig6i

Edited by
A.J.RUTTER

B.Sc. Ph.D.

Imperial College of Science

and TechnologYt London

and

F.H.WHITEHEAD

M.A. D.Phil.

Imperial College oj Science
and Technology, London

MARINE
BIOLOGICAL
LABORATORY

I RY

:.s.

JOHN WILEY & SONS INC
NEW YORK

© BLACKWELL SCIENTIFIC PUBLICATIONS I963

This book is copyright. It may not be reproduced by any means
in whole or in part without permission. Application with
regard to copyright should be addressed to the publishers.

FIRST PUBLISHED 1963

Printed in Great Britain

LABORATORY 1

LIBRARY I

CONTENTS |-^^^^^LE,MASSr
Preface I W. H. 0- 1- \ ix

WATER AND WATER MOVEMENT
IN THE ENVIRONMENT

Climatic Diagrams as a Means to Comprehend the Various
Climatic Types For Ecological and Agricultural
Purposes 3

H.Walter, Botanisches Institut, Stuttgart-Hohenheim, West Germany

Potential Water Dehcit as a Climatic Discriminant io

F.H.W. Green, Speyside Research Station, Nature Conservancy,
Achantoul, Aviemore, Invernesshire, Scotland

The Role of Evaporation in the Surface Energy Balance 19

M.J. Blackwell, Meteorological Office, Agricultural Research Unit,
School of Agriculture, University of Cambridge

Dew: Facts and Fallacles 37

J.L. Monteith, Rothamsted Experimental Station, Harpenden, Herts.

The Effect of Dissolved Salts on Water Movement 57

D.A. Rose, Rothamsted Experimental Station, Harpenden, Herts.

Model Tests on the Ecological Effect of Vapour

Movement in Soil due to Temperature Gradients 65

W.R. MuUer-Stoll & G. Lerch, Botanisches Institut, Padagog.

Hochschule, Potsdam, East Germany

PHYSIOLOGICAL STUDIES OF WATER BALANCE
AND MOVEMENT IN PLANTS

The Pathway of Water Movement Across the Root Cortex

and Leaf Mesophyll of Transpiring Plants 85

P. E. Weatherley, Botany Department, University of Aberdeen,

Scotland

vi CONTENTS

Water Saturation Deficit and its Development in Young

AND Old Leaves ioi

Jiri Catsky, Institute of Biology, Czechoslovak Academy of

Sciences, Praha, Czechoslovakia

WATER RELATIONS IN NATURAL CONDITIONS

On the Distribution of the Precipitation in a Spruce
Stand : An Attempted Analysis i i 5

M.G. Stalfelt, University of Stockholm, Sweden

Measurement and Signihcance of Throughfall in Forest

Stands 127

E.R.C. Reynolds & L. Leyton, Department of Forestry,

University of Oxford

The Behaviour of Norway Spruce {Picca abies (L.) Karst) in
Central Jutland, Denmark, in the Summer of 1955 142

E.B. Oksbjerg, Royal Forestry College, Stockholm, Sweden

Climate and Water Relations of Plants in the Sub-Alpine
Region i53

Walter Tranquillini, Forschungsstelle fiir Lawinenvorbeugung,

Innsbruck, Austria

Investigations on the Water Relations of Sand-dune

Plants Under Natural Conditions 168

A.J. Willis & R.L. JefFeries, Department of Botany, University

of Bristol

Water Relations of Some Psammophytes with Inspect to

Their Distribution 190

Milena Rychnovska & Jan Kvet, Geobotanical Laboratory of the

Czechslovak Academy of Sciences, Brno, Czechoslovakia

The Water Supply of Desert Plants i99

H, Walter, Botanisches Institut, Stuttgart-Hohenheim, West
Germany

CONTENTS vii

Seasonal DiMORPrasM of Desert and Mediterranean
Chamaephytes and its Significance as a Factor in their
Water Economy 206

G. Orshan, The Hebrew University, Jerusalem, Israel

RELATION OF GROWTH AND
DISTRIBUTION TO WATER

On the Problem of the Relationship Between Hydration

OF Leaf Tissue and Intensity of Photosynthesis and

RESPIRATION 225

B. Slavik, Institute of Biology, Czechoslovak Academy of Sciences,

Praha, Czechoslovakia

The Effects of Exposure on Growth and Development 235

F.H. Whitehead, Imperial College, London

Growth and Water use of Vegetables in a Greenhouse 246

J.F. Bierhuizen, Institnut voor Cultuurtechnick en Waterhuishonding,
Wageningen, Netherlands

Photosynthesis and Growth of a Five-year-old Stand of
Poplar Trees in Relation to Water Economy of the Site 257

H. Polster, Institute of Forest Science, Tharandt, East Germany

Hydrature and Plant Production 272

K. Kreeb, Botanisches Institut, Stuttgart-Hohenheim, West Germany

A Comparison Between the Water Relations of Species with

Contrasting Types of Geographical Distribution in the

British Isles 289

Margaret S. Jarvis, Institute of Physiological Botany of the

University of Uppsala, Uppsala, Sweden

The Effect of Soil Type on the Relation Between Soil/

Water Pegime and Growth of Seedlings of Quercus petraea

(Matt.) Licbl. 3i3

P. G. Jarvis, Institute of Physiological Botany of the University of

Uppsala, Uppsala, Sweden

viii CONTENTS

Formulae for the Ecological Reaction of Crop Yields 326

W.C. Visser, Instituut voor Cultuurtechnick en Waterhuishonding,
Wageningen, Netherlands
The Growth Rjesponse of Sugar Beet to Similar Irrigation
Cycles Under Different Weather Conditions 340

B. Orchard, Rothamsted Experimental Station, Harpenden, Herts.

Cropping Pattern and Water Eolations 356

W. C. Visser, Institmit voor Cultuurtechnick en Waterhuishonding,
Wageningen, Netherlands

Water Relations of Forest Trees 366

E.E. Gaertner, Professional Agrologist, Petawara Forest, Chalk
River, Ontario, Canada

PREFACE

It is a striking illustration of the current world-wide interest in the
investigation of plant water relations that it should have been possible
for the British Ecological Society to organize a symposium, on this topic
in 1961, barely two years after a similar one had been held in Madrid,
under the auspices of Unesco*, and that a different set of contributors
of international reputation should have been available to sustain the
symposium. It is true that the Madrid symposium was mainly con-
cerned with the problems of arid lands, and this volume is to an extent
complementary in that it lays greater emphasis on temperate vegeta-
tion. The authors of the Reviews of Researchf which preceded the
Madrid symposium, performed a most valuable task in giving a syste-
matic account of the soil-plant-air system through wliich water moves
and the relation of the physiology and growth of plants to the water
factor. But already it has become possible to add, in this volume, new
information on subjects of fundamental importance to plant water
relations, such as evaporation, dew formation and water movement
through soil and plant. In addition investigations from very varied
standpoints of the relationship of water balance to growth and develop-
ment represent a valuable contribution to the understanding of the bio-
logical problems involved.

As a result of some late withdrawals of papers, matched by some
fortunate late contributions, the plan of arrangement of topics in the
symposium was somewhat disturbed, and in preparing the proceedings
for pubhcation the opportunity has been taken to re-arrange the contri-
butions in a more logical order.

The first section on Water in the Environment contains papers from
both geographical and physical points of view. It is followed by two
studies of water in the plant, one of which presents new evidence on the
path of water movement while the other critically re-examines a tech-
nique, the determination of leaf water deficit (or relative turgidity, its

* UNESCO, Arid Zone Research Series, No. 16, 1961.
t Ibid, No. 15, i960.

ix

X PREFACE

complement) which has been widely used in ecological studies for more
than 30 years. As is appropriate for an ecological society, there then
follows a considerable section devoted to investigations in natural vegeta-
tion, ranging from coniferous forest and sub-alpine vegetation, to psam-
mophytes and desert plants. Much work in recent years has been directed
to the accurate measurement or estimation of transpiration because of its
significance to mankind in water conservation and in forecasting catch-
ment yields and floods. To the botanist, however, transpiration has greater
significance. In the first place it represents a process which dissipates,
often with apparent extravagance, the water in the soil on which growth
and survival depend. Secondly, the life processes of the plant are related
in a complex way to the balance between the demand of the atmosphere
for water and the ability of the soil to supply it. From both points of
view the success of the plant is related to its abihty to regulate its trans-
piration and its potential on the gradient between soil source and air sink.
The ultimate concern of studies on water relations is surely to analyse
all aspects of the growth, development, reproduction and survival of
plants as they are affected by, or as they affect, the potentials, movement
and balance of water in the system. Although we are far from fully
understanding the responses of plants to water, our ultimate interest in
growth and development has been recognized by reserving for the final
section investigations on the relation of growth to climate, soil water and
the potential of water in the plant.

The symposium was held at Imperial College, London, by invitation
of the Rector and Professor W. O. James f.r.s., from 5 to 8 April,
1 96 1. The conveners wish to record here the thanks which were expressed
at the closing session to the College authorities and staff, and the many
willing and able helpers who contributed so largely to the smooth run-
ning of the meeting and the enjoyment of all present.

A.J. RUTTER

F.H. Whitehead

WATER AND WATER MOVEMENT IN
THE ENVIRONMENT

CLIMATIC DIAGRAMS AS A MEANS TO
COMPREHEND THE VARIOUS CLIMATIC TYPES
FOR ECOLOGICAL AND AGRICULTURAL

PURPOSES

H. Walter

Botanisches Institut, Stuttgart-Hohenheim, W. Germany

A very close correlation exists between vegetation and climate. Therefore
everyone who is interested in vegetation should be equally interested in
cHmate.

It is very difficult, however, to get an exact idea of chmate. We con-
stantly use the word 'chmate', but what is cHniate? It is possible to defme
chmate as the weather, changing in a certain mamier during the course of
a year, taken as an average of many years, as a single year may be abnormal.

What is the weather ? It is the effect of all weather or climatic elements as
temperature, rainfall, humidity, radiation, etc., combined at a certain
moment. Therefore, to get the actual chmate, it is necessary to summarise
the effects of all these chmatic elements in order to get the weather for
the entire year. But no chmatologist tells us how to do this. It is only
possible to get the tables for each climatic element. We also have many
exact maps of the distribution of the annual temperature or the annual
rainfall, the temperature of the coldest or hottest month, the rainy seasons,
the humidity, the evapotranspiration, etc., but all this does not yet fuUy
constitute the climate. As basis for chmatic maps the chmatologist employs
chiefly the maps of vegetation and also the climatic types are named after
the vegetation, for example, desert chmate, steppe chmate, forest chmate,
alpine chmate, etc.

Climate is a unity. It is not possible to express cHmate by a figure or by
formulae, even by the most compHcated ones, because it is necessary to
know the seasonal rhythm of the most important factors. Therefore we
have to use a diagram, quasi as a picture of the chmatic type.

During the year 1954-55 I was a guest professor at Ankara in Anatolia
and I desired a quick overall picture of the different chmatic types of
Anatoha. I obtained the meteorological tables from approximately 66
meteorological stations with long-term observations, but it was very
difficult to get a synopsis of the chmatic regions. I decided to use the
diagram method and I remembered a suggestion given by H. Gaussen at
the International Botanical Congress in Paris in 1954 to use the same units

4 H.WALTER

of length for io°C and 20 mm of rainfall respectively. Using this scale, io°C
equal to 20 mm, Gaussen estabUshed for the Mediterranean region a
strictly arid period prevailing when the rainfall curve goes belov/ the
temperature curve and a humid period when the rainfall curve rises above
the temperature curve (Fig. i, cHmatic diagram of Ankara). I appHed this
method to the cHmate of Ankara and the diagram showed the actual dry
period beginning with June and ending in the second half of October.
When I checked the method for tropical summer rain regions (South

o^ ANKARA (8&5m) ll,7°3iil

Fig. I

_G0BABIS(1445m)i
[30-521

19,A° 362

STUTTGART (267m) 10,0° 673
[ 50 - 40 1

-2.1
-25,0

Fig. 2

Fig. 3

ODESSA (43m)
111-24)

-21

K

9,A 368

Fig. 4

CLIMATIC DIAGRAMS

DOUALA (13m)
1 10)

26,^ 39A8

353
30-

-72

/

( 1

k

-JO

Fig. 5

Figures 1-5. Explanation of climatic diagrams.
a-Station.
b -Altitude,
c- Number of years of observation (the first stands for temperature, the second for

precipitation).
d-Mean annual temperature in °C.
e-Mean annual amount of precipitation in mm.

f-Mean daily minimum of the coldest month.

g- Absolute minimum.

h-Mean daily maximum of the hottest month.

i- Absolute maximum.

j-Mean daily range of temperature.

k- Monthly means of temperature (thin line) in °C.

1-Monthly means of precipitation (thick hne) in mm.
m-Arid period (dotted area),
n- Humid period (hatched area).

o-Perhumid area (black area), mean monthly rainfall over 100 mm (scale reduced
ten times).

p-Additional precipitation curve (io°C=30 mm) showing the less extreme dry

period.
q-Months with a mean daily minimum below o°C.
r-Months with an absolute minimum below o°C.
s-Mean number of frost-free days.

6 H.WALTER

West Africa) and temperate regions of which I knew the exact chmate
(Stuttgart, etc.), it worked, out as well (Figs. 2 and 3).

The only exception was the temperate steppe chmate with a summer
maximum of rainfall. The diagram of Odessa shows a short arid period in
the spring and a httle longer arid period in July and August. This was a
contradiction as the whole summer m Odessa is dry, though not as dry as
in the Mediterranean region. In these cases it proved to be useful to draw
an additional rainfall curve with a scale of io°C equal to 30 mm (i : 3) and
to distinguish an extreme drought period and a less extreme dry period
(Fig. 4, chmatic diagram of Odessa).

Comparison between the curve of the monthly mean temperature and
monthly mean rainfall is allowable because evaporation is mostly pro-
portional to temperature. To get the water balance it is necessary to know
the ratio of the evaporation to rainfall. As evaporation values are published
only for very few stations, temperature values have to be utihsed instead of
the missing evaporation values. This is only possible, however, when the
temperatures are above o°C, as below o°C the evaporation is negligible.

Many authors have used the ratio of precipitation to temperature in order
to obtain a picture of the water balance (Lang, de Martonne, Koppen,
Angstrom, Church and GuefFroy, Thornthwaite, etc.). The formulae they
used are, more or less, comphcated. But the ratio of the temperature to
rainfall does not much deviate from 1:2 or 1:3 as used by us. For the
drawing of thousands of diagrams the ratio must be a simple one, therefore
we employ mostly only the ratio i : 2 and distinguish between an extreme
drought period and a less extreme dry period if desirable, by employing
the ratio 1:3.

The horizontal extension of the different areas on the diagrams shows
us the duration of the periods, the vertical extension, the intensity of
humidity or aridity respectively.

But it is not enough to characterise unfavourable seasons caused by water
shortage. To get an idea of the chmate or the chmatic type, we also have
to know the unfavourable season, caused by cold. Therefore the months
with a mean daily minimum below o°C are indicated by black blocks. This
is the average cold season of the year. The months with only an absolute
minimum below o°C are hatched (Figs. 1-4). During this season frost
was observed, but frost may not occur every year, sometimes only in
exceptionally cold years. Some additional chmatic data are provided by
figures. Complete diagrams are shown in Figs. 1-4. In the tropics the
monthly rainfall may be extremely high and in order to simphfy the dia-
gram, the scale for rainfall above 100 mm per month is reduced ten times.

CLIMATIC DIAGRAMS 7

This area is shown in black (Fig. 5, cHmatic diagram of Douala) and is a
perhuniid season.

In the equatorial region the temperature shows a much larger daily than
seasonal variation. Therefore it is necessary to give additional figures : the
mean daily maximum of the hottest month, the absolute maximum tem-
perature and the amphtude of the mean daily variation of the temperature

(Fig- 5).

The diagrams of all dd meteorological stations of AnatoHa were drawn

and attached to a large wall map of Anatoha. At a glance one could see

the distribution of the main cUmatic types without any interpolation. This

was also accomplished for Iraq during a visit to Baghdad. Later on the

same method was apphed to Africa, while the maps were pubhshed in

Germany. Since they proved to be very useful, we decided to prepare a

world atlas of the climatic diagrams. The first part is already pubhshed

by VEB Gustav Fischer- Verlag Jena and comprises the complete Southern

Hemisphere, India, the Near East, the Iberian Peninsula and Western

Europe. Maps of the other parts of the world are in preparation and will be

pubhshed next year.

It is impossible to show the diagrams of all stations on the maps or
chmatic cartograms of the world atlas because the scale of the maps is too
smaU. It is necessary to unite diagrams of the same type to groups and
to show only the distribution of these on the maps with diagrams of
one or two stations as examples. The position of each station is shown on
the maps by a number. The diagrams of these stations are listed under
the same number on supplementary sheets.

The following ten principal climatic types are distinguished as indicated
by roman numerals :

I Equatorial type, humid or with two rainy seasons.
II Tropical type, with summer rain.

III Sub-tropical type, hot and arid.

IV Mediterranean type, with arid summer and winter rams, frost rare.
V Warm temperate type, humid, frost rare.

VI Temperate type, with cold winter, humid.
VII Temperate arid type, with a cold season.
VIII Boreal type, with a long winter season.

IX Arctic type, cold, only a short warmer season.
X Mountain types, belonging to different chmatic regions.

The subdivisions of these types are indicated on each map by arable figures
or letters. They are prehminary and only when all maps are ready will it

8 H.WALTER

be possible to give a detailed classification of all different climatic types
based on climatic data only and not on vegetative regions. Only then
shall we be able to carry out a true comparison between chmate and
vegetation.

In Eastern Europe such a comparison shows that the border lines of the
vegetation regions (forest, forest steppe, steppe, semi desert) are much more
compHcated than the borders of the corresponding cHmatic regions. This
can easily be understood, as the vegetation depends not only on chmate but
also on soils. In a region with loess soils, steppe invades the forest belt in
tongue- or island-like extensions (Walter 1957).

The borders between two vegetation regions are much sharper than
those between two chmatic types. In flat countries there is a steady transi-
tion from, one cUmatic type to another. A cartogram with climatic dia-
grams shows this clearly. Border lines on ordinary climatic maps in a
region of this type are, to a degree, misleading and arbitrary.

All diagrams of the world atlas (about 10,000) are drawn in the same
manner, therefore it is easy to compare the climate of different stations.
The months are printed for stations on the Northern Hemisphere, starting
with January, those on the Southern Hemisphere starting with July, so the
warm season always comprises the middle of the diagram. This is necessary
to facilitate comparison. When confronted with the question where a
climate, corresponding to the climate of the Central Anatolian steppe,
might be found in other parts of the world by comparing different dia-
grams, it was easily possible to see that the climate of Ankara is similar to
that of Salt Lake City (U.S.A.) and Kabul (Afghanistan). In fact these three
places have a similar geomorphological situation and the vegetation of
these regions is equally similar.

We hope that this atlas may prove useful in dealing with problems
concerning ecology, plant geography, agriculture, forestry and many other
fields of study. I wish to emphasise, that the figures in the diagrams are
exactly those pubHshed by the meteorological stations. Therefore, if
required, these data may be read from the diagrams. The diagrams comprise
only the most important cHmatic factors. Minute details should be avoided,
as the diagrams become overcrowded and consequently less clear. The
diagram gives only a rough idea of a climatic type. It is impossible to do
more, as even the most exact meteorological data do not correspond to the
plant climate, for they are, (i) measured in a screen, which means protected
from the radiation and (2) 2 m above ground. Moreover, only long-term
means are published.

A normal climate, as given by the mean values, does not exist. There

CLIMATIC DIAGRAMS 9

are periods every year either too cold or too warm, too dry or too huniid.
The extremes often are more important for the plants than the average
conditions, and for agriculture or forestry purposes it is extremely impor-
tant to know how often such extremes may occur. To get a better idea of
the climatic conditions in a certain region with respect to its extremes, we
use climatograms. Their construction is nearly the same as that of ordinary
climatic diagrams, except for the curves. Instead of using the long-term
means, the values for single years (for a period at least of 20 years) are used
instead. Such cHmatograms show at a glance, how often extreme years
with strong deviations occur.

We hope the method of cHmatic diagrams described here will prove
useful and find a wide appHcation. The maps of our atlas need further
improvements, as they are a first attempt.

LITERATURE

Publications in which the method of cHmatic diagrams was used.

Beydeman, I.N. & KORCZAGYN, A.A.(i962) Report on the World Atlas of cUmatic

diagrams and the Russian publications in which this method was used. Bot.Z. 47.

288-290.
BoRHiDi, A.(i96i) KUmadiagramme und klimazonale Karte Ungam. Ann. Unit'.

Scient. Budapestinensis, Sect. Biol. 4, 21-50.
Gaussen, H.(i955) Expression des miHeux par des formules ecologiques; leur repre-
sentation cartographique. CoUoqiics Int. du Centre Nat. Rech. Scient. 59, 257-269.
GoLUBic, 5.(1958) Beitrag zur KUmakenntnis des Jugoslavischen Kustenlandes.

Geogr. Glasnik, 20, 139-148.
Panntier, F.(i952) El climatogramma. Un aspecto neuva para el conocimiento del

cUma y de la distribucion de la vegetacion en Venezuela. Ergebn. dtsch. Limnol.

Venezuela-Exp. I, 57-66.
Paterson, S.S.(i959) Forslag till bioklimatisk regionindelning av Nordcn. Suensk

Geogr. Arsbok, 35, 102-122.
PiSEK, A. (i960) Immergriine Pflanzen. Encyclopaedia of Plant Physiology, 5, 415 ff.

Berlin.
Walter, H.(i957) Die Klima-Diagramme der Waldsteppen- und Steppengebiete in

Osteuropa. Lautensach-Festschr., Stuttg. Geogr. Studien, 69, 253-262.
Walter, H.(i962) Die Vegetation derErde, Bd. I, Jena.
Walter, H. & Leith, H. (i960) Klimadiagramm-Weltatlas. Jena i960.

POTENTIAL WATER DEFICIT AS A
CLIMATIC DISCRIMINANT

F. H.W.Green
Nature Conservancy

This paper consists of two parts. In the first I will explain what is meant by
'Potential Water Deficit', and in the second I will suggest how useful the
concept can be to ecologists as a chmatic discriminant.

It may be stated simply that Potential Water Deficit or Potential Water
Surplus (PWD and PWS, respectively, for short) is the difference between
rainfall (and/or snowfall) and potential evaporation; it is a deficit or surplus
of water according to which of these quantities is the greater. One need not
at the moment say much about rainfall measurement beyond pointing out
a few of the known difficulties in measurement. For instance, 'rainfall' is
not always rainfall; it may be precipitation of water in other forms, e.g.
snow, hail, or ice pellets, all of which it is normally attempted to measure
in rain-gauges. Then there is so-called 'occult precipitation', which includes
dewfall and condensation from fog. Again, what is measured in a standard
rain-gauge may not be quite the same amount as in fact falls on the
neighbouring ground. Those difficulties will be referred to again later. For
the moment it may first be said that in fact, in this as in most countries, an
attempt is made to measure rainfall under certain 'standard' conditions,
which are inevitably arbitrary.

It needs now to be explained what is meant by potential evaporation (or
evapo-transpiration). Broadly, it is the amount of water which would be
evaporated if there were always water available to be evaporated. It thus
may differ from actual evaporation which is dependent upon availabiUty of
water. Measurement of potential evaporation (or 'PE') presents difficulties,
so that, since it is related, like air temperature, to incoming radiation (direct
and indirect), it has commonly been computed, by various formulae, from
other chmatic elements which are widely measured. It is, however, possible
to measure PE by means of irrigated lysimeters, provided various precau-
tions are taken, and certain 'standard' conditions are accepted. Then, as
with rainfall, comparison can, with caution, be made between values at
different places.

The measurement of PE by lysimeter involves the remainder method,

WATER DEFICIT AS A CLIMATIC DISCRIMINANT it

i.e. it is the difference between water going into the lysimeter- natural and
added-and what percolates through. Expressed as an algebraic equation
it is:

VE = R+A-N±S

where R is rainfall, A is added water, N is percolate, and 5 is the difference
in the amount of water stored in the lysimeter. There are various ways in
which 5 can be ehminated from the equation, and ^ and Ncan be measured
quite accurately, so the main element of doubt is due to uncertainty that
R is measured correctly.

If, however, one considers the PWD or PWS, it is possible to ehminate
R, since

(i) PWD = PE-R

(ii) PWS=R-PE

which equations are the same as

(i) VWD = R+A-N-R

(ii) VWS =R-R-A+N

these simplify to

(i) PWD=^-N

(ii) PWS =N-A

so long as A is always kept high enough to ensure that N does not sink to
nil-i.e. there must be enough irrigation water to ensure that percolation is
maintained, since otherwise it is not possible to allow for variations in
storage.

PWS is potentially run-off, while PWD is an indication of water short-
age, or alternatively, of drying power. It is not necessarily the same as the
actual water deficit, because the potential evaporation may not be the same
as the actual evaporation. The latter (AE) differs from PE by amounts
which depend upon many factors, the nature of the soil, the vegetation
cover, the land use and treatment, and other differences in the surface. But
the PWD is an inescapable climatic factor, and so long as there is a potential
water deficit, there must be an actual water deficit of some sort, unless
water is supplied from elsewhere.

PWD and PWS can be assessed according to different unit lengths of
time. If this time unit is one year, there will be either a single deficit or a
single surplus. To quote a year's surplus would be quite misleading how-
ever. In the example shown in Table i , although an annual assessment gives
a PWS of 1 0-0 in. an assessment made by calendar months shows this
PWS to be made up of a winter PWS of i6-o in. minus a summer PWD of

12 F. H.W.GREEN

6-0 in. Even a month is too short a unit for considering a water budget, and,
from the point of view of vegetation requirements, the unit of time should
be short enough for the plants concerned not to suffer from water shortage.
In an average soil (with average water retention properties) in a temperate
climate, all but extremely shallow-rooted plants will be able to endure lack
of rain for up to about five days. Table i thus gives assessments made, not

Table i
Potential water deficit and potential water surplus at Achnagoichan, 1959

J F M A

M

J

J

A

S

0

N

D

Year

Calculated by twits of one year:

PWD _ _ _ —

—

—

—

—

—

—

—

—

0-0

PWS _ _ _ _

—

—

—

—

—

—

—

—

lO-O

Calculated by units of one calendar month:

PWD — — — — 2-1 0-3 0-4 1-3 1-9 — — — 6-0
PWS 2-7 0-8 0-6 1-2 — — — — — 3-5 3-9 3-3 i6-o

Calculated by wet and dry periods of five days or more:

PWD — — 0-2 o-i 2-1 0-3 1-6 1-3 1-9 0-5 — — 8-o
PWS 2-7 0-8 0-8 1-3 — — 1-2 — — 4-0 3-9 3-3 i8-o

(Values in inches.)

only by whole calendar months, but by calendar months divided into wet
and dry spells, the dry spells being continuous periods of five days or more
with no rainfall (and/or rainfall far less than the PE over the same period).
Even this does not allow for isolated heavy thunderstorm downpours,
which may cause flash floods because the rate of fall is greater than the rate
of penetration into the soil.

It will be seen in the example that some calendar months can, in total,
have both a surplus and a deficit. If the rainfall were distributed evenly
throughout the month, there could be only one or the other. If the rainfall
distribution is very uneven, there can be both, because, for instance, the
surplus at one time will have disappeared as run-off before a dry period
commences, and will not be available, necessarily, to make up for the deficit
in that period.

Let us consider first what happens at a site where no period of PWD
occurs. Rain is always falling at a greater rate than it can be removed, either
by evaporation, run-off, or deep percolation, and this is virtually the case

WATER DEFICIT AS A CLIMATIC DISCRIMINANT 13

whatever the nature of the surface and subsoil (other than a sloping sheet of
impervious concrete or 'tarmac', which could dry between showers). Thus
no amount of artificial drainage could prevent waterlogging, and improv-
ing the land for arable agriculture is practically impossible. The natural
vegetation cover is blanket bog ('chmatic' bog) consisting of plants with
very shallow roots, growing on top of the decayed remains of their
predecessors. Lack of oxygenation of the waterlogged substratum prevents
any development of hving roots downwards. Only where slopes are too
steep for the dead or living vegetation to be retained (or where, because of
altitude, cold and wind enforce an upper hmit) is there no bog. Here there
is only bare rock, save for occasional very exceptional sites, where deeper
rooted plants may temporarily obtain a footing in rock crevices. In the
olden days, in the north-western Highlands and islands of Scotland, the
inhabitants hit on one of the few possible methods of very shghtly amehorat-
ing the conditions-by the laborious construction each year of 'lazy-beds',
deep ridges and furrows, which did permit of a certain amount of drainage,
and so of oxygenation, in the upper parts of the ridges.

There does not at present exist a very satisfactory general map showing
the distribution of peat deposits in Scotland, but Fig. i shows the distribu-
tion of 'improved land' (i.e. arable and ley), which is complementary to it.
It wiU be seen that -excluding hill and mountain-it corresponds with the
map (Fig. 2) showing the observed PWD in 1957- a year probably fairly
close to the average. On the basis of the known distribution of 'chmatic'
peat, and of 'improved land', one can tentatively insert the average line of
no significant PWD (less than ^-i in. or 13-25 mm calculated on a calendar
month basis, in an average year) as shown on this map. Almost the only
satisfactory arable land in the north-west is on the coastal 'machair'-
calcareous dune sand -forming a relatively fertile porous soil, where it can
be saved from wind-blow. But it should be noted that, with evaporation
augmented by strong winds, and shghtly less summer rainfall than occurs a
httle way inland, there are probably 'outhers' of rather greater PWD here
also.

Many places with small PWD will be in the same state as those with no
PWD, because there is no practicability of artificial drainage. Almost all of
north-western Scotland is in tliis position, the few areas of cropland being
precisely at those places where the local physiography and geology specially
favour drainage. Places with a larger PWD in an average year would, it is
suggested, develop bog only where drainage is impeded, and if this
impedance is removed, arable cultivation becomes possible. This is the case
in most lowland areas in the east and south of Scotland, where it is on

14

F. H.W.GREEN

Fig. I. The distribution of arable land in Scotland. (From L. D. Stamp: The Land of
Britain, Longmans, Green & Co., London, 1948).

historical record that much of the now most fertile land was peaty until
it was either drained or the peat taken away or both.

It is important to see where the threshold Hne, as here described, passes

WATER DEFICIT AS A CLIMATIC DISCRIMINANT

15

JFMAMJJASOND

Fig. 2. The monthly distribution of potential water deficit and surplus at five stations
in Scotland in i960. The black line indicates the generalised limit of areas with no
potential water deficit.

across north-west Europe, outside Scotland. A map has been compiled on
lines somewhat similar to those discussed in this paper, by Mohrmann
(1958) and this shows that the areas of negligible PWD can be found in
Ireland, Wales, north-west England, and in Norway, with an outher in the
Alps. But Mohrmann based his map on computed values of PE and he does
not work on PWD by wet and dry periods - i.e. he does not take into account
the distribution of rainfall. If he had done so, it is unhkely that nearly so many
areas would be included. Much of Wales, north-west England, and Norway

i6

F. H. W. GREEN

would have been omitted, and almost certainly the Alpine and Alpine
foreland areas. Why is this? The summer rainfall in the latter areas occurs
mainly in heavy showers, with long dry periods in between ; these allow for
aeration of the soil.

Rainfall and PE have been measured in recent years at Cwm Dyli at the
foot of Snowdon. Here the annual rainfall is of the order of 150 in., and in
all calendar months in i960, for instance, rainfall exceeded PE. Thus, if
assessed by calendar months, Cwm Dyh had no PWD in that year. If
however, the assessment is made by wet and dry periods, Cwm Dyli is
seen to have had about 6 in. PWD in i960. At Cwm Dyh there is good
grassland ; it has been possible to drain the soil and prevent it from being

NORTH
WEST

SOUTH
EAST

SEA-LEVEL

Fig. 3. Diagram illustrating the suggested altitudinal distribution of certain different
'water balance regions' in a section across Europe (not to scale). A is fell (Montane
Zone), B is the extreme 'oceanic' type, witli no significant potential water deficit, C is
the main humid region of north-west Europe but with significivit periods of potential
water deficit each year, D is the Mediterranean type, with dry summers and wet winters,
E is steppe. (See text.)

permanently waterlogged during the growing season. The chmatic situa-
tion in summer in the pastures of Switzerland and Norway is comparable.
It is different in the truly humid areas of north-western mainland of Scot-
land, which in this sense can be described as the most 'maritime' in Europe.

This brief paper has attempted to deal only with one threshold which can
be studied, and defined, in this manner. It needs to be investigated whether
light can be shed on other chmatic limits. Figure 3 shows diagramatically
the nature of the possible Hmits of the Mediterranean type of vegetation;
the relevant numerical values of PWD and PWS, and their seasonal
distribution, need to be determined. There is great scope similarly for
investigating 'finer' hmits, for natural plant communities, and individual
cultivated crops, between these very broad divisions.

It may be useful to make reference here to some other physiological effects
on plants-and animals-and of the lack of a period of PWD. As a first

WATER DEFICIT AS A CLIMATIC DISCRIMINANT 17

example, it has been shown by Alvin (i960) that moisture stress is an essen-
tial requirement for flowering of the coffee plant; it is no good irrigating a
coffee crop unless it has been allowed to experience a period of water
shortage. If there is continual water surplus, rank vegetative growth
appears to be encouraged, but maturation is inhibited. It is but common-
sense to expect that a crop which consists largely of water, such as a vege-
table marrow, will not be able to develop unless there is, as in Britain in
1958 or i960, a plentiful supply of water when the fruit is enlarging. But
there could very well have been no flowering, and thus no fruit to enlarge
at all, unless the period of plentiful water had been preceded by a period of
water stress.

Turning from flora to fauna, it has been found that many invertebrates
exhibit variations in movement, and in population density, according to
whether or not there has been a moisture deficit in the soil or other habitat.
Thus Pearce, working in the Moor House NatureReserve in Westmorland,
found that Enchytraeid worms move upwards in the soil under conditions
of PWS and downwards in periods of PWD.

If one accepts that the chmatic threshold described in this paper has a
vahd close correlation with the vegetational and agricultural features as
suggested, one can speculate about secular changes. It would require only a
very small change in 'total chmate'-i.e. the results of secular changes in
atmospheric circulation- to throw a place from one side of the threshold to
another. An attempt has been made at an individual station in Scotland, to
estimate monthly PWD in retrospect, back to the middle of last century.
Since this had to be done by subtracting measured rainfall from PE computed
by formula -both, values being suspect and valid only relatively -one could
not place very great confidence in the result. It is significant that no obvious
general trend was discernible over this period (though quite incidentally it
may be remarked that the individual years 1955 and 1959 had the highest
values of PWD in the whole 104 years). Indirect evidence exists however
that significant changes in PWD could be found over the preceding cen-
centuries and these can be correlated with existing knowledge of the
changes in vegetation and agricultural practices at places near the thres-
hold.

Human interference has been referred to above, when it takes the form
of deUberate improvement of drainage for agricultural purposes, but
climatic bog can be affected by indirect improvement of drainage. Induce-
ment of increased grazing by animals, and moor-burning for various
purposes, will alter the surface sufficiently to intensify the natural effects of
short periods of PWD. The combined effects of a slow natural secular

i8 F. H.W.GREEN

increase in the annual PWD, combined with human-induced modification
of the natural surface, can often be sufficient to start spectacular erosion of
bog which had developed during a period when the annual PWD was
insignificant in amount.

REFERENCES

Alvin, p. de T. (i960) Moisture stress as a requirement for flowering coffee. Science,
132, No. 3423, 354.

MoHRMANN, J.C.J. (1959) A tentative survey of the water deficiencies in Europe and
the need of (supplemental) irrigation. Report of the Conference on Supplemental
Irrigation, Copenhagen, 1958, 25-34. (Published by the Institute for Land and
Water Management Research, P.O. Box 35, Wageningen, Netherlands.)

THE ROLE OF EVAPORATION IN THE SURFACE

ENERGY BALANCE

M.J.Blackwell

Meteorological Office, Agricultural Research Unit, School of
Agriculture, University of Cambridge

I. INTRODUCTION

During the past fifteen years, a small research group of the Meteorological
Office has been working in Cambridge on the development of methods for
the evaluation of natural evaporation from land surfaces. For much of tliis
time, the subject has been viewed as a meteorological problem in turbulent
transfer and several observational programmes have been designed to test
the physical basis of an aerodynamic equation first suggested by Thorn-
thwaite and Holzman. Although the method is vahd only for occasions
when the lower layers of the atmosphere are in the near-adiabatic state,
Hmited practical use can be made of the method if certain conditions are
observed in the siting of apparatus.

Other theoretically inspired or empirically derived modifications of this
equation have been shown to be capable of providing accurate results in
conditions other than adiabatic, but further refinement entails more exacting
observations requiring highly specialised techniques which tend to become
impracticable for routine use. Nevertheless a fundamental insight into the
nature of the physical mechanisms seems necessary if the more promising
of the simpler field techniques are to be modified to yield acceptable results
over a wide range of conditions.

In order to introduce an independent and continuous check on the degree
of success achieved by the aerodynamic method, techniques have recently
been developed for measuring the four components of the energy balance
at the surface. To handle such a vast amount of data, modern methods of
data-handUng have been introduced. The main purpose of these is to
measure gradients or profiles by digitisation on to counters, but there is an
additional facihty for computing the energy balance components directly
by means of an analogue computer.

The combination of the aerodynamic approach and the surface energy
balance control is beginning to enable us to assess the role of evaporation
under a wide range of conditions. It is hoped that the shortcomings in the
theories of turbulent transfer, which result from over-simpHfication of our

20 M.J. BLACKWELL

working models of atmospheric turbulence, will soon be determined on a
more quantitative basis.

2. TURBULENT TRANSFERCONSIDERATIONS

An attempt is made here to indicate the elements of atmospheric turbulence
theory applicable to the particular problem of evaporation, and the hmits
of practical appHcation of this theory. At the outset it should be made clear
that there are two distinct concepts of the mechanism of atmospheric
turbulent transport, one being that of continuous mixing by eddies and
the other being the classical theory of transfer in terms of the product of a
transfer coefficient and the gradient of the property concerned. Regarding
the first concept, evaporation is derived from the simple equation :

E=pw'q' (i)

where £ is the eddy flux of vapour and w' and q represent the fluctuations of
vertical velocity and specific humidity. Its simphcity suggests that other
methods are hardly necessary. Yet it is only in the last few years that
instrumental techniques and data-processing equipment have begun to
allow the potentialities of the method to be reahsed, e.g. by Swinbank
(1955) and Taylor and Dyer (1958).

The second concept was followed by Pasquill (1949) in taking the
laboratory established wind-profile law for aerodynamically rough
surfaces :

where k is von Karman's constant (0-4), tq is the surface drag or shearing
stress, and Zq is a parameter based on the characteristic roughness length of
the surface. This has been shown to apply in the atmosphere in conditions
of neutral stabihty (i.e. when there is no gradient of potential temperature).
It is convenient at this stage to introduce the stabihty parameter known as
the Richardson number :

R<=lr''^^-^ <5)

which takes values Ri<o for unstable, Ri = o for neutral and Ri>o for
stable conditions. It is found that u, logz profiles are convex to the H-axis
for Ri<o and concave for R/>o.

EVAPORATION IN THE SURFACE ENERGY BALANCE 21

Lastly, the definitions of the three coefficients of eddy transport are
given:

eddy viscosity, Km = — ^ (4)

"i

where, for practical purposes, t (the momentum flux) can be considered
effectively constant = tq

E

eddy diffusivity, Kw = — ^r- (5)

dz

where x is absolute humidity and E is the flux of vapour, also effectively
equal to Eq the evaporation at the surface.

eddy conductivitv, Kh= — -j^ T (^)

where P is the dry adiabatic lapse rate and Q is the flux of sensible heat.
The eddy transfer of momentum, water vapour and sensible heat involves
three aspects of atmospheric diffusion. Considerable progress in the subject
has been made by assuming the equahty of at least two of the diffusivities,
and sometimes of all three. Thus there is a distinction from the somewhat
analogous case of molecular diffusion, from which the mixing length
concept originally arose. Two main compHcations should be kept in mind.
For Ri ^ 0, eddy viscosity becomes comparable with molecular diffusion
as fully turbulent flow degenerates into laminar flow. For Ri <^ 0, free
convection affects the transport mechanism and might be expected to
introduce (or increase) differences between the diffusivities. Between these
extremes, it can be assumed to a first approximation that the diffusivities
are equal.

3. ENERGY BALANCE CONSIDERATIONS

With sufficient accuracy for nearly aU practical purposes, the energy balance
at the earth's surface may be expressed by the equation :

R + XE+S+Q=o (7)

where JR. is the net flux of short- and long-wave radiation, S is the flux of
heat in the ground and A is the latent heat of evaporation.

In the last few years it has been possible to place more and more confi-

22 M.J. BLACKWELL

dence in direct measurements o( R, by means of ventilated net flux radio-
meters (e.g. as described by MacDowall, 1955). Previously, solarimeters
were used to measure the short-wave components received and reflected
back from the surface; grass minimum thermometers were used to
estimate the radiative temperature of the surface, from which the upward
long-wave component was calculated; and the downward atmospheric
radiation was computed from radiation charts. The type of net flux radio-
meter referred to above permits measurements to be made under broken
cloud but not in rain. Its accuracy can approach + 5%, or a little better
with careful checks. Recently, a most promising radiometer, covered with
thin hemispherical polythene shells, has been developed by Funk (1959).
This removes the need for forced ventilation and is not affected by precipita-
tion. Its accuracy is probably of the order of + 2% and impressive measure-
ments of radiative flux-divergence have already been made. Over periods of
a day or more, the integrated radiation is as large as the total of the other
three fluxes. It is therefore of paramount importance to measure it with an
accuracy not worse than ± 2%, if energy balance checks of other methods
are to be fully effective. In recent work at Cambridge a significant, though
apparently simple, step has been made in duplicating all the sensing instru-
ments for the four components in the energy balance. In this way, con-
sistency of calibrations, efficient working of the data-logging circuits and
possible sampUng differences between neighbouring sites can be monitored
continuously. Sooner or later in this type of study, most workers are faced
with the problem of how representative their measurements are in space
and in time.

The second item in the balance concerns the flux of heat in the ground.
Here we are faced with more serious problems of heterogeneity in soil
density, specific heat, moisture and other physical parameters. As with the
radiation measurements, it has been possible in the last few years to place
more confidence in suitably calibrated soil flux-plates to record the varia-
tions of heat flux. This avoids the need to compute the flux from the
equation :

S=-Kpc^J^=ks^ (8)

dz dz

where K is the thermal diffusivity, and kg the thermal conductivity.
However, although the laborious measurement of p and c from soil samples
and the difficulty of measuring the temperature gradient near the surface
are ehminated, certain precautions must be observed. The first of these is
that two or more flux-plates should be used in series to obtain a representa-

EVAPORATION IN THE SURFACE ENERGY BALANCE 23

tive measurement. The plates should be near the surface to minimise storage
errors arising from undetected changes in the surface layers, but deep
enough to permit proper growth of grass or other cover. For many of the
larger-rooted crops it is, of course, necessary to revert to temperature
profiles, though soil flux-plates can still be used with advantage to measure
the flux at a level below the roots. In addition warning should be given
concerning the use of flux-plates near the surface in very dry conditions.
Drying out or cracking of the surface layers is then Hable to cause imperfect
thermal contact with the flux-plate, and evaporation may occur at depths
below that of the detecting instrument, giving false indications of the lack
of an energy balance.

For specialised short-term appHcations, it may be desirable to correct for
the storage term. This could be done quite accurately by invoking the
well-known exponential decrease of the ampHtude of the diurnal tempera-
ture variation with depth, and also the linear dependence of the phase lag
of temperature with depth. By comparing graphically the results of two or
three flux-plates buried at suitable intervals of depth, values of the flux at
the surface could be derived by extrapolating first for zero phase lag and
then adjusting the ampHtude in accordance with the exponential law.
Strictly, this assumes that the physical parameters for the soil are constant
with depth, but only a second-order approximation is involved here. After
initial trials have been carried out for a particular site and arrangement of
instruments, it might be possible to allow for phase lag by altering the time
scale, and for ampHtude by incorporating a correction in the caHbration
constant.

The original method of caHbration used was one described by Hatfield
and Wilkins (1950) using layers of felt as the surrounding medium. To
obtain more reaHstic conditions, the felt was replaced in turn by dry sand,
oven dried soil and finally by sHghtly moist soil. Though S is often as Httle
as a tenth o£ R, and typicaUy of the order of a fifth of i^, it becomes of
similar importance during the night when systematic errors must be avoided
if insight is to be gained into the variation of K^ under stable conditions.
The typical order of accuracy of soil flux-plate caHbrations has been about
± 20%, due largely to variations in thermal conductivity of the soil com-
pared with that of the flux-plate. To bring about a significant improvement
it has been found necessary to caHbrate in situ. For this, a caHbrating box is
placed over the site of the flux-plate, for various soil conditions, and a
constant flux is directed downwards until a steady reading is obtained.
This takes about two days to achieve and the apparatus is therefore made
self-balancing. By suitably varying the heat flux, the phase lag and ampHtude

24 M.J. BLACKWELL

reduction factor can also be determined. Again it must be stated that these
techniques are only suitable for level, bare or short grass surfaces, but these
are nevertheless the natural surfaces which must be used first for fundamental
investigations of high precision. When the theoretical, or soundly-based
semi-empirical, advances are well estabHshed, then the simpler techniques
which give satisfactory results for these surfaces can be extended to other
crops. With the developments described above, it seems possible to obtain
heat-flux measurements in soil to about ± 5-10%. This will give energy
contributions of similar absolute accuracy to the R terms.

We have now come to the main point of difficulty reached in all energy
balance studies. From eq. 7, we have :

XE+Q= -{R+S) (9)

where the sign convention is that fluxes directed away from the surface
are considered positive. The classical approach was that of Bowen (1926)
who expressed eq. 9 as :

-{R+S) = XE{i + QIXE) (10)

where QjXE is known as the Bowen ratio B. The direct measurement of Q
encounters difficulties similar to that for E, and the ratio B has therefore
received considerable study. To gain some insight into the behaviour of
B, we can substitute from eqs. 5 and 6 :

dz

where 6, the potential temperature, is used instead of T+Fz, and x is
replaced by pq.

Priestley (1959) has discussed the ratio KnjKw for varying stabiHty and
various heights near the ground. Although this ratio varies considerably,
for near neutral conditions and with approach to the surface, KnlKm and
hence KhjKw (see section 4) is very close to unity. Within these Umits then,
we have :

XB=c,f (12)

where the gradients have been replaced by finite differences. Moreover, for
land surfaces in temperature cUmates, JB is sufficiently small to enable the
evaporation to be detern-dned with much greater accuracy than that of B

EVAPORATION IN THE SURFACE ENERGY BALANCE 25
itself, since :

A (i + B) ^"'

Unfortunately, in arid regions whete accurate knowledge of evaporation
is vital, B is no longer small and KhjKw may vary widely from unity.

In several respects, therefore, we have come to regard the Bowen method
as a rough check for E, but of less use for Q, e.g. in studies of eddy conduc-
tivity Kh- Considerable discussion has taken place in the hterature, e.g.
Rider andRobinson (195 1), on why the diftusivities for heat, vapour and
momentum should not be identical when the profiles of the elements have
the same form, as this impHes that the ratios of the gradients, and hence of
the diffusivities themselves, must be constant with height. It must be
remembered however that, with the accuracy until recently possible in
measurements of the elements, the test of the identity of the profile shapes
is not very critical. Management of wet- and dry-bulb thermocouples has
always been difficult, with corresponding scatter being caused in humidity
profiles ; recording of temperature is affected by radiation and emergent-
stem errors ; while wind profiles measured with sensitive cup anemometers
have recently been shown to be much afl'ected by position errors (Rider,
i960). There is also the problem of deciding, for a particular site, whether
typical profiles have been estabhshed in the available distance upwind or
witliin a given time of measurement. Until profdes can be obtained, as a
routine, with an accuracy sufficient to determine their second derivatives,
controversy about the ratios of the diffusivities is unlikely to be settled by
this method and hopes must rest with the eddy fluctuations approach.

Although there is no simple method for measuring Q, a most promising
direct check on E has recently become available following the development
of a very large soil-balance by Morris (1959). One of these has been used
successfully at Cambridge at intervals during the i960 season, both
evaporation and dewfall being recorded satisfactorily. The soil container
carries some 2000 Kg of soil which is representative of the site and is
covered with a crop of short grass. The latter is accurately coplanar with the
natural surface, with as small an air gap as possible. The load is supported
on a triangular structure wliich in turn is supported by three levers, one of
which receives the load from the other two. In this way the total load can
be balanced by a single load from a secondary lever. Having roughly
balanced the weight of soil, changes of weight are balanced by the
movement of travelling weights, driven by a synchronous motor which
is controlled by a self-balancing optical system.

26 M.J.BLACKWELL

In the Cambridge version, movement of the secondary lever interrupts
the illumination of a photo-transistor which in turn operates the relay
controlling the drive motor. This scheme was originally developed at
N.I. A.E. and gives a saw-tooth type of record which can be read to about
± 10 g. As originally developed the soil-balance used a pen-recorder, with
consequent loss of sensitivity through friction. To overcome this the pen
and chart system can be removed and a remote-recording system instituted.
A drive taken off one of the moving weight pulleys is used to turn a hehcal
potentiometer which feeds a variable voltage to a recorder. The system has
the advantage of requiring less frequent removal of the guard plants for
chart changing.

For the derivation of £ and Q by the aerodynamic approach (historically
the first major problem of the group), wet- and dry-bulb fine wire thermo-
couples were finally adopted for measurement of temperature and huirddity
gradients or differences. These were chosen partly to facihtate future
investigations in and above growing crops where forced ventilation would
disturb the local regime, and partly to reduce radiation errors to a value
which is not only very small but also constant for each level. One new
disadvantage is the efficiency with which the thermocouples respond to
rapid temperature fluctuations. For wind profiles, sensitive cup contact
anemometers are used.

4. THE AERODYNAMIC METHOD

At this stage, we must return to the basic concepts of turbulent transfer
theory already touched upon in section 2. It follows from eq. 2 and the
definitions o£ Km and Kiv in eqs. 4 and 5 that:

provided that Kw = Km- This result was first apphed by Thornthwaite and
Holzman (1942). The analogous relation for Q:

Q_ ^V^p("2-"i)(^i-'^2) (^^)

KS

depends on the assumption that Kh = Km but has not been tested as
effectively.

For conditions when vigorous buoyancy forces are absent, the aero-

EVAPORATION IN THE SURFACE ENERGY BALANCE 27

dynamic method relies on the eddy viscosity being expressible in terms of
relatively easily measured wind profiles. In the simplest case of near-neutral
stability, we obtain from eqs. 2 and 4 that :

Km=k^Z^~ (16)

Thus from eq. 5, Pasquill (1949) was led to investigate the non-dimensional
parameter :

(17)

3m 3x ^%^

dz dz dz

If Km = Kw, then values of this parameter should equal k'^ [^^o-ij). By
determining £ from small evaporimeters and careful weighing, it was shown
that the near-neutral experimental results were grouped closely about o- 1 7.
A direct verification of the identity Kw = Km was therefore provided for
near-adiabatic conditions.

By measuring tq with drag plates,Rider (1954a) was further able to show
that the non-dimensional parameter :

,3„ ('«)

z

dz

had virtually identical values to those given by the parameter in eq. 17,
not only in neutral conditions but over a wide range of stabihties. This
makes the identity Kw = Km of general appHcation.

BothRider (i954a) and PasquiU (1949) found that such parameters varied
systematically with the departure of the wind profiles from the simple
logarithmic form of eq. 2, or with the Richardson number Ri. In general,
this stabiHty dependence can be expressed :

= fe'/(^') (19)

dzdz ^ \dz)

The major problem now facing us is the specification of the function,
f{Ri). First of all it must be remarked that wind profiles tend to approach
the simple logarithmic form near the surface, and correspondingly that
variations of stabihty or Ri become less for measurements made near the
ground. This has dominated most practical apphcations of the method
(e.g. Rider, 1954b, 1957) and it seems probable that fluxes based on the

28 M.J.BLACKWELL

formula (eq. 14) can be derived with an accuracy of about ± 20% for
typically wet seasons in this country, with a fairly small range of stability
and for periods of a few hours.

To give a practical example of the advantage of taking measurements
near the ground, Pasquill (1949) showed that the non-dimensional para-
meters of eq. 19, which we refer to as k^f[Ri), would have a two-fold
variation at a height of 37-5 cm for a corresponding ten-fold variation at
150 cm. The variation found at the lower level covered a wide range of
natural conditions, from moderate stabihty to marked instability, and is
merely another expression of the statement above that fluxes derived from
the assumption that f{Ri) equals unity would normally be in error by up to
±20%, even with the most favourable experimental arrangements, for
short-term rates of evaporation.

Returning to the definition of eddy viscosity, we must next re-examine
the behaviour of Km with stability, and hence of Ki„. It is clear that, to
explain the stabihty dependence found :

i^,n = (i^m) neutral • /(^O M

For unstable conditions, the most promising approach has been to follow
Deacon (1949) who proposed that wind profdes could be well represented
by relationships of the type:

~ = az^& [a and ^ being independent o£z) (21)

where j3 is a slowly varying parameter, close to unity, taking values ^>i,
I and <i in unstable, neutral and stable conditions respectively. Noting
the observed tendency of non-neutral wind profdes to approach the
logarithmic form (as for neutral conditions -eq. 2) near the surface. Deacon
assumed the boundary condition (n = o at z = z^ to hold in the general
case. Integrating eq. 21 and allowing for the profile tendency to approach
the logarithmic form as ^ approaches unity, he obtained the generahsed
wind profile:

Since eq. 21 is not an exact relationship, values of ^o derived from eq. 22
are found to vary markedly with stability. To overcome this difficulty, it
is customary to determine z^^ separately from neutral wind profiles and to
regard eq. 22 as determining /3 for various conditions of stability. From the
definition of Km and the generalised wind profile :

EVAPORATION IN THE SURFACE ENERGY BALANCE 29

dz

f^^HS

which implies, over the range of vaHdity of eq. 22, that

2/9-2

Because of the failure of eq. 22 in stable conditions, attributed mainly to
the fact that z^ is no longer constant in these conditions, eq. 24 cannot be
applied for Ri>o. In neutral and unstable conditions, however, there is
excellent agreement between the parameters given in eq. 19 and

'■©'"■

It is not intended to make more than a passing mention of the suggested
forms for f{Ri) under stable conditions. The best known are due toRossby
and Montgomery (1935) :

and to Holzman (1943), who gave:

f{Ri)^i-aRi (26)

This latter relation has often been used as a basis for discussing experimental
results, even for unstable conditions, for example, by Priestley (i959)-
Suggested values of ct are given in the next section.

5. PRACTICAL ASPECTS

The first modification of the formulae given in the previous section arises
when measurements are required over a crop which is tall compared with
the heights of the apparatus above ground level. This may be allowed for
by replacing z by (z-d), where J is known as the zero-plane displacement.
Rider (1954b) used the simple eq. 14, with this modification, throughout
the growing season of a field of oats. For tall crops which bend appreciably
with wind, d can change with wind speed by a factor of two as well as
varying progressively with crop height. It is determined by plotting Uz
against loge{z-d) for suitable values of (/ until a linear relation is found.
Daily evaporation from similar cropped surfaces can be obtained with an
accuracy of about 15%, there being a systematic tendency to underestimate
the water loss.

30 M.J.BLACKWELL

If, following Rider (1954b), an attempt is made to use the generalised
wind-profile method of eq. 22, it is found that the complex dependence
of d on crop height and wind speed makes it impossible to determine
Deacon's stabiHty parameter ^ with the accuracy required to give E from
the modified aerodynamic equation:

The existence of errors in readings from the present type of anemometers
must also be borne in mind. Even i % errors can produce changes in j8 of
the order of 10% and there is no doubt that we must reject any further ideas
of using tliis method over tall crops. Simultaneous measurements, with two
sets of apparatus used at different heights, again confirm the value of making
measurements at the lowest practicable height. It is unfortunate that this
requirement causes almost insuperable difficulties in determining the zero-
plane displacement and other parameters needed in the calculations.

In the present writer's opinion, one of the next steps must be to arrange
for StabiHty effects to be clearly recognisable so that the function/(Ri) can
be investigated and suitably corrected for. In addition, in the simple
aerodynamic formulae (eqs. 14 and 15) for E and Q, and in the energy
balance control checks (eq. 1 1), we may have to introduce simple ideahsed
models for the variation of KhlK-m with the Richardson number. The fact
that the use of formulae, vahd only for neutral conditions, leads to results
which have even some limited practical value, makes it seem worthwile to
introduce an equally simple and idealised stabiUty function f{Ri)- A
schematic diagram of the main results from three observational pro-
grammes, designed by members of the Cambridge group, is given in
Fig. I , together with a hue based on Deacon's eq. 24 and two Holzman-type
lines based on the Cambridge data. The latter are :

f{Ri) ^ i-isiRi (for Ri < 0) (28)

and ■ f{Ri) = 1 - ilRi (for Ri > o) (29)

These values of a are of a similar order to those found elsewhere. It is to be
expected from recent work on free convection that a fairly sharp transition
will occur between the regimes for forced and free convection.

It is perhaps surprising that Rider and Robinson's (195 1) method of
extrapolating 'aerodynamic' fluxes to zero height, or to zero Pdchardson
number, has received so httle attention in later years. This method clearly
needs careful investigation, but it is interesting that the experimental

EVAPORATION IN THE SURFACE ENERGY BALANCE 31

scatter of the results of the three programmes, shown in Fig. i, would be
fitted to a first approximation by two straight hnes, implying that the
corresponding extrapolation of the fluxes would also be linear.
Rider (1957) made further measurements over bare soil and over three

k^f(Ri)

0-9-

o-e-

0-7.

0-6-

0'5.

0-4-

0'3-

0-2'

oo«.

-400

unstable

neutral

-300

-200

t

-100

stable

k^(l - l5Ri) for Ri <0
k^{l - 7Ri) for Ri> O

• • • • results of three observational
programmes

o

100

200

300

Ri X lO-^

, 400

Fig. I. Showing the variation of eddy diffusivity with stabiHty of the atmosphere.
The simple aerodynamic formula gives ky{Ri) — const, (i.e. o- 17) • Possible modifications
are indicated by the straight lines k^{i-aRi).

different crops which were said to be transpiring at their potential rates,
and concluded that the water losses could be significantly different for the
three crops. It was found that the humidity gradients over neighbouring
crops could vary over fairly wide hmits. This work suggested re-examina-
tion of the assumption, that potential transpiration is the same for all green

32 M.J.BLACKWELL

crops which completely cover the ground, made in applications of Pen-
man's (1948) method for the calculation of irrigation needs. However,
quite apart from the short term microclimatic variations, it seems highly
probable that significant differences of surface roughness would also qualify
the assumption. Equally, depending on the roughness of a crop, evapo-
transpiration can often exceed evaporation from a smooth surface of open
water, a result which was not predicted by earher workers in the subject.
One last method, suggested by Deacon and Swinbank (1956), might
overcome some of the earlier difficulties arising from stabiUty dependence.
The surface drag coefficient Cn, defined by:

T = pCnUn^ (30)

where Un is the wind speed at the height of measurement Zn, can be deter-
mined from wind profJes obtained in neutral conditions for a given site.
Then, since Kip=Km,

^=-i^Zii (31)

T M2"""l

and substituting from eq. 30:

E=pCnUn\^^^^^' (32)

For convenience, Zn and z^ can be made identical, and Z2 chosen to be high
enough to obtain the required accuracy in the measurements. Cn does vary
sHghtly with stabiHty, but much less so than the roughness parameter Zo-
The essential feature of the method is that no assumptions are made con-
cerning the logarithmic profde law, only that the profiles have the same
form. Provided that Zn can be made sufficiently low to be independent of
StabiHty effects, eq. 32 will be vaHd for all stabilities.

6. DATA-PROCESSING

In my introduction, it was pointed out that a programme involving a
combination of the intricacies of the aerodynamic method with the
continuous control of energy balance considerations would yield a vast
amount of somewhat intractable data. The change to semi-automatic data-
processing, however, is not one which many physicists take to Hghtly since
in the first place some loss of accuracy is almost inevitable, and secondly
there are recognised stages in most experimental investigations where
discrimination, selection and rejection thought-processes are required.
These processes require the integrated experience and insight of the

EVAPORATION IN THE SURFACE ENERGY BALANCE 33

physicist and must take place before the purely numerical processes are
carried out by a suitable computer. As against this, it must be admitted that
computing aids are needed to cope with the volume of material, that
machines can be unbiased and objective in the processing of the data and
can accept a flow of data more rapidly than the human observer is able
to do.

The latter point was one of the historical reasons for the development of
the apparatus to be described. At the end of section 3 it was mentioned that,
since unaspirated fme wire thermocouples have been adopted as the
sensing elements for temperature and humidity, their output is going to
consist of rapidly fluctuating voltages, following natural eddy fluctuations
in the frequency range 0 to 100 c/s.

The obvious way to record such voltages would be to use suitably
damped galvanometers and photographic recorders. Anyone who has
attempted to analyse such records would be only too willing to take the
next step, which is to use galvanometer-digitisers or galvanometer-
amphfiers. In the original apparatus described by House, Rider and Tugwell
(i960), the former method was in fact used to produce pulses from a photo-
cell which were proportional to some simple function of temperature. The
pulses were apphed to a pulse amplifier and could then operate electro-
magnetic counters directly. The electrical contacts of the Sheppard-type
cup anemometers were used to energise quenched relays which operated
the wind counters. The original system is still used for measuring the mean
wet- and dry-bulb temperatures, but improved methods have since been
adopted for the gradients themselves.

These are now detected and ampHfied by a highly speciahsed D.C.
ampHfier which detennines the pulse rate of a blocking oscillator and so
operates the wet- and dry-bulb temperature gradient counters. At con-
venient stages in these circuits, there are conventional analogue computing
circuits which solve the psychrometric equation and also compute E and Q,
using the simple aerodynamic equation. The radiation and soil heat fluxes
are recorded by a galvanometer- amplifier which also operates counters via
the pulse-rate of a blocking oscillator. The counters are photographed at
desired intervals. The programming of the whole apparatus is determined
by a seconds-contact chronometer and uniselectors.

As previously mentioned, the sensing heads which are self-directing into
wind have now been duphcated and readings of these are either computed
once per minute to give E and Q, or integrated to give mean profiles over
desired periods, usually of an hour. In the present writer's opinion, caution
is needed in interpreting the computed values. More or less instantaneous

34 M.J. BLACKWELL

determinations of profiles or gradients will clearly be influenced by eddy
patterns which may result from temporary horizontal inhomogeneity. In
the mean profiles, for a suitable site with adequate fetch, these cross-
correlation terms effectively cancel out. Furthermore, the concept of eddy
transfer coefficients is only vahd, at best, for describing mean flow condi-
tions. Although, therefore, the means of many computed values of £ and Q
are eventually compared with the values derived from the mean profiles,
there is no a priori reason for expecting perfect agreement. It is also thought
that the periods for which the profiles are obtained should be reduced to
about 1 5 minutes to ehminate diurnal effects, and errors caused by averaging
non-linear quantities.

Prehminary results obtained over the last three seasons are still being
evaluated but the following tentative trends can be seen. In the cool, wet
season of 1958, an energy balance appeared to be estabhshed over some 80
hours of data. During the hot, dry season of 1959, an energy balance was
often not obtained during the 180 hours of recording but this could not be
expected with the much wider range of stabihty encountered, since the
original equations are based on near-neutral stabihty conditions. The use of
f{Ri) for these results is being investigated. Effects of storage in the surface
layers of the soil were of significance for short periods in 1958. Cracked soil
and evaporation in depth, mentioned in section 3 , caused difficulties in 1959.
A very important point, arising from the 1958 results, was that in many
circumstances the energy used in evaporating water is roughly equivalent to
the net radiative input (House, PJder and Tug well, i960). This was not
substantiated by the 1959 work, and it appears that the whole question
will require further investigation. It is too soon to give any definite results
from the i960 data, but among the more novel aspects are the first available
comparisons of £ (aerodynamic) v. E (soil balance), both evaporation and
dewfall being recorded satisfactorily. There are also a few soil flux measure-
ments at different depths, from which the storage error can be determined
by the method described in section 3 .

7. CONCLUSIONS

A rather over-simphfied version of the two standard meteorological
approaches to the measurement of evaporation, as followed at Cambridge
between the years 1 947-1 961, has been given as an attempt by a physicist
to describe the successes and hmitations of current theories and methods, in
the hope of giving workers in allied subjects an up-to-date survey of the
present state of knowledge.

EVAPORATION IN THE SURFACE ENERGY BALANCE 35

Apart from the special difficulties of working over tall, flexible crops, it is
thought that acceptable results can now be obtained (albeit with highly
complex apparatus) over 'ideal' sites in the absence of 'oasis' or advection
situations. This can be done by using knowledge (which is already avail-
able) of the stabihty dependence of the aerodynamic parameters described
above. With the energy balance checks and data-processing apparatus now
available, it should soon be possible to provide a standard against which the
more promising of the simpler field techniques can be compared.

ACKNOWLEDGMENTS

The writer has only recently taken over the work of the Meteorological
Office Research Unit at Cambridge and is indebted to his immediate
predecessor, Mr. J. B. Tyldesley, and to his colleague, Mr. C. P. Tugwell,
for many stimulating discussions and for access to unpubhshed results on
the 1959 and i960 seasons' work. However, the responsibility for presenta-
tion and criticism is my own. This paper is pubhshed with the permission
of the Director-General of the Meteorological Office.

REFERENCES

BoWEN, I.S. (1926) The ratio of heat losses by conduction and by evaporation from

any water surface. Phys. Rev. 27, 779-787.
Deacon, E.L. (1949) Vertical diffusion in the lowest layers of the atmosphere. Quart.

J. R. met. Soc. 75, 89-103.
Deacon, E.L. & Swinbank, W.C. (1956) Comparison between momentum and

water vapour transfer. UNESCO Canberra Sympos. Clir,iat. arid Zone, Pap. No. 2,

38-40.
Funk, J. P. (1959) An improved polythene shielded net radiometer. J. 5fi. Instrum. 36,

267-270.
Hatfiexd, H. S. & WiLiaNS, F.J. (1950) A new heat-flow meter. J. Sci. Instrurn. 27, 1-3 .
HoLZMAN, B. (1943) The influence of stabiUty on evaporation: boundary-layer

problems in the atmosphere and ocean. Ann. N.Y. Acad. Sci. 44, 13-18.
House, G.J., Rider, N.E. & Tugwell, C.P. (i960). A surface energy-balance

computer. Quart.]. R. met. Soc. 86, 215-231.
MacDowall, J. (1955) Total radiation fluxmeter. Met. Mag. 84, 65-71.
Morris, L.G. (1959) A recording weighing machine for the measurement of evapo-

transpiration and dewfall. J. agric. engng. Res. 4, No. 2, 161-173.
Pasqulll, F. (1949) Eddy diffusion of water vapour and heat near the ground. Proc.

Roy. Soc. A198, 1 16-140.
Penman, H.L. (1948) Natural evaporation from open water, bare soil, and grass.

Proc. Roy. Soc. A193, 120-145.
Priestley, C.H.B. (1959) Turbulent Transfer in the Lower Atmosphere. University of

Chicago Press.

36 M.J. BLACKWELL

Rider, N.E. (1954a) Eddy diffusion of momentum, water vapour and heat near the

ground. Phil. Trans. A246, 481-501.
Rider, N.E. (1954b) Evaporation from an oatfield. Quart. J. R. met. Soc. 80, 198-211.
Rider, N.E. (1957) Water losses from various land surfaces. Quart. J. R. met. Soc. 83,

181-193.
Rider, N.E. (i960) On the performance of sensitive cup anemometers. Met. Mag. 89,

209-215.
Rider, N.E. & Robinson, G.D. (195 i) A study of the transfer of heat and water

vapour above a surface of short grass. Quart. J. R. met. Soc. 77, 375-401.
RossBY, C.G. & Montgomery, R.B. (1935) The layer of frictional influence in wind

and ocean currents. Pap. phys. Oceanogr. 3, No. 3, i-ioi.
SwiNBANK, W.C. (1955) Eddy transports in the lower atmosphere. C.S.I.R.O. Div.

Met. Phys. Tech. Pap. No. 2, 1-30.
Taylor, R.J. & Dyer, A.J. (1958) An instrument for measuring evaporation from

natural sources. Nature, l8l, 408-409.
Thornthwaite, C.W. & Holzman, B. (1942) Measurement of evaporation from

land and water surfaces. U.S. Dept. Agric, Tech. Bull. No. 817, 1-143.

DEW: FACTS AND FALLACIES

J. L. MONTEITH
Rothamsted Experimental Station, Harpenden, Herts.

I. INTRODUCTION

When plant leaves cool at night below the dew-point of the surrounding
air they become covered with moisture, either in a surface film, or more
spectacularly in visible droplets of dew.* 'Every poet who has sung the
beauties of Nature has added his tribute to the sparkling dew drop, and
Ballantine in his widely known song has drawn a comforting lesson from
the thought that 'ilka blade o' grass keps its ain drap o' dew' (Aitken, 1885).
Lacking a sound physical basis, many ecological investigations of dew have
strayed into descriptions which belong to poetry rather than to science, and
in an extensive hterature, fact and fallacy are often confused. Their distinc-
tion is attempted here by appeal to physical theories for the dependence of
condensation on the properties of the atmosphere and of the soil.

2. CONDENSATION RATE AND WEATHER

Fluxes of water vapour at the earth's surface are governed by radiation,
temperature, humidity and wind speed ; and from analysis of the surface
heat budget, aU four variables may be combined to give a formula such as
Penman's (1948) for evaporation and Hofmann's (1955) for dew. The
Penman and Hofmann equations are formally similar, and the derivation
which follows contains elements from both.

Condensation on an isolated horizontal surface such as a leaf or a dew
gauge cannot begin until the surface is colder than the ambient air. If the
condensation rate is W (g cm ~ ^hr "i) the release of latent heat A W (cal cm "^
hr~^) will be accompanied by a transfer of sensible heat C from relatively
warm air to cooler surface. With a surface at temperature Tj (°C) surrounded
by air at temperature Ta, this transfer rate can be written

C=h{TA-Ts) (i)

* Dewdrops have often been confused with guttation, water exuded from within
the plant through leaf hydathodes. Distinguishing features were described by Long
(1958) with photographic illustration.

38 J.L.MONTEITH

where h is a transfer coefficient depending on wind speed and surface
aerodynamic properties. Ignoring a small difference between the molecular
diffusion coefficient for heat and water vapour, latent heat transfer may be
written

XW=h{eA-es)ly (2)

where Ca, es are vapour pressure in the air and at the surface(mb), and where
y ( = 0-66 mb/°C) is a constant required to make the equation dimen-
sionally correct.

The heat balance of the leaf or gauge can be written

R = XW+C+M ■ (3)

where R is the net loss of heat by radiation and Mis the decrease of internal
heat content (both in cal cm -2 hr"^). Assuming that M is neghgible and
that air in contact with the dewed surface is saturated, Tg and Cs can be
ehminated from eqs. i, 2 and 3 to give

A + y

where r= relative humidity ( ^ i)

t'^' = saturation vapour pressure

A = de^ldT

This formula is independent of the source of dew, to be discussed in
section 5. At sunset on a clear night, net radiation loss R increases and
saturation deficit e^[i — r) decreases. Condensation begins whenever R
exceeds he^{i — r)IA and continues throughout the night if the sky remains
clear. If gathering cloud reduces R below the value he j(i — rjjA , dew which
has already formed will begin to evaporate.

For a simple estimate of radiative loss from an isolated horizontal leaf,
assume that both upper and lower surfaces behave hke black bodies at
temperature T^ emitting radiation at a rate cTa'^ from each surface; that
radiation emitted from the ground beneath the leaf is oTa^; and that
downward radiation from the atmosphere is Ld = (f>-(^TA^, where ^ is a
function of vapour pressure. Net radiative loss is then

R=2aTA^-aTA*-cf>aTA^={l-cl>)aTA' (5)

In the British Isles

<;^=: o-53 + o-o65'v/e^ (Monteith, 1961) (6)

DEW: FACTS AND FALLACIES 39

and error in using this formula elsewhere will be unimportant in this
analysis.

The maximum or 'potential' rate of dew formation, found by setting
r= I in eq. 4 and eA = e^ in eq. 6 is

W = ARIX{A+y) (4a)

and is therefore proportional to radiative loss. Table i shows that potential
condensation increases with temperature from o to I5°C (because A
increases with temperature) but decreases at higher temperatures (because
radiation loss decreases with increasing vapour pressure). Over a wide
temperature range, potential condensation Hes within ± 10% of 0-067
mm/hr.

Table i
Variation of potential condensation with temperature

T(°C)

0

5

10

15

20

R (cal cm -2 hr-i)

8-7

8-2

7-6

6-8

5-8

>liy(ca]cm-2hr-i)

3-6

4-0

4-3

4-3

3-9

W (10-^ mm/hr)

62

69

73

73

68

The dependence of transfer coefficient on wind speed is needed to fmd
condensation when r<i. From measurements on the evaporation from
smaU pieces of filter paper, de Vries and Venema (1953) gave

h = 3-9F0-7 cal cm-2hr-i°C-i

where V is wind speed in m/sec, and with this value in eq. 4, condensation
rates were calculated for varying wind speed and relative humidity (Fig. i).

Equation 4 sets an upper hmit on leaf dew formation, unhkely to be
achieved in practice, even on rare occasions when the atmosphere is
saturated, because the approximate value of R in eq. 5 is a dehberate over-
estimate. First, in the spectral region 3 to 25 microns, the emissivity of
many leaves is 0-90 to 0-95 (Gates and Tantrapom, 1952) so the assumption
of black body emissivity overestimates R by 5 to 10%. Second, because
Ts< Ta, radiation emitted by the leaf wiU be less than ZaTg'^ by an amount
which can be estimated for two special cases :

Case I : isolated horizontal leaf exposed some distance above a crop
canopy which has radiative temperature Tg

R=2GTs^-aTs^-U

40 J.L.MONTEITH

Case 2 : leaf forming part of crop canopy with underlying leaves at
temperature Ta

R= 2aTs^-uTA^-Ld
^{i-<f>)aTA'-SaTA^{TA-Ts) {jb)

Writing formally

Rn=R+uf{TA- Ts): f= 4ctT^3

eq. 4 becomes

A + Y{i + iiflh)

CONDENSATION RATE
mm/hr (T= 15 'O

90 85

RELATIVE HUMIDITY 1%)

SO

Fig. I. Condensation on horizontal leaf for given wind speed and relative humidity,

calculated from eq. 4.

The difference in W calculated from eqs. 4 and 8 is approximately 0-002
n/F mm/hr for Ta between 10 and 20°C and F between 0-5 and 4 m/sec.
With these two sources of error, 'potential' condensation determined from
the simple radiation balance of eq. 5 may exceed real condensation from a
saturated air-stream by 10 to 20%.

Anticipating discussion in section 4, eq. 4 gives potential condensation
on a closed crop canopy per unit area of underlying ground and can be used to
distinguish field measurements which are physically reasonable from those
which violate the conservation of energy. Monteith (1956) found that the
rate of vapour transfer from the atmosphere to a short grass surface

DEW: FACTS AND FALLACIES 41

(dewfall) increased during the night as relative humidity rose slowly
towards 100%, and on one night reached an absolute maximum of 0-035
mm/hr shortly before dawn. Allowing for simultaneous distillation of
moisture from the soil to the grass (which could not be measured separately),
total condensation may have reached 0-05 mm/hr, close to the theoretical
Hmit. The maximum dewfall for a whole night was 0-13 mm. Dewfall
on agricultural crops was measured at Rothamsted from 1957 to i960
using a field balance designed by Morris (1959). The machine gives a con-
tinuous record of the change in weight of a block of soil 56 x 56 inches
square and 24 inches deep, carrying the same crop as the field in which
it is buried. Rumiing at normal sensitivity, the scale is too coarse for con-
densation to be measured hourly, but Table 2 gives maximum nightly
totals in milhmetres with an accuracy of about ± 0-02,

Table 2
Maximum dewfall on crops at Rothamsted (mm/night)

Spring wheat 20 May, 1957 0-26

Sugar beet 8 August, 1958 0-47

Grass (60 cm) i August, i960 0-20

These figures, and many others in the hterature, fall below the theoretical
hmit and are consistent with the predictions from Fig. i when relative
humidity is a few per cent below saturation. On the other hand. House,
Rider and Tugwell (i960), using a surface energy balance computer,
observed a maximum dewfall rate of 0-097 nim/hr over short grass. The
contemporary radiation loss was 6 cal cm"^ hr~^ and air temperature was
I5°C, giving a potential condensation rate of 0-065 mm/hr. The observed
rate is energetically impossible.

Very high dewfall figures from two independent sets of observations in
the United States are often quoted in the literature (e.g. by Went, 1955).
First, Thornthwaite and Holzman (1941), using profiles of wind speed and
vapour pressure measured to a height of 25 ft over a meadow, calculated
maximum dewfall totals of o-8 to 1-2 mm/night, barely possible energeti-
cally, and a ten-month total of 45 mm (compared with 300 mm evapora-
tion). Subsequent experience showed that the Thomthwaite-Holzman
formula is invahdated by vertical temperature gradients unless observations
are made within a few feet of the ground. AppHed to the mean gradient
over 25 ft, the formula may seriously overestimate vapour transfer on a
clear, calm night.

42 J.L.MONTEITH

Still higher values came from the lysimeters at Coshocton, Ohio (Harrold
aiid Dreibelbis, 195 1). From 1944 to 1949, annual condensation recorded on
various crops was 230 to 270 mm, and daily records showed that the
maximum condensation rate was about 0-5 mm/hr (in the early evening)
exceeding the theoretical maximum by an order of magnitude. These
figures reveal a curious failure in lysimeter performance and it is surprising
to fmd them seriously quoted as estimates of dew.

3. DEW GAUGE MEASUREMENTS

Many workers have attempted to 'measure' dew from the increase in
weight of a 'dew gauge', often a plate of metal, glass or wood of arbitrary
dimensions exposed during the night at an arbitrary height above the
ground. Such measurements are open to dangerous misinterpretation, but
useful observations are possible when the design and siting of a gauge are
guided by physical principles rather than by whim or expediency. Similar
condensation will form on a dew gauge and on adjacent (horizontal) leaves
provided their thermal and aerodynamic properties are similar, and the
following conditions should therefore be satisfied :

(a) the gauge should be a thin plate so that the area of vertical faces is
much less than the area of horizontal faces. Equations 5, 7^ and jb
are then valid ;

(b) emissivity should be close to unity. Pohshed metal surfaces are
unsuitable except when their low emissivity is exploited dehberately
(as in Hofmann's instrument) ;

(c) the heat capacity per unit surface area should be small enough to
make M<^R over the shortest period of observation;

(d) the gauge should have approximately the same size and shape as
adjacent leaves.

In saturated air, condition (d) can be relaxed because potential condensation
is independent of wind speed and surface shape. Theoretically, potential
condensation on a gauge satisfying conditions (a), (b) and (c) will be the
same as potential condensation on a crop (per unit ground area) if the gauge
is exposed close to the crop canopy but is unshaded by surrounding leaves.
The gauge designed by Duvdevani (1947) was designed primarily for
optical estimates of dew from the pattern of condensation, but it has also
been used gravimetrically. (The optical method can be used by relatively
unskilled observers with httle auxiUiary equipment, but has the serious
disadvantage that the surface properties determining the dew pattern
change after a few months' exposure.) This gauge is a block of painted wood

DEWrFACTS AND FALLACIES 43

which has an area of 5 x 32 cm and a tliickness of 2-5 cm, dimensions which
fail to satisfy condition (a). The emissivity of the paint is unknown but is
unhkely to be less than 0-9, satisfying condition (b). Assuming a specific
heat of 0*4 cal/g, heat capacity is 0-4 cal/cm^, satisfying condition (c) for
periods exceeding a few hours. The relation between amounts of dew on a
Duvdevani gauge and on underlying vegetation have not been studied
systematically, but in a short series of observations by Angus (1958) the
mean gauge deposit was o-oi mm/hr compared with o-oo6 mm/hr on short
grass. As the fdter-paper method used to absorb moisture from the grass
inevitably underestimates condensation, this agreement is good. The
duration of dew on a Duvdevani gauge and on crops was examined by Shaw
(undated report) who found that the correlation coefficient r^ was highest
when the gauge was exposed at the same height as the crop canopy and
when the canopy was completely closed. Over grass, r2 = o-93 with the
gauge at the surface, decreasing to o-8o at a height of 50 cm and to 0-74
at 100 cm. With the gauge at the crop surface, r2 = o-98 for soybean and
0-96 for maize. These results suggest that observations of the duration of
dew on a correctly exposed Duvdevani gauge, or on any simple surface
satisfying the first three design criteria, may be useful in plant disease studies ;
but there is obviously no advantage in using such a gauge unless it is self-
recording.

Maximum dew deposits measured with various dew gauges were
reviewed by Hofmaim and by Jones (1956). Values in Table 3 support the
conclusion from Table i that potential condensation is virtually independent
of cHmate. The largest values are equivalent to about 7 hours maximum
condensation from a saturated atmosphere but the real period of dew forma-
tion was probably 10 to 12 hours with a correspondingly lower rate of
condensation when the atmosphere was unsaturated.

Table 3
Maximum dew on artificial surfaces (mm/night)

Israel

0-45

Jamaica

0-43

England, south

0-43

Germany, Munich

0-43

Germany, Baltic Coast

0-37

Moravia

0-25

France, Montpellier

0-22

U.S.S.R., Moscow

0-22

Rumania

0-17

44 J.L.MONTEITH

Empirical formulae for the dependence of gauge condensation on
physical properties and exposure were presented by Suzuki (1944)-

4. DEW ON NON-HORIZONTAL SURFACES

By definition, potential condensation on a surface is independent of
aerodynamic properties and is proportional to radiative loss (eq. 4^). When
the surface is horizontal this loss can be calculated from a simple empirical
formula (eq. 6) and, in practice, the same formula is vahd for a crop with
horizontal dimensions much greater than the vertical irregularities of the
canopy. The crop may then be treated as an infinite surface with total
emission and absorption independent of surface contours. Isolated plants
and trees have surfaces which are not horizontal and their radiative loss is
found by integrating R{9) cos {e-ijj)^e AS where R{e) is the net loss of
radiation from a horizontal surface at zenith angle 6, and d5 is an element
of surface with zenith angle ifj. If this integral exceeds the radiative loss
from a horizontal surface with the same projected area by a factor p,(>i)
potential condensation per unit projected area will be

W=pAR^l'\{A^-y) (9)

where R^ is evaluated for a horizontal surface (jp=i)- Theoretical values
of p will be given for a cylinder, cone, and hemisphere.

(i) Vertical cylinder.

According to Linkc (quoted by Hofmann), R{e) is proportional to
cos"0 and n:=o-4 at e^ = 9 mb. For a vertical cylinder with height x and
diameter d, evaluation of the integral gives

p=i+i-6xjd (10)

The approximation that R is independent of d{n = 0) gives

p=i + 2xld (11)

The data in Table 4 arc from Hofmann's review of observations by
Hiltner. Agreement is less close for other species.

(2) Cone with base on ground

A simple analytical solution for non-integral values of n is unobtainable.

With » = o, base diameter d and slant height /

;, = 0-5 + lid (12)

and comparison of eqs. 10 and 1 1 shows that this expression will over-
estimate potential condensation.

DEW : FACTS AND FALLACIES 45

Regularly spaced heaps of stones cover several hillsides in the Negev
region of Israel. It is generally agreed that they were built by Nabatean
communities about the first and second centuries a.d., and that their pur-
pose was agricultural; their Arabic name is teleilat el einab, 'the hillocks for
grapevines' (Glueck, 1959). Tadmor and others (1957) discounted a sugges-
tion that the teleilat were built to collect dew, on the negative evidence
that no plant material has yet been found within them. Assuming from
present dimensions that the teleilat were originally conical with a diameter
of 3 m and a height of about 1-2 m, then p= 1-15. The maximum yield
from a saturated atmosphere at a temperature of 20°C would be about
0-5 htres per hour and, allowing for unsaturation in the early evening,
condensation may have reached 2-3 htres per night. If dewy nights were
frequent this would be sufficient to maintain several small plants with their
roots beneath the stones.

Table 4

Theoretical and measured values of p for single plants of geranium
and bean (after Hofmann)

Geranium

Bean

X cm

25

125

d cm

18

30

p from eq

10

3-2

7-2

p from ratio of dew

on

plant

to dew

on gauge

4-1

6-6

Gigantic stone piles on the hills above the port of Theodosia in the
Crimea had roughly the same shape as the teleilat, but their height was
10 m and their diameter 24 to 30 m (Hitier, 1925). Maximum yield,
calculated from potential condensation and p= 1-15, is about 300 litres per
night. From the size of the aqueducts leading from the cairns to the famous
fountains of Theodosia, Zibold estimated the yield from each to be 55.400
Htres per day: dismissing dew as totally inadequate, the only alternative
mechanism for moisture collection is the interception of fog and cloud
droplets. On Table Mountain, the annual mean fog precipitation is 3-75
mm/hr (Nagel, 1956) and, assuming the same figure for Theodosia, each
cairn could have produced about 12,000 Htres per day in favourable
weather.

At MontpeUier in the south of France, L. Chaptal attempted to estimate
the yield of the Theodosia cairns by building a miniature version in the

46 J.L.MONTEITH

form of a pyramid of calcareous stones with base 3x3m and height 2-5 m.
During summer months, the amount of water collected daily was between
I and 2-5 Htres consistent with present calculations. At Dakar, attempts to
exploit this simple method of obtaining water from the atmosphere appear
to have been unsuccessful (Lejeune and Savornin, 1958).
(3) Hemisphere with base on ground.

With // = o, p= 1-5, independent of size.

Two fallacious conclusions have been drawn from the observation that
dew on isolated plants (expressed on the basis of ground area) often exceeds
condensation on a gauge. The first is that condensation on a field crop can
be estimated by multiplying gauge condensation by a 'plant factor'
equivalent to p and determined from dew measurements on an isolated
plant of the same species. For example, Ashbel (1949) apphed Hiltner's
factor for beans {p = 6) to dew gauge measurements in the Negev, obtaining
an annual dew total of 10-25 cm. A more acceptable estimate for the region
is 10-25 mm (Gilead and Rosenan,i954). Hofmann quotes similar examples
and shows that in unsaturated air, p may vary from zero to infinity depend-
ing on the variation of relative humidity with height near the ground. The
variabihty of 'plant factors' v^^hen the atmosphere is unsaturated makes
them worthless in ecological studies of dew.

The second fallacy is that the net water loss from isolated and heavily
dewed plants is less than from plants of the same species in a closed com-
munity. Incoming radiation received by an isolated plant during the day
always exceeds the radiation falUng on a plane surface covermg the same
groimd area, and when there is no physiological control, transpiration is
greater than from the equivalent area of a closed canopy. Because potential
evaporation is normally much greater than potential condensation, the net
water loss from an isolated plant will then be greater, not less, than the
loss from a closed canopy covering the same ground area.

The effect of plant spacing on dew may become important for xerophy tic
species when transpiration rates are comparable with potential condensa-
tion. Deacon and others (1958) suggested that the natural habit of desert
species growing in isolated clumps may represent an optimum spacing for
maximum dew, but there is no experimental evidence for this hypothesis.

5. SOURCES OF DEW

Controversy over the source of dew is more than two thousand years old,
and in 1929 it reached the pages o£ Nature. Theories of rising and falHng
dew both received support, but Simpson (1929) stifled further correspon-

DEW : FACTS AND FALLACIES 47

dence with the categorical statement that : 'Dew is nowhere until it appears
on the surface (of plant leaves) : it therefore neither rises nor falls.' It was
legitimate to adopt this standpoint in section 2 where the rate of dew forma-
tion was calculated without reference to initial sources of water vapour,
but their differentiation is important ecologically.

The immediate source for condensation on plant leaves is water vapour
in the surrounding air, but for continuous condensation throughout the
night this vapour must be replaced from the free atmosphere, from the
soil, or from both. Distinguishing terms are 'dewfall', for the downward
flux of water vapour from the atmosphere; and 'distillation', for the
transfer of water vapour from relatively warm soil to cooler leaves. Both
dewfall and distillation are diffusion phenomena with fluxes which can be
represented formally by the product of a vapour pressure gradient and a
transfer coefficient Kw (cm^/sec). For dewfall, Kw is a coefficient of turbu-
lent diffusion, determined by wind shear and atmospheric stability. Several
metres above the ground on clear nights its order of magnitude is 10^. In
contrast, characteristic values o£ Kw for distillation on short grass are close
to the value for molecular diffusion, 0-24 cm^/sec (Monteith, 1956).
Although respective transfer coefficients differ by four orders of magnitude,
dewfall and distillation fluxes are often comparable, and their theoretical
ratio may be estimated from the surface heat budget.

In Fig. 2, showing relevant fluxes, the wavy line represents a closed crop
canopy at a lower temperature than the underlying soil. Sensible heat
transfer C is now split into two components, Ca from the atmosphere, and
Cu from the soil. Similarly, the latent heat flux has components XWd
(dewfall) and XWu (distillation). Corresponding temperature and vapour
pressure profiles are shown in papers by Long (1958) and Penman and
Long (i960). Within the soil, the main mechanism for heat transfer is
conduction at a rate G, and latent heat transfer, normally a small fraction
of G, wiU be neglected. When the moisture content of the soil is suffi-
ciently high for the soil atmosphere to be assumed saturated (see Fig. 3),
and when the free atmosphere is also saturated, the ratios XWalCa and
XWulCu depend on temperature alone, and at surface temperature Tg

XWulCu = XWalCa = ^{Ts)ly (13)

The heat balance for the crop canopy is

R=Wa+Cd+lVu+Cu (14)

and for the soil surface is

G=Wu+Cu (15)

48 J.L.MONTEITH

(Penman and Long showed that a crop may gain heat from the soil radia-
tively at a rate comparable with C„ : here the term R includes this exchange.)
Combination of eqs. 13-15 then gives

WdlWu=RlG-i (16)

The theoretical Hmit G=R is observed when the atmosphere is so calm
and stable that atmospheric fluxes of heat and vapour are both neghgible.
Then lVd=o; I^M = (AR/A(A + y)). With incrcasmg wind speed, turbulent
transfer rates increase and soil heat flux decreases. Theoretically, when

Cd

CROP
CANOPY

Fig. 2. Heat balance of crop canopy. For symbols, see text.

G->o, lVu->o and H^<i^(AR/A(A + y)), but this condition is never met in

nature.

When Wd and Wu are both fmite, the ratio R/G depends on the relative
thermal properties of soil and atmosphere. Relevant parameters for the
soil are volume heat capacity p^c^ (cal/cm^) and thermal diffusivity k
(cm2/sec) ; and for the air, volume heat capacity p-zc^ and the turbulent heat
transfer coefficient Kjy (cm2/sec) . Priestley (1959) showed that the assump-
tion of constant k and Kh, though far from reahstic, gives satisfactory heat
flux ratios if their values are chosen 'some distance from the surface', and
he derived an expression from which

RIG

Pl^lVx

(17)

DEWrFACTS AND FALLACIES 49

Equation 17 is valid only when there are no latent heat fluxes, but a similar
expression can be obtained for an isothermal saturated atmosphere, assum-
ing equahty o£ Kw and Kh, and using eqs. 13 and 16 to give

^,/^,^/^^^^Vt^^(f^/y)^ (18)

Frankenberger (1955) determined Kh at 30 m for wind speed (at 10 m) in
classes o-i m/sec, etc., and from Priestley's tabulation of piCj, a value of
0-04 c.g.s. units is appropriate for moist soils. Using these data, RjG values
calculated from eq. 17 are in good agreement with field measurements at
Rothamsted (Monteith, 1958), and the same data were used to compute the
values of WajWu in Table 5.

Table 5

Variation of dewfall/ distillation ratio with wind speed F (m/sec at 10 m) : saturated air,

temperature io°C (eq. 17)

V

O-I

1-2

2-3

3-4

4-5

WalW,

0-20

0-50

0-79

1-3

1-5

The predicted variation of the dewfall/distillation ratio with wind speed has
not been directly tested, but is consistent with measurements over very
short grass referred to the wind speed at 2 m (Monteith, 1956). When the
wind dropped to 0-5 m/sec or less, dewfall was a negUgible fraction of
distillation. With wind about 2 m/sec, dewfall was maximum at about
0-03 mm/hr, and the value of Waj Wu estimated from radiation and
temperature data was 1-5, consistent with a wind of 4-5 m/sec at 10 m.
Dewfall/distillation ratios will normally be much less than the theo-
retical value of eq. 1 8 because it is uncommon for the air above a crop to be
saturated at night without fog. Both leaf temperature Tl and the dew-point
temperature Td of the surrounding air decrease from mid-afternoon
onwards, whether dew is forming or not. When the wind is very light,
Tl falls more rapidly than Td\ and at sunset, or even before, condensation
begins when Tl= Td- The removal of water vapour as dew helps to keep
the air slightly unsaturated (relative humidity 96-99%) but, after further
cooling of the air by radiation, saturation is reached and fog appears. With
stronger wind, theoretically more favourable for dewfall, Tl approaches
Td more slowly and condensation may not begin until several hours after
sunset. Radiative cooling of the air is neghgible ; relative humidity near
the ground remains between 96 and 99%, increasing slowly throughout the

50 J.L.MONTEITH

night ; and the potential dewfall rate is never reached. In practice, the dew-
fall/distillation ratio does not increase systematically with increasing wind
speed but reaches a maximum at some optimum value, about 2 m/sec at
3 m over short grass. Gravimetric measurements of dew in south-east
England and in Victoria, Austraha (Mcllroy, private communication) show
that distillation is normally the dominant component of dew on agricultural
crops.

Some workers expose dew gauges at different heights above the ground
and infer the source of dew from its variation with height. This interpreta-
tion is invahd. The so-called 'dew gradient' depends on the vertical
distribution of temperature, humidity, and wind speed, and is not uniquely
related to the direction of vapour transfer.

The distinction between dewfall and distillation is relevant to studies of
plant water balance. Dewfall on plant leaves is a real accretion of water in
rainless weather, it is the only significant mechanism for transferring
moisture from the atmosphere to the soil/plant system. Distillation is a
redistribution of water within this sytem. Transpiration losses arc neghgible
v/hile dew is evaporating from plants, but the evaporation rate from wet
leaves is normally somewhat greater than the corresponding rate of
potential transpiration from dry leaves. Dewfall decreases the extraction of
soil moisture by plant roots, whereas distillation increases soil moisture
depletion by providing a short-cut for the transfer of water from the soil
to the atmosphere.

6. ABSORPTIONOF WATER VAPOUR

The uptake of water vapour by plants and by dry soil without the formation
of visible water has been called 'liidden dew' and 'occult condensation',
names which obscure an important thermodynamic difference between
condensation on a plane surface and absorption by a hygroscopic medium.
When water vapour condenses, latent heat is released and the condensation
rate is Umited by the rate at which this heat can be removed to prevent an
increase of surface temperature. When water vapour is absorbed both latent
heat and 'free energy' are released but the direction and rate of vapour
transfer are determined by the potential gradient of free energy rather than
by the availabihty of a heat sink. Absorption may be accompanied by a
shght rise in temperature from the 'heat of wetting'. The fundamental
unit for free energy is ergs/g but it is more convenient to use the equivalent
gravitational potential H expressed in metres. For water in the atmosphere,
plant, or soil H<o.

DEW: FACTS AND FALLACIES

51

The free energy of atmospheric water vapour Ha is related to relative
humidity and absolute temperature by the equation

H^ = 47oT(-lnr)

= -i-38.io*hir atr=293°K

(19)

and Fig. 3 shows equivalent scales of — Ha and r. In leaf cells (assumed
completely vacuolated), the free energy deficit { — Hl) is the difference
between the osmotic potential energy of the vacuolar fluid and the elastic
potential energy of the ceU wall, a quantity known to physiologists as

region oF rapid
absorption fronn
saturated air

<^'^y so,i

sandy

Fig. 3. Variation of water potential with soil moisture (per cent dry weight) for two
idealised soils. The horizontal axis shows the relation between water potential and
equilibrium relative humidity. The water potential of the clay soil at S% moisture
content is about — 100 m and absorption of atmospheric water vapour would occur
only when relative humidity exceeded 99%-

diffusion pressure deficit (DPD). The water deficit of plant leaves after a
period of transpiration is normally met by the transfer of water from other
parts of the plant and ultimately from the roots; but the direct uptake of
atmospheric water vapour through the cuticle is possible when Hl<Ha-
Leaves at the conventional '15 atmosphere' wilting point {Hl= — i55 i"^)
will absorb vapour from an atmosphere with relative humidity exceeding
98-8%, and for a plant surviving at Hl= - i 120111 (Slaty er, 1958) absorption
is possible when the relative humidity is 92%.

The free energy of soil moisture Hs is determined by its salt concentra-
tion and by the radius of the largest water-occupied pores. At the soil
surface, and in the neighbourhood of plant roots, Hs decreases during the
day as moisture content decreases. The condition for uptake of atmospheric
water vapour during the night is Hs<Ha.

52 J.L.MONTEITH

Normal transfer of water through plants from the soil to the atmosphere
requires

Ha<Hl< Hs

By imposing the reverse gradient

Hs<Hl< Ha

in the laboratory, Slatyer and others demonstrated the absorption of vapour
by the leaf cuticle and the simultaneous transfer of water to the roots.
Further transfer from roots to soil is theoretically possible but the experi-
mental evidence is ambiguous. In Slatyer's experiments with one-year-old
Pinns echinata seedhngs, water vapour was absorbed when the atmosphere
was held saturated (H=o) or with relative humidity 98-8% {H= -155 m).
With strict temperature control ( ± o-ooi°C) there was presumably no leaf-
air temperature difference and therefore no condensation of hquid water
on the plant leaves. In nature, plant leaves are usually cooler than the
atmosphere by i or 2°C during the night, so condensation begins when the
relative humidity rises to 96 or 98% (Fig. i). Unless H is exceptionally
low (< — 300 m) condensation will precede and preclude cuticular absorp-
tion of vapour. The only species Hkely to benefit from vapour absorption
are those which can survive extreme water stress. For example. Stone,
Went and Young (1950) found that a Pinus coulteri seedlmg growing in soil
unwatered for ten months could absorb vapour from air with relative
humidity below 90%, implying H< - 1400 m.

Exposed to bright sunsliine, surface soil may dry to very low values of H,
say to -10^ m in equilibrium with air at relative humidity 48%, and
subsequent absorption of vapour at night is common. In a study of vapour
uptake by Indian soils, Ramdas and Katti (1936) found that the moisture
content in the surface layer of a 'black cotton soil' increased from 2-6% dry
weight in the afternoon to 7-7% in the early morning. Damagnez (1958)
measured absorption rates of 0-15 mm /night and showed that for given
atmospheric conditions, uptake was greater at lower soil moisture contents.
At Rothamsted, maximum absorption by fallow soil (a clay loam) was
0-6 mm/night, measured with the field balance on May 6, 1957.

Most of the moisture absorbed by a dry soil is held at levels of free energy
far below those available to plant roots (Fig. 3). Because tliis moisture cannot
subsequently be absorbed by roots, it makes no direct contribution to plant
water economy; but plant transpiration may be shghtly reduced for a few
hours after sunrise while absorbed moisture evaporates from the soil

surface.

Confusion over the relationship between soil moisture and the relative

DEW: FACTS AND FALLACIES 53

humidity of the soil atmosphere has led some workers to study the con-
densation on artificial surfaces buried within the soil. Such observations are
irrelevant to the water economy of plant roots.

7. DEW AND PLANT GROWTH

In purely physical aspects of dew formation, it is relatively simple to
distinguish fact and fallacy. Stone's (1957a) review showed that the
biological picture is less clear because there is so httle relevant evidence
from the field. Dew is known to promote the spread of plant disease by
providing a suitable environment for plant pathogens (Duvdevani, 1946) ;
but when there is no potential disease, many farmers and gardeners beheve
that dew stimulates the healthy growth of plants in dry weather. Duvdevani
(1957) claimed that the yield of cucumbers exposed to dew was 50%
greater than from undewed controls, but experimental details have yet to
be published.

In countries where little rain falls during the growing season, there are
two ways in which dew may contribute to plant water economy (Slatyer,
i960) : the evaporation of dew from leaves may reduce transpiration in the
early morning; and foliar absorption during the night may reduce local
water deficits and accelerate growth. For purely physical reasons, the
decrease in transpiration after dew is unlikely to benefit mesophytic plants
because in cloudless summer weather the ratio of potential condensation to
potential evaporation is (very roughly) i : 7 in a humid chmate and i : 14 in
an arid climate. Dewfall evaporates within a few hours of sunrise and plants
with inadequate soil moisture reserves endure severe water stress for the
hottest part of the day. The hfe of a plant not adapted to such stress may be
prolonged for a few days wliile dew nights are frequent, but death is
inevitable in the continued absence of rain. For desert plants, dewfaU which
cannot be absorbed is a luxury : none of the mechanisms by which xero-
phytes conserve moisture require the presence of liquid water on the
external organs.

Data for dew absorption (Lehmann and Schanderl (1942); Arvidsson
(195 1); Waisel (1958) and others) show wide differences between species,
attributable to differences in cuticular permeabihty and in the free energy
deficit of leaf cells. Distinguishing carefuUy between the nocturnal uptake
of moisture from the soil and from the atmosphere, Waisel found that
average saturation deficits* o£Pinus halepensis and Oka enropaea were

* Now using the term in its physiological sense: loox (saturated leaf weight —
actual leaf weight)/saturated leaf weight.

54 J.L.MONTEITH

Evening: 19%

Following morning: dewed 10%

undewed 17%

The measurements were made during September 1954 in Jerusalem after
several months without rain. A further experiment showed that dew
absorption increased the leaf water content of Ceratonia siliqua saplings
exposed to drought by 10% during the night, whereas the increase for
irrigated saplings was 7%. These figures suggest that the absorption of
dew by plants growing in dry soil may usefully supplement the absorption
of soil moisture, but Waisel emphasised that dew absorption was never
sufficient to restore full leaf water content. Stone (1957b) showed that when
seedlings oiPinus and other forest species grew in soil with moisture at the
wilting point, hfe could be prolonged for several weeks by spraying the
foHage with artificial dew.

The effect of dew on photosynthesis has not yet been studied in the field
but there is convincing laboratory evidence, recently reviewed by Stocker
(i960), that when leaves subjected to severe water stress are subsequently
wetted, the photosynthetic rate increases rapidly. As an example of
recovery from sub-lethal stress, Montford and Hahn (1950) found that when
leaves of Caltha palustris were dehydrated to 59% of their normal water
content, photosynthesis increased within two hours of wetting to 40% of
the value for controls. Synthesis of similar laboratory studies with field
measurements of the Waisel type is needed to estabhsh the significance of
dew absorption for plant metabohsm.

On the available evidence it is unhkely that dew is of great physiological
importance, either in humid cHmates or in the desert. Where rainfall is
marginal, there may be a few species which grow and reproduce more
vigorously when their leaves are frequently wet at night. At least three
plants of economic importance -cotton, pineapple and melon- are reported
to yield well in climates where there is little rain but abundant dew, but a
causal relation between dew and growth, exploitable in arid zone agricul-
ture, has yet to be estabUshed.

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tanten olandischer Pflanzenvereine nebst Bemerkungen uber Wasserabsorption

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DEW: FACTS AiSfD FALLACIES 55

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291-297.
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Lejeune, G. & Savornin, J.(i958) Recovering water-vapour from the atmosphere.

Trans. International Conference on the Use of Solar Energy, 3, 1 38-141.
Long, I. F. (1958) Some observations on dew. Met. Mag. 87, 161-168.
MoNTEiTH, J.L.(i956) Dew. Quart.]. R. met. Soc. 83, 322-341.
MoNTEiTH, J. L. (1958) The heat balance of soil beneath crops. UNESCO Arid Zone

Research, XI, 123-127.
MONTETTH, J.L.(i96i) An empirical method for estimating long-wave radiation

exchanges in the British Isles. Quart.]. R. met. Soc. 87, 171-179.
MoNTFORD, C. & Hahn, H.(i95o) Atmung und Assimilation als dynamische Kenn-
zeichen abgestufter Trockenresistenz bei Famen und hoheren Pflazen. Planta, 38,
503-515-
5

56 T.L.MONTEITH

Morris, L. G. (1959) A recording weighing machine for the measurement of evapo-

transpiration and dewfall. J. agric. Engng. Res. 4, 161-173.
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Penman, H. 1.(1948) Natural evaporation from open water, bare soil and gra^s. Proc.

Roy. Soc. A193, 120-145.
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Ramdas, L.A. & Katti, M.S. (1936) Agricultural meteorology: Studies in soil

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Shaw, R.H. (undated) Observation of dew deposition on various types of cover.

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Book of Agriculture. ^

THE EFFECT OF DISSOLVED SALTS ON
WATER MOVEMENT

D.A.Rose

Rothamsted Experimental Station, Harpenden, Herts.

If plants are to survive drought they must have a source of water available
near the roots, and to be of use the source must also be accessible. Because
root extension is not unhmited, at some stage the water must move to the
roots, and the flow wiU be governed by the product of a conductivity and a
potential gradient (cq. 5). Full understanding of 'drought resistance' needs
detailed study of both conductivity and potential, and in real soils there is
great complexity arising from sweUing and shrinking during wetting and
drying. In the present note the complexity is avoided by concentrating on
the behaviour of a rigid matrix.

TOTAL POTENTIAL OF WATER IN A POROUS

SYSTEM

There are several possible components that can make up the total water
potential in a porous system, but only two arc important in the present
context. First there is the inatric potential, which the water possesses because
it is held in a framework of fme pores, and arises from capillarity (dominant
in wet media) and physical adsorption (dominant in nearly dry media). In
the wetter media there is a curved meniscus separating water from air, the
radius of curvature (r cm) being determined by the size of pore the meniscus
occupies. Standard theory shows that the hydrostatic pressure in the water
is less than that of the atmosphere by an amount zS/r in absolute units,
where S dyne cm"^ is the surface tension of water. This pressure deficit can
be defined as the matric potential in a convenient practical unit, the height
of water column h cm required to product this deficit, when

I ^^ / \

n= — era (i)

pgr ^ '

where p gm cm-^ is the density of water, and^ cm sec~^ is the acceleration
due to gravity. Note that the meniscus is a perfect semi-permeable mem-
brane : water molecules can pass across it freely but solute molecules cannot.

58 D.A.ROSE

The second important component arises from the presence of such solutes
and is an osmotic or solute potential that becomes important for water
movement through semi-permeable membranes such as plant roots or a
water surface from which there is evaporation. Over the meniscus of a salt
solution the vapour pressure is less than it would be over a meniscus of pure
water or over a plane surface of solution, and the decrease below what would
exist over a plane pure surface is a measure of the total potential :

ip — — In —cm (2)

5 Po

where tp cm is the total potential, R erg gm"^ °C "^ is the gas constant per
gm of water vapour, p is the vapour pressure over the meniscus, and po
is the value it would have over a plane surface of pure water at the same
temperature T°K.

Note that p/p^ is the equihbrium relative humidity, never greater than
unity, and so (/» is either negative or zero. Thus tp has the same sign as h, and
may be split into components

0= /j+7Tcm (3)

where tt represents the osmotic potential. It too is negative. The osmotic
potential is proportional to the solute concentration m, so eq. 3 may be
rewritten

ip = // + Amcm (4)

where A = 4-73 x 10* for NaCl when m is measured in molal units. The partial
specific Gibbs' free energy of the water is then gip erg gm~\ while
Schofield's pF = logiQ { — ^)-

The matric potential can be measured by tensiometer, suction plate,
pressure plate, or pressure membrane devices : the total can be measured by
freezing point determinations or by a variety of vapour pressure techniques
such as that of Monteith and Owen (1958).

MOVEMENT OF WATER

If a gradient of potential exists, water movement can be expressed by the
relation

,=^4^=-Av^ (5)

where Q/f gm sec ~* cross an area A cm^ normal to the direction of flow
when moving under the total water potential gradient V<A. Equation 5

EFFECT OF DISSOLVED SALTS ON WATER MOVEMENT 59

defines k cm sec"\ the capillary conductivity of the water in the medium,
hi soils free from solutes there is general agreement that both hquid and
vapour move under a potential gradient V<A=v/j because 7r=o, vapour
movement having been treated theoretically by Phihp (1955). When
solutes are present, however, there are differences of opinion as to their
effect on water movement.

Edlefsen and Anderson (1943, pp. 278-280) consider that an osmotic
potential gradient along a soil column will lead to water movement
before the solute concentration gradient has been brought to zero by ionic
diffusion. In contrast, Richards and Weaver (1944) observe that, if a tensio-
meter is fdled with distilled water and the manometer allowed to attain an
equihbrium reading with the porous cup standing in distilled water, then
almost no change in pressure (less than 0-003 atm) is registered when
saturated NaCl solution is substituted for the distilled water surrounding the
cup. They state that 'in the absence of semi-permeable membranes moisture
flow is produced primarily by gravity and gradients in soil-water tension,
and not directly by solute concentration gradients'. Schofield (1952) also
expressed the view that 'two distinct processes are involved in water move-
ment, (a) bulk flow of the solution governed by its viscosity and one aspect
of the geometry of the pore space, and (b) diffusion (of the water and solutes
in opposite directions) governed by the diffiision coefficient and a different
aspect of the geometry of the pore space'. Low (1955), from a thermo-
dynamic treatment of the equihbrium and movement of soil water,
predicted that osmotic potentials would act as negative hydraulic pressures
in influencing water diffusion. His equation was tested on clay suspensions
and shown to be vahd, but the measured osmotic potentials were much
lower than theoretically calculated values.

The following analysis assumes that vapour moves under the total water
potential gradient V >Jj, but that hquid moves only under a matric potential
gradient V h.

THEORY OF THE DIFFUSION CELL

Consider the system ABODE (Fig. la), consisting of a porous block BCD
between air gaps AB, DE, with water potentials ip^, ip^, W, ^g, ifj^ imposed
such that )Ai>i/'2 >^>h>'p4. and</ri + )A4 = )/'2 + 'A3 = 2'^. In the steady
state under these conditions the flux of water is uniform, either as vapour
distilling across the air gaps AB and DE or as hquid diffusing through the
porous sample BCD. In practice, A and E are pads of fflter paper saturated
with NaCl solutions of concentration m^ and ttiE respectively, and BCD

6o

D.A.ROSE

is a block of porous stone containing NaCl solution of concentration
mQ='h{tnA + mE). At the outset the solute is redistributed in the sample, the
concentration m^ at B decreasing, and concentration m^ at D increasing,
until a steady-state solute profde is attained when the transfer of solute ions
by mass flow of the water from B to D is balanced by a counterflow due

Q

B . . . C,

, . . '
I

• ■ • I

Q_i

vopour

2

X=-l

liqluid

x=-o

Q

vopour

%

Fig. la. Theory of diffusion cell.

to ionic diffusion from D to B. This is the case of water transfer through a

semi-permeable membrane (the air-water interface). If it is assumed that:

(i) Hquid movement occurs solely under the matric potential gradient,

(ii) there is equihbrium of the solute,
and (iii) steady state conditions obtain,

then, at any plane in the region -/<.v< + /, the left-to-right transfer of
solute is qm, and the right-to-left transfer is D,(d;«/d.v) where

c[ cm sec^^ is the velocity of Hquid flow, governed by the matric

potential gradient,

m is the molal concentration of the solute at the plane,
and D, is the coefficient of diffusion of the solute molecules through the

pores of the medium. At equilibrium,

or

m

dHi

= -oexp(g)

(6)

(7)

where m^ is the concentration at C (.v = o).
Hence, at B (.\"= — /),

h2 = ^2- ^"h = 'A2- '^'"o exp {- ^J
andatD(x= +/),

EFFECT OF DISSOLVED SALTS ON WATER MOVEMENT 6i
The matric potential difference across the block is

/i3-/j2 = (iA3-^2)-A'"o{expUl^j-exp( -1-jj (8)

and, anticipating that ql/Dg will be small, this reduces to

^3- K = (!A3-</'2)-2Amo^//D« (9)

In the steady state

q=k{h^-h^l2l (10)

where k cm sec~^ is the true capillary conductivity of the porous system.
In the experiment the total potential difference is measured, from which an
apparent conductivity, k' is calculated

q=k'{^s-^,)l2l (II)

Combining equations 9,10 and 1 1

I I Xnin , »

At a given moisture content -and so far there has been no assumption
about the degree of saturation of the porous system-a plot oiijk' against
niQ should yield a hne of slope A/Dg, intercepting the axis at ijk.

The most convenient check of the analysis is at saturation, when it is to
be expected that the rate of diffusion of ions through the pore space,
expressed as a fraction of the rate in free water [DslDso say) will be the
same as the corresponding ratio {D/Dq) for gaseous diffusion through the
same system when completely dry.

EXPERIMENTAL

Measurements were made in sealed brass diffusion cells. Fig. ib. The porous
sample BCD is held between an evaporating source A and a condensing
sink E, separated from them by fixed air gaps maintained by spacing rings
F of piano wire encased in polyvinylchloride insulation sleeving. The sam-
ples used were circular disks, 5 cm diameter, approximately i cm thick, of
porous building stones, kindly supplied by the Building Research Station.
The source and sink are pads of filter paper saturated with NaCl solutions
at concentrations chosen to match the water potential in the sample so that
equal fluxes of water vapour distil from the source to the upper surface of
the sample and from the lower surface of the sample to the sink, the moisture

62

D. A.ROSE

content of the sample thus remaining constant. All measurements were
made in a thermally insulated box in a constant-temperature room, and
possible temperature gradients across a cell were minimised by maintaining
metal-to-metal contact around a cell by inserting each into a G-clamp.
Each experiment lasted for 24 hours during which temperatures were kept
constant to within o-i°C at 25°C. Total vapour transfer was about 100 mg
day"\ i.e. q is of the order of 5 x 10 "^ cm sec~^.

A

B

D
E

Fig. lb. The diffusion cell.

Knowing the potentials ^^ and ifj^ at the source and sink respectively, and
measuring the mass of vapour transferred across each air gap, the potentials
02 and i/fg can be inferred from the physical properties of water vapour and
the dimensions of the diffusion cell. Hence the conductivity of the porous
medium can be found.

Each experiment was conducted with five repHcates of each of two stones,
Portland hmestone (a consohdated bed of oolitic aggregates), and Green-
brae sandstone (a consohdated bed of sand grains). Vapour transfer was
measured with the pore space saturated with NaCl solutions of molal
concentrations varying between 0-15 and o-8o. On Fig. 2 are results of
ijk' plotted as a function of Wq. Clearly relations of the form of eq. 12 hold,
for which least-squares analysis gives :

Portland ^ = (3-53 + 7-50 Wq) x io1«

Greenbrae ~ = (2-97+ 4-8i Wq) x io^o

From eq. 12, using the values of A= 4-73 x 10*, and Dso= 1-475 >< 10 "^
cm2 sec-i given by Robinson and Stokes (i955. pp- 46i, 495) the diffusion
ratios are

Portland DsjDso = 0-0427

Greenbrae DsjDsn = 0-0667

EFFECT OF DISSOLV ED SALTS ON WATER MOVEMENT 63

Measurement of D/Dq for the diffusion of hydrogen through the dry
stones using the method of Currie (i960) gave

Portland D/Do= 0-0430
Greenbrae -D/Dq = 0-0664

Akhough the almost exact agreement is probably fortuitous, it suggests
that the analysis is correct, and the assumptions in it are acceptable. One of
these, between eq. 8 and eq. 9, takes ql/Ds as small. Its value for Portland
stone is 0-045, and the assumption is vaHd.

lOr

l/K'

PORTLAND/"

X 10'° sec /cm

GREENBRAE

j_

0.2 0.4 0.6

NaCI CONCENTRATION mo

0.8

Fig. 2. The effect of dissolved salts on water movement.

CONCLUSION
In soil in which there is both a matric potential gradient and an osmotic
potential gradient the bulk movement of water is controlled only by the
former even though the latter may add greatly to the total potential
gradient, or even impose an opposing gradient, which will happen when
fertihsers are drilled in bands alongside the plants. There seems to be no
serious risk that the very strong osmotic gradient set up by the fertiHser
will successfully compete with the plant roots in drawing water out of the
region between them. Water vapour will, it is true, move towards the

64 D.A.ROSE

fertiliser in the soil, but the predictions of Phihp (1955), that vapour
conductivity is several orders of magnitude lower than liquid conductivity
in fairly moist soil, broadly confirmed by my current experimental work,
show that this effect is hkely to be small compared with Hquid movement
towards the roots.

In more general terms the presence of solutes causes an osmotic potential
which tends to decrease the diffusion rate of water, this decrease being
proportional to the solute concentration and inversely proportional to the
diffusion coefficient of the solute molecules in the porous medium, thus
confirming the views of Schofield (1952). Extension of this work to
unsaturated media should provide information on the decrease of ionic
diffusion as moisture content decreases, which should be of value in the
study of movement of ions in the soil, the translocation of plant nutrients
being an important example.

ACKNOWLEDGMENTS

The author gratefully acknowledges the award of a research scholarship
from the Agricultural Research Council. He also thanks members of the
Building Research Station for providing stone samples, and H. L. Penman
for his help and encouragement.

REFERENCES

CuRRiE.J. A. (i960) Gaseous diffusion in porous media, Parts i and 2. Brit. J. appl. Phys.

II, 314-324-
Edlefsen, N.E. & Anderson, A. B.C. (1943) Thermodynamics of soil moisture.

Hilgardia, 15, 31-298.
Low, P.P. & Deming, J. M. (1953) Movement and equilibrium of water in hetero-
geneous systems with special reference to soils. Soil Sci. 75, 187-202.
Low, P.P. (1955) Effect of osmotic pressure on diffusion rate of water. Soil Sci. 80,

95-100.
MoNTEiTH, J.L. &: Owen, P. 0.(1958) A thermocouple method for measuring relative

humidity in the range 95-100%./. sci. Instrum. 35, 443-446.
Philip, J. R. (1955) The concept of diffusion applied to soil water. Proc. nat. Acad. Sci.

India, 24A, 93-104.
Richards, L. A. & Weaver, L.R.(i944) Moisture retention by some irrigated soils as

related to soil-moisture tension. J. agric. Res. 69, 215-235.
Robinson, R. A. & Stokes, R.M.(i955) Electrolyte solutions. London: Butterworths
Schofield, R.K.(i952) Private communication to Low& Deming (i953)-

MODEL TESTS ON THE ECOLOGICAL EFFECT

OF VAPOUR MOVEMENT AND CONDENSATION

IN SOIL DUE TO TEMPERATURE GRADIENTS

W.R. Muller-Stoll &G.Lerch
Botanisches Institut, Padagog. Hochschule, Potsdam, E. Germany

I. THE PROBLEM

It is well known that the surface of naked and sparsely overgrown soils is
subject to extreme temperature fluctuations between day and night, in
particular during bright weather.

Most of the solar energy directly reaching the earth is absorbed by the
uppermost shallow layers of soil, and, therefore, the soil surface grows
hotter than the adjoining parts of soil and air.

At night the inverse procedure prevails. A great deal of the accumulated
heat is re-radiated leaving the ground surface much cooler than the regions
above and below it. In this way a temperature gradient results between the
soil surface and the adjoining layers of air and soil. This gradient is most
distinct under a clear, cloudless sky when great differences in temperature
commonly arise between the soil surface and just a few inches above or
below it (see Geiger, 1950).

Due to this temperature gradient water vapour moves from points of
higher energy level to those of lower free energy, i.e. from warm moist
parts into cold dry layers where condensation follows above ground, well
known as dew.

This, too, happens underground. By day the deeper parts are cooler than
the surface layers, and vapour moves downward. At night, on the con-
trary, vapour tends to move upward condensing to hquid water near the
ground surface.

It has never been denied that water vapour does move in such ways.
There are very different opinions, however, on the question whether an
ecological importance should be attributed to that vapour movement
caused by temperature gradients, i.e. whether the water volume trans-
ported in this way might be sufficient to affect noticeably the water turnover
of plants.

At present the majority of authors in soil science tend to deny this. Their
reasoning was outlined and summarised recently by Veihmeyer, 1956
(citing further hterature), and formerly by Walter (1951)- In brief, these
reasons^are based upon two points :

66 W. R. MOLLER-STOLL AND G. LERCH

(i) When soil moisture has decreased below field capacity Hquid water will
be conducted through soil at only an extremely slow speed.

(2) If roots have dried out a certain soil volume available, the lost soil
moisture will be replaced so slowly from the neighbouring parts of
soil that usually the roots elongate much more rapidly, thus actively
invading new water sources (Walter, 195 1 ; Kausch, 1955 ; Veihmeyer,
1956).
Apart from this group of contributors there are those who consider the

vapour movement in soil under temperature gradients to be of practical

importance to plants (Brawand & Kohnke, 1952; Lebedeff, 1927, 1928;

Smith, 1934, 1943); in particular Trenel (1949, 1950, 1954, 1955); Trenel

et al. (1958). The main points of view of this group are as follows:

(i) Plants can be kept at fuU turgescence over several weeks, even months,
getting the necessary moisture by no other means than a vapour-
saturated atmosphere. Plants cultivated in this way may even grow,
flower and bear fruit if provided with a suitable amount of minerals.

(2) If open Petri dishes or similar glass containers are mounted in hori-
zontal tunnels driven at different levels into a soil profile, condensed
water wiU accumulate in these dishes on warm days (Trenel, 1954,
measured about 30 mm per year).
Those experiments, however, did not deal directly with the problem of

whether the plants are able to use the vapour condensation in soil, caused by

temperature gradients.

On account of the methodological difficulties comphcating experimental

work in the field a series of model tests was performed to produce some

contributions to this subject.
Work was done in 1957 in the Field Station of the Botanical Institute at

Potsdam-Sanssouci, Germany. Technical performance was done by a

student, Christa Giesche, using experience achieved in our laboratory

from previous investigations made on similar subjects under direction of

Dr. Lore Steubing.

II. MATERIAL AND METHODS

For the purposes of this subject an experimental set-up had to be developed
allo^ving the changes of soil moisture to be traced during the test without
disturbing the test plants. This was achieved in satisfactory manner by the
following equipment (Fig. i) :

Each apparatus consisted of two glass tubes, 4-5 cm wide and 10 cm long,
one put upon the other after having been prepared before in different ways.

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL

67

The lower end of the basal tube was tightly closed by a rubber plug in
order to prevent water from invading from outdoors. The lower end of the
apical tube was closed by a piece of fine Perlon gauze.

Fig. I. Test equipment, (a) with test plants, (b) without test plants, apical containers
enclosed in ice jacket. Key : (i) Test plant, (2) Petroleum jelly- vaseUne sealing, (3) Glass
wall of the apical tube, (3a) Apical soil column ( = 'top'), (4) Perlon diaphragm, (5) Fold-
ed rubber hose, (6) Strip of plaster, (7) Glass wall of the basal tube, (7a) Basal soil column
(= 'base'), (8) Rubber plugs, (9) Thermometers, (10) Hollow cylindrical ice containers.

Both containers were filled with fme soil (loamy sand) as firmly as
possible. In the apical tubes seedlings of Pisum sativum ('Maiperle') were
grown in the usual manner until their root systems had thoroughly
permeated the small soil column available.

At the beginning of each test the soil surface in the apical tube was sealed

68 W.R. MOLLER-STOLL AND G.LERCH

by a layer of petroleum jelly-vaseline, and this container was then put with
its bottom of Perlon gauze upon the open end of the basal tube filled to
the brim with soil. In order to improve the sealing between the two tubes
their adjoining ends were enclosed in a piece of folded rubber hose. In
addition to it a strip of plaster, 2-5 cm wide, was fitted around the rubber
cuffs and held both glass containers together during the test period.

Thus the soil columns of those two tubes were connected forming a
practically uninterrupted unit, merely separated by a Perlon diaphragm
which prevented the roots in the upper container from invading into the
basal soil column.

The two containers, however, could be separated at any time during the
experiment and individually weighed, thus allowing the control of mois-
ture movement in the upper and lower part of the test set-up.

As a rule, the temperature gradient was induced by a hot-water bath.
The bottom of the basal tube was standing to about 4 cm depth in a hot-
water basin the temperature of which vv^as controlled by means of an
electric heater combined with contact thermometer, relay and electric
stirrer.

Two thermometers with a long and a short base were inserted into the
test containers with their mercury bulbs resting in the apical tube about
2 cm and in the basal tube 18 cm below the common soil surface. Since
the long thermometers piercing the diaphragm prevented the soil columns
in their containers from being easily separated, the temperature gradient
was checked in all cases by additional closed systems as shown in Fig. ib.
They were added to the test containers with rooted plants being thus
subject to exactly the same temperature treatment.

In order to increase the temperature gradient or to cool down the con-
tents of the tubes an ice jacket was applied to the containers. For these
purposes a hollow cylindrical tin can was constructed the interior convex
surface of which fitted tightly around the glass tubes. The can was filled
with a mixture of ice and salt thus cooling the top of the apparatus as well
as its bottom.

For technical reasons and in order to approach field conditions the
artificial temperature gradient was run, as a rule, from 8.00 a.m. to 6.00 p.m.
At night the temperature differences vanished gradually, and on the next
morning the soil around the thermometer bulbs in both tubes showed the
same temperature of about 2i°C.

Each experiment, including check tests, was repeated three times at
least. Thus the data pubHshed in the following sections each represent an
average value of four single observations.

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 69

Experiments were performed during June and July, 1957, in a glass-
covered green-house.

III. EXPERIMENTAL EVIDENCE

I. Model Tests on Vapour Movement in Naked Soil due to Tempera-
ture Gradients

A series of introducing tests was made without hving plants in order to
check the range of water transfer through the soil columns used for these
experiments.

For the purposes of these tests both open ends of the test set were closed
by rubber plugs ; thermometers were inserted through the apical stopper
(Fig. lb). Experiments with these closed systems were run over 12 hours.
Loss or gain of moisture in both glass containers of each set were registered
by weighing every 30 minutes.

Results differ according to soil moisture gradients. Three typical varia-
tions will be described here, see Fig. 2.

(a) Equal and Sufficient Moisture in both Containers

The temperature of water bath was maintained constantly at 45°C from
30 minutes after the beginning of the test. The temperature of air varied
due to insolation being increased by the accumulation of heat below the
glass roof of the greenhouse.

Temperatures within the soil columns changed but shghtly keeping in
the basal tubes close to the water temperature, and about io°C lower in the
upper containers thus exceeding the air temperature by far, except in the
forenoon.

Due to the lack of a uniform temperature in the atmosphere, the
temperature gradient between the lower and the upper containers could
not be kept exactly constant, but a difference of io-i2°C on average was
maintained fairly steadily during the entire period of the experiments.

Within the apical soil columns moisture content increased in a nearly
linear relation from ii-o up to 12-4%. The corresponding loss of water
could be measured from the basal tubes.

(b) Different Soil Moisture in both Containers

Fig. 2b shows similar relations to Fig. 2a, but resulted from a different
initial situation. At the beginning of the test the apical tube held dry soil
(2-8% moisture content). From the moist soil (ii'0% water content) in the

70

W. R. MULLER-STOLL AND G. LERCH

basal container however, that much water was transferred upward, due to
the same temperature gradient (about io°C), that soil moisture in the upper
tube increased up to 4-2%. Thus, after twelve hours the initial soil moisture
in the upper containers had increased by approximately 50% compared
with the initial status.

o

u

i" 40H

^ 3-0-
o 2-8 -

water bath
■r^"/' / y /■ > ^ X /-

basal soil column

■50

°C

-40

-30

-20

n

120-

110-

I "^ I ' 1^1

I I I I

I ' I ^ I ' I ^ I ' I

8 10 12 14 16 18 20t

10 12 14

Time on test day

20hrs

Fig. 2. Vapour condensation in bare soil due to temperature gradients. Initial water
contents in apical and basal soils respectively (a) 11%, 11%; (b) 2-8%, 11%; (c) 11%,

Inverse experimental conditions -higher soil moisture (ii-o%) in the
apical tubes, dry soil (2-8%) below them- did not cause any change in the
water content of the apical soil columns (Fig. 2c).

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 71

These results, however, are not simply due to the inversion of the moisture
gradient or to low moisture content in the basal containers, although this
must be taken into consideration, too. In this case the temperature gradient
proved to be too weak.

Temperature gradients of 30°C and more are well able to force water
out of even such dry soils into colder parts, regardless of their water content.
This was achieved in our experiments by refrigerating the apical tubes
while the bottom of the apparatus was heated by hot water.

If the water bath v/as omitted, leaving the apical containers enclosed in
their ice-wrap, a temperature gradient of about io°C appeared, and this
too was followed by the same results in moisture movement as described
above.

By an inverse temperature gradient caused by cooling the lower tubes,
the water vapour was caused to move downward, and the upper tubes
lost water in favour of the lower ones.

2. Model Tests on the Ecological Effect of Vapour Movement in
Soil upon Plants due to Temperature Gradients

The tests described in the preceding section were to provide information
on the approximate range of vapour transfer in soil due to the temperature
gradients. It should be tested now whether that vapour movement might
be of practical use to the water relations of plants.

For the purposes of these tests the apical tubes containing pea-seedhngs
were used. After the soil surface had been sealed with petroleum jelly-vasel-
ine, water could be lost from these containers only by transpiration of the
test plants. This transpiration loss was registered by weighing the apical
tubes at the end of each day. The actual loss of water by transpiration
should be somewhat higher than the estimations made in this way, because
these data are affected by the gain of substance due to daily photosynthesis
and growth. The error, however, may be neglected since it does not alter
the general results of the experiments.

In this series of tests temperature and temperature gradient as well as
the soil moisture content had to be varied. The most typical variations will
be described in the following :

(a) Equal, Sufficiently Abundant Soil Moisture in Both Tubes

This is the simplest case. The soil in both tubes held about 10% water. The
bottom of the basal tube was heated again by the water bath; temperature
gradient could be maintained at io-i5°C through every day. Within the
6

72

W. R. MOLLER-STOLL AND G. LERCH

control sets a natural temperature gradient of about i°C persisted between
top and bottom of the soil column.

Results are very conspicuous, as shown in Fig. 3.

Temperature gradients, drawn in this and the following diagrams
represent the average values of soil temperature reached about 30 minutes

days

Fig. 3. Ecological effect of vapour movement and condensation due to a temperature
gradient in a moist soil with a rooted plant (see Fig. i). Hatched area: temperature
gradient within the test soil. Base = basal soil column, top = apical soil column,
W.P. = wilting point. Initial soil moisture, per cent, in brackets. Vapour tension of
air: 45%.

after the test had been started, and being maintained up to the end of each
day. Night temperatures have not been regarded, because they do not affect
the course of the experiments. Radiation like that in the field did not occur
under the experimental conditions in the greenhouse.

The relations found in the control containers agreed with the results
previously published by other authors (see Veihmeyer, 1956), in particular

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 73

Kausch (1955). The basal soil columns hardly lost water, whereas the soil
in the apical tubes was much desiccated, by the plants, and on the sixth day
permanent wilting percentage was reached.

Within the test sets, however, the soil of the lower tubes lost so much of
its water content, due to the temperature gradient, that on the first day of
the test the moisture in the upper container increased, and -in spite of
transpiration from the plants- was kept nearly on the same level during the
following days, decreasing but slightly. In this case the loss from transpira-
tion was nearly completely reimbursed by the water supply from below.

(b) Dry Soil in the Apical Tubes

The apical containers were filled with soil that had been previously dried
out to an approximate moisture content of 4%. The basal tubes held soil of
either the same low water content (4°o) or a moist packing of nearly 11%
water (Fig. 4).

The other environmental factors, in particular the temperature of air and
water bath, were the same as in the preceding section.

The basal soil columns within the control sets did not lose water, as in
the preceding cases, and the graphs of soil moisture loss in the apical tubes
are similar to one another. The small difference in water loss may be
attributed to slightly different transpiration from the control plants. All
control plants wilted on the sixth day of the experiment.

The test plants in the sets containing dry soil in top and bottom behaved
in the same way. The moderate temperature gradient of io°C on average
could not force sufficient water vapour from the lower containers which
lost but very little of their moisture into the apical tubes. Test plants wilted
there on the same day as did the controls after having exhausted their soil
columns.

When sufficient water was available, however, within the lower soil
columns, vapour could move upward in such quantities that in the upper
containers the water loss from transpiration could be reduced considerably
at the expense of a corresponding marked loss of moisture from the basal
tubes. Consequently the test plants did not wilt in these cases.

(c) Extreme Temperature Gradients (30°C)

For these tests soil of the same moisture was used as described in section (b),
but the temperature gradient was raised to the extreme limit of 30°C, and
even more, by an ice- wrapping appHed to the top of the apical tubes while
the bottom of the basal tubes stood in the hot-water bath. This time the
control containers, too, were heated by the water bath, thus being subject

74

W. R. MOLLER-STOLL AND G. LERCH

to a moderate temperature gradient of about 8°C. Therefore, the lower
soil columns of the control sets also lost water in this case.

days

Fig. 4. Ecological effect of vapour movement due to a temperature gradient m soils,
with rooted plants, of different moisture. For key, see Fig. 3. Vapour tension of
air: 58%.

From the dry basal soil less vapour moved upward than from the moist
soil. The control plants above the dry basal soil thus wilted on the sixth
day again, those with a moist soil in their basal tubes did so one day later

(Fig- 5).

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL

75

The extremely strong temperature gradients, however, existing within
the test sets were able to force so much water even out of the dry soil that

8 days

Fig. 5. Ecological effect of extreme temperature gradients on vapour movement and
condensation in soil with rooted plants. For key, see Fig. 3. Temperatures: test, base
38-5°C; test, top 4-5°C; control, base 38-5°C; control, top 30°C.

76

W. R. MOLLER-STOLL AND G. LERCH

the relations, as shown by Fig. 4, were partly inverted here. From the
dried-out basal soil, water could be moved upward to such an extent that
soil moisture in the upper tubes decreased but very shghtly. From the
moist soil, fmally, so great a quantity of water was transferred into the
apical containers that soil moisture increased here continuously in spite of
the transpiration from the test plants. When the experiment was stopped
after 8 days no test plants showed any signs of wilting.

(d) Low Temperature

During the tests described so far, the temperature gradient was estabhshed
by leaving the top of the test set-up in the temperature of the surrounding
air (20-30°C), and by heating the bottom of the lower tubes up to 45°C.
Thus the whole set-up was subject to relatively high temperatures, although
the temperature gradient itself did not exceed io-i2°C. The same tempera-
ture difference, however, could be maintained by omitting the water bath
and merely enclosing the top of the apical tubes in an ice jacket. Tempera-
tures within the test set-up ranged then from 5°C at the top to 1 5°C at the
bottom.

Figure 6 shows the results of these tests. In principle there is no change to
the previous evidence. Vapour moved upward, condensed there, and was

I

(8-3%)

6 days

Fig. 6. Ecological effect of a moderate temperature gradient at low temperature on
vapour movement and condensation in soil with a rooted plant. For key, see Fig. 3-
Vapour tension of air: 63-3 %.

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 77

used by the test plants which wilted 2 days later than the controls. From the
desiccated soil less water could be extracted and transferred upward than
from a moister soil.

The quantity of water, however, moved at these low temperatures was
much smaller than under the influence of higher temperatures though the
temperature gradient remained the same.

T-30

days

Fig. 7. Ecological effect of an inverse temperature gradient on the vapour movement
and condensation in soils of different moisture, with rooted plants. For key, see Fig. 3.
Vapour tension of air: 60%.

78 W. R.MULLER-STOLL ANDG. LERCH

(e) Inverse Temperature Gradient

If the temperature gradient was inverted by cooling the basal tubes, w^ater
vapour moved dov^nward, causing the relations shovv^n by Fig. 7.

This time the soil within the upper containers lost more water the higher
the initial soil moisture content. Consequently water moved downward,
and increased the weight of the basal tubes. Due to this additional loss of
water from the upper tubes the test plants wilted on the fourth day of the
experiment, whereas the control plants were kept fresh up to the end of the
test, after 7 days.

IV. DISCUSSION

The data of our model tests proved that under the experimental conditions
chosen here the vapour movement and condensation in soil due to tem-
perature gradients had practical importance to the plants.

As long as the basal soil columns were heated and thus the temperature
gradient was maintained water vapour moved upward into the apical
tubes, and the test plants grown here always wilted several days later than
in the control containers with uniform temperature conditions, where the
roots had nothing but the moisture of the apical tubes available.

The quantity of water moved in this way depends, at least, upon three
variables :
(i) Range of temperature gradient.

(2) Temperature levels.

(3) Soil moisture content.

Apart from these, the duration of the temperature gradient and the specific
texture of the soil concerned will doubtless affect the vapour movement,
too.

The tests performed by relatively simple means do not yet allow a mathe-
matical formulation of the influence of the variables, but a few relations
stand out quite distinctly.

By the same temperature gradient considerably more water is extracted
from a greater soil moisture, at best not much below field capacity (see
Smith, 1934, 1943), than from a lower moisture content. Likewise at high
temperatures more water is translocated than at low temperatures.

Most effective is an increase of the temperature gradient itself. The
extremely high gradient of 30°C was able to extract water even from a
very dry underlying soil and to force it upward into moister layers of
soil, a procedure that had been impossible under temperature gradients of
merely io°C.

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 79

Inverse temperature gradients achieved by cooling the basal tubes con-
cluded the evidence. The upper soil columns now lost water, in a propor-
tional ratio to their initial moisture content, to the lower containers, and
the test plants wilted several days earlier than the control plants.

More difficult is the problem how far these model tests enable conclusions
to be drawn about field conditions.

First of all the range of water volume moved by the temperature
gradients will be considered. Leaving aside the extreme data there was an
average quantity of o- 4-2-0 g of water translocated per area of 15-3 cm^
every day. This would correspond to 0-3-1 -3 mm precipitation per day.
This evidence is confirmed by investigations of Trenel (1954, 1955) who
measured a water gain of at least 40 mm per year due to condensation in the
soil at 15 cm depth near Berlin. Trenel presumed that there are approxi-
mately 50 days in the year having suitable temperature relations to make an
extensive vapour condensation in soil possible. According to a personal
communication by Prof. Dr. Trenel, investigations recently made under
subtropical conditions in Viemam, revealed a gain of 90 mm condensed
water within one week at the same depth in the soil. In this case, however,
vapour condensation from the atmosphere should be included.

The absolute levels of temperature used in our tests come near to field
conditions.

The temperature gradient of io°C along a distance of 16 cm is doubtless
somewhat higher than the average field values in our Central European
climate at the same depth of soil. In the loamy sand soil of our field station
at Potsdam we found an average temperature gradient of 5-8°C between
2 and 20 cm depth on bright days in summer. Similar values are reported
by the most authors (Kraus, 191 1 ; Heilig, 1930; Volk, 193 1 ; Miiller-Stoll,
1935; Walter, 1951; Geiger, 1950).

There is considerable evidence, however, of higher temperature gradients
even in Central Europe. Miiller-Stoll (1935, p. 186 f.) ascertained tempera-
ture gradients exceeding i8°C between 5 and 1 5 cm depth in a silt loam soil
of xerotherm grass slopes in the Kraichgau (S.W. Germany) on bright days.
Under similar conditions Heilig (1930) found temperature gradients
exceeding even 30°C between the ground surface and a depth of 20 cm
in the Kaiserstuhl (S.W. Germany). Kraus (1911, p. 132) measured
temperature gradients up to I2°C between 2 and 12 cm depth in a naked
garden soil at Wiirzburg (Germany) during summer. Similar temperature
differences may be read from the tables and graphs pubhshed by Geiger
(1950).

The experimental conditions of our model tests thus come near to the

8o W.R.MULLER-STOLL AND G.LERCH

temperature relations on dry locations, and even the extreme temperature
gradients used in these tests do not appear too monstrous if temperatures
of the ground surface are included in the considerations.

Similar temperature differences result within a short distance in the upper
layers of soil due to nightly radiation, in particular under a clear sky, see
Geiger, 1950; Lebedeff (cited by Trenel, 1949, p. 145) ; Walter, 195 1. Then
water vapour moves upward from the warm deep layers of soil to its
cooler surface.

The real distances through which soil moisture is moved in the field due
to temperature gradients may be estimated to be even much greater than
the length of the small apparatus used in our tests. This means also a greater
temperature gradient between the soil surface and the deeper layers of
soil where considerable resources of water are available.

Of the two possible directions of water translocation in soil due to
temperature gradients -by day downward from surface to depth, at night
upward from depth to surface -the latter one must be given the greater
practical importance. At night the ascending soil moisture may be able to
increase the water content of the upper layers in soil. This procedure is
supported by condensation of dew from the atmosphere.

In humid cHmates the temperature gradients in soil are much lower, of
course, but under such conditions water movement in this way will not
be of any practical importance, anyway, to the plants. High atmospheric
precipitation combined with low evaporation rates involve a sufficient
abundance of capillary water in the upper layers of soil, and roots are not
dependent on the meagre quantities of vapour condensation. Thus, humid
soil conditions, as a matter of course, should not be taken into the practical
considerations of this problem at all (Trenel, 1954, 1955 ; Trenel et al, 1958).

Under dry conditions, however, if the capillary water resources have
been used up to a great extent, the vapour movement and condensation
due to the much stronger temperature gradients may certainly be of
practical importance in the water supply of plants, provided that there is a
distinct effective radiation surface, i.e. that the plant cover is not too dense
and too high. Such conditions may be found even in Central Europe, i.e.
on warm slopes of dry land weakly overgrown with natural sand or steppe
plant communities.

By day the steady strong insolation must cause the soil moisture in the
upper layers not only to evaporate into the dry air but also partly to move
down into cooler layers of soil. At night it will return to the upper layers
cooled down by nightly radiation and will be used there by the roots.

In this connection one more result of our tests should be interesting : when

MODEL TESTS OF VAPOUR MOVEMENT IN SOIL 8i

test plants and controls wilted (e.g. Fig. 4), the wilting percentage in the
control soils was higher than in the test containers, i.e. the soil could be
dried out much more within the test containers before the plants began to
wilt. It may be supposed that the roots or root hairs of the test plants are
points of condensation for the ascending water vapour, which in this way-
need not be bound to the soil colloids, but is at once made available to the
plants. Trenel (1950) believes that vapour will be taken up 'in statu nascendi'
of condensation by the roots.

Trenel (1949, 1950), citing papers of other authors, in particular Lebedeff
(U.S.S.R.), Kekkonen (Finland), Beskow (Sweden), Chaptal (France)-
Literature, see Trenel, 1949, summarised by Trenel et ah, 1958 -pointed
out that vapour movement and condensation in soil may even affect the
ground water level. Water is supposed to move from subsoil to topsoil in
winter, in the opposite direction in summer. Keilhack (19 12) considers
vapour condensation in soil to be responsible for the fact that the ground
water level may rise if gloomy weather with high air humidity has pre-
vailed for a long period without precipitation. In the end, the drained
water volume of a certain catchment area may be greater than the total
amount of precipitation. In 1888 a total precipitation of 762,300 m^ was
registered for the area of the Remscheid dam (Germany) compared with a
total drain of 800,630 m^. It must be doubted that this surplus of nearly
40,000 m^ was only due to vapour condensation in soil, nevertheless this
kind of water translocation seems to be of greater ecological importance
than hitherto considered.

This opinion is supported by observations recently made at different
field stations by the MeHoration Department of the Agricultural Faculty,
University of Rostock* (E. Germany). Measurements conducted there over
several years, on different soil types below different crops, showed that
soil moisture was usually higher than expectations, calculated from the
amount of precipitation.

Most importance, however, must be attributed to water movement due
to temperature gradients in winter. The ice shield within the frozen soil
surface is steadily increasing by condensation and freezing of water vapour
ascending from deeper layers in the soil. The result is a considerably higher
humidity in soil being available to the crops in spring.

From the results of our model tests it may be summarised that vapour
movement and condensation in soil due to temperature gradients may be of
considerable ecological importance under suitable conditions. A rough

* The authors are indebted to Prof. Dr. M. Olberts, Institut iir Meliorationswesen
der Universitat, Rostok, for kindly supplying this information.

82 W. R. MULLER-STOLL AND G.LERCH

estimate shows that the experimental evidence may be generaUsed with
some restrictions to field conditions, but before making final statements
additional quantitative investigations must be performed in the field.

REFERENCES

Brawand, H. & KoHNKE, H.(i952) Microclimate and water vapor exchange at the

soil surface. Proc. Soil Sci. i6, 145-148.
Geiger, R.(i95o) Das Klima der bodcnnahen Luftschichten, 3. Aufl. Braunschweig.
Heilig, Hilde (1930) Untersuchungen iiber Klima Boden und Pflanzenleben des

Zentralkaiserstuhls. Z. Bot. 24, 225-279.
Kausch, W. (1955) Saugkraft und Wassemachleitung im Boden als physiologischc

Faktoren, unter besonderer Beriicksichtigung des Tensiom.eters. Planta (BerL),

45, 217-263.
Keilhack, K. (1912) Lehrbuch der Gruiidwasser- und QueUetikimde. Berlin.
Kraus, G. (191 i) Boden und Klima auf kleinstem Raum. Jena..
Lebedeff, A.F. (1928) Die Bewegung des Wassers im Boden und im Untergrund.

Z. Pflanzenerndhrung u. Diing., Teil A, 10, 1-36.
Lebedeff, A. F. (1927) Methods of determining the maximum moisture holding

capacity of soils. Proc. First int. Congr. Soil Sci. i, 551-563.
MiJLLER-SxoLL.W.R. (1935-36) Okologische Untersuchungen an Xerothermpflanzen

des Kraichgaus. Z. Bot. 29, 161-253.
Smith, W. O. (1939) Thermal conductivities in moist soils. Soil Sci. Soc. Amer. Proc.

4, 32-40.
Smith, W. O. (1943) Thermal transfer of moisture in soils. Trans. Amer. Geophysic.

Union, 24, 511-523.
Trenel, M. (1949) Zur gutachtlichen Beurteilung des Einflusses der Grundwasserab-

senkung auf den Eniteertrag im LoB. I. Mitteilung. Z. Pfianzenerndhr., Diing. u.

Bodenkunde, 45, 133-147.
Trenel, M. (1950) Zur gutachtlichen Beurteilung des Einflusses der Grundwasser-

absenkung auf den Emteertrag im L06. Ill: Mitteilung. Z. Pfianzenerndhr., Diing.

u. Bodenkunde, 49, 224-237.
Trenel, M. (1954) Uber Kondensationsvorgange im Boden. Sitzber. dtsch. Akad.

Landwirtschaftsu'iss., Berlin, 3, Heft 6, 1-30.
Trenel, M. (1955) Uber Kondensationsvorgange im Boden. 2. Mitteilung: Zur

pflanzenphysiologischen Bedeutung des dampfformigen Wassers im Boden.

Sitzber. dtsch. Akad. Landwirtschajtswiss., Berlin, 4, Heft 14, 1-28.
Trenel, M., Weber, H. & Lindner, H. (1958) Uber die Kondensation des Wasser-

dampfes im Boden. C. R. et Rapp. Ass. Gen. de Toronto, 1957 (Gentbrugge 1958)

2, 517-522.
Veihmeyer, F.J. (1956) Soil moisture. Encyclopedia of Plant Physiology, ed. by W.

Ruhland, vol. Ill, 110-112. Berhn-Gottingen-Heidelberg.
Volk, O.H. (193 i) Beitrage zur Okologie der Sandvegetation der Oberrheinischen

Tiefebene. Z. Bot. 24, 81-185.
Walter, H. (195 i) Grundlagen der Pflanzenverbreitung. Standortslehre. {Einfiihrung

in die Phytologie, Bd. III/i). Stuttgart.

PHYSIOLOGICAL STUDIES OF WATER BALANCE
AND MOVEMENT IN PLANTS

k

THE PATHWAY OF WATER MOVEMENT ACROSS

THE ROOT CORTEX AND LEAF MESOPHYLL OF

TRANSPIRING PLANTS

P. E. Weatherley
Botany Department, University of Aberdeen

I. INTRODUCTION

In its passage from the soil to the atmosphere, water of the transpiration
stream must traverse two cellular barriers: that between the soil and the
xylem elements of the root, conveniently designated root cortex, and that
between the xylem of the leaf vein and the transpiring cell, designated leaf
mesophyll. Transpirational loss of water from the mesophyU cell causes a
gradient of water potential through the leaf tissue in response to which
water moves from the vein. This results in a reduction of hydrostatic
pressure in the xylem in response to which water moves across the root
cortex from the soil.

Of course such cellular barriers present an extremely complex pathway.
The question before us in this paper is whether the water moves from
vacuole to vacuole crossing the cell walls and membranes of each cell in
turn or moves roimd the cells keeping within the cell walls (or perhaps in
addition witliin the outer region of the cells as well) thus bypassing the
vacuoles. We have in a sense two pathways in parallel. Water will move
through both, but if there is a large difference in resistance between the
two, water wiU move largely through the one with the lower resistance.

The older view was certainly that in the leaf, movement was from
vacuole to vacuole and this seems to persist. Evidence that movement is in
fact through the mesophyll cell walls was obtained by Strugger (1938-39)
using fluorescent dyes although Hiilsbruch (1956) has cast doubt on the
validity of this evidence. Levitt (1956) on the basis of purely thoeretical
considerations concludes that movement through the mesophyll cannot be
diffusional and is prseumably mass flow in the ceU walls. But there seems
to be a dearth of positive experimental evidence one way or the other. In
the furst part of this paper a new experimental approach is described which
strongly points to a superficial pathway round the mesophyll cells.

The root has been the subject of more extensive study but the position is
more complex than that in the leaf and even less well understood. The
complexity arises because the root is the seat of vigorous secretory processes

86 P.E.WEATHERLEY

and because the flux of water is very possibly different in the detopped
plant from that in the intact transpiring plant. Sabinin (1925) showed that
the exuding root behaved hke an osmometer and the thorough study by
Arisz et al. (195 1) confirmed and greatly extended this conclusion. This
implies that the flux is through semi-permeable membranes. Yet De
Lavison (19 10) showed that some solutes could penetrate the cortex rapidly
as far as the endodermis, indicating a rapid movement in the cell walls
stopped by the casparian strips. Other solutes which could enter the
cytoplasm could pass the endodermis. Later Scott & Priestley (1928)
emphasised the endodermis as a barrier to free movement in the cell walls
of the cortex and in more recent years the apparent free space concept is
clearly in accord with rapid physical movement up to the endodermis
(Bernstein and Nieman, i960).

The osmotic barrier indicated by Arisz et al. would presumably therefore
reside in the endodermis. Thus between the external medium and the
xylem of the root there will be a catena of at least three Hnks: (a) free
diffusion or probably mass flow up to the endodermis, (b) osmosis across
the endodermis and (c) probable mass flow beyond the endodermis. As is
well known, the flux through such resistances in series will be largely
controlled by the Unk with the highest resistance, provided its resistance is
much higher than that of the other links. Osmosis across the endodermis
is hkely to be such a high resistance Hnk, so that even if the pathway across
the cortex and within the stele is by mass flow, the flux will be doirdnated by
the endodermis, and the root after all will behave Hke an osmometer. But
can we exclude the possibihty under transpiring conditions, of a mass flow
through the cytoplasm of the endodermal cells, through passage cells or
even via the cell walls of the endodermis in regions of the root where the
casparian strips are not suberised; In this event we are faced with the
endodermal link itself presenting two pathways in parallel: one diflu-
sional, the other permitting mass flow.

Theoretically it ought to be fairly easy to detect and even to measure
the relative resistances of two such parallel pathways. Movement in
response to an osmotic potential gradient should be less than that in
response to an equal hydrostatic pressure gradient, since the latter woidd
not only cause an osmotic flux equal to the former, but would also draw
water through the mass flow pathway in addition. Such a difference in the
case of a hving cellular barrier was demonstrated by Kramer (1932) using
a hollow petiole. The work described in the second part of this paper
represents an attempt to apply this approach to the root system (Mees and
Weatherley, 1957).

I

THE PATHWAY OF WATER MOVEMENT 87

II. MOVEMENT THROUGH THE MESOPHYLL

This problem was approached by constructing a hypothetical model of
the leaf cell. The behaviour of the model under certain experimental
conditions was studied and experiments performed on the leaf to see
whether it behaved in the way predicted by the model. If so, the model was
considered to be a good representation of the leaf.

I. First Hypothesis

If water moves from vacuole to vacuole as represented in Fig. lA, loss of
water by evaporation from cell a will lead to a reduction in its water
content and concomitant fall in its water potential. This depression of
water potential* will lead to a diffusion of water from cell b and in turn
from cell c and so from the xylem element. In this way a water deficit
arises in cell a depending on the rate of transpiration and the sum of the
resistances imposed by cells b, c, the xylem elements and those resistances
lying below (e.g. root resistance). Thus it is the depression of water potential
in cell a which is the operative force in moving the transpiration stream up
to that point. Fig. iB represents a model of cell a. The apparatus is filled
with water, v represents the vacuole and the capillary tube c the resistance
in the transpiration stream lying below cell a. The bulb b is porous and as
evaporation takes place from it, water is drawn from the reservoir w
through the tube c and since this imposes a resistance to flow a reduction
of pressure in v arises and mercury is drawn up the vertical tube. This
reduction of pressure represents the depression of water potential in the
cell. For a given rate of transpiration a certain reduction of pressure will be
manifest as the mercury reaching a steady height //, and the volume of
mercury occupying the length h in the vertical tube will represent the
water deficit in the cell.

If the tap t is now closed, i.e. evaporation stopped suddenly, water will
continue to move into the cell through c whilst the mercury in the vertical
tube falls, and finally h will become zerof when uptake through c will cease
and the cell will have reached saturation. During this die-away in uptake
the rate of uptake^ at any instant will be proportional to ht at that instant,

/. = ''f (i)

where r is a constant proportional to the resistance of the tube c. Hence

* Depression of water potential = D.P.D. = suction force.

f Differences in level between water and mercury reservoirs are ignored.

7

88 P.E. WEATHERLEY

the rate of uptake/^ plotted against the height of the mercury lit will give a
straight line as in Fig. iC. It can be shown that the die-away in uptake is
logarithmic and may be represented by the equation :

ft =/oe-«/'-' (li)

where/o is the steady rate of flow (evaporation) up to the instant of turning
off the tap and r' a constant similar to r. Thus a plot of/r against time will
give a logarithmic die-away curve as in Fig. iD and plotting the logarithms
of/( against time will give a straight line (Fig. lE). The constants in these

LEAF

log.ft = log.fo" logizt/'"'

TIME

TIME

Fig. I. A: Diagrammatic representation of a train of mesophyll cells. B: Model of
transpiring cell on the hypothesis that the water moves through the vacuoles, v, vacuole;
c, capillary tube; w, reservoir of water; t, tap; /), porous bulb. C, D and E: Graphs
showing the characteristics of the die-away curve of uptake by the vacuole when the
tap t is closed.

equations are characteristic for a piece of apparatus of given dimensions
and all data, say, starting from different evaporation rates would fall on
to the same curves.

THE PATHWAY OF WATER MOVEMENT

89

B

TIME

TIME

Fig. 2. A: Model of transpiring cell on the hypothesis that the water moves round the
vacuoles, c", capillary tube separating the vacuole from the transpiration pathway;
other lettering as in big. lA. B, C and D: Graphs showing the characteristics of the
die-away curve of uptake by the vacuole when the tap / is closed. ( r= transpiration
rate.)

2. Second Hypothesis

If water passes round the outsides of the cells (through the cell walls)
rather than from vacuole to vacuole the hypothetical model must be
modified. The imphcation now, is that there is a resistance between the
pathway and the vacuoles. Such an additional resistance is shown in Fig. 2 A
in which the vacuole v is separated from the main stream by a capillary c"
of resistance r". With steady evaporation the mercury will rise as before
and attain the same steady state position in relation to/o and r as it will still
measure the reduction of pressure h at the point p. Closing the tap will,
however, have an entirely different effect. During the period of steady
transpiration water is dragged through the capillary tube c alone, whereas

90 P.E. WEATHERLEY

after the tap has been closed and the mercury begins to fall, water must be
dragged through both capillary tubes c and c". Thus the rate of uptake will
instantaneously fall from that given by eq. i to:

/ = — (.»)

After the instantaneous fall, / will decline logarithmically according to
eq. ii. Thus the curve of rate of uptake (Jt) plotted against time will appear
as in Fig. 2B and the logarithmic plot as in Fig. 2C. If the rate of uptake is
plotted against the water deficit h (Fig. 2D) instead of a straight hne there
will be an instantaneous fall from each transpiration rate (Ti, T^, T3 etc.)
on to the general straight line defmed by eq. i though in this case the
resistance is (r+r"). It wiU be seen that these two hypothetical models
predict that if transpiration could be stopped suddenly, the pattern of
continued uptake of water in response to the water deficit in the mesophyll,
would be entirely different according to whether the water of the
transpiration stream moves round the cells or through them.

3. Experimental

Data were obtained using leaves o£ Pelargonium zonale, Popuhs candicans
and Rihes sanguineum. In each experiment a detached leaf was fitted into a
simple potometer as shown in Fig. 3. Uptake was measured by following
the movement of a meniscus in the horizontal tube using a travelling
vernier microscope. At first a steady measured rate of transpiration was
maintained for one or two hours. Transpiration was then stopped suddenly
by immersing the leaf in water or medicinal paraffin by raising a beaker
from below and the die-away in uptake followed. Similar results were
obtained using either water or medicinal paraffin. In the course of each
experiment the total amount of water virtually to saturate the leaf was
measured by the potometer and clearly this represented the initial water
deficit in the leaf Further, the water deficit at any time was measurable as
the amount of water subsequently absorbed to attain full saturation. Typical
results are shown in Fig. 4A, B and C. Clearly all these results fit the second
hypothesis and not the first.

The experimental results do however differ from those predicted by the
second hypothesis in that the drop in rate on stopping transpiration is not
exactly vertical (Fig. 4B). This is undoubtedly due to the pathway itself
having a water deficit and taking up water to saturation. This uptake by the
pathway appears to die-away logarithmically hke that of the inner space of
the cells but much more rapidly, indicating a low resistance between itself

THE PATHWAY OF WATER MOVEMENT

91

and the water supplied at the cut end of petiole. On this interpretation the
initial steep fall in Fig. 4B represents the die-away in uptake by the pathway
(outer space of the cells, e.g. cell walls) and the subsequent slower fall
represents the die-away in uptake by the inner space of the cells (vacuoles,
etc.). Now if we assume that the pattern of uptake by the inner space of
the cells was uniform throughout, its die-away curve during the first 10

RESERVOIR

TAP

VALVE RUBBER

-■C

Fig. 3. Simple potometer showing method of attachment of leaf. Transpiration could
be stopped suddenly by raising the beaker to submerge the leaf.

minutes will be represented by the hne of extrapolation to ip and the line
pr represents the die-away in uptake by the inner space throughout the
experiment. Thus the rates of uptake by the inner space alone during the
first 20 minutes were obtained by taking antilogs of values lying along ;)^,
and by subtracting these rates of uptake from the experimental values
(total uptake) the rates of uptake by the pathway alone were obtained.

Integrated curves showing the progressive saturation of the two spaces
in the leaf were obtained bv summation of the rates derived in the above

92

p. E. WEATHERLEY

uj7

a
^5

T

A

K

cr
lij

0-1

0
1

V

►*-^

0 30 50 70 90

0

2-5

UJ

<

t-

0.

D

cc

UJ

<

5

li- 1 c

0l-5

2-0

<

1-0

0-5

O 10 20 30 AC 50 60
TIME (MINUTES)

20

^ 1-6

a

3

a 1-2

UJ

I

ii-o-e
0

<

O-O-A

JI»».tfO'

Tat 6-26

6 10 14

WATER DEFICIT

16

30

z

UJ
^201-

8

a

UJ

'

-roTAU—-. — * •

Voo*

•

e
1

PATHWAY (CUTER SPACE)

1

a

1

,H^4Ef^^— •—

U-'-"

10

15 20 25 30 35
TIME( MINUTES)

40 45 50

10 20 30 AO 50 60
TIME (MINUTES)

70

Fig. 4. A : Die-away curve of rate of continued uptake by a leaf on stopping transpira-
tion. Inset: the same data from 10 minutes onwards plotted on a different scale. The
form of the whole curve is an almost instantaneous drop followed by a slower die-away.
Cf. Figs. iD and 2B {Ribes sanguineum). B: Logarithmic plot of the die-away curve.
For pqr, see text. Cf Figs. lE and 2C {Pelargonium zonale). C: Relationship between
rate of water uptake and leaf water deficit during the progressive saturation of a leaf
on stopping transpiration. Data from a single leaf following two rates of transpiration.
Cf. Figs. iC and 2D {Ribes sanguineum). D : Curves showing the progressive saturation
of the inner and outer spaces of a leaf. The water contents were obtained by summating
the rate data given in Fig. 4B. For further explanation see text. The rate of water
uptake in all cases is expressed in arbitrary units based on the rate of travel of the
water meniscus in the potometer tube. (T= transpiration rate.)

THE PATHWAY OF WATER MOVEMENT 93

way and are shown in Fig. 4D. It will be seen that whilst the pathway
became virtually saturated after 20 minutes, the inner space would have
taken several hours. Evidently in detached leaves at least, rapid fluctuations
in water content of the pathway would be accompanied by relatively slow
changes in the inner space. But from the point of view of the present
discussion perhaps more significant is the fact that the rate of uptake repre-
sented hy p (Fig. 4B) is only Jg of the transpiration rate T. In other words,
in the case of this Pelargonium leaf water of the transpiration stream moved
through the pathway about sixty times faster than water could pass into
the inner space. A figure of about fifty times is obtained from Fig. 4A which
refers to Popidus candicans.

No great significance is claimed for the precise values of these ratios.
They merely serve to show that water can move through the outer spaces
much faster than into the inner space, and it should be emphasised here that
the values for the latter are really summated values for all the individual
cells each taking up water from its surrounding outer space. If on the other
hand water were forced to move through a train of inner spaces in series,
the total resistance would be correspondingly greater and the rate even
less.

If the pathway is indeed located in the outer space of the cells, say the
cell walls, and the offstream, inner space, is enclosed within a cytoplasmic
membrane, not only will the rates of water movement into them be very
different, but also they might well react differently to a change in tempera-
ture. Mass flow through the cell walls should be rather insensitive to
temperature, whilst it is recognised that the permeabiHty of cytoplasmic
membranes is often much reduced by a lowering of temperature. To test
this, transpiration was stopped suddenly as before except that in this case
water at about 3°C was used for immersion. The results of such an experi-
ment are shown in Fig. 5 A in which the logarithms of rate are plotted
against time. It will be seen that the rate fell away logarithmically with no
break until after 22 minutes, uptake had completely stopped. Thereafter
no uptake was recorded for a period of 60 minutes when the cold water
surrounding the leaf was replaced by water at 23 °C. As will be seen uptake
was resumed at once and after attaining a maximum the rate declined
logarithmically as in the previous experiments. Thus uptake into the
pathway seemed to be little affected by temperature whereas uptake into
the iimer space was stopped completely by the low temperature. This is
certainly consistent with the hypothesis that movement through the path-
way is through cellulose cell walls whilst movement into the inner space
of the cells is through cytoplasmic membranes.

94

P.E. WEATHERLEY

2-2

^2-0
a 1-8

D
UJ

I

0

ttO-8
gO.6

\

1-4

1'2-

0-4,

2 5-2 9 C

O 10 20

Ihr.

22-6"'C

fX-

\<

O 10 20 30 40 50
TIME (MINUTES)

ra-s^c

e'c 195°C

70-5

v.^..

E

■\

' ~ - «.

^04

•

""---.,

cn

""~ •- , •

XO-3

D
-I

u.

• *,•

0-2

• /

cr

/

UJ

-•- /

h-

•-. /

<0-1

--^.7

2 3 4

TIME (HOURS)

Fig. 5. A: The effect of temperature on uptake into the inner and outer spaces. Trans-
piration was stopped by immersion in water below 3°C. The first phase of the die-away
proceeded normally for 22 minutes (i.e. into the outer space). Thereafter there was no
uptake for i hour. Only an immersion in water at 22-6°C was the second phase of
uptake able to proceed (i.e. into the inner space) . B : The effect of lowering the tempera-
ture on the flux of water through a tomato root system with the continuous application
of a pressure difference of 2 atm across the cortex. (Redrawn from Jackson and
Weatherley, 1962.)

III. MOVEMENT ACROSS THE ROOT CO RTEX

Here, entirely different methods were used. In essence these were based
on the following concept. If a permeable barrier permits only diffusional
passage of water, then equivalent osmotic and pressure gradients will
result in an equal flux of water. If on the other hand mass flow can occur

THE PATHWAY OF WATER MOVEMENT 95

in addition this will only come into operation with a pressure gradient
and wiU result in a greater flux in response to pressure than to an equivalent
osmotic gradient.* It has been shown (Sabinin, 1925; Arisz et al, 195 1)
that root exudation conforms to the equation

f=ko{Os-Om) (iv)

where/equals the flux of water across the cortex, Og the osmotic potential
of the xylem sap and O^ the osmotic potential of the external medium,
j^o is a constant, the osmotic permeability coefficient, reflecting the pernie-
abihty of the root cells to the osmotic movement of water. If in addition
there is a difference of hydrostatic pressure P across the cortex:

f^ko{Os-Om) + k^P

Further, if there is a mass flow component of water movement across the
cortex :

f=ko{Os-Om) + k,P+k'P

where ^' is a coefficient reflecting the reciprocal of the resistance of the
cortex to viscous flow of water. Thus

f^k,{Os-Om)+{ko+k')P (v)

For practical purposes it is convenient to lump (^0 + ^) as a single con-
stant kp the pressure permeability coefficient. Evidently if there is no mass
flow (^ =0) then kp = kQ. Thus the problem resolved itself into measuring
feo and kp.

Experimental

Tomato plants grown in water culture were used. Detopped plants were
placed in a pressure canister through the lid of which the cut stem pro-
truded and in which the pressure on the medium surrounding the roots
could be raised by compressed air The medium could be rapidly changed
and thus the osmotic potential around the roots varied (Mees and
Weatherley, 1957). In practice direct measurement of /jq ^^d kp from eqs.
iv and v was not possible owing to changes in k^ itself in response both to
changes in the osmotic potential of the surrounding medium and to changes

* The view is held (see Pappenheimer, 1953) that osmosis itself involves mass flow.
But if an osmotic flux through a semi-permeable membrane is regarded as a catena
involving mass flow through the pores but with a diftusional link in the chain (at
the orifice of each pore), then osmotic pressure and hydrostatic pressure will still have
identical effects.

96 P.E. WEATHERLEY

in hydrostatic pressure. The eventual technique for estimating the osmotic
permeabihty coefficient was to measure the immediate change in flux
caused by a change in the osmotic potential of the medium, the hydrostatic
pressure remaining constant (Arisz's method). Thus

f,= k,{Os-Onn)

/2= kQ{Os-Om?)
^1-/2 = K{Oni2- Omi)

or

L =

where/i and/2 are the water fluxes with external media of osmotic potential
Omi and Om2- In this method the duration of the measurements was kept
very short so that the osmotic potential of the xylem sap (Og) had no
chance to change appreciably. The pressure permeabihty coefficient was
measured as the change in flux caused by a change in external pressure, the
osmotic potential of the medium being kept constant. Thus from eq. v

f^=k^{Os-Om) + kpP^
f^=ko{Os-Om) + kpP2
f,-f,= kp{P,-P,)

^^=AP

where /i and/2 are the water fluxes with appHed pressures of Pj and P^.
Under conditions of appHed pressure the osmotic potential of the xylem
sap {Os) was small so that any changes in Og could be safely neglected. In
effect the osmotic permeabihty coefficient was measured as the change in
flux in response to unit change of osmotic potential of the external medium
whilst the pressure permeability coefficient was measured as the change in
flux in response to unit change of apphed pressure.

A comparison of measured values of the osmotic and pressure perme-
abihty coefficients is shown in Table i. It will be seen that in every experi-
ment kp was greater than /?„, the mean value of fep/^o being about 1-3. This
imphes that with a pressure gradient of about 2 atm f of the flux was
osmotic and | mass flow.

These two fluxes could also be differentiated by the use of cyanide. As
shown in Table 2, three hours after the addition of cyanide k^ suffered an

THE PATHWAY OF WATER MOVEMENT

97

Table

I

Comparison of permeability coefficients

Osmotic

potential

Pressure

Osmotic Pressure

of the

(atm)

permeability permeability

Experiment

medium

coefficient, coefficient,

number

(atm)

kg kp

kp/k'

I

1-25

2-03

4-35 5-9

1-36

2

0-6

2-01

11-9 14-5

1-22

3

0-6

2-i8

9-4 13-9

1-48

4

0-6

2-i8

8-9 II-6

1-30

(Data from Mees and Weatherley, 1957)

almost 90"/o inhibition whereas kp-ko only 20% in one experiment and
about 60% in another.

One of the most striking features of these results was the demonstration
of a several fold increase in k^ following a rise in pressure of about 2 atm.
This constitutes a direct confirmation of the conclusions of Brewig
(1936-39) and Brouwer (1953-54) who worked with whole transpiring
plants. Significant though this may be in indicating that transpirational
tensions reduce the resistance of roots to osmotic water flux, it hardly
clarifies the complex picture of water movement through the root for the
mechanism of this change in permeabihty is as yet unknown. In view of the
insensitivity of the transpiration pathway in the leaf to low temperature it is
noteworthy that flux through the root is not only sensitive to metabohc
inhibitors as shown above but is also greatly reduced by lowering the
temperature (see Fig. 5B). Evidently metabolic activity is necessary to 'keep

Table 2
The effect of cyanide on the osmotic and pressure permeability coefficients

^0

kp

kpjko

kp-ko

Before addition of KCN

expt. I

8-26

11-66

I-4I

3-40

expt. 2

5-80

8-84

1-52

3-04

3 h after addition of

expt. I

i-oi

2-23

2-21

1-22

5X 10 m-KCN

expt. 2

0-70

3-53

4-97

2-83

Inhibition (%)

expt. I

87-75

—

—

64-1

expt. 2

87-9

■

"

20-6

(Data from Mees and Weatherley, 1957)

98 P. E. WEATHERLEY

the door open' to the water flux in response to the purely physical force of
a pressure difference.

IV. CONCLUSIONS

An analysis of the die-away curve of continued water uptake by a detached
leaf when transpiration is suddenly stopped, can be understood in terms of
a model which suggests that the water in the leaf consists of two phases :
the pathway of transpiration itself and a second phase lying off-stream and
separated from it by a barrier of relatively high resistance. Thus at the
instant of stopping transpiration, water was found to pass into the second
phase at only about J^ of the rate of the transpirational uptake.

In view of the cell consisting broadly of regions of high permeabihty
(e.g. cell walls) on the outside separated by barriers of low permeabihty in
the cytoplasm from imier regions (e.g. vacuoles), it seems likely that the
transpiration pathway is the 'outer space' of the cells and the off-stream
phase is the 'inner space'. The experiments which have been described do
not tell us precisely whether the outer space of the cells includes the cyto-
plasm or is the cell wall alone. The seeming lack of sensitivity of water
uptake into the outer space to temperatures a little above freezing point
suggests perhaps that the cytoplasm is not included. The cytoplasm might
well be in a gel state at these low temperatures when uptake of water would
be mainly diffusional and probably too slow for the observed rapid
absorption. In this connection it is interesting that from their study of the
water relations of leaf discs Carr and Gafr(i96i) have concluded that the
cell-wall water is a significant and important fraction of the leaf water
content and indeed their evidence strongly suggests that the outer space
referred to in this paper should be regarded as the cell wall. We have
obtained no information on the relative volumes occupied by the inner
and outer spaces ; this is clearly essential for ascertaining their nature and
will be the subject of further work.

The conclusion that the water deficit in a leaf can be partitioned into
phases is perhaps a side-issue from the point of view of this discussion.
Nevertheless it may have important physiological, ecological and even
technical implications (Carr and Gaff, 1961 ; Barrs and Weatherley, 1962).
For example the inner space, at least in detached leaves responds to changes
of external water potential at only /^ of the rate of the outer space, and
this could lead to the inner space being cushioned from external fluctuations
as envisaged by Carr and Gaff This aspect clearly deserves further intensive
study.

THE PATHWAY OF WATER MOVEMENT 99

If water moves so readily through the mesophyll walls the same might
well be expected of parenchymatous cells generally and the root cortex in
particular. How then is this reconciled with at least 75 % of the flux through
the root being due to osmotic diffusion and its extreme sensitivity to cyanide
and low temperatures? As was suggested in the introduction the answer
probably lies in the root endodermis. Here, as is well known, flow through
the walls is prevented by the casparian strips and the transpiration stream
must be canalised through the cells. Thus the root behaves Hke an osmometer
albeit one possessing a membrane endowed with solute secreting proper-
ties, sensitive to pressure gradients and needing constant metabohc activity
to maintain its permeabiHty to water.

As for the difference between k^ and kp this may be regarded as due to
mass flow through the passage cells in the endodermis or through regions
in which the casparian strips are not suberised. In the case of culture-grown
tomato plants these together seem to allow about J of the flux through the
root as mass flow with pressure differences of about 2 atm. On this view
and assuming movement in the xylem is by mass flow, transpirational flux
is a purely mechanical flow between soil and air except at one point, the
endodermis, which constitutes the only Hving barrier in the whole complex
catena. Thus the flux from soil to air through the plant is a tensile stream
everywhere save through the inner space of the endodermis where the
water representing at least | of the total flux is transitorily under pressure.
The other cells of the root, cortex, stele and leaf, play little part as Dixon
recognised (1938), but merely act like manometers attached to the main
stream and adjusting their water content, perhaps somewhat tardily, to the
tension therein. No doubt they are also in a state of dynamic equilibrium
with the stream as regards ions and other solutes (Jackson and Weatherley,
1 961). But through the endodermis alone are water and solutes dispensed
through the hving cells. As was recognised long ago, it is a knowledge of the
physiology of this important tissue which may be crucial to our further
understanding of water and ion movement in the higher plant.

REFERENCES

Arisz, W.H., Helder, R.J. & Nie, R. van (195 i) Analysis of the exudation process in

tomato plants. J. exp. Bot. 2, 257.
Barrs, H.D. & Weatherley, P. E. (1962) A re-examination of the relative turgidity

technique for estimating v^^ater deficits in leaves. (In the press)
Bernstein, L. & Nieman, R.H. (i960) Apparent free space of plant roots. PI. Physiol.

35, 589-
Brewig, a. (1936) Beobachtungen iiber den Einflusz der Sproszaugung auf die
StofFdurchlassigkeit der Wurzel. Ber. dtsch. Bot. Ges. 54, 80.

100 P.E. WEATHERLEY

Brouwer, R. (1953) Water absorption by the roots of Vicia faba plants at various

transpiration strengths. Proc. Kon. Ned. Akad. Wet. Series C56, 105, 129.
Brouwer, R. (1954) The regulating influence of transpiration and suction tension on

the water and salt uptake by the roots of intact Vicia faba plants. Acta hot. Need.

3, 264.
Carr, D.J. & Gaff, D.F. (1961) The role of the cell wall water in the water relations

of leaves. Utiesco-Spain Symposium on plant-water relationships in arid and semiarid

conditions. Paper 28.
De Lavison, J. DE RuFZ (1910) Du mode de penetration de quelques sels dans la

plante vivante. Revue gen. Bot. 22, 225.
Dixon, H. H. (1938) Transport of substances in plants. Proc. Roy. Soc. B 125, i.
HiJLSBRUCH, M. (1956) Water transport in parenchyma. Encyclopedia of Plant Physiology.

Ed. W. Ruhland, vol. Ill, 522.
Jackson, J. E. & Weatherley, P.E. (1962) The effect of hydrostatic pressure gradients

on the movement of potassium across the root cortex. J. e.xp. Bot. 13, 128.
Kramer, P.J. (1932) The absorption of water by root systems of plants. Amer.J. Bot.

19, 148.
Levitt, J. (1956) The physical nature of transpirational pull. PI. Physiol. 31, 248.
Mees, G.C. & Weatherley, P.E. (1957) The mechanism of water absorption by

roots. I : PreUminary studies on the effects of hydrostatic pressure gradients.

II : The role of hydrostatic pressure gradients across the cortex. Proc. Roy. Soc.

B147, 367, 381.
Pappenheimer, J.R.(i953) Passage of molecules through capillary walls. Physiol.

Rev. 33, 387-

Sabinin, D. a. (1925) On the root system as an osmotic apparatus. Bull. Inst. Recherche
biol. Univ. Perm. {Molotov) 4, Suppl. 2, 129.

Scott, L. I. & Priestley, J. H. (1928) The root as an absorbing organ, i : A recon-
sideration of the entry of water and salts in the absorbing region. New Phytol. 27,

125-
Sthugger, S. (1938-9) Die Lumineszenzmikroscopische Analyse des Transpirations-

stromes in Parenchymen. Flora, Jena, 133, 56.

WATER SATURATION DEFICIT AND ITS
DEVELOPMENT IN YOUNG AND OLD LEAVES

Jmf Catsky

Institute of Biology, Czechoslovak Academy of Sciences,
Praha, Czechoslovakia

INTRODUCTION

The origin and development of the water saturation deficit (WSD) in
plants in situ represents a problem not yet satisfactorily explained from the
point of view of ecology. The authors of the first studies on the water
deficit of plants (Stocker, 1928, 1929a, b; Magyar, 1930; Schanderl, 1930;
Vassiljev, 193 1, and a number of others) emphasised the importance of
this then newly-defmed value especially in ecological investigation, par-
ticularly in view of the fact that the values of the water deficit make it
possible to compare the water balance of plants from different locaHties.
The significance of the water deficit is, however, not restricted to this type
of work. Its values gain in importance especially on detailed examination
of wilting of plants and in studying the relationships of individual life
processes in plants on the supply of plant tissues with water.

The present communication was conceived from this very point of
view, its aim being to be extended by further studies of the dynamics of
plant wilting. It attempts to correlate the existing rather varied and
occasionally contradictory fmdings on the water deficit from the point of
view of physiological ecology, to check the methods of its determination
and to obtain fundamental data on the course of wilting of some model
plants.

LITERATURE

The concept of water deficit as one of the most important indicators of
plant water balance was introduced by Stocker (1928, 1929a, b) on the
basis of Iljin's studies (1923). His original method of estimation of WSD
was used by a number of authors. Relatively very detailed data on the
absolute value of the water deficit under normal and extreme conditions
resulted from their work, together with data on its diurnal and seasonal
changes, relationships with climatic factors, etc. As was mentioned in a
previous paper (Catsky, 1959) the rehabihty of these data is unfortunately
rather questionable on account of the considerable error which might be

102 JIRICATSKY

incurred on application of Stocker's method to not quite mature leaves.
The uptake of water by a severed young leaf is not produced only by a
momentary incomplete water saturation of the tissues but to a considerable
extent also by their extension growth. The saturation to constant weight
required by Stocker's method which is reportedly achieved in young
leaves within several days actually marks the beginning of leaf dying.
From this point of view it is possible to explain even some surprising data
found in the Hterature concerning the dynamics of wilting of young and old
leaves (e.g. Magyar, 1930; Arvidsson, 195 1) or the annual pattern of water
deficit (e.g. Ackley, 1954).

The possibility of an error in estimating the water deficit in growing
tissues was mentioned by Welten (1933) and by Miiller-StoU (1935) who,
however, did not consider its value as significant and did not pay any
attention to it. More recently the possibility was taken up by Weatherley
(1950) and Yemm and Willis (1954). The last-named authors, therefore,
when estimating the water deficit of detached whole leaves, determine the
shape of the saturation curve and by means of graphical extrapolation
subtract the amount of water required for growth. Rutter and Sands (1958)
also call attention to the very slow uptake of water by the dwarf shoots of
Pinus sylvestris after 10 hours of saturation ; they consider it as a consequence
of osmotic changes within the tissue which contained abundant starch. It
is very hkely that this 'osmotic uptake' actually plays a role during satura-
tion of detached leaves or leaf discs.

The importance of the WSD values as a rehable indicator of water balance
was clearly demonstrated both by the author of the term and by a number of
his followers. The weakest point of the investigation of WSD is now
apparently the method of its estimation which, strangely enough, has
remained practically unchanged since the time of the first of Stocker's
papers. It was only Weatherley who (1947, 1950, 195 1) used, for estimating
the WSD, discs cut out from experimental leaves and floating on water. A
similar method was used by Wormer (1956). Recently a method was
suggested for estimating the WSD in discs saturated in a moist plate made
of polyurethane foam (Catsky, i960). By using the discs it was possible to
cut down the time required for attainment of full turgescence of the tissue
and thus to decrease the effect of extension growth on the WSD value
obtained. Even here, however, the possibility of a certain even if small
error due to this growth persists.

More complete data on the dynamics of wilting of plants in situ are very
rare in the hterature. Important contributions to this problem are cited by
Stocker (1929a), Magyar (1930), Arvidsson (1951), Slavik (1955), Halevy

WATER SATURATION DEFICIT 103

(i960) and others. These authors call the attention to the high WSD of
young leaves (as determined by Stocker's method) on plants under natural
conditions. Rutter and Sands (1958) and Sands andRutter (1958) bring out
the close relationship between the WSD and transpiration and soil humidity.
Both of their papers contain valuable data on the WSD values during
different water content of the soil.

MATERIAL AND METHODS

About ioo-150-day-old plants of fodder cabbage [Brassica oleracea L.,
convar. acephala /DC. I Ahf., var. meduUosa Thell. in Hegi) of the sort
Markstammkohl, and of rape [Brassica napiis L., var. oleifera DC.) of the sort
Slapska, grown in pots in a greenhouse were used for the experiments.
Plants of both species had between 6 and 9 leaves.

The water deficit was estimated by a method suggested earher (Catsky,
i960) modified for young leaves: a cork-borer was used to cut out discs of
8 mm in diameter from the leaves; the discs were then weighed, saturated
in openings (75 mm in diameter) in a moist plate of polyurethane foam.
After 3 hours of saturation the discs were taken out, dried with filter paper,
weighed and saturated again. After another 3 hours they were again dried,
weighed and desiccated at I05°C. The WSD was calculated by the
following formula:

0/ ^3j) ^ {2x weight after 3 h)- (weight after 6 h)- initial wt. ^ ^^^
[ix weight after 3 h) — (weight after 6 h) — dry wt.

The apphcabiUty of this modification was confirmed by experiments to be
described in the experimental section.

Other details of method will be presented with the individual
experiments.

RESULTS

I . Saturation Curve of Whole Leaves

The experiments carried out in this section were to investigate the course of
water uptake by detached whole leaves during estimation of WSD
according to Stocker ; the results were to serve as a basis for the experiments
to be described later concerning the experimental proof of 'growth-
WSD'. Six young and 6 old leaves were detached from well-watered
plants in pots. The leaves were weighed and saturated in the dark through
8

V / V

I04

JIRICATSKY

their petiole immersed in water in a water-saturated atmosphere. At given
time intervals the leaves were dried with a filter paper and weighed. Water
uptake was expressed as percent initial value after subtracting the dry-
weight. The result (Fig. i) clearly demonstrates the qualitative difference
between the saturation curves of young and of old leaves.

Fig. I . Saturation of old (1,2) and young (3 , 4) leaves in estimating the water saturation
deficit by Stocker's method, i, 3-rape; 2, 4-fodder cabbage. Abscissa: time of
saturation in hours ; ordinate : weight of water in per cent initial weight.

2. Origin of *Growth-WSD' in Leaf Tissue Discs

Experiments shown in Fig. 2 were designed to demonstrate experimentally
the origin of the 'growth-WSD' and its subsequent disappearance. Two
equal sets of discs were cut out from young leaves of fodder cabbage and
saturated in the polyurethane plate (see Methods). After 3 hours the discs
were weighed ; the control ones were saturated further and the experimental
ones were placed on a nylon mesh in a Petri dish containing a water-satu-
rated atmosphere and placed in darkness. After i hour, these experimental
discs (in which a growth WSD and hence an actual WSD was presumed to

WATER SATURATION DEFICIT

105

be produced) were then saturated in the polyurethane plate. It follows
from the results that the experimental discs reached the control curve, i.e.
that growth persisted in spite of interrupted water supply and gave rise to
a growth WSD (Fig. 2).

Fig. 2. Saturation of two sets of discs from young leaves in one of which water supply
was cut oif between the third and fourth hour. For details see the text.

3. Verification of the Applicability of the Method of WSD
Estimation by Means of Extrapolation

It was the aim of the following experiments to test the apphcability of
extrapolation (Yemm and WiUis, 1954) in estimating the WSD by the
'disc method'. Experimental leaves were saturated in the dark for 24 hours
with their petioles immersed in water in a water-saturated atmosphere.
After that, rectangles of leaf tissue without large nerves were cut out from
them, well dried and left to wilt on a nylon mesh. After reaching a certain
WSD, which was calculated from the observed loss in weight of the initially
saturated rectangles, discs were cut out from the whole area of the sample
and their WSD estimated after saturation in a polyurethane plate by extra-

io6

JIRICATSKY

%

WSD

20

10

0

%

WSD

20

o

/ o

o /
° /q o

o /

PP o

o

/{?

c?

10

Fig. 3

20

;

o

o

o / o

°/ o

a/ o

o/ °.

o

o

o ,
O / r

' oood8>ocxx>— '

^ooo
o o

/o

20

Fig. 4

Figs. 3 and 4. Verification of the water saturation deficit estimation by the disc method
and extrapolation in old (Fig. 3) and young (Fig. 4) leaves. Abscissa: WSD values
obtained by the disc method; ordinate: WSD values derived from wilting of
saturated tissue (see the text).

WATER SATURATION DEFICIT 107

polation (for the formula, see Methods). It was found by this experiment
(Figs. 3 and 4) that the extrapolation procedure is apphcable even to young
leaves as the error caused by extension growth is decreased to a very low
value.

4. Origin and Development of the WSD in Plants In Situ during

Decreasing Soil Moisture

Experimental plants (a total of 18 plants of fodder cabbage and 36 plants
of rape) were divided into groups of six. These groups were then taken as
single samples. Before the experiment the plants were weU watered and
left overnight in a water-saturated atmosphere. Then three discs were cut
out from each leaf of the genetic spiral and their WSD determined jointly
in corresponding leaves (i.e. 18 discs from the first leaves, 18 discs from the
second leaves, etc.) . The plants were then placed in a greenhouse at 1 8-23 °C
and at 65-75% relative humidity and were not watered. During wilting
two more samples were removed for estimating the WSD. Figures 5 and 6
show the course of wilting of leaves of different age in average values.

DISCUSSION

The long-known observations and morphological descriptions of the course
of wilting of plants fmd an experimental counterpart in the results of the
above experiments. Let us consider first the methodological significance of
the described experiments. Their results emphasise very clearly the necessity
of careful interpretation of the results of Stocker's method as well as of
critical interpretation of the general conclusions advanced in older papers
about the water deficit. This is not to say, of course, that Stocker's method
in its original form would be of no use or that it would yield nothing but
erroneous results. The observed effect of extension growth on the WSD
estimation cannot be neglected however, and particularly in cases where
the water deficit of the whole plant is to be estimated. The original method
of Stocker was intended even for estimations of this type and a number of
authors have actually appHed it. On account of the fact that young or at least
partially growing leaves represent a considerable proportion of the leaf
total in most plants, the utmost care should be exercised in such work. To
my mind, this drawback of Stocker's method has probably given rise to
the data on the high water deficit of young leaves (e.g. Magyar, 1930;
Arvidsson, 195 1 and others) and apparently to the data on higher WSD of
plants during the spring months as compared with later seasons (e.g.
Ackley, 1954).

io8

JIRICATSKY

0

Fig. 5

Figs. 5 and 6. The course of wilting of a plant in situ during decreasing soil moisture;
fodder cabbage (Fig. 5) and rape (Fig. 6). Abscissa: days from the beginning of
experiment (= days of wilting) ; ordinate: percent water saturation deficit. The figures
for individual curves indicate the position of the leaf on the genetic spiral begiiming
from the top (leaf no. i : area about 8 cm^^.

The second methodological contribution of this paper consists in the
method apphed to the estimation of the actual water deficit employing discs
of leaf tissue. The use of discs for the estimation of the WSD possesses a
number of advantages over the estimation in whole plants: among others
(technical ones, for instance) are the rapid saturation of the tissue (and thus
a decrease of the extension growth effect) and further the possibihty of
taking representative samples without destroying leaves or whole plants.
Only this method makes it possible to investigate directly the course of
wilting. From the physiological point of view there are no serious objec-
tions to the use of leaf discs as is well seen in the successful work of
Weatherley (1947, 1950, 195 1) concerning water deficit. A basis for the
technical arrangement of the procedure was found in the paper by Bartos,
Kubin and Setlik (i960) and in the hitherto unpublished results of the same

WATER SATURATION DEFICIT

109

authors. Bartos et al. (i960) demonstrated that the intensity of photo-
synthesis (which certainly is a sensitive indicator of the physiological state
of the tissue) is maintained on the same level for several hours (6 and more)
when leaf discs are exposed in a moist polyurethane plate. It thus appears
probable that even water uptake leading to WSD saturation will be the
same in the disc as in the whole leaf at least for a certain period of time.
The saturation curve of young leaf discs has a roughly exponential shape
(Fig. 2) which is in agreement with the Uterature (Oppenheimer, 1954;
Fritz, 1956). In young leaves, the clear linear phase described by Yemm and
WiUis (1954) and amenable to extrapolation could not be found here. It
does not appear probable that the extension growth in the disc would
proceed at a completely identical rate for the whole duration of exposure,
i.e. for 6 hours. In spite of this, the extrapolation suggested by Yemm and
WiUis (1954) and appUed here might help to come closer to the true values
of actual WSD ; Fig. 4 provides some information about the accuracy of
this type of estimation in yoimg leaves. Young leaves display a greater
dispersion of values than older leaves. It must be borne in mind, however,
that the dispersion in both leaf groups is not due only to an error in

no JIRICATSKY

estimation but largely also to the heterogeneity of the leaf-blade (Slavik,
1959)- Another very important source of dispersion in young leaves lies
in the anatomical structure of these leaves, particularly the high number
of large nerves, which cannot be avoided in young leaves and which
might considerably affect the values obtained.

So far attention was devoted solely to problems of method. Let us
consider the results from a general point of view. As was said above, the
uptake of water by a detached young leaf or tissue is caused by a tendency
to saturate the actual water deficit and secondly by the requirement for
water used for extension growth. On the basis of these findings it was
possible to distinguish between the actual water deficit and the 'growth'-
WSD produced in the course of time. We are not dealing here purely with
a problem of method; if the water deficit is considered as a dynamic feature
expressed by water requirement then the growing tissues wiU really possess
a sort of potential water deficit. The 'growth'-WSD thus cannot be
separated from the actual WSD in any strict fashion even if their distinction
is quite clear. This growth-WSD is shown very markedly in experiment
no. 2 where, during a complete cut-off of water supply to a saturated tissue,
this tissue produces a growth-WSD, which, of course, becomes at once an
actual WSD. After restoring the water supply this actual WSD is satur-
ated. A prerequisite of this compensation is the following : the true actual
water deficit, i.e. the sum of the WSD caused by wilting (decrease in
weight) which can be hardly avoided methodologically, and of the
growth-WSD must not reach such level and must not act for such a long
time as to cause inhibition of extension growth.

On the basis of these facts some measurements of the actual WSD were
carried out on plants during decreasing soil moisture. It was the aim of
these experiments to employ the proposed method for obtaining some
fundamental data on the wilting of plants in situ, which could serve as a
basis for more detailed investigation of the dynamics of wilting. The results
support quite unequivocally the view about the preference of young leaves
during wilting of the whole plant. It was not possible, however, to demon-
strate quite unambiguously the differences in the water deficit at the
beginning of wilting, i.e. at WSD between 5 and 8%. It appears that within
this range young leaves possess actually a sHghtly higher deficit than mature
leaves which may be expected in view of the greater transpiration intensity
of young leaves (Slavik, 1956; Halevy, 1956). It cannot be demonstrated
quite conclusively, however, whether this, even if small difference, is not
due to a very intense extension growth of the tissue at the beginning of
estimation. With the possibility of the growth intensity being decreased

WATER SATURATION DEFICIT iii

between the third and sixth hour of estimation, this error cannot be
eHminated by extrapolation. On the other hand, the very small differences
in WSD values obtained by extrapolation in young and old leaves of fully
turgescent plants oppose this possibility. The solution of this problem must
be postponed to further work.

ACKNOWLEDGMENTS

It is my pleasure to thank Dr. B. Slavik for the interest he has taken in the
work described and for many valuable discussions on the topic. My thanks
are due to Mrs. Mandlova for skilled technical help.

REFERENCES

AcKLEY, W.M.B. (1954) Seasonal and diurnal changes in the water contents and water

deficits of Bartlett pear leaves. Plant Physiol. 29, 445-448.
Arvidsson, 1.(1951) Austrocknungs- und Diirreresistenzverhaltnisse einiger Reprasen-

tanten olandischer Pflanzenvereine nebst Bemerkungen iiber Wasserabsorption

durch oberirdische Organe. Oikos, suppl. i, 1-181.
Bartos, J., KuBiN, S. & Setlik, I. (i960) Dry weight increase of leaf disks as a measure

of photosynthesis. Biol. Plant. 2, 201-215.
Catsky, J. (1959) The role played by growth in the determination of water deficit in

plants. Biol. Plant. I, 277-286.
Catsky, J. (i960) Determination of water deficit in disks cut out from leaf blades.

Biol. Plant. 2, 76-78.
Fritz, M. (1956) Ubcr die Aufsattigung abgeschnittener Blatter bei Einstellen in

Losungen von Elektrolyten und Anelektrolyten. Protoplasma, 46, 198-209.
Halevy, a. (1956) Orange leaf transpiration under orchard conditions. V: The

influence of leaf age and changing exposure to Ught on transpiration, on normal

and dry summer days. Bull. Res. Counc. Israel, 5D, 165-175.
Halevy, A. (i960) Diurnal fluctuations in water balance factors of Gladiolus leaves.

Bull. Res. Counc. Israel, 8D, 239-246.
Iljin, W.S. (1923) Der Einfluss des Wassermangels auf die Kohlenstoffassimilation

durch die Pflanzen. Flora, N.F. 116, 360-378.
Magyar, P. (1930) Novenyokologiai vizsg^latok szikes talajon. Pflanzenokologische

Untersuchungen a.u{Szikhdden. Erdeszeti Kiserletek (Sopron) 32, 75-1 18, 237-256.
Muller-Stoll, W.R. (1935) Okologische Untersuchungen an Xerothermpflanzen

des Kraichgaus. Z. Bot. 29, 161-253.
Oppenhelmer, H.R. (1954) Critique experimental de deux methodes employees en

vue d'etabUr le deficit de saturation hydrique (DSH) des feuilles. Rapp. Comm.

^hne Congr. int. Bot. (Paris), Sec. 11-12, 218-220.
Rutter, A.J. & Sands, K. (1958) The relation of leaf water deficit to soil moisture

tension in Pinus sylvestris L. I : The effect of soil moisture on diurnal changes in

water balance. New Phytol. 57, 50-65 .
Sands, K. & Rutter, A.J. (1958) The relation of leaf water deficit to soil moisture

tension in Pinus sylvestris L. II : The variation in the relation caused by develop-
mental and environmental factors. New Phytol. 57, 387-399.

112 JIRICATSKY

SCHANDERL, H. (1930) Okologisclic und physiologische Untersuchungcn an der

Wellen- und Muschelkalkflora des Maintales zwischen Wurzburg und Gambach.

Planta, lO, 756-810.
Slav'k, B. (1955) K dynamice vodnfho deficitu rostlin. (Uber die Dynamik des

Wasserdefizits der Pflanzen.) Preslia, 27, 124-153.
Slavik, B. (1959) Water relations within the area of one leaf blade. Proc. 9th int. hot.

Congr. (Montreal), 2, 367.
Stocker, O. (1928) Das Wasserhaushalt agyptischer Wiisten- und Salzpflanzen. Bot.

Abhandhmgen Qena), Hft. 13, 200.
Stocker, O. (1929a) Vizsgalatok kiilonbozo terniohelyen nott novenyek vizhianyanak

nagysagarol. Uber die Hohe des Wasserdefizites bei Pflanzen verschiedener

Standorte. Erdiszeti Kiserletek (Sopron), 31, 63-76, 104-114.
Stocker, O. (1929b) Das Wasserdefizit von Gefasspflanzen in verschiedenen Klima-

zonen. Planta, 7, 382-387.
Vassiljev, I.M. (193 i) Uber den Wasserhaushalt von Pflanzen der Sandwiiste im

siidosthchen Kara-Kum. Planta 14, 225-309.
Weatherley, P.E. (1947) Note on the diurnal fluctuations in water content in floating

leaf discs. New Phytol. 46, 276-278.
Weatherley, P.E. (1950, 1951) Studies in the water relations of the cotton plant.

I: The field measurement of water deficits in leaves. New Phytol. 49, 81-97;

II : Diurnal and seasonal variations in relative turgidity and environmental factors.

New Phytol. 50, 36-51.
Welten, M. (1933) Physiologisch-okologische Untersuchungcn iiber den Wasser-
haushalt der Pflanzen mit besonderer Beriicksichtigung der Wasserabgabewider-

stande. Planta 20, 45-165.
WoRMER, Th.M. (1956) Mise au point d'une technique pour I'etude du bilan d'eau

du palmier a huile {Elaeis gtiineensis). C. R. Conf.franco-brit. sur le palmier a huile,

1956, 181-190.
Yemm, E. W. & Willis, A.J. (1954) Stomatal movements and changes of carbohydrate

in leaves o{ Chrysanthemum maximum. New Phytol. 53, 373-396.

WATER RELATIONS IN
NATURAL CONDITIONS

I

ON THE DISTRIBUTION OF THE PRECIPITATION

IN A SPRUCE STAND

AN ATTEMPTED ANALYSIS

M. G. Stalfelt
University of Stockholm, Sweden

An attempt was made to analyse the water economy of a natural plant
community. This was done by measuring the water supply to the root
zone and the water uptake through overground organs, as well as by
measuring the distribution of the precipitation by transpiration, interception
and surface run-oft'.

For this purpose, I chose a plant community of simple composition,
namely, a spruce wood, in which the tree layer consisted only of spruce
{Picea excclsa Link.) and the remainder of the higher vegetation was chiefly
in the form of mosses. The stand was about 40 years old, and was not
completely closed. The trees covered about half the ground surface. The
other half-that is, the gaps between the trees-was covered mainly by
Hybcomium species. Mosses grew near the periphery of the surface under
the tree canopy; otherwise, there was only a htter of needles, pieces of bark,
twigs, remains of cones, etc.

The site was in southern Sweden (Scania). It is a low-hiHed moraine,
.e., an imstratified, unsorted glacial deposit, of which about half consists
of fens and bogs. The other half-the low hills-is covered by woods.

Transpiration was measured in 11 spruces; these are denoted in the
following as the experimental trees. Three of them grew on the edge of a
fen, with the water table about 0-2 m below the base of the tree stems. The
remaining trees grew on the moraine hills, and had a distance to the water
table ranging from 2 to 7 m.

Precipitation was measured on the open ground, as well as below the
crowns of the trees, and in the gaps between the trees. Triangular troughs,
with a length equal to half the diameter of the crown, were placed under
the crowns. Their opening measured 53-66 dm^. The apex of the triangle
lay close to the stem of the tree, and the base in the periphery of the crown.
The triangular shape was chosen in view of the fact that the quantity of
water penetrating the crown of a spruce differs in the peripheral and central
parts of the ground covered by it. The quantity increases from the centre
outwards, and is relatively great under the tips of the branches.

1

ii6 m.g.stAlfelt

Two such troughs were used for each of 5 of the experimental trees. One
trough was empty, and the other contained a piece of the top portion of the
soil. This was cut from the ground below the trough, and consisted of the
organic layer of raw humus and litter lying on the mineral soil. The roots
of the trees spread in the uppermost layer of the mineral soil, and penetrated
to a varying depth, generally a maximum of 0-5 m.

Interception in the crowns of the trees and in the top portion of the soil,
as well as the quantity of water that penetrated the top portion of the soil
and reached the root zone of the trees, were calculated from the values for
precipitation on the open ground, in the empty trough, and in the trough
containing the top portion of soil.

The gaps between the trees were usually small (a few or some tens of
square metres), and were infdtrated by the roots of the trees. Consequently,
the precipitation on these areas could be utihsed by the trees. Rain gauges
were also set up in the gaps; they were round and smaller than the troughs,
having an opening of 375 cm^. In each of 4 gaps (2, 4, 10 and 74 m^) two
gauges were set up. One was empty, and the bottom of the other one was
covered with a piece cut out of the top portion of the soil-in this case
consisting of moss, with the htter present in it. The gaps were surrounded
not only by the experimental trees, but by many other trees as well. The
interception in the mossy layer was calculated from the values obtained for
precipitation.

Calculations were also made of the rain-shielding effect of the surround-
ing trees -that is, of the screening effect on the precipitation (precipitation
is less in the gaps than on open ground) -and of the quantity of water which
penetrated the top portion of the soil, and reached the mineral soil, and
thereby the root zone of the trees. The depth to which this water penetrated
was determined, among other ways, by measuring the humidity of soil
specimens taken at various times of the year.

Attempts were also made to measure the water uptake through needles
and other overground organs. Weighing of whole plants allowed determi-
nation of their water deficit, as well as of the changes that took place after
they had been immersed in water for some hours, or had stood in rain or
fog. It could then be estabhshed that a not inconsiderable amount of water
was absorbed by the overground organs, if they had previously had a water
deficit. In the case of the experimental trees, the exact quantity could not,
however, be determined.

The whole experimental period amounted to 4 years. The collected data
on precipitation were divided into two periods, namely, the months of
September- April and May-August. The object was to permit a comparison

PRECIPITATION IN A SPRUG£ STAND 117

with the transpiration of the trees, which was measured during the 4 months
of May-August. At the site in question, appreciable transpiration occurs
only during this time.

During the 4 experimental years, the mean annual precipitation at this
site was 793 mm of which 495 mm fell in September- April, and 298 mm
in May- August. The distribution of these quantities on the canopy, the top
portion of the soil and the root zone of the trees can be seen from Fig. i,
showing the distribution on and below the tree canopies. Fig. 2 shows the
distribution in the gaps between the trees.

The crowns of the trees are effective chiefly through their strong intercep-
tion. This took about half of the precipitation, namely, 170 mm (57% of
298 mm) in May- August, and 257 mm (52% of 495 mm) in September-
April. It must, however, be pointed out that the crowns of the experimental
trees were well developed, and reached the ground or close to it. The surface
covered by the individual crown was minimally 14 m^ and maximally 56.
The quantity of needles belonging to each tree- which was measured and
calculated at the end of the experimental period -ranged from 53 to 204 kg.

Actually, the interception of the crowns is greater than that shown in
Fig. I. To these figures should be added the precipitation screened off from
the gaps by the crowns; it is denoted by the values /and L in Fig. 2.

The values given for interception are the total figures for several months.
If the interception on individual occasions is compared, varying values are
noted, since the quantity of intercepted water is determined by the precipi-
tation per time unit, and by the duration of precipitation. The quantity of
intercepted water may be shght-for example in a cloudburst. It may, on
the contrary, be great -approaching 100%-when the quantity of rain is
small.

Interception in the top portion of the soil was also considerable. During
the summer months, almost half the precipitation reaching the gaps was
retained, and in September-April about one-fourth.

The annual precipitation reaching the root zone below the canopy was
262 mm; 73 mm during the summer, and 189 mm in September- April.

The water supply to the root zone in the gaps is somewhat greater. This
is because the precipitation is greater in the gaps than below the canopy.
Consequently, interception is greater in the gaps, and the water supply to
the root zone also greater. Of the 793 mm annual precipitation, altogether
3 16 mm reached the root zone in the gaps; 100 mm in May- August, and
216 mm during the rest of the year.

The gaps occupied about the same area of ground as the part covered by
the crowns of the trees. The water supply to the root zone can therefore be

Ii8

M. G. STALFELT

calculated as half the precipitation (measured in mm) on these two surfaces.
This gives 87 mm (half of 73 + 100 mm) for May- August, and 202 mm (half
of 189 + 216 mm) for September- April, or totally 289 mm.

The transpiration of the trees was determined by the 'momentan method*
(Stocker, 1929), i.e. by weighing severed leaves, shoots or parts of shoots.

aoo

600-

L AOO

200

Precipitation

on open

ground

3
<

I

(0

Z

Precipitation
upon and under
the crowns

7/

B

C Interception
in the crowns

D Intercept, in
the top portion
oF the soil

E , Precipit reaching
the root zone

F. Interception in
the crovyns

Intercept in the
top portion of
the soil

H. Precipit reaching
the root zone

Fig. I. Precipitation on and below 5 spruce trees (mean value of 4 years). A and B.
Annual precipitation on open ground: 793 mm; 495 mm in September-April (A) and
298 mm in May-August (B). C. Interception in the crowns during September-April:
260 mm (52-3% of 495 mm). The interception in the crowns includes the (unknown)
quantity of wind-driven precipitation collected, and thus screened-ofF from the gaps.
D. Interception in the top portion of the soil (moss, Utter and raw humus) in Septem-
ber-April: 46 mm (9-3% of 495 mm). E. Precipitation reaching the root zone of the
trees in September-April: 189 mm (38-4% of 495 mm). F. Interception in the crowns
during May-August: 170 mm (57-2% of 298 mm). The interception in the crowns
includes the (unknown) quantity of wind-driven precipitation collected, and thus
screened off from the gaps. G. Interception in the top portion of the soil (moss. Utter
and raw humus) in May-August: 55 mm (18-4% of 298 mm). H. Precipitation
reaching the root zone of the trees in May-August: 73 mm (24-4% of 298 mm).

PRECIPITATION IN A SPRUCE STAND

119

The reliability of this method is dependent on whether or not the cut part
of the plant does, in fact, give off the same quantity of water before and
after cutting. No generally appHcable answer can be given to this question,
since the effect of cutting may vary in different species. Moreover, it may
vary with such factors as the hydration and osmotic equipment of the plant,

800r

600

£ AGO

200

O

Precipitation
on open
ground

a
<

I.

a

<

I

Precipitation
in the gaps
between the trees

Precipitation
I. screened oFF
from the gaps

Intercept, in the
J. top portion oF
the soil

Precipitation
K.reaching the
root zone

Precipitation
L. screened ofF
From the gaps

Intercept, in the
M.top portion of
the soil

Precipitation
'^reaching the
root zone

Fig. 2. Precipitation in the gaps between the trees (mean value of 4 years). A and B. As
in Fig. I . /. Wind-driven precipitation collected by the tree canopy, and thus screened
off from the gaps: 205 mm (41-5% of 495 mm). J. Interception in the top portion of
the soil: 74 mm (14-8% of 495 mm). K. Precipitation reaching the root zone of the
trees: 216 mm (43 "7% of 495 mm). L. Wind-driven precipitation collected by the
tree canopy, and thus screened off from the gaps: 106 mm (35-6% of 298 mm). M.
Interception in the top portion of the soil : 92 mm (30-9% of 298 mm). N. Precipitation
reaching the root zone of the trees: 100 mm (33-5% of 298 mm).

its xeromorphy and rapidity of reaction. Examples have been given by
Parker (1957) and by Eger (1958). Consequently, it is necessary in every
individual case to test the agreement between the size of transpiration before
and after cutting.

9

120

M. G. STALFELT

Unfortunately, a control study of this kind often meets with great
technical difficulties. This apphes in particular when the plants consist of
large trees, as in the present investigation. 1 therefore used young (5- to
8-year-old) spruce plants for the control measurements, as described earlier
(1944). Transpiration was then measured by weighing the plants, after the

Precipitation
eOOr °^ open ground

600

I.

E

400

200

a
<

I

L.
SI

<
I
>-

Water
supply to
the trees

Transpiration
from trees on
ground- water
depth. 0'2nn

to the
root zone
P- during Sept-
April

during
'^ May- August

2.7nn

Fig. 3. Comparison between transpiration and water supply of the trees. A andB. As
in Fig. I. O, P, Q. Water supply to the trees from the soil below them and in the
gaps, as well as from the water-absorption of the needles. O. Moisture supply from
the ground-water and from the water-absorption of the needles. Quantity not
defmitely known. P. 202 mm (41% of 495 mm). Mean value for 5 spruces, and for
the root zone of the trees under the crowns and in the gaps. Q. 87 mm (29% of
298 mm); otherwise as in P. R and S. Transpiration. R. 211 mm (71% of 298 mm).
Mean value for 8 trees (5 in P and Q and 3 other trees on the same site), with a
ground-water depth of 2-7 m. S. 378 mm (127% of 298 mm). Mean value for 3 trees,
with a ground-water depth of about 0-2 m.

roots had been freed from soil by suspending them in water, and wrapped
in aluminium foil. After several weighings, the stem was severed close to
the root and weighing continued for the next 5 minutes. In some cases

PRECIPITATION IN A SPRUCE STAND 121

transpiration increased after cutting the stem, whereas in other cases it
decreased. The number of decreases was, however, greater than the number
of increases, and transpiration was about 10% lower after cutting the
sample than before it.

Allerup (1959), using 7- to lo-day-old wheat plants grown in water
culture, found an increase in transpiration after cutting stem or root in air,
immediately or shortly after this process. He assumed that the plants were
well supphed with water, since they were taken from a water culture. It
therefore appears, he says, 'reasonable to assume that in order to find an
increase in transpiration upon cutting, it is necessary to ensure that trans-
piring parts of plants have ample available water reservoirs . . .' (p. 912).
For this reason, Allerup criticised my experiments with spruce (1944), and
stated that my failure to find an increase in transpiration in all my experi-
ments must probably be attributed to the fact that the plants used had
different water reserves. He also suggested that the plants I used had injured
roots, since they had been freed from soil by suspension directly before the
experiment.

With respect to the question of whether or not the experimental plants
should be water-saturated, it must be stressed that my control experiments
were not only intended to test how the plants reacted when water-saturated,
but also how plants with a varying water deficit reacted to cutting. My
transpiration measurements on spruce were, in fact, made at different times
of the day, and on days with varying weather- during both rainy and dry
periods. Consequently, they were made on objects which almost invariably
had a water deficit of varying degree. Normally, there is an initial water
deficit in the morning- when transpiration starts -and it increases in the
course of the day. Furthermore, the deficit is lowest immediately after a
rainy period, and rises with increasing length of the subsequent dry period.
It was in order to make the control measurements comparable with
measurements of the transpiration of forest trees under normal conditions-
that is, with varying degrees of water deficit-that I used spruce plants that
also had a varying water deficit.

I do, on the contrary, attach greater importance to Allerup's other
criticism, namely, that possible injury to the roots may have influenced the
reaction after cutting the stem. I therefore repeated these experiments, but
using spruce plants that had been allowed to grow in a nutrient solution for
some weeks beforehand. The plants were 2 years old, and were taken from a
plant nursery.

After the roots had been freed from soil by suspension in water, the plants
were placed in a nutrient solution for 6-8 weeks before starting the experi-

122

M. G. STALFELT

ment. Transpiration was then measured in the same way as earHer. Thus,
the root system was wrapped in aluminium foil. The plants were then placed
on a scale on which rapid readings could be made. They remained on the
scales during the whole experimental period, during which they were
exposed to illumination of about 1 5,000 m candles. The weight was read off
every 2 or 3 minutes. After 10-15 minutes, the stem was severed at the
base, the plants were weighed at once, and then every other minute for 6
minutes. Before the experiment, the plants were allowed to transpire with
or without a water supply for a varying period. This resulted in a water
deficit ranging from 0 to 32%.

In 28 such experiments, either an increase or a decrease in transpiration
occurred during the first 6 minutes after cutting. In 12 of these cases an
increase occurred, and in 16 cases a decrease. In another such experiment,
the value remained unchanged. As in the earlier measurements (1944), the
sum of the decrease in the individual experiments was about 10% greater
than the sum of the increase.

The results are in agreement with the measurements made by Rutter
(1959) on Pimis sylvestris.Kuttet compared the transpiration of 3-year-old
plants which could be weighed intact in pots, and of detached branches, in
the 10 minutes following cutting. He found that the transpiration of the
detached branches was about 12% less than that of undamaged plants.
Similar results were obtained by Rawitscher (i955) in a study of Coffea
arahica, and by Parker (1957), who investigated Pinm strohus L. in the same
way. The latter author stated that transpiration of excised twigs or fascicles
'declined only shghtly after severing in the subsequent 6 minutes'.

Consequently, the possible root damage that occurred in my earher
measurements (1944) cannot have had any appreciable effect on the results,
as was claimed by Allerup (i959)- The results do not, in any case, conflict
with Allerup's experiments and conclusions. This is because the spruce
plants used in my experiments lacked the ample water supply considered
by him to be a prerequisite for an increase in transpiration after cutting.

Thus, according to the control measurements, the mean values for
transpiration given by the momentan method are not higher-but are rather
lower -than the transpiration immediately before the organ is severed. This
is provided that the measurements are Umited to the minutes directly after
cutting. It was for this reason that I chose the 'momentan method' for
measuring the transpiration of the 11 experimental trees.

The needles from the last 5 years were used for the measurement. The
samples were taken at various levels of the crown, up to 6 m above the
ground, and from all sides of the trees. From 7-8 measurements were made

PRECIPITATION IN A SPRUCE STAND 123

each day. The daily transpiration was calculated from these values. The
quantity of needles (in kilogrammes) per tree was also measured at the end
of the experimental period. The number of experimental days was 42,
distributed over the months of May- August during 4 years. The days were
chosen irrespective of the weather, except that measurements were not
made on days when it rained for more than 4 hours.

The total transpiration during the 4 months of May- August was calcu-
lated from the mean values of the daily measurements. For trees on dry sites
it amounted to 21 1 mm, and for trees on damp sites to 378 mm, calculated
as the precipitation on the root zone of the trees under the crowns and in the
gaps.

Naturally, I am aware that the method has its deficiencies. The greatest
error is probably that the transpiration measurements were made on
samples taken only from the lower third of the crowns, and that the samples
were allowed to transpire at a level of merely 1-2 m above the ground. The
trees were about 20 m high. At the natural site of the samples -higher up
in the crowns of the trees -there are greater opportunities of evaporation.
This applies particularly to the upper half of the crowns. This error can be
expected to have a one-sided effect on the experiments, resulting in the
values for transpiration being too low. Obviously, extrapolation of short-
term values to longer periods, such as days and months, is an additional
source of error. Even so, I consider that the deficiencies and difficulties of
the momentan method are less than those inherent in other methods for
measuring the water consumption of plants under natural conditions.

A comparison between the water consumption of the trees and the supply
of precipitation to the roots is shown in Fig. 3. It can be seen that the trees
on a dry site [R in Fig. 3) utilise a quantity of water corresponding to the
precipitation supphed to their roots during the summer and, in addition,
a considerable part of the precipitation stored in the ground during the
autumn and winter. On a damp site (5 in Fig 3) -where the roots of the
trees reach the ground-water-the quantity of water consumed represents
the entire annual precipitation in the root zone, as well as part of the
ground-water. Thus, at damp sites, the trees have a draining effect on the soil.

How the water supply to the root zone influences the consumption of the
trees can be seen from a comparison made between the trees on the two
sites during a rainy and a dry period, respectively. It was found that the
trees on the damp site transpired about as much (0-73 and 0-74 kg of water
per kg of needles per day) during both periods. Their water consumption
was thus practically independent of the current precipitation. The water
consumption of the trees on the dry site was about as large (0-69 kg) during

124 M.G.STALFELT

the rainy period. However, during the subsequent period of dry weather,
the values fell to 0-57 kg even after a few days, so that the consumption
became less than on the damp site. The difference between the values R
and 5 in Fig. 3 is due to such differences in water supply.

The water consumption of trees on a dry site is thus dependent on the
current precipitation, and is hmited by it. Had more water been available,
the consumption would have been greater, and probably as great as that of
the trees on a damp site.

The total quantity of water reaching the root zone of the trees-that is,
the sum of P and Q in Fig. 3 -is 289 mm, and the transpiration of the trees
211 mm. The difference, 78 mm, consists of water that has evaporated, and
possibly of the surface run-off on frozen ground as well. No excess water
capable of sinking to the ground-water is, on the other hand, present on the
dry site (distance from the water table 2-7 metres). It was possible, by means
of special measurements, to estabhsh that the precipitation that had sunk
through the moss and htter layer had remained cliiefly in the 20-cm thick
uppermost layer of the mineral soil. The water that sinks deeper (5 % during
the summer and 23% during the winter) reaches a maximal depth of
70-100 cm, but can be carried further by diffusion, and penetrate to a depth
of about 150 cm in the morainic soil. The water is subsequently returned to
the root zone, when the latter becomes dry.

According to these measurements, interception is the largest debit item
in the water economy of woods. Partly on this account, the wood's need of
precipitation is probably greater than that of other plant communities. An
example has been given byRutter (1959) who found the water consumption
of an 18-year-old Pinus sylvestris plantation to be 15-36% greater than that
of grass.

The many-layered structure characterising naturally-growing woods- as
well as their large leaf surface per unit of ground surface- gives these plant
communities a transpiration capacity that requires an ample water supply
to be fulfilled. Since the supply is diminished to such a great degree by
interception, it can be presumed that woods on the mainland have sufficient
water only on such occasions when precipitation is so plentiful, and so
frequent, that the soil is kept constantly damp. But if the precipitation
amounts to only 600-1000 mm a year-as in most regions of Scandinavia -
precipitation-free periods of one or several weeks are common. Under
such conditions, transpiration can take place without restriction only during
a few days after plentiful rain. During the rest of the time, consumption is
restricted by the lack of water, so that the transpiration regulators of the
plants come into action.

PRECIPITATION IN A SPRUCE STAND 125

It has, in fact, been found that if the changes in the stomatal vakies are
followed over a long period -in the spruce, for example -a large and per-
sistent stomatal width is present only during the first few days after a down-
pour (Stalfelt, 1926, 1929, p. 324). The width and duration of opening
subsequently decrease, as the soil dries out. After some time, the stomata
are found to be open only in the morning, and still later only during an
hour or so directly after sunrise. Similar observations have been made by
Pisek and Cartellieri (193 1, 1939), Pisek and TranquiUini (195 1) and by
Rutter and Sands (1958).

In the present investigation, water consumption was 167 mm more on
the damp sites than on the dry ones. But during the rainy periods-when
the soil was wet through -transpiration was about as large in both kinds of
trees. It was not until the rain had ceased, and the ground had started to
dry, that transpiration began to decrease in the trees on the dry sites,
whereas it remained practically unchanged in those on the damp sites. On
dry sites, consumption is limited by the water supply. The trees utilise the
water suppUed during the winter-or that stored in the soil from the winter
months -and they would be able to consume more if the supply were
greater.

REFERENCES

Allerup, S. (1959) Transpiration and water movement in young wheat plants.

Physiol. Plant. 12, 907.
Eger, G. (1958) Untersuchungen zur Methode der Transpirationsbestimmung durch

kurzfristige Wagung abgeschnittener Pflanzenteile besonders an Wiesenpflanzen.

Flora, 145, 374.
Parker, J. (1957) The cut leaf method and estimations of diurnal trends in transpiration

from different heights and sides of an oak and a pine. Bot. Gaz. 119, 93.
Pisek, A. & Cartellieri, E. (193 i) Zur Kenntnis des Wasserhaushaltes der Pflanzen.

I: Sonnenpflanzen. J/), wiss. Bot. 75, 195.
Pisek, A. & Cartellieri, E. (1939) Zur Kenntnis des Wasserhaushaltes der Pflanzen.

IV: Baume und Straucher. J6. wiss. Bot. 88, 22.
Pisek, A. & Tranqulllini, W. (195 i) Transpiration und Wasserhaushalt der Fichte

(Picea excelsa) bei zunehmender Lufttrockenhcit. Physiol. Plant. 4, i.
Rawitscher, F. (1955) Beobachtungen zur Methodik der Transpirationsmessungen

bei Pflanzen. Ber. dtsch. bot. Ges. 68, 287.
Rutter, A.J. (1959) Evaporation from a plantation of Pintis sylvestris in relation to

meteorological and soil conditions. Int. Ass. Sci. HydroL, Publ. 48. loi.
Rutter, A.J. & Sands, K. (1958) The relation of leaf water deficit to soil moisture

tension in Pinus sylvestris L. Variation in the relation caused by developmental

and environmental factors. New Phytol., 57, 387.
Stalfelt, M. G. (1926) Die Abhangigkeit der 'Stomataren Difllisionskapazitat' von

der Exposition der Objekte. K. Svenska Vet. Akad. Handl. Ser. 3, Band 2, Nr. 8.

126 M.G. STALFELT

Stalfelt, M.G. (1939) Die Abhangigkeit der Spaltoffnungsreaktionen von der
Wasserbilanz. Plarita, 8, 287.

Stalfelt, M.G. (1944) Granens vattenforbrukning och dess inverkan pa vattenom-
sattningen i marken. K. Lantbruksakad . Tidskr. 83, 3.

Stocker, O. (1929) Eine Feldmethode zur Bestimmung der momenthanen Trans-
pirations- und Evaporationsgrosse. Ber dtsch. hot. Ges. 47, 126.

MEASUREMENT AND SIGNIFICANCE OF
THROUGHFALL IN FOREST STANDS

E.R.C.P^YNOLDS &L.LEYTON

Department of Forestry, Oxford University

INTRODUCTION

Much work is currently in progress attempting to measure the water
balance of vegetative covers, and very frequently, these investigations are
made on a comparative basis to obtain information relevant to the problem
of land use and water supply. However, to discriminate between vegetative
types in this way, it is essential that the various parameters of the water
balance should be measured by techniques which give data of adequate
and measurable precision.

Some of these techniques have been examined in a woodland near
Oxford. In a small plantation of 1 7-year-old Picea abies (L.) Karst., a square
plot (side 140 ft) was marked out, and for sampHng purposes, a one-foot grid
superimposed; random positions within the stand were defmed by co-
ordinates drawn from tables of random numbers. The average distance of
one tree from another was 4| ft and the mean tree height at the beginning
of 1959 was 26 ft. Methods of estimating different phases of the water
balance (gross precipitation, throughfall, evaporation from the woodland
floor, the transpiration of the trees and the soil moisture) are being studied,
but only work on the first two have advanced sufficiently to report in this
paper.

PATTERN OF THROUGHFALL

Throughfall is defmed as the precipitation which reaches the ground under
the trees; included in this is stem flow, which is commonly measured
separately.

A defmite pattern of throughfall distribution was detected by using
twenty gauges with smaU collecting areas (the British Meteorological
Office standard 5 in. diameter rain gauge), distributed at random within
the plot. This pattern can be represented by hnear regressions of catch on
distance from the stem, as shown in Table i. Evidently, the tree crowns
were sufficiently close to each other to allow for such simple Hnear regres-
sions despite the presence of a drip zone located near the edge of the
crown where somewhat higher throughfall is found than under gaps in

128 E. R. C.REYNOLDS AND L.LEYTON

Table i

Throughfall distribution patterns under young Spruce, 1959
y= throughfall in inches, x— distance from tree stem in inches

Inches

Stationary 5-in. gauges

Moved 5-in. gauges

gross

>«^

X

r '

N

f

■\

Period

rainfall Regression

r

Regression

r

13-4 -10-6

2-21

y= 0-63 + 0-029

o-65t

10-6 -24-7

1-62

y= 0-26 + 0-027

0-79*

24-7 -30-7

1-07

Y=-

-0-03+0-028.V

0-81*

y= 0-22+ 0-017

o-67t

30-7 -14-8

1-68

y=

0-24+ 0-042.%'

0-77*

y= 0-12+ 0-048

o-8i*

14-8 -22-10

1-29

Y=

0-20+0-025A:

0-75*

"i''= 0-53+ 0-013

0-42

22-10- 4- 1 1

1-03

y-

0-26+0-0I5X

0-64*

y= 0-41 +0-009

0-50^

4-II-I8-II

1-02

y=

0-2I + 0-0I6.V

0-74*

y= 0-36+0-010

0-56:1:

24-7 -1 8- 1 1

6-09

y=

0-87+0-I3.V

0-79*

* Significant at o-i% level, t at 1% level and % at 5% level. (Gauges not moved
between 10-6 and 30-7.)

the canopy (see Fig. i). However, perhaps the most marked discontinuity
in the pattern of throughfall occurs near the stem where water trickhng
down the trunk is concentrated over a small but iU-defmed area around
the base. Stem flow has been measured on twenty trees selected at random
within the stand. If we express this part of the throughfall arbitrarily in
terms of the projected area of the trunk at \\ ft, i.e. 'breast height'
(B.H.), the mean stem flow (Table 2) varied between four and twenty
times the incident rainfall.

IMPLICATIONS OF THROUGHFALL DISTRIBUTION

During certain periods, the uneven distribution of throughfall below a
forest stand wiU lead to an uneven distribution of soil moisture and this may
have some important consequences ; however, surprisingly few systematic
investigations have been made into this phenomenon. Voigt (i960)
investigated the effect under considerably larger trees of the species Tsuga
canadensis and Vinus resinosa, using fibre-glass resistance units at four depths
down to two feet, at each of five points along a radius of the tree crown.
With Tsuga, stem flow increased soil moisture near the trunk, but only at
shallow depths; with Finns, although stem flow itself had no measurable
effect, increasing throughfall with increasing distance from the tree was
reflected in increasing soil moisture even down to a depth of two feet.

THROUGHFALL IN FOREST STANDS 129

Table 2
Stemflow in young spruce, 1959. (Means of 20 trees)

Contribution

Inches

Volume

to total

Stem flow

Period

gross

per tree

thxoughfall

based on B.H

rainfall

(cu. in.)

(in.)

area (in.)

10-6 -24-7

1-62

81

0-02

7-3

24-7 -30-7

1-07

92

0-03

8-2

30-7 -14-8

1-68

264

0-07

23-6

14-8 -22- 10

1-29

220

o-o6

19-7

22-10- 4- 1 1

I-03

193

0-05

17-3

4-II-I8-II

1-02

232

o-o6

20-7

24-7 -I8-II

6-09

lOOI

0-27

89-5

In the present investigation, we have installed resistance units and
tensiometers along a random radius of each of six trees. The distances from
the stem are respectively, 0%, 40% and 95 % of the radius of the tree crown,
as well as halfway across the adjacent opening in the canopy. The depths
at each of these points are dependent on the depth to impermeable clay,
but the shallowest is at one foot and there are three locations at greater
depths. PreHminary results have indicated the presence of a soil moisture
pattern corresponding with that of throughfall, which we hope to confirm
with further measurements.

The uneven distribution of soil moisture would be expected to influence
evaporation from the forest floor, and this should be borne in mind when
measuring evaporation as a factor in the water balance. Drainage might
also be affected; it is therefore neither sufficient to take samples for soil
moisture measurement, nor to install soil moisture detectors, without tak-
ing into account the possibility of local sinks. It would be interesting and
important to know whether greater water abstraction by tree roots coin-
cides with areas of the woodland floor receiving greater quantities of water.
Under some conditions, leaching too might be expected to show a corres-
pondingly uneven pattern, with consequent pedological implications. For
example, Stewart (i960, unpubHshed) has reported an increasing depth of
A2 horizon in a podzol below Scots Pine with increasing distance from the
stem. Since the micro-environment of the forest floor is also affected by
throughfall distribution patterns, this might underhe certain observed
distributions of regeneration and of soil organisms.

130

E. R. C. REYNOLDS AND L. LEYTON

0-5-

3-0-

2-0

O

lOr-

0-5

O

60inches

j^ Incident
"J^ rainfall

_i I 1 L

r

Crown ^ edq«
1 L

30Jul)' - 14 August
I 1 1 I

lO 20

■"►incident*
rainfall

30

.-,o

40

.-it'

50 60 inches

,-OvO^

Crown

J J I 1 I L

edge

4Noy. - I8NOV.

_l J L.

lO 20 30 40 50

Distance of gauge from tree stem

_l
60irich«s

Fig. I. Relationship of 5-in. gauge catch on position beneath trees for three periods,

1959-

THROUGHFALL IN FOREST STANDS 131

The importance of total throughfall in a stand is that it often represents
all the water available for transpiration and drainage. Its accurate measvire-
ment is therefore of considerable hydrological significance. The presence
of a pattern of throughfall distribution, however, introduces certain
complications which have not always been appreciated by workers in this
field.

MEASURING TOTAL THROUGHFALL

Because of the spatial variability of throughfall, a sampling technique must
be selected which provides an estimate with an appropriate statistic of this
variability ; in the present case we will employ the standard error expressed
as a percentage of the mean. One object of the present investigation was to
compare the efficiencies of various measuring techniques.

Some difficulty has been experienced in the past in keeping the standard
error of throughfall estimates, exclusive of stem flow, sufficiently low and
yet maintain a manageable set up.

Wilm and Niederhof (1941) found that estimates based on stationary
gauges in forest stands were subject to large standard errors. To improve
the samphng procedure, Wilm (1943) employed a single 8-in, gauge in
each experimental plot, moving it after every storm, to one of twelve
random positions. However, this experimental design did not achieve the
desired precision, and calculations suggested that the number of alternative
positions in each plot should have been increased to forty.

In Yorkshire, Law (1957) adopted a somewhat similar approach, but
used a rather restricted randomisation of ten 5-in. gauges beneath a stand
of Sitka spruce, moving each of these after approximately equal amounts
of rain to one of thirty-six alternative positions. Over a period of a whole
year, though not for shorter periods, he obtained a standard error of almost
12%: for a strictly random (but less practicable) design, the corresponding
figure was 6-4%.

In the present investigation with twenty 5-in. gauges sited at random in
the plot, large standard errors were also found (simple S.E., Table 3).

An attempt has been made to increase the precision of the estimates from
stationary gauges by taking into account the relation between catch and
the distance from the stem, as presented in Table i. From the appropriate
regression equation, the catch was calculated for the mean position under
the canopy (estimated for a large number of random locations), and the
standard error of this value determined, taking into account the variance
of the estimate of mean position. Niederhof and Wilm (1943) used a some-
what similar approach but over a much greater range of canopy conditions.

132 E.R. C.REYNOLDS AND L.LEYTON

Table 3
Standard errors of Stationary 5-in. gauges, 1959. (Expressed as % mean)

Simple Regression

Period S.E. method Stratification

34-7 -30-7

I4-I

9-1

9-3

30-7 -14-8

II-7

8-1

8-4

14-8 -22-10

II-I

7-8

8-5

22-10- 4-11

9-0

6-5

6-8

4-11-18-11

9-7

6-9

7-6

24-7 -1 8- 1 1

10-9

7-3

7-8

In the present investigation, there was some improvement in precision
compared with that of the simple mean (Table 3).

As another approach (cf. Kittredge et ah, 1941), the data were stratified
into three zones corresponding to <50, 50-80 and >8o% of the crown
radius ; the use of relative positions of the gauges under the crown allows
for variations in crown size. The areas of these zones were readily calcu-
lated from a number of random locations. For each zone, the mean catch
and its variance were calculated, and a value obtained for the stand as a
whole by weighting the means according to the areas represented. The
standard errors obtained (Table 3) were again about o-y times those asso-
ciated with the simple mean of all the gauges, and so still rather large.

Besides these mathematical methods, the effect of moving another set
of twenty 5-in. gauges to new random positions after approximately each
inch of incident precipitation was tested. As is evident from Table 4, over a
period of four months involving five different gauge distribution patterns,
the standard error of 5-7% indicated a definite improvement over the
stationary gauges, although the variabiHty within any individual distribu-
tion pattern was similarly high.

A more logical solution to the problem of measuring precipitation under
trees would be to increase the gauge size so as to integrate the throughfall
pattern over a larger area.

In Germany, Delfs (1955) reports the use of troughs 20 cm wide and 5 m
long, but, in the absence of replicated measurements, no information is
available as to the precision of the estimates, and it is impossible to decide
therefore, whether or by how much troughs are superior to small gauges.

Troughs have also been tested in the present investigation; these had
rectangular collecting areas, 3 ft x 2 ft, i.e. forty-four times that of the 5-in.
gauges. Twenty troughs were placed in the area with their centres at

THROUGHFALL IN FOREST STANDS 133

Table 4

Standard errors of moved gauges, troughs and stem gauges, 1959.
(Expressed as % mean)

Moved Stem

Period 5-m. gauges Troughs gauges

13-4 -10-6

10-2

10-6 -24-7

II-9

5-5

24-0

24-7 -30-7

12-6

6-6

20-5 •

30-7 -14-8

12-8

6-6

16-9

14-8 -22-10

10-6

6-4

16-7

22-10- 4- 1 1

8-4

5-0

18-7

4-II-I8-II

8-2

4-8

i8-2

24-7 -iS-II

5-7

5-6

16-9

(5-in. gauges not moved between io-6 and 30-7.)

random locations. The results (Table 4) show that for long or short periods,
the standard errors of the estimate ranged around 6%. Over a four month
period, there was httle to choose between moved gauges and the troughs
and, although with more frequent moving, 5-in. gauges would be expected
to give a stiU smaller standard error, the increase in labour should not be
minimised.

The desired level of precision will be dependent of course, on the
precision of the measurements of any other phases of the water balance with
which throughfall is intended to be combined. Although much depends on
local conditions and on the application of the data, for many purposes a
standard error of about 5% of the mean would appear to be acceptable.

It must be emphasised that it is the reliability or precision of the estimates
of total throughfall obtained by various methods which is being exairdned.
The mean values given in Table 5 indicate differences of up to 5% between
the various estimates.

It is necessary to point out that the trough size adopted was almost
certainly not the most efficient for the pattern of throughfall which
occurred in this plantation. This pattern is related to the spacing and habit
of the trees, and the troughs were a little less than a quarter of the mean
area occupied by a tree. The size of the troughs used was still small enough
to reflect the relationship between catch and distance of the trough centre
from the surrounding trees (see Fig. 2).

Although the results have not shown it, troughs are more susceptible

134 E. R. C.REYNOLDS AND L.LEYTON

Table 5
Comparison of mean catch by various methods, 1959. (Inches of water)

Stationary 5-in.

gauges

A

(

■\

Simple

Moved

Period

Mean

Regression

Stratification

. 5-in. gauges

Troughs

13-4 ■

-10-6

1-36

—

10-6 -

-24-7

—

—

—

1-09*

I -08

24-7 -

-30-7

0-70

0-74

0-74

0-73*

0-70

30-7 ■

-14-8

1-35

1-40

1-41

I-I9

I-3I

14-8 •

-22-10

0-86

0-89

0-89

0-92

0-84

22- 10-

- 4-II

0-65

0-67

0-67

0-66

0-65

4-1 1-

-I8-II

0-64

0-66

0-66

0-64

0-68

24-7 •

-I8-II

4-20

4-36

4-37

4-14

4-19

(*Not moved between io-6 and 30-7.)

to bias than small gauges, simply due to the fact that they camiot be placed
with their centres nearer a tree than a distance of half their width. Using a
mathematical model approximating to the stand conditions, J. F. Scott
(unpubhshed) has shown that with 5-in. gauges, this bias may be in the
region of 2%, whereas troughs of the dimensions used could increase the
estimate by as much as 19% over the true mean.

For more accurate measurements, annular gauges might well be installed
to sample the throughfall in the area which is not adequately sampled by
the troughs. There is no reason why such annular gauges should not be
made to incorporate stem flow measurement.

Increasing the size of the collecting area through the use of troughs,
considerably increases the work of measuring and recording the large
volumes of water collected. An automatic measuring system has therefore
been devised on the principle of the tipping bucket rain gauge. The
movement of the bucket is made to actuate a counter directly, or electri-
cally through a microswitch. The trough collection can then be readily
measured at any interval appropriate to the investigation, with a reasonably
low standard error, yet without any need to move the gauges or to record
the collection at unnecessarily frequent intervals.

Stem flow was measured separately on twenty random trees using a
plastic putty collar held in position by a copper band and receiving through-
fall within one centimetre of the trunk at a height of 41 ft. The percentage

I-O

0-5

2-0

S i-o

-^inc ident
rainfall

J I L

24July- aOJuly

I I I I I

lO

20

30

40

50

60 inchcf

, incident
rainfall

30 July - l4Augu-.l

I L

lOH

0-5

^ incident
rainfall

30

40

50

J. J.

601r,chc5

Ol L

J L

4 Nov. - I 8 Nov.

I I I I I

10

20 30 40 50

Distance of trough centre from tree

60 inches

Fig. 2. Relationsliip of trough collection to position for three periods, I959-

10

136 E.R. C. REYNOLDS AND L. LEYTON

Standard errors were very high (Table 4) but, since the amount collected
formed only a small part of the total throughfall (Table 2, column 4), its
contribution to the variability of the latter was negligible. If stemflow is
investigated as a separate entity, because of its local significance, the
regression techniques adopted by Wicht (1941), and by Wilm and
Niederhof (1941), offer means of studying the causes of variation, which
Voigt (i960) has examined experimentally.

INCIDENT PRECIPITATION

Commonly, throughfall estimates are deducted from the precipitation
incident upon the canopy to determine interception, that is, the amount or
proportionof the precipitation which fails to reach the ground. Measure-
ment of incident precipitation, however, is beset with many complica-
tions. Usually, it has been measured in adjacent open ground, but this is
not always available and the occasional attempts which have been made,
using gauges mounted above the trees, have proved generally unsatisfac-
tory. In neither case is it sufficient to append statistics of variabihty to the
mean catch of such gauges; evidence must be presented to support the
contention that the measurement is not subject to errors due to difference in
location or, in the case of 'tree-top' gauges, to instrumental errors. Instru-
mental errors associated with rain gauges above trees are considered to be
particularly great in areas where wind speeds are appreciable. Under his
relatively exposed conditions. Law (1959, impubhshed) suggests the addi-
tion of 15% to the catch of gauges elevated 10 ft above the tree canopy;
this correction was based on the relationship of catches of gauges at different
heights over short grass.

For critical investigations into the water balance, it is essential to have
estimates of incident precipitation and of its spatial variabihty over the
plantation.

In the present work, therefore, sixteen gauges of various types were
installed above the tree crowns (cf Plate I) ; these gauges were at random
locations. The water was conducted down P.V.C. tubing to ground
level and collected in enclosed bottles. Six unshielded 5-in. gauges were
placed in the canopy itself, as low as possible to obtain shelter from the
wind, yet not so low as to be affected by interception or splash. All other
gauges were 38 ft above the ground, 10 ft above the mean tree height at the
beginning of i960. Eight of these gauges were 5-in. gauges, two being
surrounded by 60° Nipher sliields with a horizontal wire mesh border, and
six by Alter shields such as are used with the International Standard rain

THROUGHFALL IN FOREST STANDS 137

gauge. The two remaining gauges were designed by Prof. Thorn at
Oxford, and have an aerodynamic profile which was shown in wind-tumiel
tests to give only a 6% increase in wind speed immediately above the
collecting area ; these gauges have two concentric compartments of equal
area, to provide internal comparison. In one of the gauges, these chambers
are each shghtly smaller than the 5-in. gauge, and in the other, rather larger ;
in both there is an outer guard chamber. In open ground 350 yds from
the plot, a recording rain gauge and two 5-in. gauges are exposed in the
standard mamier. As expected, there were differences in catch between
gauges of the same type located in different places, and between the various
types of gauge. Over several months, the gauges provided with Nipher
shields agreed with the standard ground level gauges to within 1%, while
the catches of the unshielded elevated gauges, the Alter gauges and the
larger aerodynamic gauge were lower by about 2%. It should be pointed
out that the conditions in this plantation were far less exposed than in that
of Law.

Data for selected storms occurring in autumn i960, have been examined
by multiple regression teclmiques. Up to half the variabihty between
different types of gauge could be attributed to, or was associated with,
variables which might be expected to affect evaporation from the gauge, or
aerodynamic factors affecting gauge catch (wind velocity, temperature,
etc. measured at the centre of the plot above the trees).

It is difficult, if not impossible, to distinguish between local variations of
true rainfall and other local climatic variations which effect gauge efficiency.
However, the regression approach shows some promise in assessing the
capabilities and limitations of the various gauges which might be used to

Table 6
Stem flow, trough catch, incident precipitation and interception. (Inches)

Period Stem Trough Total Gross

1959 flow catch throughfall precipitation Interception

10-6 -24-7 0-02+ 0-005 i-o8± 0-059 I-I0+ 0-060

24-7-30-7 0-03 ±0-005 0-70+ 0-046 0-7010-046

30-7-14-8 o-07±o-oi2 i-3i±o-o86 i-3i±o-o86

14-8 -22-10 0-06+0-0I0 0-84+0-054 0-84+0-054

22-10-4-11 0-05+0-010 o-65±o-033 0-6510-034

4-11-18-11 0-06+0-012 o-68± 0-033 0-68 + 0-035

24-7 -18-11 0-27+0-046 4-20+0-230 4-4610-240 6-09 1-64

1-62

0-51

1-07

0-34

1-68

0-31

1-29

0-39

1-03

0-33

1-02

0-27

138 E.R. C. REYNOLDS AND L.LEYTON

measure incident precipitation above trees. Further work along these lines
may suggest the type of gauge subject to the smallest instrumental errors.

INTERCEPTION

When the water reaching the ground is subtracted from that incident upon
the canopy, a figure for interception is obtained. Under our particular
conditions, interception was generally about 30%, though occasionally as
low as 18% (see Table 6) and is of the same order as figures pubHshed
elsewhere for forest canopies (e.g. Delfs, 1955). Wider recognition is now
being given to the fact that interception losses rarely, if ever, should be
interpreted independently of transpirational losses. It is probable that there
is an inverse relationship between transpiration from the plant and simul-
taneous evaporation of intercepted water. Burgy and Pomeroy (1958) have
shown that for grasses, evaporation of intercepted water proceeds to an
equal amount, and instead of, the transpiration which would have taken
place if the foHage had not been wetted. On the other hand, other evidence
suggests that the intercepted water evaporates rather more rapidly than
that which would have been lost by transpiration. Nevertheless, it is ahnost
certain that transpiration is reduced while intercepted water is being
evaporated, and this is supported by consideration of energy relations.

Graphs representing the relationship between incident rainfall and
throughfall (excluding stem flow) as in Fig. 3^4, have been extrapolated to
determine incident precipitation at zero throughfall. This value has been
termed 'canopy saturation', and under the present conditions, is in the
region of a twentieth of an inch. Consideration of stem flow (cf Fig. 3-B)
indicates that appreciably more rain must fall in the summer months before
water begins to trickle down the stems. However, the computation of
'canopy saturation' is very approximate, partly because of the high errors
associated with extrapolation, and partly because the relationship neces-
sarily departs from Hnearity with small storms, since the sUghtest showers
must penetrate canopy gaps. Inclusion of records for small storms in com-
puting the linear regression would therefore slew the line giving a smaller
figure for 'canopy saturation'. Curves of this type have also been used to
compute mean throughfall for the mean storm size (Wilm, 1943).

CONCLUSION

Though much useful information on the water cycle in a forest stand
might be gained by studies on isolated phases, it is clear that their inter-

[facing p. 138

A. General view of the stand;

C. Alter shield;

Plate I. The measurement of precip-

B. 60° Nipher shield;

D. Prof. Thoni's aerodynamic gauge,
itation incident on the canopy.

THROUGHFALL IN FOREST STANDS

0'6r A

0-5

c 0-4

0-3

o 0-2

Ol -

o

003

002

E

O-OI-

O

• • cl*

O'

o.

.c:

t

mean
storm
size

lO June - 14 August

0-2 0-3 0-4 0-5 06 0-7

Gross precipitation (inches)

mean
storm
size

1

lO June - 14 August

O-l 0-2 0-3 0-4 0-6 0-6

Gross precipitation (inches)

0-7

139

Fig. 3. Relationship between throughfall and storm size, 1959. A throughf^ill excluding

stem flow; B stem flow alone.

140 E. R. C.REYNOLDS AND L.LEYTON

pretation would be incomplete without reference to other phases of the
cycle. For example, evaporation from a forest includes both transpiration
and evaporation of intercepted water, and because these two phenomena
are related, measurements of one or the other alone are of hmited value ;
similarly, studies on soil moisture must also take into account the pattern
of throughfall distribution.

In view of their importance, it has been the purpose of this communica-
tion to stress the need for techniques, which by virtue of their precision
and practicability, can be incorporated into water balance studies. It has
been shown that reasonably precise estimates of throughfall could be
obtained by using troughs with relatively large collecting areas, but a
suitable technique has still to be developed for the ineasurement of pre-
cipitation incident on the stand, since precipitation measurements made
on nearby open ground are inadequate. Attention has been largely restricted
to these two measurements, but investigations arc continuing on the
development of techniques to measure the other components of the water
balance.

ACKNOWLEDGMENTS

Mr. J. F. Scott (Unit of Biometry, Oxford University) has given invaluable
advice and help with the statistical aspects of this study. Dr. A. Carlisle
(Nature Conservancy) was associated with the initial work. Mr. J. Kemp,
through the co-operation of the Forestry Commission, has considerably
assisted the investigation. We are pleased to acknowledge the financial
support of the Department of Scientific and Industrial Research.

REFERENCES

BuRGY, R.H. & POMEROY, C.R. (1958) Interception losses in grassy vegetation.

Trans. Amcr. Geophys. Un. 39, 1095-1100.
Delfs, J. (1955) Die Niederschlagszuriickhaltung ini Walde (Interception). Mitt.

Arhcitskr. 'Wald mid IVasser'. (Koblenz); 2, 7-54.
KiTTREDGE, J., LouGHEAD, H.J. & Mazurak, A. (1941) Interception and stem flow in

a pine plantation. J. For. 39, 505-522.
Law, F. (1957) Measurements of rainfall, interception and evaporation losses in a

plantation of Sitka Spruce. Paper read to nth Gen. Assem. (Toronto) Int. Ass.

Hydrology.
NiEDERHOF, C.H. & WiLM, H.G. (1943) Effect of cutting mature Lodgepole Pine

stands on rainfall interception. J. For. 41, 57-61.
VoiGT, O.K. (i960) Distribution of rainfall under forest stands. For. Set. 6, 2-10.
Wight, C.L. (1941) An approach to the study of rainfall interception by forest

canopies. J. S. Afr. For. Ass. 6, 54-7°.

THROUGHFALL IN FOREST STANDS 141

WiLM, H.G. (1943) Determining net rainfall under a conifer forest. J. agric. Res. 67,

501-512.
WiLM, H. G. & NiEDERHOF, C. H. (1941) Interception of rainfall by mature Lodgepole

Pine. Trans. Amer. Geophys. Un. 22, 660-665.

THE BEHAVIOUR OF NORWAY SPRUCE (PICEA

ABIES (L.) KARST) IN CENTRAL JUTLAND,

DENMARK, IN THE SUMMER OF 1955

E.B.Oksbjerg
Royal Forestry College, Stockholm

THE WEATHER CONDITIONS

The summer of 1955 was very hot and dry in large parts of northern
Europe. Observations made at the meteorological station Loendal, in
Central Jutland, are shown in Fig. i comprising temperatures at 2 p.m.
and rainfall, computed as averages and sums respectively, for 5-day periods.
Compared with 'normal figures' from cHmate tables, April, May and
June of 1955 were very cold, humid and windy and the cloudy weather
reduced the occurrence of night frosts to five occasions. At Loendal
station (a cupboard on poles 1-5 m above soil surface) the five lowest
minimum temperatures were between —0-2 and — i-8°C. At an experi-
mental field between Loendal and Salten mentioned below, the night
temperatures measured on the soil surface were lower and frosts occurred
more frequently (Oksbjerg, 1956).

OBSERVATIONS ON GROWTH AND INJURY IN
SPRUCE PLANTATIONS

The extension growth of leader shoots of late- and early-flushing spruces
during the sprouting period, shown in Fig. i, was observed in 1955 in an
experimental plantation 2 kilometres north of Loendal. The two plots
were estabhshed in 1952 by separate planting of four-year-old spruce
plants which in the spring of 19 51 in the nursery were marked out as
extremely late- and extremely early-flushing individuals.

The flushing process of spruce is strongly influenced by temperature,
and the belated sprouting appearing in Fig. i for both spruce types, about
three weeks later than usual, is undoubtly due to the coldness.

Some scattered frost injury occurred in the early-flushing plot on the
new shoots of the lowermost branches which, as is well known, flush
before the leader.

In the years 1952, 1953 and 1954 the shoot growth of the two plots had
been equal, and as the differences shown in Fig. i cannot be due to soil

THE BEHAVIOUR OF NORWAY SPRUCE

143

ll ll. I .1 nil.

a b c d e f

a b c d e F

a b c d e f

--r— slight \ night frost
— _ — severe J ^

Fig. I. The march of air temperature (at 2.00 p.m.) and precipitation (averages and
sums respectively for 5-day periods) at Loendal, Central Jutland, together with the
growth of leading shoots oiPicea abies.

2 '^^Mlk^^.

'§^m

\

Fig. 2. Drought injury in late-flushing Picea abies.

144 E.B.OKSBJERG

differences, the only cause appears to be that the weather of the summer of
1955 has influenced the two flushing types in different ways. The check in
leader growth of the late-flushing plot continued in the following years
and significantly different figures for early compared with late-flushing
spruces were for 1955, 33-26; for 1956, 19-9; and for 1957, 21-9 cm.
Later the differences diminished and have now disappeared.

Some observations on visible damage proved that the late-flushing
spruces had less resistance to drought. Of 140 plants in every plot, 100
standing on bare soil (sand, Hght coloured) and 40 in grass vegetation (sand
rich in humus), 2 and 37 respectively died in the late-flushing plot but in
the early-flushing plot only 0 and 2. In addition, damage such as distortion
of the shoots, death of the younger shoots or parts of them, needle loss,
etc. predominantly occurred in late-flushing plants (see Fig. 2).

In the spring of 1956 it was evident that in Centraljutland only extremely
late-flushing spruces flowered. That means that flowering is influenced not
only by general temperature effects but also in some cases by a decided
drought, and that the progeny of seed collected in 1956 do not represent
the whole population of a locality, but only the late-flushing part of this.

In the summer of 1955 the sprouting period of the late-flushing plants
coincided with the culmination of high temperature and drought, whereas
the early plants had finished growth and to some extent had lignified the
shoots before the conditions became critical. The severe damage and the
growth depression in the late-flusliing plot could be presumed to be caused
by high transpiration rates of the leafy, soft shoots having a very thin
peridermis. An examination of the transpiration situation for one-year-old
shoots and sprouting ones showed, however, that in most cases the older
had highest values whether these were expressed on the basis of weight or
of surface area, and whether of shoot or only of needles. When sprouting
shoots are terminating their growth, transpiration seems to increase,
probably in connection with the differentiation of stomata (Oksbjerg,

1961).

During drought periods the transpiration rate of sprouting shoots will
be higher than or equal to that of one-year-old ones, probably because of
the fact that the main part of transpiration during drought passes through
the cuticule. In the last weeks ofjuly, 1955, 1 found that transpiration from
one-year-old shoots had nearly stopped, whereas young shoots, checked in
sprouting by the drought, continued to loose water.

Another part of the explanation of the pronounced difference in drought
damage to late- and early-flushing spruces is differences in 'hydrature' in
the sense of Walter (193 1). The growth features and related metabohc

THE BEHAVIOUR OF NORWAY SPRUCE 145

processes presuppose a low osmotic pressure in the tissues. The high water
content produces high transpiration rates even in the older shoots.

A third part of the explanation is the fact that the needles of older shoots,
even those of the previous year are shed during a drought, whereas the
needles of the ripened parts of the new shoot survive. The corresponding
bark gives rise to a new bud formation.

Concurrently with the drought damage a depression in diameter growth
in spruce took place. A comparison between late- and early-flushing
individuals is very difficult because many late-flushing spruces -even trees
under 20 years of age-flowered and fructified in 1956 and therefore
suffered from an extraordinary loss of dry matter. I hope later to have an
opportmiity to elucidate these questions. In passing it can be mentioned
that drought damage of the summer of 1947 affected the early-flushing
spruces more than the late-flushing types (Oksbjerg, 1956, 1958).

One of the reasons for growth depressions, during and after drought
periods, may be that drought can produce a colour change from dark to
light green or to yellow occurring in connection with a decline in the
N-content of the needles, decreasing from about i • 1 5 to o- 8 % of dry weight.

Two years after the drought, in the summer of 1957, attempts were
made to measure the needle temperatures under different conditions,
though periods of drought did not occur in this summer.

OBSERVATIONS ON NEEDLE TEMPERATURES

The apparatus used had ten thermocouples in the simple form of bare wire
ends and one couple in contact with the reference temperature, an ice
inixture in a thermos flask. The existing couples could be sharpened
sufficiently, or new couples of thimier copper and constantan wires could
be made, for an insertion in spruce needles. This operation was less difficult
in needles on soft shoots but also possible in big needles on fully ripened
shoots.

When the couple points were introduced in needles the electric wires
were fixed to suitable twigs with clothes pegs. The readings were often
irregular and only repeated readings which could be reproduced were
recorded. The galvanometer deflections could be directly converted to
degrees centigrade.

The results ought to be presented in a table with detailed information
about weather conditions, supposed to be important for the course of the
needle temperature, such as solar radiation, air temperature, precipitation
and evaporation levels in the hours and days previous to the moment of

146 E.B.OKSBJERG

observation. In order to save space I have tried to present the many
scattered measurements by diagrams, from four days in succession, but am
well avvrare of the fact that the observations were made under such different
conditions that strictly speaking they are not comparable and, therefore,
should not appear in the same diagram. In representing the observations
the question of eventual differences in needle temperatures in older and in
sprouting shoots is left out of account (see Fig. 3).

All measurements show that needle temperatures under the experimental
conditions in question (moderate shelter in a 2-4 m high spruce plantation)
are higher than air temperature from dawn to sunset whether in sunshine,
cloudy weather or mist. No measurements are made when needles are
wet from rain but a few minutes after the needles had dried up after a
shower the needle temperature was again higher than air temperature.
Immediately after sunset the needle temperature wiU be lower than air
temperature when the sky is clear.

The difference in temperature is an important factor governing trans-
piration and is the reason for a shght transpiration which takes place when
spruce plants (or probably all green plants =) are put into a transparent vessel
saturated with water vapour (for example a glass flask the inside of which
is covered by permanent wet filter paper) , when the flask is illuminated only
by diffuse dayhght, not sunshine.

Unfortunately no opportunity occurred of measuring needle tempera-
tures during the drought of 1955 nor in the warm summer of 1959. The
difference between needle temperature and air temperature is biggest in
the early afternoon with high sun radiation intensity and decreasing
transpiration (see Fig. 3 b) when the water content in the shoots is reduced.
Lack of water naturally will increase the needle temperature while thermal
loss to evaporation diminishes it.

The widest difference between needle temperature and air temperature
appearing in Fig. 3 is about 5 centigrade and in no reUable observation
during the summer of 1957 is this value exceeded. But in a dry and hot
summer, no doubt needle temperatures of over 3 5 centigrade will occur.
At such temperatures the respiration is very high and the balance of
carbohydrates in the needles is certainly negative. Probably the loss of
nitrogen in the needles is caused by proteolysis also causing decomposition
of chlorophyll.

In many circumstances in a cold and wet August, or especially a dry
and hot summer, the colour of the vegetation changes from dark to hght
green in connection with flowering and ripening of seed (e.g. in grasses).
In many summers this may also occur as a result of a fall in available

THE BEHAVIOUR OF NORWAY SPRUCE

147

la) 17. 7. 57.

6 10

(c)19. 7. 57

1A

IS

22

■D

3
0
u

L

25
20
15
10.

t9

r

>

>

0

^

0

>

0

L

n

u

fn

u

3

J_l

N

±j

0

r

u

i-

0

1/1

> L -y

D

r
i/i

(b)1B.7. 57

c

E

1.

a
&.

L
W .

a
E

10 14 18 22

Time oF day

id)20.7. 57.

Fig. 3. A comparison of needle and air temperatures on four successive days in

July 1957.

nutrients or, as we have seen, may be caused by heat. In all cases the colour
change probably consists of a reduction of the chlorophyll concentration
of leaf and needles.

It is possible to construct an equation relating thermal radiation and
transmission to and from an area and the total evapotranspiration from the
same area, an equation in the sense of Penman (1956). The equation can
naturally only be formulated for a fully transpiring, green crop which
covers the soil completely. Such endeavours can, no doubt, be of great use
for certain regional estimations of ideal, maximal values of evapotrans-
pirations, but they cannot teach anything about evapotranspiration from
different vegetation types. The influence and extent of changes in colour
or leaf area of the vegetation and the occurrence of imperfect transpiration
(see the transpiration curve in Fig. 3b) can only be elucidated through
detailed ecological field observations.

SOIL MOISTURE

Soil moisture was measured in an old-fasliioned manner by digging out
the soil samples, opening a new profde at every new examination.

148 E.B.OKSBJERG

The water content in April after a winter rich in precipitation is taken
to represent field capacity. Very infrequently the state of field capacity was
established artificially. With the available facilities the estimation of
permanent wilting point was undertaken by balancing the soil samples
against sulphuric acid in closed jars, placed in a cool dark cellar.

The water capacity or the accessible water is a vague idea comprising
among others a quantity which I have called the apparent water capacity,
i.e. the difference between field capacity and wilting capacity in the soil
space occupied by the root system. The investigation led to the advancing
of another concept, the physiological water capacity, which means the
difference between field and wilting capacity in the soil space from which
the roots can take up all accessible water during a critical period of drought,
i.e. the volumes of the soil where the density of roots is so high that complete
utihsation occurs after a longer period of drought.

In some cases in the following account the water capacity of the raw
humus layer (or better the spruce mor) is indicated in brackets after the
figure of the total water capacity, for exainple in locahty nr. i,Rosenholm:
120 (45). This arises from the assumption that a part of the water content
in this superficial layer is exposed to atmospheric influence and conse-
quently open to direct evaporation, a water loss which does not benefit
much the physiological processes of the stand.

Locahty i , Rosenholm. A spruce stand planted more than a hundred
years ago on drift sands formed as dikes alternating with strips bared to the
hard pan. A larger sand drift is examined and the course of soil moisture
is graphed in Fig. 4. hi Table i some data of the profile are collected.

Excluding the horizons 5 and 6 which are nearly free of roots, the apparent
water capacity of the given example is about 115 (45 mm) of rain. In Fig. 4
it appears that even durhig a drought of two months the accessible water
is not exhausted in the three uppermost horizons. To avoid further indis-
tinctness in Fig. 4, the curves of the horizons 4, 5 and 6 for the summer 1955
are not drawn. In these horizons the water content was reduced slightly
but significantly, by 15-20% of the field capacity even though the root
density is very low and very different. Roots occur most frequently in the
horizon 4, near the boundaries to horizon 3 and 5.

The uptake of water from the soil seems to desiccate it only very
moderately during a 'normal' summer as that of 1953, considering the
balance of the soil in Fig. 4. But even in a very dry period the accessible
soil water is not completely evacuated from the horizons penetrated by
roots. Judging from the conditions of 1955 the physiological water capa-
city of the profile in question is assessed to be about 60 mm.

Horizon

THE BEHAVIOUR OF NORWAY SPRUCE 149

Table i
The soil profile at Rosenholm

Ignition Depth

loss Field Wilting of the Sample

(% dry capacity capacity horizons depth

weight) (vol. %) (vol. %) (cm) (cm)

I.

Spruce mor

85-95

55

9

o-io

5

2.

Bleached sand or drift

sand, humic

3i-3i

15

3

10-22

15

3-

Fossil humus, previous

surface with heather mor

4-7

22

6

22-29

25

4-

Usual bleached sand or

drift sand, poor in humus

1-2

9

2

29-85

45

5-

Humic iron pan

3-3i

29

8

85-98

90

6.

Sub-soil, C-horizon

if-^i

7

2

100-

115

The most huniid 'pockets' in the profile in September 1955 were recorded
in the bottom of the mor layer and in horizon 3 , the fossil hinnus. The water
content in both these horizons is, to a certain extent, 'dead capital', pro-
bably due to a lack of living root tips which, by the way, were very actively
formed just in these humid volumes in the month of September 1955,
when root formation otherwise was very sparse and slow.

Locahty 2, Kompedal plantation, dpt. 408. A sixty-year-old spruce stand
planted on previous field cultivated heath. The profile, therefore, is
'disturbed' and the numbering of the horizons will only apparently corres-

c

L
til

a
E30

9

15-

^ O

APR.

MAY

JUNE JULY

AUG.

SEPT.

Fig. 4. The march of water content during the summers 1953 and 1955 in different
horizons of the soil at Rosenholm. Numbers refer to horizons in Table i.

150

The soil

E.B.

profile

OKSBJERG

Table 2
in^Kompedal ph

mtation

Horizon

Field

capacity

(vol.%)

Wilting
capacity
(vol.%)

Depth (cm)

1. Spruce mor

2. Humic sand or gravel

4. Bleached sand

5. Hard iron pan with humus

6. Sub-soil

38

12

8

16-24

9

8

3
2

3-6
2

(I) (2)
0-8 0-6

8-14 6-26
14-29 26-30
29-39 30-42
39- 42-

pond with those of the above mentioned profile. A summary of the data
from locahties i and 2 is given in Table 2.

In this soil many roots occur down to 50 cm (the designation 'sub-soil'
used in table 2 is therefore wrong as to defmition, it only refers to colour).
The apparent water capacity of the soil dealt with in Fig. 5 and Table 2
is about 70 mm of rain because the computation includes the pan and the
uppermost 10 cm of the sub-soil.

The march of water content in the horizons during the summers of 1953
and 1955 was very similar to those of the locahty Rosenholm, but in
Kompedal the decline set in more simultaneously and more uniformly in
the different horizons, probably because of the more shallow root system
and therefore more equable temperature and root density in the soil of the
root volume.

APR. MAY

JUNE

JULY

AUG.

SEPT.

Fig. 5. The march of water content during the summers 1953 and 1955 in different
horizons of the soil at Kompedal. Numbers refer to horizons in Table 2.

THE BEHAVIOUR OF NORWAY SPRUCE

I5f

But here also much accessible water remains in the different horizons and
the reason may also here be an insufficient number of root tips per unit of
root volume. The physiological water capacity of the Kompedal profile is
at most 40 mm of rain.

Locahty 3 , the experimental plantation near Loendal mentioned in sec-
tion 2. The soil was previously cultivated and no 'natural' profdes occur.
Both in the grass-covered and in the bare, light-coloured sand, roots
occurred down to a depth of 40-45 cm. On 22 July the whole rooted
volume of the grassy soil was devoid of available water and by i September
the bare soils had also reached the wilting capacity. In the spring of 1957
the field capacity was determined, and a definitive account is presented
in Table 3 .

Table 3
Water-holding properties of soil near Loendal

Field

capacity

Wilting capacity

Water capacity

<

Calcu-

t \

Calcu-

c

Calcu-

lated for

lated for

lated for

45 cm
depth.

45 cm
depth,

45 cm
depth.

gm/1

mm

gm/1 mm

gm/1

mm

Grass-covered soil with

high humus content

150

68

30 14

120

54

Bare soil poor in humus

90

40

24 II

66

29

As will be remembered the plants on bare soil survived whereas many of
those on grass-covered soil died; in the late-flushing plot all the latter died.
The cause may be a high consumption of water by grass and a very intense
root penetration by spruce in the previous field-soil rich in humus.

Locahty 4, a very good forest soil on moraine. On a sHght, north facing
slope in Silkeborg Sonderskov, dpt. 232, Norway spruce 25 years ago
succeeded beech. Samples were taken in September 1955 and three times
during the summer of 1957. The profile, which was rooted to 85 cm, was
presumed to be fairly represented by samples from three different depths,
and a rough estimation showed that there was left more than 50 mm
accessible water in September 1955 before any important shower had
fallen after the drought. Water content increased with depth, and in no

II

152 E.B.OKSBJERG

place, not even in the uppermost layers, did it approximate to wilting
capacity. In the summer of 1957 no substantial fluctuations occurred in
the water content except for a sHght and nearly uniform decrease in the
uppermost 50 cm. The field capacity of the profile to a depth of 85 cm is
about 215 mm and the wilting capacity ca. 100 mm.

CONCLUSION

The investigations of soil moisture show that Norway spruce during severe
drought does not exhaust the accessible soil water to the depth of the
deepest roots, except in one example, in a former field soil. In older
plantations, especially on podsoHsed soils the spruce roots become more
and more superficially situated or concentrated in some 'rootfriendly*
horizons.

But also young plantations show-e.g. in comparison with oak- a very
ineffective water uptake which sometimes can be an advantage. As an
example I shall mention two young stands, one of spruce and one of oak
[Qnercus rohur (L.)), growing side by side in Silkeborg Forest district in
Central Jutland. In the summer of 1955 some of the spruce plants died
about 20 July, and by 28 July 8% had died. After that none of the spruces
died even though drought and heat continued. Until 28 July not a single
oak had died- on the contrary they seemed to appreciate the heat-but
in the first week of August the whole plantation of oak died. No examina-
tions of soil humidity were undertaken in a quantitative sense but the soil
under the oaks was considered to be completely desiccated whereas it was
evident that some humidity was left in small pockets under the spruces. One
got the impression that the spruces were already thirsting by the middle
of July whereas the oaks had grown well until the last days of their hfe.

REFERENCES

Oksbjerg, E.B. (1956) Sommervejrct 1955 pa en midtjydsk lokalitet og torkens
virkning pa parceller med tidligt og sentudspringende rodgraner. (English
summary-The weather of the summer 1955 and the effect of the drought upon
plots with early and late flushing Norway spruce.) Datisk Skovforcnitigs Tids-
skr. 41, 273-302.

Oksbjerg, E.B. (1958) Udspring og torketalsomhed. (Enghsh summary -Flushing
time and drought resistance.) Dansk Skovforenings Tidsskr. 43, 292-307.

Oksbjerg, E.B. (1961) Transpiration of growing shoots in Norway spruce {Picea
abies) with some notes on drought phenomena. St'ensk Bot. Tidsskr. 55, 397-
415.

Penman, H.L. (1956) Estimating evaporation. Trans. Arner. Geophys. Utiion, 37, 43-5°.

Walter, H. (193 i) Die Hydratur der PJianze.Jen^.

CLIMATE AND WATER RELATIONS OF PLANTS
IN THE SUB-ALPINE REGION

Walter Tranquillini
Forschungsstelle fiir Lawinenvorbeugung, Innsbruck, Austria

INTRODUCTION

The water balance of a plant is favourable as long as its transpiration and
water absorption are equal. If the water loss exceeds the absorption the
balance becomes negative. Plants have several means of recovering a good
balance or avoiding an increase of water deficit. They can

1. intensify the water absorption

(a) through extension of the root system by growth thus reaching
parts of the soil still wet

(b) through increase of their suction forces by which they are able to
take up soil water that is held more furmly ;

2. reduce the water loss

(a) through reduction of the transpiring surface (shedding of leaves)

(b) through increase in diffusion resistance of leaves (closing of stomata,
incipient drying of cell membranes) .

Especially the last possibihty is frequently used by plants because it is
effective very quickly. An increase in transpiration resistance can be easily
measured by checking the relation between transpiration and evaporation,
the so-called 'relative transpiration' (Livingston, 1906). As long as the
water balance is favourable transpiration is closely related to evaporation,
and the relative transpiration remains constant. If the balance becomes
negative the stomata begin to close. In such a case transpiration lags
increasingly behind evaporation. The stomata will close completely, if a
certain water deficit is reached. Now the transpiration resistance of the
cuticle becomes effective. If cuticular transpiration still exceeds water
absorption, the balance gets worse and worse. This will be recognised by a
further decrease of the water content of a plant or by an increase of the
osmotic values of the cell sap. Plants tolerate this dehydration only to a
certain Hmit. If this hmit is exceeded they suffer drought damage. The
saturation deficit beginning to cause injuries is the 'sublethal deficit'
(Oppenheimer, 1932; Pisek and Berger, 1938). Walter (195 1) coined the
term 'maximum osmotic value' for the osmotic value corresponding to
this water deficit.

154 WALTER TRANQUILLINI

Besides the above mentioned protections against a negative balance, the
abihty to endure extensive drought periods depends on several internal
conditions prolonging the period in which the sub-lethal deficit will be
reached. Such conditions are the following ones :

1. rate of cuticular transpiration

2. the remaining water storage from which plants recover their
cuticular water loss after complete stomatal closure

3. the amount of sub-lethal deficit, i.e. the 'resistance to dehydration'.

Before describing the water relations of some characteristic plants of the
sub-alpine region in the Tyrolean part of the Central Alps it is necessary to
discuss the chmatic features of this area. I have made use of the investiga-
tions of our extensive ecological research station situated at an altitude of
2000 m above sea level, just above the timber line near Obergurgl, the
highest village of Austria. The station covers a part of the western slope of
the Gurgler valley. The studies were made by a team of botanists and
cUmatologists.

CLIMATE AND WATER RELATIONS IN SUMMER

From a physical point of view transpiration of plants depends on the
vapour-pressure gradient from the transpirating surface to the surrounding
air. Therefore transpiration is the greater the less water vapour the air
contains and the higher the temperature of the transpiring surface, which
is almost saturated with water. All the other chmatic factors affecting
evaporation uifluence transpiration over this vapour-pressure gradient.
Solar radiation raises the temperature of plants above the temperature of
the air and increases thereby the gradient. The wind cools off the plants
whereby transpiration is reduced; on the other hand, it removes the air
rich in water vapour from the vicinity of leaves and replaces it with drier
air thereby increasing the gradient again.

With rising altitude the vapour pressure of the air decreases so much
that the air at an altitude of 2000 m contains on the average only one half
of the amount of water vapour as at sea level As Rathschiiler (1949) has
pointed out for the Salzburger Alps tliis difference in gradients is especially
marked during the night, while there is no difference between the bottom
of valley and higher stations in the daytime. Its importance for evaporation
loses significance if the temperature differences at different altitudes are
considered.

Figure i shows the annual trend of the air temperatures at Obergurgl in
comparison with the values of a station at an altitude of 500 m in the

CLIMATE AND WATER RELATIONS

155

_L

_L

J_

_1_

25H
20

15

10

Monthly averages of

maximum 1

daily average >air temperature at 2000r

mininnum

maxirnum lair te

daily average ^^ ^qq;

■ — • minimum

maximum i needle t

minimum f at 2000

-5-

-10

1 1

D J F

M

Fig. I. Annual trend (Oct. 1954-Sept. 1955) of monthly maximum, minimum and
daily averages of air temperature at different atlitudes (Obergurgl 2070 m, Innsbruck
580 m) and of temperatures of pine needles at Obergurgl.

cal /crrfi/d
600-

4O0-

O N D

2000m
in%200m^2« ^^^ 16^ 1^7 128 119 114 111 112 129 18.8 202

Fig. 2. Annual trend of monthly averages of solar radiation at different altitudes
(Obergurgl 2070 m, Wien 200 m). (From Turner, 1961a).

156 WALTER TRANQUILLINI

vicinity. It will be recognised at once how much cooler it is in the higher
region. Especially in summer during the growing season, the monthly
average air temperatures at 2000 m are about 8-10° lower than those of
the valley station. The temperature ranges, hmited by annual trend of
maximum and minimum temperatures, do not overlap, i.e. the average
monthly maximum temperatures at Obergurgl just reach the minimum
temperatures at Innsbruck. In winter the differences are smaller because
temperature inversions occur frequently then.

The average temperatures of leaves are similar to the air temperatures.
We have measured the temperature of needles of young pine trees (Pinus
cemhra L.) at 2000 m for a whole year almost without interruption and
found (Tranquillini and Turner, 1961) that the average monthly tempera-
ture deviates from the air temperature by only 2°C at the most. The average
extremes though are twice as far apart as those of the air temperature; thus
the average maxima of the needle temperature at 2000 m correspond
approximately to those of the air temperature at 500 m (Fig. i).

Since analogous measurements of plant temperature in lower regions
have not been recorded, we have to observe Row other factors important
for the heat relations of plants change with increasing altitude, i.e. solar
radiation and wind. Only then is it possible to estimate whether plants
growing in higher altitude are heated above air temperature more highly
than those in lower regions.

In Fig. 2 the annual trend of average monthly solar radiation measured
at the research station near Obergurgl is compared with that found at an
altitude of 200 m (Vieima) (Turner, 1961a). Radiation at 2000 m is much
more intensive than at lower altitudes. This depends less on the intensity of
direct sun radiation than on the intensity of diffuse radiation under cloudy
conditions because of the smaller thickness of the cloud layer at 2000 m.
Because the horizon in the mountain area is strongly masked by elevations,
radiation in summer is only 10-20% higher than that of lower regions.
Radiation in winter will be referred to later.

Wind velocity also increases with higher altitudes especially if we leave
the forest area which covers the lower parts of the slopes in the mountains.
During a long time we have measured the average wind velocity 3 m above
ground in different places along a line being a cross-section of the valley.
Auhtzky (1958) has pointed out that the wind velocity next to the timber-
Hne is already 40%, and at the tree-line only 200 m above the timber-Kne
is 70% higher than on the bottom (1800 m above sea level) of the valley

(Fig- 3). ^ ,

This increase in wind velocity is probably not important for the water

CLIMATE AND WATER RELATIONS

157

Fig. 3. Average wind velocity at several locations on the eastern and western slope
of the Gurgler vaUey. Cross-section of the Gurgler valley. The points indicate the
places where measurements were taken. (From Aulitzky, 1958.)

loss of the vegetation in summer because the effect of the wind on transpira-
tion is only great at a very low velocity. It decreases rapidly with increasing
wind velocity (Stalfelt, 1932).

To summarise, during the summer at an altitude of 2000 m plants may
not be subjected to much stronger evaporation than plants in lower regions.
The lower water content of the air is more than compensated by lower air
temperatures above which plants may be heated only a little more than
those of lower regions.

This is confirmed by measurements of evaporation at several places of
the station area (Prutzer, 1961) if we compare them with those values which
Walter (195 1) has collected from different chmatic regions. In late summer
evaporation (measured with the Piche Evaporimeter) rose only a little over
I ccm/h in our location in 2000 m. It is therefore not higher than in lower
regions of Central Europe.

If the other conditions are the same, water absorption of plants depends
on the water storage in the soil which in turn depends on the amount of
precipitation.

Precipitation increases rapidly with increasing altitude (Turner, 1961b).
This is especially true for the peripheral zones of the Alps (Fig. 4). Our
research area, however, is sheltered from the wind bringing precipitation
by mountain chains. Therefore it receives comparatively little precipita-
tion; only 1000 mm/annum on the average. The maximum amount of
precipitation falls in summer from July to August. The minimum occurs
in March, i.e. before the growing season (Table i).

158

WALTER TRANQUILLINI

2000

1500-

1000-

500 1000 1500 2000

Annual precipitation , mm.

2500

Fig. 4. Annual precipitation in mm at several locations in the eastern Alps at different

altitudes. (From Turner, 1961b).

Table i

Monthly, half-yearly and annual precipitation (mm) at Obergurgl at the timber-line

(2070 m). Mean from 1911-1950

I II III IV V VI VII VIII IX X XI XII Win. Sum. Year
55 73 53 83 87 92 105 103 80 77 71 63 392 551 944

Therefore 60% of the annual precipitation falls in the summer half-year
and only 40% in the winter half-year. Precipitation is evenly distributed
throughout the summer; on the average there is precipitation every second
day, and every fourth day brings precipitation exceeding 5 mm. Periods
without precipitation do not last long, in summer 14 days at the most,
on the average 4 days ; only outside the growing season are there longer
periods without precipitation (up to 20 days) (Table 2).

Table 2
Maximum duration of dry periods in days at Obergurgl from I954-I959

I

II

III

IV

V

VI

VII

VIII

IX

X

XI

XII

Mean

10

9

7

5

6

4

4

5

7

10

12

10

Maximum

13

20

10

7

14

5

5

8

II

13

19

18

CLIMATE AND WATER RELATIONS 159

In the continental research area dew (63 days) and fog (14 days) are not
important for the water relations of plants.

The even distribution and quantity of precipitation in the summer keep
the soil wet in the root zone of plants.

Because of the equal amount of evaporation and the higher precipitation
in summer even continental high regions in the Eastern Alps (i.e. the area
near Obergurgl) are more humid than lower ones.

Therefore it is not surprising that all field investigations of transpiration
and water balance carried out in the sub-alpine and alpine region have
demonstrated that water relations are only seldom stressed severely. This
has been shown by the osmotic values of about 100 species of plant com-
munities of this region round Innsbruck measured by Pisek, Sohm and
CarteUieri (1935). The osmotic values do not exceed 18 atm; they only
rise to 20 atm in the evergreen dwarf shrubs and conifers. Another reason
for a favourable water balance is that most of the tested plants are very-
sensitive to the smallest water deficits and start reducing transpiration very
quickly. This has been shown convincingly by Berger-Landefeldt (1936)
and CarteUieri (1941). Therefore even at the end of an extreme dry period
in August extending over 3 weeks (which very seldom occurs in high
regions) the osmotic values of some dwarf shrubs grown on southern
slopes did not exceed 25 atm; only Erica carnea reached 27 atm (Pisek and
CarteUieri, 1934).

CLIMATE AND WATERRELATIONS IN WINTER

In winter the conditions are quite different. The decrease in temperature
with increasing altitude causes a longer cold season at 2000 m and a shorter
growing season than in lower regions (Fig. i).

About half the amount of precipitation faUs as snow. The period with
continuous snow-cover lasts 6 months on the average. If the ground is
covered with forest the distribution of snow on the ground is even,
because the forest raises and whirls the streamlines of the wind. Above the
timber-hne the wind acts down to the ground. It carries away the snow
from aU wind-exposed elevations and accumulates it at wind-screened
locations because the wind mainly comes from one direction only. There-
fore in the sub-alpine and alpine region which are strongly undulated the
snow cover may be quite different within the smaUest distances. EspeciaUy
windblown places hke crests and ridges are covered with snow only a few
weeks ; they may be snowless at any time during the winter. On the other
hand in wind-protected hollows of ground and troughs the snow stays for

i6o WALTER TRANQUILLINI

7^ months ; such places are constantly and. reliably covered with deep snow.

The composition of the vegetation reacts very sharply to these variations
in snow cover. This means that they are of great importance to the vegeta-
tion and they influence basically the water relations of plants in winter as
we shall see later on.

The areas with no or only a thin snow-cover support only a certain com-
munity of Lichenes (Alectorietum), or the dwarf azalias (Loiseleurietum)
rich in Lichenes ; in troughs very long covered with snow there grows the
alpine rose (Rhododendretum ferruginei) or some other community (in
our station area, i.e. Festucetum Halleri). Between these extremes of loca-
tion there are many transitions which are occupied by defined plant
communities (Vaccinietum uhginosi and Vaccinietum myrtilli) (Fig. 5).

Corresponding to the different snow cover we can separate 3 types of
wintering by evergreen plants :

1. plants growing in locations mostly without any snow protection

2. plants that grow in snow-covered places, but with parts project-
ing from the snow

3 . plants wliich are completely covered by snow during the winter.
First we v/ill consider the evaporation conditions to which plants or

parts of plants protruding from the snow are exposed. The evaporation
conditions firstly depend on the temperature of the plant. Therefore they
depend on solar radiation.

In winter the snow-covered mountain slopes reflect so much radiation,
that in this season a horizontal area gets a radiation twice as intensive as one
in low regions. The curve of the annual trend of solar radiation is so
asymmetrical that the intensity of solar radiation in April is as high as in

Alectorietum
lextr. 'windexposed )

Alectorietum
Loiseleurietum
Vaccinietum uliginosi
Vaccinietum nnyrtilli
Rhododendretum ferrugine
Festucetunn halleri

Fig. 5. Average duration of continuous snow cover (>5 cm high) for several plant
communities at our research station near Obergurgl. (From Turner, 1961b.)

CLIMATE AND WATER RELATIONS i6i

July (Fig. 2). This higher intensity of radiation in high altitudes causes
plants to be heated above the air temperature in winter much more than
in lower regions. So we have found that the temperature of the needles
of pine trees is surprisingly often above the freezing point; on 83% of all
the days, during a research period from September to May, the temperature
of the needles exceeded o°C at least for a short time (Tranquillini, 1957).
Especially at the end of winter when the snow had not yet melted and when
radiation was very intensive there were high temperatures and liigh vapour
pressure gradients from plants to the cold air poor in water vapour. By
March the temperature of pine needles rose to 4-6° on the average, in the
extreme to 18-4° at midday, in April to 14-4° on the average, in the extreme
to 297°; therefore sometimes the temperature is as high as in summer

(Fig- !)•

It is very important for the water relations of such parts of plants pro-
truding from the snow and being occasionally heated very much, whether
the water loss, which at times is as high as in summer, can be made good by
water absorption from the soil. This question can be answered from records
of soil temperature, carried out by Auhtzky (i 96 1 ) at a snowless and a snowy
site at different depths of the soil at our station (Fig. 6). In the snow-covered
place the temperature of the soil sinks below 0° only in the upper 20 cm
of soil but does not fall below — i°C. This is the result of the good thermal
insulation of the snow-cover. On the other hand the ground not covered
by snow or with only a thin snow-cover freezes completely to a depth of
more than i m at the beginning of December and thaws only near the
surface at the end of April, and to a greater depth in the middle of May
(Fig. 6).

Whether the plants can absorb water from the soil in winter depends upon
the temperature at which the water freezes in the soil. This has been showTi
by measurements of the soil moisture by means of electrical resistance
blocks. Water does not freeze at a certain temperature at once but succes-
sively. With decreasing temperature ice is formed in the larger pores first,
later in the smaller and smallest ones. The water turning to ice last, is held
so firmly in the soil that it cannot be absorbed by the plants, although it is
not yet frozen. The water available for plants is frozen at — i°C (Larcher,

1957)-

It can be concluded that plants in snowless locations certainly cannot
absorb water from the soil during a period of 5 months ; this is a long time
during which they permanently lose water. At the end of the winter this
water loss occasionally reaches an amount similar to that in the summer.

On the other hand the water absorption of plants that grow in snow-

l62

WALTER TRANQUILLINI

covered places and parts of which stick out of the snow is not interrupted
as a rule. Of course the absorption of water is reduced at low temperatures.
Doring (1935) has found that spruce trees absorb one third less water at
o°C than at 20°C. The absorption is also reduced because the roots do not
grow in winter, therefore the soil moisture near the roots is soon exhausted.
From the parts of soil still wet water moves to the roots slowly. Abundant
moistening of the root zone takes place at the time of snow melting, which
occurs between February and March. Therefore those plants wiU suffer the
greatest deficits until February.

In a snosA/- covered place

Fig. 6. Tautochrones of monthly averages of the soil temperature at different depths
in the soil. The region where the temperature falls below o°C is indicated by grey
shading. (From AuHtzky, 1961.)

The Siberian pine tree (Pintis cemhra) winters in three different ways in
our station area. Above the timber-hne young plants grow on windblown
ridges which are without any snow during the winter ; at the timber-line
there are many young plants which are entirely covered with snow through-
out the winter, and there are also taller plants and adult trees, which protrude

CLIMATE AND WATER RELATIONS

163

partly out of the snow. Therefore it is possible to follow clearly the effect
of the environmental conditions in winter on the water relations from the
annual trend of the osmotic values and the water content of needles of this
tree species (Fig. 7).

atm

35

N 30

25-

20-

o o adult pine trees

o o young pine trees standing out of the snow

o o — •■ — covered ^th snow during the v^'inter ,*

« « — ■• — in a place without snovv' cover

/

/

Y - - \

1 1 1 1 1 1 1 1

SONDJFMAM

M

Fig.

7. Annual trend of osmotic values of the needles of some pine trees at several
places at the research station near Obergurgl.

We will begin with young plants growing in a snow-covered location.
The upper shoots of them stick out above the surface of the snow just a
little. In this case the plants were about i m tall. In summer especially when
the plants sprout, the osmotic values (o.v.) are low (16-18 atm). At the end
of September they increase strongly (24-5 atm) as a result of an active
accumulation of the osmotically effective substances. This is the case in
all evergreen plants at the beginning of the cold season. The further
increase up to 30 atm, however, is attributed to water loss. The water
content decreases to 36% between October and February. That this

i64 WALTER TRANQUILLINI

decrease is not greater is due to the fact that water absorption is possible
from the snow-covered soil at least at times.

The water balance of comparable plants which are completely covered
with snow is different. Beginning at the time when they are snowed-up the
water content of their needles rises slowly but steadily. Therefore the o.v.
falls continuously under the snow. Plants do not lose water by transpiration
because the air within the cavities of snow is saturated with water vapour.
Hence they are able to balance slowly their water deficit existing at the
beginning of the snow cover, first by absorption by the needles, later on by
absorption from the soil. For this reason shortly before plants melt out of
the snow their o.v. is as low as in the summer.

Adult trees also have a favourable water balance because they are able
to compensate greatly the water loss of their crowns by absorption from
the unfrozen soil. Their o.v. does not rise over 28 atm, and the water
content of the needles decreases only by 13% of that at the begimiing of
November. That their needles dry up less than those of smaller plants on
comparable places is due to the bigger water storage in their branches and
stems.

In snowless locations above the timber-line young plants have the worst
water balance. In winter they lose 52%, that is somewhat more than one
half of the water content in autumn. Their water content decreases to 78%
of the dry weight, and their o.v. increases to 42 atm.

We have to compare tliis dehydration with the aimual trend of the
resistance to dehydration, measured by Pisek and Larcher (1954), of several
plants in the sub-alpine region, to decide whether the critical Hmit at which
plants begin to suffer injuries was exceeded or not (Fig. 8).

From Fig. 8 can be seen that only in winter are plants dried severely
and that this dehydration has its maximum between February and April.

We see also, that during tliis time the water content of needles of grown
up pine trees remains well above the level of dehydration injury.

Larcher (1957) has collected all measurements of water content which
Pisek and co-workers carried out near Innsbruck above the timber-line
during several years from January to April. From this collection we can
determine the mean and the maximum drought stress (Hofler, Migsch and
Rottenburg, 1941; Larcher, i960) (Table 3). This shows that this tree
species is extremely adapted to drought.

Smaller pine trees are stressed much more because they have in their
stems less water than taller trees.

In snowless sites in the zone between timber-line and tree-line the water
content of pine plants decreases to the critical hmit (Fig. 7).

CLIMATE AND WATER RELATIONS

165

150-

130-

110-

0>9O

> 70
V

SO

^130

c

0 110

9Q

70-

50-

30-

JASONDJF MAMJJASONDJFMAMJ

1 1 I I 1 ' I I I I I I 1 I I I I I J ! 1 1 L

Pinus cembra

Loiseleuria procumbens

Picea zxczlsa

needles begin to drop ^ — —

Rhododendron ferr.

ISO
130
110
■90
70
-50
-130
110
■90
70
50
30

T 1 r 1 1 1 1 1 1 1 1 1 1 1 1 1 : 1 1 1 1 1 I r

J ASONDJFMAMJ JASOTJDJFMAMJ

Fig. 8. Natural (circles) and sub-lethal water content (solid line) in percentage of dry
weight of several sub-alpine plant species without snow cover at the Patscherkofel
in winter. (From Larcher, 1957).

In winter the dehydration of needles of grown up spruce trees [Picea
excelsa) approached the critical hinit more than that of the adult pine trees
especially if we take the beginning of the dropping of their needles as an
injury.

Tables

Injury delay of cut-off leaves and twigs exposed to the open air in February and March
(Pisek and Berger, 1938) and drought stress (actual as per cent sub-lethal deficit)
(Hofler, Migsch and Rottenburg, 1941 ; Larcher, i960) in the natural habitat

Injury delay (days)

A

Drou

ght Stress

f

Leaves

Twigs

r

Mean

Alaxjmum

Pinus cembra (adult trees)

26

49

15

26

(young plants)

—

—

34

50

Picea excelsa

20

28

18

64

Loiseleuria procumbens

14

26

34

51

Rhododendron ferrugineum

5

21

42

>I00

i66 WALTER TRANQUILLINI

The water loss of leaves of the alpine rose {Rhododendron ferrugineum)
clearly exceeds the critical limit at some measurements (Fig. 8). If we cut
off twigs of this plant m winter and expose them to the open air in February
and March they wilt after only 21 days (Table 3). Twigs of pine trees can
endure the same conditions for 49 days. Therefore the alpine rose depends
on the protection of a snow cover and grows only in such places which are
covered with snow reliably and for a long period during the winter.

Among the tested plant species the trailing azalea [Loisekuria procumhens)
has an exceptional position. When a twig is cut off and is exposed to the air
it starts wilting after nearly the same time as a twig of the alpine rose. This
is due to the high cuticular transpiration and little water storage in the
shoots (Table 3) but in its natural habitat it is not more stressed than are
young pine trees (Fig. 8, Table 3). For this phenomenon the only explana-
tion is that the azalea is well supphed with water in late winter, although it
grows in snowless places (Fig. 5), where the soil is certainly frozen. On warm
sunny days during this period there is a lot of water from melting snow,
which cannot penetrate into the soil. Therefore it saturates the Utter and
mould layer. In this wet layer numerous adventitious roots are spread by
which the plant can absorb this water.

REFERENCES

AuiiTZKY, H. (1958) Waldbaulich-okologische Frageii an der Waldgrcnze. Cbl. ges.

Forstwesen, 75, 18-33.
AtniTZKY, H. (1961) Die Bodentemperaturverhaltnisse an einer zentral-alpinen

Hanglage beiderseits der Waldgrenze. Arch. Met. Gcophys. Bioklim. loB, 445-

532.
Berger-Landefeldt, U. (1936) Der Wasserhaushalt der Alpenpflanzen. Bihl hot. 115.
Cartellieri, E. (1941) Ober Transpiration und Kohlensaureassimilation an einem

hochalpinen Standort. Sitzungsher. Akad. Wiss. V/ien, math.- naturw. Kl. Abt. I.

149, 95-143-
DoRiNG, B. (1935) Die Temperaturabhangigkeit der Wasseraufnahme und ihre

okologische Bedeutung. Z. Bot. 28, 305-383-
Hofler, K., Migsch, H. & Rottenburg, W. (1941) Uber die Austrocknungsresistenz

landwirtschaftlicher Kulturpflanzen. Forschuiigsdiaist, 12, 50.
Larcher, W. (1957) Frosttrocknis an der Waldgrenze und in der alpinen Zwerg-

strauchheide auf dem Patscherkofel bei Innsbruck. Veroff. Ferdinandeum Innsbruck,

37, 49-81.

Larcher, W. (i960) Transpiration and photosynthesis of detached leaves and shoots
of Quercus pubescens and Quercur ilex during desiccation under standard condi-
tions. Bull. Res. Counc. of Israel, 8D, 213-224.

Livingston, B.E. (1906) The relation of desert plants to soil moisture and to evapora-
tion. Carnegie Inst. Publ. 50.

CLIMATE AND WATER RELATIONS 167

Oppenheimer, H.R. (1932) Zur Keiintnis der hochsommerlichen Wasserbilanz

mediterraner Geholze. Bcr. dtsch. hot. Ges. 50A, 185-245.
PiSEK, A. & Berger, E. (193 8) Kutikulare Transpiration und Trockenresistenz isolierter

Blatter und Sprosse. Planta, 28, 124-155.
PiSEK, A. & Cartellieri, E. (1934) Zur Kenntnis des Wasserhaushaltes der Pflanzen.

III. Zwergstraucher. J/), iviss. Bot. 79, 131.
PiSEK, A. & Larcher, W. (1954) Zusammenhang zwischen Austrocknungsresistenz

und Frostharte bei Iinmergriinen. Protoplasma, {Wien), 44, 30.
PiSEK, A., SoHM, H. & Cartellieri, E. (1935) Untersuchungen iiber den osmotischen

Wert und Wassergehalt von Pflanzen und Pflanzengesellschaften der alpinen

Stufe. Beih. bot. Zhl. 52, 634-675.
Prutzer, E. (1961) Okologische Untersuchungen in der subalpinen Stufe. Die

Verdunstungsverhaltnisse. Mitt, forstl. Bundesuers. anst. Mariahrunn {Wien), 59,

231-256.
Rathschuler, E. (1949) Uber die Anderung des Tagesganges der Luftfeuchtigkeit

mit der Hohe im Gebirge. Arch. Met. Geophys. Bioklim. iB, 17-31.
Stalfelt, M.G. (1932) Der Einfluss des Windes auf die kutikulare und stomatare

Transpiration. Svensk bot. Tidskr. 26, 45.
Tranqulllini, W. (1957) Standortsklima, Wasserbilanz und C02-Gaswechsel junger

Zirben {Pimis ccnibra L.) an der alpinen Waldgrenze. PlaiitiT, 49, 612-661.
Tranquillini, W. & Turner, H. (1961) Okologische Untersuchungen in der

subalpinen Stufe. Pflanzeutemperaturen. Mitt, forstl. Bundesvers. anst. Mariabrunn

{Wien),S9, 127-151.
Turner, H. (1961a) Jahresgang und bilogische Wirkungen der Sonnen- und Himmels-

strahlung an der Waldgrenze der Otztaler Alpen. Wetter und Lehen (Wien), 13,

93-113-
Turner, H. (1961b) Okologische Untersuchungen in der subalpinen Stufe. Die

Niederschlags- und Schneeverhaltnisse. Mitt, forstl. Bundesvers. anst. Mariahrunn

(H//e»), 59, 265-315.
Walter, H. (1951) Statidortslehre. Stuttgart: Eugen Ulmer.

12

INVESTIGATIONS ON THE WATER RELATIONS
OF SAND-DUNE PLANTS UNDER NATURAL

CONDITIONS

A.J. Willis & R. L. Jefferies

Department of Botany, University of Bristol

INTRODUCTION

Although many studies of the water relations of plants have been made,
only a few of them relate to the behaviour of plants under the normal
conditions of their habitat. The aim of the present investigation has been
to gain information concerning the water balance of plants in their natural
environment of sand dunes. In this habitat, conditions tend to be somewhat
extreme, especially on the dunes themselves where rates of evaporation are
often high, and the water supply limited during the summer. Furthermore,
conditions are strongly contrasting within the dune system, as although in
some parts insolation is considerable and the water content of the sand
very low, elsewhere the sand may be water-saturated and some shelter
afforded. These habitat differences are most marked during the summer, a
time when any physiological differences between plants with regard to
their water relations are likely to be clearest. The data reported here are of
studies made in mid-June (1952-60) on a range of plants of the dune
system of Braunton Burrows, North Devon.

Previous investigations have stressed the importance of the water factor
in respect of plant distribution on the Burrows (Wilhs, Folkes, Hope-
Simpson and Yemm, 1959), many species being restricted to low-lying
'slacks' where their roots are always within reach of the capillary fringe of
the water table and others occurring characteristically on the drier dune
slopes. An attempt was made to estimate to what extent plants of these
various sites differed in respect of their water relations. Hygen (195 1, 1953)
has attempted an ecological characterisation of plants in terms of their
rates of stomatal and cuticular transpiration, and has shown the usefulness
of transpiration decline curves in this connection. Somewhat similar studies
have been made in the present investigation alongside assessments of
stomatal behaviour and water deficits. In particular, the diurnal course of
transpiration has been followed under natural conditions, measurements
being also made of physical factors of the environment such as temperature,
relative humidity and hght intensity, as well as the rate of evaporation, at
different times of the day and night.

WATER RELATIONS OF SAND-DUNE PLANTS 169

Despite the difficulties associated with field measurements and the
interacting complex of changing factors, these exploratory studies were
planned to provide some basic data concerning the diurnal changes of
water deficit, transpiration rate and stomatal behaviour in a range of
species, and thus elucidate characteristic differences in the water relations of
plants of different sites.

EXPERIMENTAL METHODS

The choice of plants for the experiments was made so as to include some
representatives of the vegetation of the dune slopes and of the 'slacks'. A
plentiful supply of leaves of suitable size and shape for weighing was
required and it was also desirable that the epidermis should strip readily
for stomatal studies. The most extensive investigations were with Senecio
jacohaea L., Cynoghssum officinale L. and Hydrocotyle vulgaris L. (all amphi-
stomatous species) ; a number of other plants was also studied.

The various methods used to investigate features which affect the water
balance of the plants are considered in turn.

(a) Measurement of the Water Content of the Soil

Soil samples were collected from freshly excavated holes, at various sites,
in 2 in. X I in. specimen tubes, sealed with Vv^axed corks and tape. The
samples were dried to constant weight at 8o°C, and the water content
expressed as a percentage of the weight of the oven-dried soil.

(b) Physical Factors of the Environment

The chief physical features assessed were temperature, relative humidity,
light intensity and the rate of evaporation ; measurements were made at
frequent intervals.

Air temperature was taken as the dr)'-bulb reading of a whirhng psychro-
meter, which was swung rapidly at approximately i m above ground
level for about 20 seconds. The relative humidity was estimated from the
depression of the wet bulb.

Light intensity was measured by means of an EEL Lightmaster photo-
meter, graduated in three ranges — o-io, o-ioo and o-iooo ft candles
(lumens/sq. ft). The sensitivity of the cell to different wavelengths is
recorded by Ashton (1958). To extend the range of the photometer to
approximately 10,000 ft candles, a cHp-on neutral density filter was
employed. Although Hght intensities are expressed in this study in terms of
foot candles, it is clear that these units are arbitrary, and that the measure-

170 A.J. WILLIS AND R.L.JEFFERIES

ment of light intensity in absolute units in the field is of great complexity
(Evans, 1956).

An indication of the rate of evaporation was obtained from the changes
in v^eight of saturated filter paper suspended from a torsion balance on the
dunes. Pieces of filter paper, usually of 12-65 sq. cm or 4 sq. cm area, were
saturated with water, weighed initially and again at appropriate intervals
(usually about i min) for some 10 min. In the experiments reported here
the rate of loss of water vapour was seen to be uniform over this period.
Estimates made in this way at every hour were found to give a satisfactory
indication of the diurnal changes in evaporation.

(c) Estimation of Water Deficits

The water deficits of leaves at different times of day were measured by the
method described by Yemm and WiUis (1954), which is similar in principle
to that of Weatherley (1950). After an initial weighing of the leaf, im-
mediately after excision, it was transferred to a saturated atmosphere, and
its cut petiole allowed to stand in distilled water. The leaf was then weighed
at appropriate intervals until it was fuUy turgid; the dry weight of the leaf
was fmally determined. The water deficit is here expressed as the amount
of water absorbed by the leaf to reach fuU turgidity, calculated as a per-
centage of the water content of the fuUy turgid leaf (Stocker, 1929). Under
field conditions on very hot dry days difficulties were encountered in
maintaining a saturated atmosphere, and it was found convenient, parti-
cularly when high deficits were involved, to allow the leaves to pick up
water overnight, a final weighing being made early the next morning.
However, many plants restored their deficit in less than 3 hours, the course
of water uptake being as illustrated by Yemm and WiUis (1954, Fig. 3).

(d) Measurement of Transpiration Rates: Transpiration Decline
Curves

Transpiration rates were estimated from weight losses of detached leaves.
The decline in transpiration of the cut leaves was determined from weigh-
ings at frequent intervals ; in this way transpiration dechne curves of the
type described by Hygen (195 1, 1953) were obtained. There were, how-
ever, several important differences from the procedure of Hygen ; the
leaves were not initially always completely turgid, nor were the stomata
always open. Furthermore, the conditions under which the determinations
were made were those of the variable environment.

The method adopted in this investigation was to cut a leaf of convenient
size (100-500 mg) from the plant in its natural habitat, weigh the leaf on a

WATER RELATIONS OF SAND-DUNE PLANTS 171

torsion balance as soon as possible after cutting (usually within i min),
and make a series of subsequent weighings at known times. When there
had been a heavy dew, the leaves used in transpiration studies in the early
morning were blotted dry before the initial weighing. It was necessary to
shield the balance from wind; for this a box was used with a perspex front,
which was removed between readings. Trials showed that the results
obtained when the leaves remained on the hook of the balance were usually
fairly similar to those obtained when the leaves were removed between
weighings and suspended in the open. Only on very hot days and under
windy conditions were the differences considerable (most of the experi-
ments of this study were carried out when there was httle wind). By using
a torsion balance with a scale of o-ioo mg, and by employing appropriate
counterbalance weights, it was possible to weigh to an accuracy of o-i mg.
The timing was accurate to one second.

The form of the transpiration dechne curve of leaves investigated usually
conformed to that described by Hygen (195 1). At first there is a rapid,
fairly uniform transpiration rate (the 'stomatal phase'), the decline follow-
ing a rectilinear course; this is succeeded by a phase of decreasing trans-
piration rate (the 'closing phase'), which is followed by a fmal rectilinear
portion of the decline curve (the 'cuticular phase') when the rate of loss of
water vapour is low. In the experiments of Hygen the leaves were brought
to a condition of full turgidity initially, the stomata being assumed fully
open; by the end of the second ('closing') phase the stomata were regarded
as completely shut. Although in many of the experiments of the present
study carried out during the day the leaves were not fully turgid, and the
stomata not fully open, decline curves showing initial and fmal portions
approximating to straight lines were often obtained; however, the initial
rectilinear portion was frequently short. On the other hand, the decline
curves for leaves detached in the early morning or during the evening are
not so readily interpreted in terms of three phases, as these are not sharply
defmed. Some examples of curves obtained at different times of day are
given for leaves o{ Senecio jacobaea in Fig. i. The decline curve for the leaf
detached at about 1 1 a.m. indicates three phases, but these are less clear for
the leaf detached in the evening, when the initial rectilinear phase is short.
Very different is the curve for the leaf excised at about 6.30 a.m., as the
transpiration rate is rather low initially and fairly uniform for a consider-
able time (a prolonged steady rate of transpiration of leaves excised in the
early morning has been often observed in the present study). The major
differences in the curves are clearly in part referable to different physical
conditions at different times of day and in part to differences with respect

172 A.J. WILLIS AND R.L.JEFFERIES

to the behaviour of stomata. For example, stomatal closure from fairly
wide apertures (c. 4-5 /x) probably occurred about one hour after excision
of the leaf at 1 1 a.m. ; however, in the leaf detached in the early morning,
although the stomata were initially of only moderate aperture {c. 3-3 /la),
closure was delayed.

The rate of transpiration at the time of cutting was estimated by extra-
polation of the decline curves to zero time. The vaHdity of this estimate
may be questioned in view of the quick changes in transpiration rate
which may occur on cutting a leaf, in particular when the stomata are

ii-

100

z

se

o
z

0

_j

z
0

Q.

200

300-

TIME

90
EXCISION

Fig. I. Transpiration decline curves for Scncciojacobaea. For simplicity in comparison,
transpiration losses are calculated as mg/g initial fresh weight of the excised leaves.

A selection of the results for leaves cut at 6-27 a.m. (• •), 10-55 a.m. (O O)

and 6.18 p.m. (a a) on 18 June 1958 is shown.

only partly open. Substantial increases in transpiration rate on leaf excision
have been noted by many observers, including Andersson, Hertz and
Rufelt (1954) and Parker (1957) ; similar observations have also been made
under some conditions in this laboratory. Milthorpe and Spencer (1957)
obtained evidence of increased transpiration rates and opening of stomata
following the removal of the water supply of leaves, and further showed
that data of Hygen (1953) are consistent with these findings. However,
there is only httle indication of appreciable increases in transpiration rate
on leaf excision in the present field studies ; in fact, the points of the majority

WATER RELATIONS OF SAND-DUNE PLANTS 173

of the decline curves appear to fall closely on a straight line for the first
few minutes and to form the basis for a useful comparative estimate of
transpiration rate. In practice, the estimate of the rate of transpiration at the
time of excision is derived by extrapolation from the values for the first
three minutes after cutting the leaf Values based on a rather longer period
give similar results ; detailed examination of records for Hydrocotyle vulgaris
showed that the estimates of rate based on the first four minutes after
excision are not appreciably different from those based on the first three
minutes. The estimates by Hygen (195 1, I953) of initial transpiration rate
are based on semi-logarithmic plots of weight against time, but, as discussed
by Williams and Amer (1957), it is not essential to take logarithms (or
compute a 'reduced fresh weight'), there being a prolonged constant rate
phase during which transpiration is independent of water content. Wilhams
and Amer (1957) further point out that Hygen's 'standard product' may
be calculated directly from the slopes of the first and second straight
portions of a plot of instantaneous weight of the leaf against time.

Transpiration rates are usually expressed on either an area or a weight
basis. In the present investigations the most convenient basis of expression,
in view of the methods used, is mg transpiration/g initial fresh weight/
minute, the initial fresh weight at the time of excision being estimated by
extrapolation. It must, however, be noted that on some occasions the leaves
were essentially fully turgid but at other times had an appreciable water
deficit, which in extreme instances was of the order of 20%. Nevertheless,
comparison of results for Hydrocotyle vulgaris showed that the diurnal
changes of transpiration rate expressed on a fresh weight basis followed a
very similar course to that of rates expressed on the basis of dry weight of
the leaves. In a few experiments leaf areas were determined, and the results
can be expressed in terms of both weight and of area.

(e) Investigation of Stomatal Behaviour

Although estimations of stomatal changes have been attempted with
various types of porometer at Braunton Burrows, the two most useful
methods of investigating the behaviour of stomata under natural conditions
were found to be the examination of strips of epidermis and the infJtration
technique.

Epidermal strips, fixed by the method of Lloyd (1908), were examined in
iodine-phenol-KI reagent (Heath, 1947) and the stomatal apertures
measured as described by Yemm and WiUis (1954) • Although there is
evidence that in Pelargonium (Heath, 1950) the stomata may open during
stripping and fixing, measurements made from epidermal strips do never-

174 A.J. WILLIS AND R. L.JEFFERIES

theless indicate trends of opening and closure of stomata (Heath, 1959).
Results obtained in the present study indicate that, for a range of plants of
sand dunes, Lloyd's strips provide a useful, if not absolute, index of stomatal
aperture. Several strips of the lower epidermis from at least two leaves were
taken on sampling occasions ; mean apertures are based on measurements of
not less than 20 stomata (frequently more), at least two strips being
examined. In view of the importance of starch/sugar changes in stomatal
behaviour, at the same time as apertures were measured assessments were
made of the amount of starch in the guard cells by the method of Yemm
and Wilhs (1954), a scale of 0-5 for starch content being used.

Infiltration methods integrate the effects of large numbers of stomata
and give quick information of stomatal apertures. A variety of infiltrating
liquids has been used by different workers (cf Heath, 1959) ; in the present
study a graded series of seven solutions involving petrol ether and alcohol
was employed. The series was as foUows: i, petrol ether; 2, 4 vols, petrol
ether/ 1 vol. absolute ethanol; 3, 2 vols, petrol ether/ 1 vol. ethanol; 4, equal
vols, petrol ether and ethanol; 5, i vol. petrol ether/4 vols, ethanol; 6, abs.
ethanol; 7, 95% ethanol. Of these solutions, no. i is the most penetrating,
and 95 % ethanol the least, entering the leaf only when the stomata are very
widely open. To aid the subjective assessment, by eye, of the degree of
penetration, crystal violet (cf WilHams, 1949) was added to solutions 3-7
[c. 100 mg/150 ml), and waxohne blue to solutions i and 2. Estimations
were made by immersing leaves in a shallow layer of the solutions, washing
quickly in water and assessing the extent of infiltration. By use of a number
of leaves it is possible to find the point in the series (the infiltration index)
giving a mean value of 50% penetration of the leaves; trends of stomatal
movement can be detected from changes in this index. Parallel studies by
the epidermal strip and the infiltration methods gave results which were
strongly correlated; for a particular species, a point on the infiltration scale
can be expressed in terms of mean stomatal aperture. Some indication of
the relation between aperture and infiltration is given for Senecio jacobaea
in Fig. 2. However, in view of differences in the structure of stomata (e.g.
the presence or absence of ridges or 'beaks' on the guard cells) in different
species, it is necessary to determine for each species the mean stomatal
aperture corresponding to a particular point on the infdtration scale.
Although the infiltration technique provides a rapid indication of stomatal
aperture, two main difficulties may be noted. The method is not suitable
for use with thickly hairy leaves (e.g. Verbascum thapsus L., Cynoghssum
officinale), as the infiltrating solutions may be trapped in the tomentum
and hence the degree of penetration is not easily assessed. A second diffi-

WATER RELATIONS OF SAND-DUNE PLANTS

175

culty is that the volatile solutions may quickly change in composition
by evaporation, especially during a hot dry day.

2 3 A 5

INFILTRATION INDEX

Fig. 2. The relation between infiltration index and mean stomatal aperture in Senecio

jacobaea.

(f ) General Procedure

As far as was practical, measurements of physical factors, of water deficits,
transpiration rates and stomatal apertures of particular species were made
at intervals of about one hour from dawn to sunset. These data were
augmented by information from many shorter-term experiments. In any
experiment, care was taken to ensure that the leaves taken for the various
assessments were as far as possible comparable. The leaves used were
fuUy expanded, but not senescent.
AU times are given in G.M.T.

EXPERIMENTAL RESULTS

For convenience, data relating to the water content of the dune soils are
given first, and then the results of investigations made on particular species.

(a) The Water Content of the Soils

Especially during the summer, there is a sharp contrast in the water content
of the sand of the dune slopes and of the 'slacks'. Even in dry years the water
content of the soil of the low-lying parts is high, whereas on the dunes
themselves it is more variable, being very low in times of drought and
moderate in wet periods.

It has already been shown (WiUis et al, 1959, Fig. 14) that in dry dune
pasture the layers of the sand above the reach of the capillary rise may be of
low water content in summer. In some years, however, moister conditions

176 A.J. WILLIS AND R.L.JEFFERIES

prevail; for example the data given in Table i indicate that in June 1956
the sand of the dune slopes had a water content of some 4-8% in the top
90 cm. On the other hand it is clear that in June 1957 the surface layers of
this site were very dry, plants rooted in the top 15 cm being extremely
limited in their water supply.

Table i

The water content of the soils at Braunton Burrows. Water contents are expressed as
percentages of the weight of oven-dried soil

Depth

Dry dune

pasture

from

(dune si

ope)

•Slack'

surface
(cm)

A

22.6.56

22.6.56

28.6.57

3-75

4-1

1-4

9-7

7-5

5-7

1-7

12-9

15

61

2-2

19-4

30

7-6

4-4

21-2

60

4-6

4-2

21-7

90

6-1

4-0

26-0

(saturated)

Plants of the 'slacks', being always near to the water table, have a much
more constant and plentiful water supply. Only rarely does the water
content of the soil fall appreciably below 10% even at the surface, and for
much of the year the soil is saturated throughout.

(b) The Water Relations of Senecio jacobaea

This study was carried out on plants in their second year of development
growing on the dune slopes well above the level of the water table.
Generally the 6th-8th expanded leaves (counting from the apex down-
wards) were used experimentally.

The results of a typical investigation are shown in Fig. 3 . The transpiration
rate was very low at dawn, and rose during the mornhig to reach a peak
value of almost 20 mg/g fresh wt/min before midday. Subsequently the
rate decreased fairly uniformly and by the end of the day was similar to
that at dawn (c. 2 mg/g/min). The changes in stomatal apertures in general
paralleled those of transpiration rate. The stomata opened quickly after
6 a.m. and were of greatest mean aperture at about 1 1 a.m. After this time
there was a progressive closure. The water deficit of the plants was con-
siderable {c. 8%) at dawn, and increased during the morning. There was,
however, some restoration of the deficit in the early evening.

WATER RELATIONS OF SAND-DUNE PLANTS

177

The records of air temperature, relative humidity, Hght intensity and of
observations on wind indicate that the greatest opening of the stomata and
the highest rates of transpiration precede the peak evaporation rates by

S-80-

-15

rr

D

D

z

<

D

ir

A

I

^

UJ

1

>

UJ

1-

A

•^60-

-10

u

A

tr

A-

&

20

15

10 y

5I

10

o

75

50"

in

z

ui
25?

I
O

3a.m

Fig. 3. The diurnal changes in transpiration rate, stomatal aperture and water deficit
in Seneciojacobaca. Some of the results of an experiment of 16 June 1959 are plotted.

The upper part of the figure shows transpiration rate (• •), mean stomatal

aperture (Q Q) and water deficit (A A)- Changes in some of the chief

physical factors are illustrated in the lower part of the figure: air temperature
(A A), relative humidity (O O), light intensity (• '•).

about 2 hours. The correspondence of the greatest transpiration rate with
the maximum stomatal opening is striking; the decrease of transpiration
rate at a time when environmental conditions are tending to increase
evaporation is strongly suggestive of stomatal regulation. It may be noted

178 A.J. WILLIS AND R.L.JEFFERIES

that this record does not indicate any re-opening of the stomata after
midday.

Similar results to those described have been obtained on a number of
occasions. Usually the transpiration rate is highest just before midday and
declines substantially in the afternoon. Less commonly a fairly high
transpiration rate is maintained well into the afternoon; for example, on
i8 June 1958, a rate of about 14 mg/g/min persisted for some 6 hours
(from about 10 a.m. to 4 p.m.), the stomata showing fairly constant aper-
tures of about 4 fjL over this period.

Characteristically the stomata of 5. jacobaea show pronounced diurnal
changes; shut during the hours of darkness, they open early in the morning
to a maximum before midday. They then tend to close with various
degrees of rapidity. On one occasion there was some indication of midday
closure of stomata, followed by sHght re-opening later in the afternoon, as
reported for various plants by Loftfield (1921) and Sayre (1926), but usually
no re-opening is observed.

Water deficits greater than 20% have been found several times, and
during the day in the summer are usually well in excess of 10%. Often the
deficit developed during the day is still quite large on the following morn-
ing, especially at times when the water content of the sand is low. Despite
the fact that the water deficit of the leaves may be 8-10% at dawn, the
stomata usually show a strong opening reaction and closure often does not
begin until the deficit reaches about 15%.

Attempts have been made to estimate the rate of 'cuticular' transpiration
from decline curves; under field conditions the final portion of the curves
is not strictly rectilinear and the assessments are to some extent arbitrary.
The results indicate a rather low value of 0-6-0-8 mg/g/min under condi-
tions of high evaporation. These values are of the order of 5-8 % of the
total transpiration losses.

(c) Observations on Cynoglossum officinale

The water relations of this plant show a general similarity to those of
Senecio jacobaea, with which it is often associated on the dry dune slopes at
Braunton Burro ws. Leaves from first year rosettes were used experimentally .
A representative set of data is given in Fig. 4. The transpiration record
indicates a gradually rising rate to a maximum value at about 10 a.m., soon
followed by a rather sharp decline. On the other hand, the rate of evapora-
tion reached a high value by 10 a.m. but remained high for some hours. It
is clear that the peak transpiration rate precedes the maximum light inten-
sity, maximum temperature and lowest relative humidity. In this experi-

WATER RELATIONS OF SAND-DUNE PLANTS

179

ment no large changes in stomatal apertures were observed; however, it
is of note that the widest apertures correspond with the greatest transpiration
rate, and the stomata are partly closed during the early morning and the
late afternoon when rates of loss of water vapour are low. The water
deficit is seen to be low at dawn, but to develop rapidly to a value of about

Fig. 4. The diurnal changes in transpiration rate, stomatal aperture and water deficit
in Cynoglossiwi officinale. A selection of the results obtained on 21 June i960 is plotted.

The upper part of the figure shows transpiration rate (• •), evaporation rate

(A A), mean stomatal aperture (Q O) and water deficit(A A)- Below

are given data for air temperature (A A), relative humidity (O O) and

light intensity (• •).

i8o A.J. WILLIS AND R.L.JEFFERIES

20% by midday. The deficit was subsequently reduced, a feature doubtless
related to the closing of the stomata and a reduced transpiration rate.

As discussed with reference to Senecio jacohaea, there is seen to be here
also evidence of stomatal regulation of transpiration ; the daily course of
transpiration appears to be rather similar in these plants. Rates of 'cuticular'
transpiration are also of about the same magnitude (o-y-o-p mg/g/min
under conditions of high evaporation). Some difference may be shown
with respect to the water deficits of leaves ; usually the deficits are more
readily restored overnight in CYnoglossum officinale than in Senecio jacohaea.
This feature may be related to differences in habit and root systems of the
plants used experimentally; in the erect second-year phnts o£ Senecio the
root and conducting systems may be inadequate to supply the water
required by the numerous leaves, whereas the first-year plants of Cyno-
glossmn have fewer leaves in a basal rosette, and an extensive tap-root (cf
Sahsbury, 1952).

(d) Investigations on Hydrocotyk vulgaris

Well-developed leaves of tliis plant collected from vigorous populations

in the 'slacks' were used experimentally.

Some of the observations made on 18 June 1958, and on 16 June 1959,
are shown in Fig. 5. Transpiration rates rise from low values in the early
morning to fairly high rates by about 8 a.m. These rates remain high for
5-7 hours, and then decline to low values in the early evening. The daily
course of transpiration of H. vulgaris is similar to that of evaporation. The
stomata are almost closed at night, opening during the morning; they
stay widely open for some hours and then close. A general parallelism may
be noted between the size of the stomatal aperture and transpiration rate ;
on 16 June 1959 the stomata closed appreciably after i p.m. and there was
a decline in transpiration rate at about this time. On the other hand, on
18 June 1958, the stomata did not close so quickly (at 2 p.m. the mean
aperture was 3-6 ij) and the transpiration rate was maintained at a high
value for longer. The record of water deficit indicates that the leaves are
turgid in the early morning, but by midday may develop a deficit of 12%
or more. This deficit is, however, to a large extent restored even by dusk.

General confirmation of these findings is given by a number of other
experiments. The results of one of them (on 21 June i960) are shown in
Fig. 6. In this investigation the stomata opened in the morning and were of
high aperture for much of the day. Typical trends in the starch content of
the guard cells were observed; starch decreased during the phase of
stomatal opening, was present in only small amounts when the stomata

WATER RELATIONS OF SAND-DUNE PLANTS

181

were wide open and. increased when the stomata were closing, there being
a negative correlation between starch content and pore width (cf Yemm
and Willis, 1954); similar observations were made on Senecio jacobaea and
Cynoglossum officinale. The changes in transpiration rate are clearly similar
to those of the evaporation rate, the relative transpiration (transpiration
rate/evaporation rate calculated on an area basis) being fairly constant, and

a3

11 Ip.m. 3

G.M.T.

Fig. 5. Diurnal changes in transpiration rate, stomatal aperture and water deficit in
Hydrocotyk vulgaris. Results obtained on 18 June 1958 (solid circles) and on 16 June
1959 (open circles) are shown. Values for stomatal aperture are given for 16 June

1959 only (A A); records of temperature, relative humidity and light intensity

for this date are plotted in Fig. 3.

declining only a httle towards the end of the day. In another experiment,
extending from 10 a.m. to 5 p.m. on 15 June 1959, there was also a marked
parallehsm of the course of transpiration and of evaporation, the relative
transpiration varying only sHghtly ; it tended to fall from an initial value
of 60% to 50% by the end of the investigation.

Some estimates of 'cuticular' transpiration gave values as high as i-8
mg/g/min (about 10% of the total transpiration) under conditions of high
evaporation.

l82

A.J. WILLIS AND R. L.JEFFERIES

9 11 1pr

G.M.T.

Fig. 6. Transpiration rate and stoniatal behaviour o£ Hyclrocotylc vulgaris in relation to
evaporation rate. The experiment was carried out on 21 June i960. Upper part of

figure: transpiration rate (• •), evaporation rate (A A); lovv'cr part of

figure: mean stomatal aperture (O O), starch content of guard cells (• •).

Records of temperature, relative humidity and light intensity for this date are shown
in Fig. 4.

(e) Studies on Other Plants

The chief results of investigations on the water relations of various other
sand-dune plants are outlined below.

Plants of the 'slacks' generally have httle or no water deficit. Even on
hot days in summer, deficits exceeding 10% are unusual for the majority
of the species. For example, low deficits are normally found in the leaves
of plants of such different growth form as Epipactis pahistris (L.) Crantz,
Scirptis holoschoemis L. and Salix atrocinerea Brot. On the other hand, some
plants characteristic of low-lying habitats on the dunes such as Orchis
praetermissa Druce and Filipendula uhnaria (L.) Maxim, have been known on
some occasions to develop deficits of the order of 10% and 1 5 % respectively.

On the dry dune slopes considerable water deficits are by no means
uncommon; under extreme conditions leaves may wilt on the plants here.

WATER RELATIONS OF SAND-DUNE PLANTS

183

Deficits of some 10% or more have been recorded in, for example, Lycopsis
arvensis L., Potentilla anserina L. and Ammophila arenaria (L.) Link. On the
other hand the leaves oiCarex arenaria L. from dune slopes do not usually
show very high deficits; an average figure for midday in June is 5%.

Transpiration rates greater than 12 mg/g/min have been observed in
Potentilla anserina and Filipendula ulmaria, with 'cuticular' rates of about 10%
of these values. Losses from, for example, Viola hirta L. and Carex arenaria
(midday values of c. 5 mg/g/min) are, however, somewhat lower; several
experiments indicate that in C. arenaria 'cuticular' transpiration may be
more than 10% of the total. Low transpiration rates have also been found in

Fig. 7. Changes in transpiration rate of Ammophila arenaria. Transpiration rates are

plotted on a weight (• •) and an area basis (0---0); rates of evaporation

are also shown (A A). The results were obtained on 24 June i960.

Salix atrocinerea (3-7 mg/g/min during the middle of the day). In Ammophila
arenaria rates of transpiration expressed on a weight basis are low, as shown
in Fig. 7. The leaves of marram have a high proportion of dry weight to
fresh weight; however, the trends of transpiration are similar when the
rates are expressed on an area basis. In this experiment inrolling of the leaf
was noticeable from 9 a.m. onwards; it is of interest in this connection that
although rates of evaporation increased substantially after 9 a.m. there was
no corresponding increase in transpiration rate (see Fig. 7).

DISCUSSION
In spite of the difficulties involved in weighing leaves under the natural
conditions of plant habitats, and in calculating transpiration rates from
13

i84 A.J. WILLIS AND R.L.JEFFERIES

decline curves, the results of the present study appear to give a fairly good
indication of the daily march of transpiration in a number of sand-dune
plants. However, a full analysis and interpretation of the course of trans-
piration is difficult in view of the many varying physical factors involved
and of changes in certain features (especially stomatal apertures and leaf
water content) of the plants themselves. When rates of transpiration are
compared it must be reahsed that here the rates are expressed on a weight
and not an area basis; as discussed by Kramer (1959), the relative rates of
different species may be quite different when expressed on a different basis.
However, many of the plants of this investigation have somewhat similar
surface/ weight ratios.

Under conditions of high evaporation in summer, plants of the dune
slopes and of the low-lying 'slacks' often show high transpiration rates
(15-20 mg/g/min). In Senecio jacobaea, for example, the water content of
the leaf may be completely replaced in 45 minutes. These rates are con-
siderably greater than the maximum rates obtained by Hygen (1953) under
standard conditions, but fairly similar to those found by Bosian (1933-34)
whose methods of investigation were in many respects Hke those employed
in the present study, transpiration being estimated from quick weighings
of cut shoots. For example, Bosian (1933-34) records rates of about 15
mg/g/hr or more for the 'xerothermic' species Artemisia campestris, Teucrium
chamaedrys and Helianthemum chamaecistus in summer (late May) on the
Kaiserstuhl near Freiburg. However, the highest rates of transpiration
recorded on Braunton Burrows are considerably lower than some of the
highest reported, under summer conditions, by Evenari and Richter (1937)
for plants in the Wddemess of Judaea, and by Oppenheimer (1951) for
plants of other hot, semi-arid countries.

It seems likely that the transpiration rates reported in the present study
may provide a better indication of the rates of the plants of the dune
slopes with regard to their own microcHmate than of the plants of the
'slacks'. This is because the detached leaves o£ Senecio jacobaea are, between
weighings, supported on the balance in conditions similar to those normally
experienced by the leaves on the plants, whereas the low-growing leaves
of Hydrocotyle vulgaris are removed from their microclimate of rather
moist, still air of the floor of 'slacks' to somewhat drier conditions for
weighing. The rates given for H. vulgaris may, therefore, tend to be too
high. These difficulties do not, however, obscure the important differences
in the course of transpiration of the plants of the dune slopes and of the
'slacks'. As shown for Senecio jacobaea and Cynoglossum officinale, the trans-
piration rate reaches a peak in the morning, and although the rate of

WATER RELATIONS OF SAND-DUNE PLANTS 185

evaporation may increase later in the day there is no corresponding
increase in transpiration but usually a decline. This behaviour seems to be
representative of many of the plants of the dry slopes. On the other hand,
in plants of the 'slacks' such as Hydrocotyle vulgaris, there is frequently a
fairly high correlation of transpiration rate and evaporation rate through-
out the day, relative transpiration being rather high and varying only
httle. A similar contrast in the daily course of transpiration, related to
differences of water supply, was noted by Bosian (1933-34).

In stomatal behaviour, most of the sand-dune plants investigated seem
to fall into the alfalfa type recognised by Loftfield (1921), the stomata
opening during the morning and closing at night. Under conditions of
high evaporation, and of water stress, early closure may, however, set in,
as observed for example in Senecio jacobaea and Cynoglossum officinale.
Midday closure of stomata has often been attributed to water stress (Loft-
field, 1921; Sayre, 1926), although Nutman (1937) has given evidence
that in Coffea arabica (a plant of shade) this closure is related to high light
intensity. More recently Heath and his collaborators (cf Heath, 1959) have
interpreted midday closure in onion as a high temperature effect, operating
through an increase in carbon dioxide in the intercellular spaces of the leaf
In the present studies midday closure has often been found to precede the
highest temperatures and hght intensities, and most frequently is correlated
with a high water deficit. Although no decisive information has been gained,
it seems probable that the early stomatal closure of the plants of the dune
slopes is largely attributable to water stress ; usually there is no re-opening
of the stomata of these plants until the following day although during the
afternoon hght intensity and temperature normally decrease. It is of
interest that on a few occasions at about or just after midday considerable
variabihty in stomatal behaviour from leaf to leaf has been observed; at
this time the stomata may well be in a very sensitive state, the dehcate
balance of turgor between the guard cells and other cells of the leaf being
easily disturbed.

In many of the records there is a general parallelism of transpiration rate
and size of stomatal aperture. This is suggestive that transpiration rates are
influenced by the extent of stomatal opening over a wide range, as indicated
by the experimental studies of Milthorpe and Spencer (1957). Stalfelt (1932)
also showed that under conditions of high evaporation, especially in moving
air, stomata influence transpiration rate up to the widest apertures obtained.
Stomatal regulation of transpiration losses seen in the present studies in
plants of the dry dune slopes is doubtless of considerable ecological signifi-
cance. The diminished rate of transpiration after midday, associated with a

i86 A.J. WILLIS AND R. L.JEFFERIES

reduction of pore size, is a feature characteristic of these but not of 'slack'
plants, in which the transpiration losses and the stoniatal apertures are more
uniform for much of the day. Survival of plants on the dune slopes may in
part depend on efficient regulation of transpiration under desiccating
conditions, especially in plants where losses may potentially be very
considerable. In some plants, for example Carex arenaria, on the other
hand losses may never be very great, whatever the conditions of evapora-
tion. Sometimes special features, such as the inrolling of the leaves of
marram, may to some extent regulate transpiration losses.

In plants of the dune slopes complete stomatal closure leads to con-
siderably diminished transpiration losses. Estimates of 'cuticular' transpira-
tion during conditions of fairly rapid evaporation usually range between
0-6-0-9 mg/g/min for plants such as Senecio jacohaea and Cynoglossiim
officinale. These represent rates of less than io% of the total transpiration.
Similar reductions of transpiration losses by stomatal closure were recorded
by Hygen (1953) for plants of dry situations in Central Norway. On the
other hand, he showed that for mesophytic species 'cuticular' losses were in
general between 10-20% of the total; corresponding values were observed
in the present study for a number of plants of the 'slacks'.

Ecological characterisation of plants by means of transpiration rates
derived from decline curves has been attempted by Hygen (195 1, 1953).
who indicated that the 'standard product' {Eg.Ec, where Eg is the transpira-
tion rate under standard conditions in water-saturated leaves with stomata
open, andEc with stomata closed) may be used as an index of xerophytism.
He demonstrated the usefulness of this parameter with studies on species of
Vaccinium, the xerophytic V. vitis-idaea having the lowest values. In the
present investigations, calculation of the 'standard product' under compar-
able conditions of high evaporation for Senecio jacohaea and Cynoglossum
officinale gave values of about 14 in both of these plants, whereas for
Hydrocotyle vulgaris it was almost double this (about 27). If (as other observa-
tions of the present study suggest) the results for these species may be taken
as representative, values of the 'standard product' appear to be a useful
means of characterising the plants of the dry dune pasture and of the
'slacks' in terms of their transpiration rates, the more xerophytic nature
of the plants of the dry dune slopes being indicated on a quantitative basis.

As might be expected, water deficits in plants of the dry dunes are often
large, and although this deficit is frequently to some extent reduced over-
night, full turgidity may not be regained by the next morning. In a period
of drought, there may be, as discussed by Slatyer (1957). a progressive
increase from day to day in total soil moisture stress, and an associated

WATER RELATIONS OF SAND-DUNE PLANTS 187

increased water deficit. Under conditions when the sand is of low moisture
content, deficits of more than 20% have been observed during the day in
some plants, with values of the order of 10% at sunrise. The studies of
Rutter and Sands (1958) and of Sands and Rutter (1958) with Pinus sylvestris
are of interest in this connection, as they give evidence that when deficits
of 17% or more develop in this plant the soil moisture has probably been
reduced to the permanent wilting point. Species differ in their capacity
to obtain water from the soil, but near wilting conditions are clearly often
experienced by plants on the dry dunes. On the other hand, in the 'slacks'
the plants are rarely under prolonged water stress and deficits developed
during the day are quickly restored at night.

Although the leaves of plants of the dry dunes may have considerable
water deficits at dawn, the stomata nevertheless usually open widely during
the morning, as the experiments on Setieciojacobaea indicate. Stalfelt(i929,
1932, 1955) has, however, shown that in Vicia faba and Betida puhescens
'hydroactive closure' of stomata begins at deficits as low as 3 and 4^0
respectively. Similar findings on some other plants (many of them shade
forms) have been reported by Pisek and Winkler (1953), but these workers
(see also Pisek and Berger, 1938) have further demonstrated that in sun-
exposed herbs 'hydroactive closure' does not usually start, under natural
conditions, until deficits reach some 10% or more, particularly when light
intensities are high. The present investigation shows that plants of the dry
dunes fall into the latter category, the success of these plants in a dry
environment doubtless being in part due to this feature of stomatal
behaviour.

The results of the present study indicate some of the important differences
in the water relations of plants of the dune slopes and of the 'slacks'. In
their differing microchmates and under the different conditions of water
availabihty, the plants show contrasted behaviour with respect to trans-
piration rates, stomatal changes and the development of water deficits.
Ecological differences and the distinctive distribution of these plants may
well in part have a physiological basis in terms of water relations; charac-
teristically, plants of the dune slopes have an efficient means of regulation
of transpiration, whereas this is not essential and may be lacking in plants of
the 'slacks'.

ACKNOWLEDGMENTS

We are indebted to past and present members of the Department of
Botany, University of Bristol, for assistance with field work and to
Professor E. W. Yemm for helpful discussion.

i88 A.J. WILLIS AND R. L.JEFFERIES

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WATER RELATIONS OF SAND-DUNE PLANTS 189

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Stocker, O. (1929) Das Wasserdefizit von Gefasspflanzen in verschiedenen Klima-

zonen. Planta, 7, 382-387.
Weatherley, p. E. (1950) Studies in the water relations of the cotton plant. I : The field

measurement of water deficits in leaves. Neiv Phytol. 49, 81-97.
Williams, W.T. (1949) Studies in stomatal behaviour. Ill: The sensitivity of stomata

to mechanical shock. Ann. Bot., Lond., N.S. 13, 309-327.
WaLiAMS, W.T. & Amer, F.A. (1957) Transpiration from wilting leaves. J. exp.

Bot. 8, 1-19.
Willis, A.J., Folkes, B.F., Hope-Simpson, J. F. & Yemm, E.W. (1959) Braunton

Burrows: the dune system and its vegetation. Part II. J. Ecol. 47, 249-288.
Yemm, E.W. & Willis, A. J. (1954) Stomatal movements and changes of carbo-
hydrate in leaves oi Chrysanthemum maximum. New Phytol. 53, 373-396-

WATER RELATIONS OF SOME PSAMMOPHYTES
WITH RESPECT TO THEIR DISTRIBUTION

MiLENA Rychnovska & Jan Kv£t

Geobotanical Laboratory of The Czechoslovak Academy of Sciences

Brno, Czechoslovakia

INTRODUCTION

The psammophytes in Czechoslovakia are grouped in characteristic plant
communities on sandy soil. Although various plants in these communities
require the same substratum, they belong to widely different areas of
distribution. A small strip of land having uniform edaphic and climatic
conditions may thus contain both continental and oceanic species, in
addition to those commonly found in the Northern Hemisphere (i.e.
holarctic plants). For some species Czechoslovakia forms part of the
boundary of their areas of distribution. The sandy region of Southern
Moravia was thus a highly suitable place for the physiological analysis of
some characteristic plants. Such analysis could lead to the causal explanation
of their distribution in Central Europe. Water relations of the psammo-
phytes and their habitats, besides their common specific adaptation to
sandy soils, were considered, after numerous observations, comparisons and
experiments, to be an important factor in the distribution of these plants
in Czechoslovakia. Having all these facts in mind, we performed a field
experiment in which we measured the daily variations in transpiration of
three characteristic psammophytes. A group of plants was artificially
supphed with water and a control group was observed under natural
conditions.

METHODS AND MATERIALS

During three characteristic days in the middle of the growing season
(1-3 June, i960) we observed the transpiration of the following plants:

Corynephorus canescens (L.) P. Beauv.

Festuca dominii Kraj. {Festuca ovina subsp. euovina var. vaginata Hack.

p. p.)
Helichrysum arenarium Moench.

They were growing on sand dunes near the railway station of Straznice-
Privoz in Southern Moravia. The tufts selected for experiment were
approximately of the same age. Some of them were artificially supplied

WATER RELATIONS OF SOME PSAMMOPHYTES 191

with water, up to 8-10% of soil moisture, while others were observed on
arid substratum, with 2-4% of humidity. Every 60 minutes transpiration
measurements were carried out by a rapid weighing followed by a 3 minutes
exposure in the original stand and another weighing. Light showers of
rain occurred between the 41st and 45th hour of the experiment. During
this period the plants, after being picked up, were cursorily dried with
blotting paper and exposed, for 3 minutes, in their original stand under a
small cover of plastic foil. Weighing was performed on a torsion balance,
the scale of which was divided into sections of i mg. Each sample consisted
of a bunch of leaves collected from the same tuft. When the whole tuft
had been used up, samples were taken from the neighbouring tuft. The
change of tuft is always noted in the appended figures. The base of the
bunch of leaves was tied up with a narrow strip of Cellux plastic band, which
greatly facilitated further operations with the grass. Each sample of
Helichrysum arenarium consisted of one terminal portion of the stem
bearing several leaves. Variations in the temperature of air and of soil at
a depth off cm, and air humidity and evaporation from the disc of the Piche
evaporimeter (5-2 cm in diameter, 5 cm above ground) were measured
every hour. At 4-hour intervals a soil sample from the root system of each
plant under study was taken with a narrow probe trowel and its moisture,
expressed as percentage of dry weight, was deterinined. When the field
experiment had been concluded, the plant samples were oven-dried at
I05°C and their water content was established. Transpiration was expressed
in miUigrams water loss per i g of the water content in i minute. The water
content was expressed as percentage of fresh weight.

RESULTS

Variations in the rate of transpiration and the water content in the tissues
of the plants, microclimatic data and soil moisture data, during the period
of 50 hours, are expressed by graphic methods in the appended figures.
Variations in the values measured, irrespective of the changes due to
accidental and unknown factors, were illustrated by a curve plotted from
moving averages of five successive measurements.

As shown in Fig. i , chmatic conditions during the 50 hours of the experi-
ment varied considerably. The weather in the afternoon of the first day,
during the following night and the whole of the second day was of an
anticy clonic type, with a high maximum temperature of 32-4°C during
the dayhght hours and with relatively low night temperature of io-3°C.
During the second night, however, the sky became overcast with clouds

192

MILENA RYCHNOVSKA AND JAN KVET

and the thermometer stood rather high at I4°C. A drizzle began at about
6 o'clock in the morning of the third day and developed to a mild shower
lasting up to 9 o'clock. The air humidity at the beginning of the second
night was also higher than that of the first. The variations in soil tempera-
ture are also in harmony with this pattern, although the extreme values
of soil temperature were recorded 1-2 hours later than those of air.
Evaporation values obtained from the Piche evaporimeter present only a
crude picture of the pattern of atmospheric conditions by which the
evaporation rate is influenced. This rate is higher on the first day than on the

Fig. I. Microclimatic data in the period between i June to 3 June, i960. Upper graph:
Variations in temperature of air 5 cm above ground (full line) and of soil at the depth
of 5 cm (dotted line). Middle graph: Variations in relative air humidity. Lower graph:
Water evaporation from the disc of Piche evaporimeter (cm^). The fifty hours of
experiment are marked on the .v-axis.

second and its values are on the whole inverse to those obtained from the
psychrometer.

The daily variations in transpiration among the control group o£Festuca
dominii (Fig. 2) were in almost perfect harmony with the physical conditions
of evaporation. The noon maximum of the second day was higher than
that of the third day, and the night transpiration of the first night was
higher than that of the following night, in full accordance with lower air
humidity at the beginning of the night. Except for a depression in the first

WATER RELATIONS OF SOME PSAMMOPHYTES

193

5 hours of the experiment, no fundamental change in the pattern of the
curve took place after the plants were supplied with water.

The daily variations in transpiration among the control group of
Corynephorus canescens (Fig. 3) differ from both the microchmatic factors
and the curve of Festuca dominii in the position of the second-day noon
maximum, which is shifted to the morning hours and followed by a
depression of transpiration. The curve of the third day, however, does not
show any depression, and the transpiration values are even somewhat

55

%

10
5

IS

2A

12

18

2A

12

\.

"1-

FiG. 2. Water relations of Festuca dominii during the three days of experiment. Upper
graph: Daily variations of transpiration. Water loss is expressed in parts per thousand,
i.e. in mg per i g of water content of the leaves during i niin. Middle graph: Water
content of the leaves (as percentage of fresh v^eight). Lower graph: Water content of
the rhizosphere of grass tufts (as percentage of dry weight). The 50 hours of experiment
are marked on the x-axis. The full Une and dots belong to plants supphed with water.
The dotted hne and crosses belong to the control group (observed under natural
conditions).

higher than those of the preceding day. The night minima do not fall to
zero and are approximately equal. The pattern of the curve is, however,
somewhat different for plants supphed with water. The noon maximum
of the second day is higher, shifting towards the midday hours, and
markedly exceeds the noon transpiration of the third day. Compared with
that of the control group, the morning increase in the third-day rate of

194

MILENA RYCHNOVSKA AND JAN KVET

20

15'

10

5'

70'
65
60

55
7o

10
5

IB

2A

12

18

24

12

Fig. 3. Water relations o{ Corynephorus canescens during the three days of experiment.

Explanation as for Fig. 2.

30

25

20

15

10

5

0
%

80
75
70

65
%

15

\ X / /

I

It

•

X >

^

/

* /

t

>

X

X

X

X

<^ »•■■»-<

•

1i

i 2-^ 6

1

12 18

24

6

12

in

J L

1 r—

1

5

1 1

0

Fig. 4. Water relations o( Hclichrysum arenarium during the three days of experiment.

Explanation as for Fig. 2.

WATER RELATIONS OF SOME PSAMMOPHYTES 195

transpiration is several hours late. The rate of transpiration during the
second night somewhat exceeds that of the first night.

The curve of the third plant under study -HelichrYsum arenarium (Fig. 4) -
reveals two distinct maxima during the dayhght hours and a depression at
noon. The rate of transpiration fell to zero during the first night while in
the second night noticeable evaporation of water was observed. The
intensity of transpiration among plants supplied with water was enhanced,
but the pattern of the curve is similar.

DISCUSSION

A comparison between the two transpiration curves oiFestuca dominii and
the climatic factors points to the unmistakable fact that this plant has lost .
its abihty actively to control its transpiration. As reflected in the morpho-
logical and physiological properties of the plant, its water turnover is
adapted to permanent water deficiency. The rate of transpiration is hmited,
that is to say, under favourable conditions it reaches definite maximum
values and is not able to surpass them. The transpiration curve runs parallel
to that of evaporation. This is exemphfied by the two curves in Fig. 2,
showing the same pattern of transpiration, whether the plants were suppHed
with water or not. No increase in the rate of transpiration was observed
after the plants were supphed with water. The rate of transpiration during
the night was also in agreement with the physical conditions, especially
with air humidity, during our experiment. Dry periods more pronounced
than those recorded during our experiment would probably result in
perceptibly reduced loss of water. Corynephoms canescens, on the other
hand, is far more active in controlling its rate of transpiration. Although
its transpiratory system does not provide for extensive variations, a
depression in the rate of transpiration takes place during hot midday hours
of a dry 'continental' day, when the plant suffers from water deficiency.
No depression, however, occurs during a wet 'oceanic' day. If the rhizo-
sphere of the plant holds enough water a definite increase in the rate of
transpiration takes place and no noon depression can be observed. During
the night hours, the water loss of plants growing on a dry substratum is
probably hmited to cuticular transpiration; if, however, the plant is
supphed with a sufficient amount of water, the vital factor of transpiration,
which depends on temperature and not on relative air humidity, plays a
more active role than the physical factor. The second night was warmer
than the first, and thus the rate of transpiration of the plant was somewhat
higher.

196 MILENARYCHNOVSKA ANDJANKVET

Helichrysum arenarintn proved to be the most adaptable plant of the
three. As shown by the noon depression, the plant regulates its water
turnover by stomatal action. Its night transpiration falls to zero, which is
apparently due to the closing of the stomata. When the plant is supplied
with water, its rate of transpiration is enhanced and the noon depression
is not so clearly pronounced. The rate of transpiration during the night is
probably also controlled by vital (rather than physical) factors. The plant,
enveloped in a warm environment both above and below ground, loses
water by evaporation, even if the atmosphere is saturated with water
vapour to a high degree. We did not take note of the state of the stomata
during our experiment. The stomata of xerophilous grasses are mostly
found on the upper, i.e. inner, side of the tube-shaped leaves, and thus are
difficult to observe by ordinary methods. This observation was not con-
sidered necessary for our study of the character of transpiration.

All these facts are in agreement with phy togeographical conditions which
have impressed their mark on the plants during their development.
Festiica dominii, a 'continental' plant, one of the group of xerophytic
Festucae inhabiting the deserts and semi-deserts of Central Asia, has become
adapted to permanent drought. As permanent closing of the stomata
would make photosynthesis impossible, the plant appears to restrict loss of
water by substantially diminishing the rate of transpiration while its
stomata remain half open. Its rate of transpiration is thus low and depends
on physical factors. Stocker, (1956), reports similar conditions among desert
plants. As the transpiratory system of Festiica dominii adapted to arid
situations does not provide for an enhanced rate of transpiration, no
increase in the rate of transpiration occurs after supplying the plant with
water. Water-retention of the soil under the dense tufts of Festiica dominii is
also perceptibly higher than under those of Corynephorus canescens, which
points to the highly economical water turnover of the former plant in dry
periods. I have reported in another paper(Rychnovska, 1961) that supplying
an experimental tuft with water does not enhance the rate of sugar produc-
tion. That again fully conforms with our hypothesis. Although the above-
mentioned water relations are highly beneficial in arid situations, they
constitute an obstacle for the vital activities of the plant in more favourable
circumstances. Thus we cannot be surprised that-as the continental
chmate gives way to the cHmate of the oceanic type in Central Europe and
competition with plants of more pronounced vital activities becomes more
intensified-Fe5f;/cfl dominii appears more sporadically. Its area of distribu-
tion does not extend further westward into regions characterised by still
fewer climatic extremities.

WATER RELATIONS OF SOME PSAMMOPHYTES 197

Corynephonis canescens, on the other hand, is an 'atlantic' plant adapted
to the water conditions of maritime dunes. Long periods of drought are
quite unknown there, and thus no adaptation to permanent drought could
develop among the plants in that area. Although the anatomy of Coryne-
phonis canescens has adapted itself to sandy soils, the plant has not lost its
ability actively to regulate its water turnover. In the more arid conditions
of Central Europe it usually restricts its water output, as shown by the
depression in the midday and afternoon hours. This controlling of the loss
of water is probably due to the closing of the stomata. If it is so, it must
result in reduced gas exchange and dimnished rate of photosynthesis. That
would constitute a serious drawback for the plant during prolonged
periods of drought, since it would reduce its vital activity, and the plant
would not be able to survive in competition with others. Indeed its area of
distribution in Central and Eastern Europe does not extend further into the
interior of the continent. The daily variations in transpiration of plants
supphed with water, without any noon depression, and the enhanced rate
of transpiration of the control samples during a rainy day conclusively
indicate that, only when sufficiently supphed with water, Corynephorus
canescens is able to retain its full vital activity. Direct evidence for the
diminished rate of photosynthesis of plants growing on dry soils and for
the enhanced rate of sugar production, after the plants were supphed with
water, was submitted in another paper (Rychnovska, 1961).

From the phytogeographical point of view, Helichrysum arenarium
occupied an intermediate position between the two above-mentioned
species. It is a continental boreomeridional European plant whose area of
distribution extends westward up to Belgium and the Netherlands and
northward to Denmark and the southern part of Sweden (Meusel, 1943).
It is highly probable that the water relations of this plant are adaptive to a
considerable degree. As shown by its transpiration curve, the intensity of
transpiration is relatively high and actively controlled. During the hot
midday hours the rate of transpiration is temporarily diminished, but in
the early afternoon it again reaches a high level. As the stomata were
apparently closed during the first night, the rate of transpiration fell to
zero in both groups. The second night, characterised by higher tempera-
ture, provided better conditions for active transpiration, although the
atmosphere was saturated with water vapour to a considerable degree. The
rate of transpiration of the samples supplied with water is higher than that
of the control group, even though the noon depression is also present. The
plant is able to endure prolonged periods of drought, because its rate of
photosynthesis is comparatively low and not immediately affected by

198 MILENARYCHNOVSKA ANDJANKVET

variations of humidity (Rychnovska, 1961). The water turnover is intensi-
fied when the soil contains a sufficient amount of water. An interesting
fact should, however, be noted in this connection. If the plant is supplied
with a large amount of water, the water content of its tissues is smaller
than that in the control group of plants. The question here is, whether the
regulating mechanism does not partially fail in plants adapted to dry
habitats when supphed with an excessive amount of water and whether a
paradoxical situation of disproportionate water loss does not arise in this
case. All this wiU have to be verified by further research.

The present paper lends further support to the idea that many phyto-
geographical problems can be solved on the basis of physiological and
ecological analysis, and that, although the ecological factors are of only
local apphcabihty and complex in character and although the plant species
have a wide range of adaptabihty (Meusel, 1943), it is possible to ascertain
the causal fundamentals responsible for the distribution of the various
species of plants. On the other hand, it would be a mistake to limit the
explanation of the causes of plant distribution to one factor only ; it is
necessary to investigate the selected species of plants in relation to all the
important factors (Boy sen-Jensen, 1949). In our case, however, the other
factors have already been analysed and the results reported in another
paper of mine already quoted. We may thus be allowed to conclude that,
with respect to specific edaphic conditions, it is the water relations of these
three plants, those water relations which resulted from the plants' adapta-
tion to the climatic conditions in the centre of their area of distribution
and which became established during the phylogenesis of these plants,
that on the boundary of their area of distribution constitute the decisive
phytogeographical factor.

REFERENCES

Boysen-Jensen, p. (1949) Causal Plant Geography. Kgl. Danske Videnskabernes

Selskab, Biologiske Neddelelser , B. XXI, Nr. 3. Kobenhavn.
Meusel, H. (1943) Vergleichende Arealkimde. Berlin.
Rychnovska-SoudkovA, M. (1961) Corynephorus cancscens{L.) P. Beauv. Physiologisch-

dkologische Studie einer Pfianzenart. Rozpravy CSAV. 71. Praha.
Stocker, O. (1956) Die Abhangigheit der Transpiration von den Umweltfaktoren.

Handbuch der Pfianzenphysiologie, Bd. III. Berlin.

THE WATER SUPPLY OF DESERT PLANTS

H. Walter
Botanisches Institut, Stuttgart-Hohenheim, W. Germany

By deserts we mean arid regions with a very low and unreliable rainfall.
It is generally supposed that perennial plants in such regions suffer from a
lack of water and need special physiological adaptations such as a physio-
logical drought resistance, low transpiration rate, high osmotic pressure,
etc. Often it is difficult to understand how perennial plants can thrive in a
desert with perhaps only 25 mm of rainfall per year, e.g. around Cairo.
But rainfall as such is not the appropriate measure to estimate the water
supply of desert plants, which is considerably better than it appears if we
consider only the rainfall data. Rainfall in mm means the amount in
htres per square metre, therefore it is also necessary to compare it with the
transpiring surface of the plants per square metre. To imderstand properly
the water economy of desert plants, we must keep two facts in mind:

(i) The density of the vegetation decreases in arid countries with the
decreasing rainfall.

(2) In extremely dry countries with a very low vegetative cover

density, the amount of run-off increases and the water is unevenly

distributed in the soil after a rain. The major portion of the soil remains

dry (the water runs off and does not penetrate into the soil) and on a

small part of the area (depressions, runnels, wadis) the water accumulates

and penetrates quite deep into the soil.

Let us consider more thoroughly the first factor. Exact measurements of

the density of plant cover were made in South-West Africa. In this region

the rainfall is nearly nil on the coast and gradually increases from WSW.

to ENE. from 0 to 500 mm. The temperature conditions remain more or

less constant over the entire region (Fig. i) .

For comparative purposes, it is necessary to utilise similar types of
vegetation for which we choose ungrazed grassland. Following the period
of the summer rains, it was relatively easy to determine the production
of dry matter per hectare by weight. The results showed that the dry
matter production increased proportionally with the rainfall (Fig. 2). For
every 100 mm of rainfall per year, the dry weight of grass was 1000 kg/ha

14

200

H.WALTER

or 100 g/m^. If we compare the same vegetative types, we can assume that
the transpiring surface is more or less proportional to the dry weight. That
means: The transpiring surface decreases in proportion to the rainfall, that is, the

100

200 3K i%% I

500

Fig. I. Rainfall map of South-West Africa in mm.

D Sites of samples for determination of the dry weight production in grassland.
• Samples for determination of the nutrition value of grassland plants (from H.
Walter, 1954).

water supply of a unit of transpiring surface is the same under arid or humid
conditions up to a rainfall of 500 mm.

This statement was checked in south-west Austraha in the Eucalyptus-
forest region with a rainfall from 500 mm up to 1 500 mm (Tables i and 2)
(Walter, 1962) :

THE WATER SUPPLY OF DESERT PLANTS

Table i
Virgin Eucalyptus forest

201

Rainfall

Amount of litter

Leaf litter surface

^

X

A

mm

Relative

kg/ha

Relative

m2/m2

1
Relative

1530

100

2400

100

I-I4

100

810

53

1280

53

0-57

50

750

49

1500

62

0-66

58

Table 2

Young growth o£ Eucalyptus forests

RainfaU

Amount of litter

Leaf litter surface

A

A

>.

r
mm

Relative

kg/ha

Relative

m^m^

Relative

1330

100

2740

100

1-30

100

1290

97

2040

75

i-os

81

560

42

1290

47

0-39

30

The data were kindly provided by Mr. Loneragan of the Forest Depart-
ment. The measurements were made in the Eucalyptus astritigens, E.
redunca, E. maroitiata and E. diversicolor forest zones. In this winter rain
region, the same rules seem to hold : The amount of the surface of the
transpiring leaves (equal to the average leaf litter) decreases proportionally
with the rainfall, therefore the water supply does not change essentially.
There are some deviations from the given proportions, but this can be
expected from a relatively short average of 3-6 years.

The decrease in rainfall and consequent reduction in plant cover density
in arid regions creates a greater distance between individual plants and
causes the water penetration into the soil to become shallower. Therefore
the root systems of plants in arid regions are shallower but the root itself
has a greater horizontal growth.

The shoot/root growth ratio also decreases with the rainfall. Some
physiological experiments allow the supposition, that the growth of the
shoot is more reduced than the growth of the roots, as the water supply of
the plants becomes more critical. Let us consider the growth of pea seedlings
in sugar solutions of different concentrations and in an atmosphere with a
relative humidity equal to the corresponding sugar solution. The osmotic

202

H.WALTER

pressure of the cell-sap and therefore also the hydrature of the protoplasm,
is in this case nearly equal to the osmotic pressure of the sugar solution.
The results show that with increasing osmotic pressure from o to 30 atm
(i.e. decreasing hydrature from 100-98%), the growth of the shoot decreases
rapidly reaching zero at about 20 atm, but on the contrary to this, the
growth of the root first increases three times, reaching a maximum at 7
atm( = 99-5% hy) and only then decreases . It was still measurable however,
at 30 atm (Fig. 3). Kausch (1955) mentioned that the same is true if the

eooo
Kglha

iOOO

mo

JOM

2000

1000

0/

0/
/o

'

/o

)

G

/

J30

m

200

JSO

■wo

500 mm 600

Fig. 2. The productivity of grassland (kg/ha) in relation to the mean yearly rainfall

in mm (from H. Walter, 1954).

soil moisture decreases. The behaviour of side roots is different and similar
to that of the shoot.

Under humid conditions the osmotic pressure is low, therefore we have
to expect a vigorous shoot and side root growth, but slow growth of the
main root. With increasing aridity the osmotic pressure increases, the
growth of the shoot is retarded, also that of side roots, but elongation oi
main root is increased. This is in accordance with the facts observed in the
field : the shoot/root ratio of plants in arid regions decreases with the
rainfall. Simonis (1936) grew TrifoUum incarnatmn in moist soil (80% of

THE WATER SUPPLY OF DESERT PLANTS

lOOi

203

Osmotic pressure

30 Atm.

98%

Relative water
vapour pressunz

100-"

Fig. 3. Growth of shoots and roots (pea seedlings) in relation to the osmotic pressure
or relative water vapour pressure (from H. Walter).

the water capacity) and in dry soil (40% of the water capacity). During the
first week the total increase in dry weight of the plants was the same in
both cases (16 g), although the ratio of the shoots to the roots decreased
appreciably in the dry soil (Table 3).

Table 3

Trifolium ituarnatum. Percentage of total dry weight of plants in

moist and dry soil

Plants in

I. Shoots 2. Roots

Ratio 1 : 2

Moist soil
Dry soil

66-0%
41-4%

34-0%
58-6%

1-94
0-71

304 H.WALTER

In this case the decreasing shoot/root ratio is attributed to a functional
adaptation. Due to the severe competition in arid regions, we find only
species with a fast-growing, genetically fixed root system.

In an area where the rainfall becomes less than lOO mm, the second
factor, the run-off, is more important. This is primarily due to the
low density of the vegetation, and consequently even in nearly flat deserts
the run-off is extremely high. The water penetrates into the soil more
readily in sandy runnels or depressions moistening the soil to a greater
depth. Following the rain the upper layer of the soil dries out, although in
the deeper layers the moisture may be conserved for years.

The type of vegetation also changes under these conditions, The 'diffuse
type, that is a vegetation more or less evenly distributed, gives way to a
'restricted type', a vegetation confined only to rather restricted areas
(depressions, runnels, wadis). In this type of area, the water supply is
usually adequate.

If the run-off in a region with 25 mm precipitation is 80%, and the area
in which the water accumulates constitutes 4% of the total area, that area
will receive an amount of water corresponding to a rainfall of approximately
500 mm. This is an appreciable amount of moisture in an arid region.

The root systems of plants in this type of situation are quite deep and
correspond to the deeper water penetration. Recently Kausch (i960)
investigated the root systems of desert plants around Cairo and recorded
the following root penetration depths :

Pituraiithus tortuosus 5 00 m

Mohkia callosa 4-00 m

Farsetia aegyptiaca 3 • 3 o m

Zilla spinosa 2-80 m

Convolvulus lanatus 2-50 m

Euphorbia cornuta 2-30 m

Centaurea aegyptiaca 2-10 m

Fagonia arahica i-20 m

These observations show that the water supply of the plants even under
extreme arid conditions is quite adequate. Therefore it is not surprising
that the osmotic pressure of the cell-sap of desert plants is not much higher
than of plants in humid regions and also the transpiration per unit leaf
surface may be quite high.

The problem of halophytes is a special one. For them, the water economy
is usually not of primary importance but rather the salt economy.

The adaptation of the perennial desert plants seems to be chiefly a

THE WATER SUPPLY OF DESERT PLANTS 205

morphological one rather than a physiological one. The chief adaptation
is the reduction of the transpiring surface, the better development of the
main root system, and the ability to reduce water loss during prolonged
drought periods to nearly nil.

A special group are the succulents in the arid parts of North and South
America and of South Africa. In the Sahara and in the arid parts of Asia
they do not play a role and in the arid parts of Austraha they are absent.*
Most of the succulents prefer an arid climate with two rainy seasons in
order to replenish their water storage tissues.

During the dry seasons the succulents can remain without water uptake.
Therefore their root system is weakly developed and shallow. The water
economy of succulent plants is quite different from that of other xerophytes
and is not considered here.

The annual or ephemeral plants and also the geophytes in arid countries
grow during the short periods when water is in abundance. Their water
supply is guaranteed and therefore does not present any problenas for them.

REFERENCES

Kausch, W. (1955) Saugkraft und Wassemachleitung ini Boden als physiologische

Faktoren. Planta, 45, 217-263.
Kausch, W. (i960) Unesco Document NS-914-58.
SiMONis, W.(i936) Untersuchungen iiber die Abhangigkeit des osmotischeu Wertes

vom Bodenwassergehalt bei Pflanzen verschiedener okologischer Gruppeu. jb.

wiss. Bot. 83, 191-239.
Waltek, H. (1924) Plasmaquellung und Wachstum. Z. Bot. 16, 353-417-
Walter, H. (1954) Gmiuilagen dcr Weidewirtschaft in Siidwestafrika. E. Ulmer, Stuttgart.
Walter, H. (i960) Standortslchre {Einf. in die Phytologie, Bd. Ill, i) 2. Aufl., p. 265 ff.

E. Ulmer, Stuttgart.
Walter, H.(i962) Die Vegetation derErde, Bd. L
Walter, H. (1962) Grtmdlagen des Pflanzenlebens{Einfiihmng in die Phytologie, Bd. I) 4.

Aufl., p. 344 flf. E. Ulmer, Stuttgart.

* One exception is the rather rare species Sarcostemma australis.

SEASONAL DIMORPHISM OF DESERT AND

MEDITERRANEAN CHAMAEPHYTES AND ITS

SIGNIFICANCE AS A FACTOR IN THEIR WATER

ECONOMY

G. Orshan
The Hebrew University, Jerusalem

INTRODUCTION

Although chamaephytes as a life form characterise high latitudes and high
altitudes where temperature is the limiting factor, they also play an
important role in steppes and deserts (Raunkiaer, 1934; Cain, 1950). In the
Middle East they are the leading species of both desert and certain Mediter-
ranean plant communities.

Seasonal dimorphism is a most common feature among the chamae-
phytes and is generally associated with a seasonal reduction in their
transpiring body. Most of them show a certain amount of growth and
development throughout the year, in spite of the dry and hot summer, but
this growth yields different kinds of leaves and branches in different seasons
which are in turn periodically shed. At present we know very Httle about
the mechanisms through which environment affects the growth and form
of chamaephytes on the one hand, and the ways through which their
particular form and growth types serve as an adaptation to the environment
on the other. It seems that even the problems have not yet been properly
defmed.

The present paper deals with aspects of the seasonal dimorphism of
chamaephytes. Their phenology and growth habit will be described, and its
effect on the extent of the seasonal reduction in their body accounted for.
In addition, data will be presented showing the annual march of their
transpiration rate. An attempt will then be made to correlate these aspects
and to fmd out what their relative importance is in the water balance of the
chamaephytes.

During the last few decades, the transpiration rates of a considerable
number of chamaephytes has been measured in Isreal, in their natural
habitat, by the cut leaf quick-weighing method (Evenari andRichter, 1937 ;
Orshansky, 1952, 1954; Shmueh, 1948; Zohary and Fahn, 1952; Zohary
and Orshan, 1954, 1956; Zohary, 1955). Recently the annual march of the
weight of the transpiring body of some chamaephytes was determined

SEASONAL DIMORPHISM OF CHAMAEPHYTES 207

quantitatively under natural conditions (Zohary and Orshan, 1954;
Orshansky, 1952; Orshan and Zand, 1961). Ten species have been selected
for the present discussion for which information both about the transpira-
tion rates and about the extent of the seasonal reduction in the plant body is
available and in addition the Hfe cycles of which are known. Six of them
are dominants of desert plant associations while four are leading species of
Mediterranean plant communities.

The measurements were carried out in several stands in two different
locaHties, a desert one nearRevivim in the Northern Negev, where annual
rainfall averages 80 mm, and a Mediterranean one in the vicinity of
Jerusalem where annual rainfall averages 550 mm. The climate in both
locaHties is typical Mediterranean. The rainy season lasts from September
to May while the summer is hot and rainless.

The desert plants which were selected for presentation are: Artemisia
herba alba Asso., and Noea mncronata (Forsk.) Asch. et Schw. which are
leading species of the Artemisietum herbae albae, one of the most wide-
spread Irano-Turanian plant associations in the Middle East (Zohary and
Feinbrunn, 195 1); Haloxylon articnlatum (Cav.) Bge. the leading species of
the Haloxylonetum articulatae plant association dominating the pluviatile
loess plains in the Northern Negev (Zohary and Feinbrunn, 195 1) ; Anabasis
articnlata (Forsk.) Moq., the leading species of the Anabasidetum articulatae
plant association dominating the small, shallow, and dry water courses
cutting the plantless Hamada plains of the Southern Negev (Zohary, 1953) ;
and Zygophylhim dumosum Boiss., the leading species of the Zygophylletum
dumosi which is the plant community occupying the most extreme habitat
within the Saharo-Sindian territory in Israel (Zohary and Orshan, 1954).

The following are the Mediterranean plants presented : Poterium spinosum
L., the leading species of the widespread Poterietum spinosi dwarf shrub
plant community which is one of the first stages in the succession from
abandoned fields; Cistus salvifolius L., one of the leading species of the
Grigue succeeding in many places the Poterietum in the succession; Thymus
capitattis (L.) Lk. et HofFm. which dominates the Thymetum capitati
occupying stands with shallow soil layers both on limestone and on a
sandstone locally called 'Kurkar', and Teucrium polium L. which is an
important component of several dwarf shrub communities (Zohary, 1955).

In addition, data are presented o£ Artemisia monosperma Del. which is a
dominant of the Artemisietum monospermae, the most important plant
community of the sand dunes of the Northern Negev (Zohary and
Feinbrunn, 195 1).

208 G.ORSHAN

THE LIFE CYCLE OF SELECTED CHAMAEPHYTES
Practically all chamaephytes in Israel are seasonally dimorphic but the
seasonal dimorphism is not always achieved in the same way. Two types
of branches may be distinguished in most of them, i.e. dohchoblasts and
brachyblasts, but these terms may be misleading as the same branch may
start growing as a brachyblast, remain short for a considerable time and
later start elongating and turn into a doHchoblast. The elongation generally
takes place in spring which is the main growing season when both tempera-
ture and water supply are optimal. Such a brachyblast may be called a
temporary brachyblast. In other plants the dohchoblasts and the brachy-
blasts are not merely different stages of development of the same branch
but are developed from different buds and a brachyblast never turns into a
doHchoblast. This type of brachyblast may be called a permanent brachy-
blast. Moreover, the brachyblasts may also be classified according to their
degree of elongation, absolute brachyblasts which do not elongate at all
and resemble small rosettes, and partial brachyblasts which show a
certain although hmited degree of elongation.

The dohchoblasts and brachyblasts are generally associated with two
leaf types, i.e. larger and more differentiated winter and spring leaves, and
smaller summer leaves. The seasonal dimorphism is attained by the
shedding and growth of the different types of branches and leaves at
different seasons.

A few types of chamaephytes differing in their types of branches and the
sequence of their development will now be discussed.

(a) Thymus capitatus. The dohchoblasts start elongating in January from
temporary absolute brachyblasts developed in the preceding spring. In
February they attain a length of 1-2 cm. During March and April, their
growth rate increases and branching takes place in their upper portions.
At the apex of these branches the inflorescences are developed during June
and July and the plant sets fruit in September. These dohchoblasts bear
larger leaves which are gradually shed in an acropetal direction, from the
middle of May until August. From the buds at the axils of these leaves
brachyblasts bearing small scale-hke summer leaves are developed. They
remain short during the whole summer and only some of them, mainly
those on the lower portion of the dohchoblasts, start to elongate in winter
turning into the dohchoblasts of the next season. The others which do not
elongate, subsequently die and fall off. The upper portions of the doHcho-
blast die back and are also shed (Fig. i).

(b) Teucrium polinm. The hfe cycle of this plant resembles that of Thymus
but its brachyblasts are partial brachyblasts elongating slowly during the

SEASONAL DIMORPHISM OF CHAMAEPHYTES

209

IP

t

, "A

r.

IV V VI Vil VIII IX

Fig. I. Life cycle of Thymus capitatus.

(a) The lower part of a dolichoblast developed during the previous spring bearing
small absolute brachyblasts (4).

(b) One of the brachyblasts of the same branch which has started elongating,
(i) Summer leaves, (2) winter leaves.

(c) The same elongating brachyblast reaching its maximal height. (3) Tlie
inflorescence.

(d) The same branch; the winter leaves already shed and the new brachyblasts
developed at their axils (4) which form the whole green cover of the plant.

H leaves absent
leaves developing
leaves persisting
leaves being shed

Upper row -winter leaves
Lower row -summer leaves

whole summer. The plant flowers in June and sets fruit in August (Fig. 2).
(c) Poterium spinosnm. While the inflorescences of Thymus and Teucrium
are developed on the dolichoblasts those o( Poterium are developed on the
brachyblasts which are absolute and permanent. The dohchoblasts generally
are developed from renewal buds and start growing late in February. Their
growth rate is very rapid during March and April and they may attain
their maximal height at the beginning of May. Branching takes place on
their upper portion and the apices of the small branches taper into spines.
The larger spring leaves of these dohchoblasts are gradually shed in an
acropetal direction from the middle of May to the end of July. In the axils
of these leaves small brachyblasts are formed druing April. They look like
half open buds and bear small summer leaves. During the summer the older
leaves of these brachyblasts are also gradually shed while new ones develop
at their apices. This process goes on during the autumn but the new leaves
which are formed from October onwards are larger and resemble the

210

G. ORSHAN

X XI XII I

I III IV V VI Vll VIII X

Fig. 2. Life cycle of Teucriuni polium.

(a) The lower part of a dolichoblast developed during the previous spring bearing
small partial brachyblasts (i).

(b & c) One of the brachyblasts of the same branch turning into a new dolichoblast
bearing winter leaves (2).

(d) The same dolichoblast reaching its maximal height. The older winter leaves
have already been shed and new brachyblasts (4) have developed in their axils.
(3) The inflorescence.

(e) All the winter leaves already shed. The upper brachyblasts slowly elongating (5).

H leaves absent
leaves developing
^ leaves persisting
[y leaves being shed

Upper row -winter leaves
Lower row -summer leaves

leaves of the dolichoblasts, and the brachyblasts then look like small open
rosettes. Meanwhile practically all the summer leaves are shed. In February,
the inflorescences are developed at the apices of these brachyblasts. By that
time the new^ dohchoblasts start developing either from renewal buds
formed on older branches or as axiUary buds on the brachyblasts. The
autumn leaves of the brachyblasts are gradually shed in March and the
beginning of April. The upper portions of the dohchoblasts die back during
the end of their first summer (Fig. 3).

(d) Artemisia herha alba. The dohchoblasts start elongating in the autumn
(October to December) from temporary brachyblasts or from renewal
buds. Their growth rate is slow in the early winter but increases rapidly
towards the spring .During April and May these stems branch once or twice
in their upper part and the inflorescence develop at their tops in September
and October. The plant sets fruit druing November and December.

There is a gradual change in leaf size and form from the base to the tops

SEASONAL DIMORPHISM OF CHAMAEPHYTES

211

H

Fig. 3. Life cycle ofPoterium spinosum.

(a) A small absolute brachyblast (i) on the lower part of a dolichoblast developed
during the previous spring.

(b) New winter leaves are formed on the same brachyblast which resembles a
small rosette (5). The renewal buds (3) appear on older branches.

(c) The inflorescence (3) appears at the apex of the brachyblast. The young
dolichoblasts (6) emerge from the renewal buds.

(d) The new dohchoblasts bearing spring leaves (4) reach their maximal height.
The autuimi and winter leaves already shed.

(e) The spring leaves of the same doHchoblasts already shed. New brachyblasts (7)
bearing summer leaves developed in their axils.

leaves absent
leaves developing
leaves persisting
leaves being shed

Upper row -autumn and winter leaves
Middle row- spring leaves
Lower row -summer leaves

of these dolichoblasts. The lower leaves are larger with many lobes while
the upper ones are bractlike, simple and linear. Leaf shedding starts in
April from the lower parts of the dohchoblasts and goes on gradually
during the late summer in an acropetal direction until the autunm when
practically no leaves remain on the stems except from a few flower bracts.
During the late summer the axillary buds at the lower part of the
dohchoblasts start developing into tiny rosette-hke brachyblasts. Although
no elongation takes place they do not stop growing, new leaves are formed
at their apex and the older ones dry out and are gradually shed. In the
autumn, part of them starts elongating, yielding the new dohchoblasts,
while the others dry out and drop. The upper portion of the dolichoblasts
die back almost to their base during their second winter.

212 G.ORSHAN

(e) Artemisia monosperma. The life cycle of this plant is similar to that of
A. herha alba with one difference, that doUchoblasts develop not only from
the base of older dohchoblasts, but also from their upper portions.

(f) Noea mucronata. The dohchoblasts start growing from renewal buds
in November. Their growth reaches its maximum rate in spring. These
branches bear larger linear leaves which are gradually shed in an acropetal
direction from the middle of May to the beginning of July. Meanwhile
(from the middle of May to August) thorny brachyblasts develop bearing
scale-hke smaller summer leaves from the axillary buds at the upper part of
these dohchoblasts. The flowers appear on the brachyblasts by September
and the plant sets fruit during October and November.

During the winter and the next summer the upper portions of the
dohchoblasts as well as all the brachyblasts die back while the renewal
buds appear in the autumn on their lower portion or on older stems.

(g) ZygophyUum dumosnm. This plant differs from those already described
in that there is no summer growing season and the two types of branches
develop and grow almost simultaneously. All the leaves are of the same
type.

The renewal buds are developed on the lower parts of the dohchoblasts
immediately after the first effective rains. The brachyblasts develop almost
immediately from the axils of the leaves of the dohchoblasts. The flowers
which appear a short time after the onset of growth are born on the
dohchoblasts. The plant sets its fruit early in summer.

Surface reduction takes place mainly through the shedding of the double
laminae which starts at about May and goes on gradually through the early
summer. During the late summer the succulent petioles alone form the
only leaf cover of the plant. They are also gradually shed with the increase
of water shortage.

(h) Anabasis articulata. This plant is an articulate stem succulent bearing
no leaves. Its dohchoblasts develop in winter after the first rains from renewal
buds situated at the lower part of the plant. They reach their maximal
length (which is generally about 10-20 cm) in March. From March to May
lateral brachyblasts distinguished from the dohchoblasts by their shorter
intemodes develop on them and later in October bear the flowers. The
plant sets fruit in November and December.

Instead of leaf shedding, which is typical of the non-articulate chaema-
phytes, the green cortex oi^ Anabasis starts dying back, becoming yellow in
an acropetal direction from May onwards. Cracks appear in it on stems older
than one year and later it is shed.

Apart from the drying and shedding of the green cortex, the transpiring

SEASONAL DIMORPHISM OF CHAMAEPHYTES

213

body o{ Anabasis is markedly reduced by the shedding of the brachyblasts
and the upper portion of the doHchoblasts.

(i) Hahxylon articulatum. This plant has a Hfe cycle very similar to that of
Anabasis.

EXTENT OF SEASONAL BODY REDUCTION

Measurements of the extent of seasonal body reduction were carried out
in desert and Mediterranean plants through two successive years, 1957 and

X XI XII I II III IV V VI VII VIII IX
1957 1958

Fig. 4. Annual march of dry weight (grams) of the transpiring body of desert plants.
h.m..-Arteniisia monosperina H.a..- Hahxylon articulatum

A.ha. -Artemisia herba alba N.m.-Noea mucronata

A.a. -Anabasis articulata Z,A.- Zygophyllum dumosum

•

1958, differing in their annual rainfall. The values for Re vi vim were 177-5

mm for the winter of 1956-57 and only 32-4 mm for the winter of 1957-58.

The corresponding values for Jerusalem were 621 mm and 384 mm

respectively.

214

G. ORSHAN

Between lOO and 150 plants belonging to each species, as equal as possible
in size, were selected in their natural habitats and marked when the
measurements were started. A sample of 5 plants was randomly removed
from the plot every month. All the green parts, whether they were leaves ,

IV V VI
1958

Fig. 5. Annual march of dry weight (grams) of the transpiring body of Mediterranean

plants.
C.s. - Cistus sabifolius Th.c. - Thymus capitatus

"P. sp. - Poteriu m spinosum T.p.-Teucrium polium

Stems or both, were^oUected from each plant separately and their dry
weight determined in the laboratory.

The annual march of the dry weight of the transpiring body is presented
in Figs. 4 and 5. From these figures, it is evident that all the plants examined
markedly reduce their transpiring body during the summer. The maximum

SEASONALDIMORPHISM OF CHAMAEPHYTES 215

values are attained in March and April at the end of the season of extensive
growth and the minimum values for most of the plants are reached in the
autumn and early winter when a great part of the older summer leaves
have been shed and the new growth of the autumn and winter branches
and leaves after the first rains have only just started.

Table i
Relative seasonal body reduction of desert and Mediterranean chamaephytes

Mediterranean plants

1957

1958

Poteriuni spinoswn

51

52

Cistus saluifolius

39

47

Teucrium polium

55

63

Thymus capitatus

64

74

Desert sand dune plant

Artemisia monosperma

57

54

Desert plants

Artemisia herba alba

72

91

Zygophyllum dumosum

84

96

Noea mucronata

91

90

Anabasis articulata

73

77

Haloxylon articulatum

72

85

The values for the relative seasonal body reduction, i.e. the decrease in
weight of the transpiring body during the summer expressed as a per-
centage of the weight in spring, are presented in Table i . This shows that
the values for the desert plants are higher than those for the Mediterranean
ones, while Artemisia monosperma, which is a desert sand dune dominant,
is intermediate between them. Table i also shows that no marked differences
between the values for 1957 and 1958 could be found although the values
for 1958 tend to be somewhat higher. On the other hand the amount of
new growth for the desert plants in 1957 was higher than that in 1958, as
seen from Table 2, in which the values for the weight of the transpiring
body of the plants in the spring of 1958 are expressed as a percentage of the
corresponding values for 1957. No clear-cut differences were found between
the amounts of new growth of the Mediterranean plants in the two years.

TRANSPIRATION RATES
The transpiration rates of the chamaephytes were measured during 1950
and 195 1 in the field by the cut leaf quick-weighing method. Because the
15

2i6 G. ORSHAN

Table 2

Dry weight of the transpiring body in the spring of 1958 expressed as a percentage of

the weight in the spring of 1957

Mediterranean plants

Poterium spinosum

85

Teucrium polium

96

Thymus capitatus

107

Cistus sahifolius

98

Desert sand dune plant

Artemisia monosperma

95

Desert plants

Artemisia herba alba

61

Zygophyllum dumosum

72

Noea mucronata

47

Anabasis artictilata

71

Haloxylon articiilatum

76

plants examined were either niicrophyllons or articulate, small branchlets
were weighed instead of single leaves. From each plant a branchlet was cut
from the southern side of the plant at a definite height with a razor blade,
tied with a silver wire, weighed and hung back on the plant for three
minutes at approximately the place from which it was detached and
weighed again. Two branchlets were weighed every hour and the trans-
piration rates calculated on a basis of fresh weight. The measurements were
started at about sunrise and continued until sunset. The average values for
each day were calculated from all the measurements carried out during the
day. The annual march of the transpiration rates is presented in Figs. 6
and 7.

The most striking fact emerging from these figures is that the curves for
practically all the plants run more or less parallel. The maximal values
occur during April and May when there is stiU a considerable amount of
available water in the upper soil layers and the saturation deficit of the
atmosphere is high. The decrease in the transpiration rates during the
summer months may be attributed to the decrease in the amount of
available water in the soil and the increase of soil water tension. The low
values for the transpiration rates during the winter are caused by the low
saturation deficit of the atmosphere. Another striking fact is the marked
difference between the values for the Mediterranean and desert plants. The
transpiration rates for the former are far higher than those for the latter.

When the relative seasonal reductions in transpiration rates, i.e. the drop
in the transpiration rates during the summer expressed as a percentage

SEASONALDIMORPHISM OF CHAMAEPHYTES

ng/g.h.

217

..A.

r" ■■■■■■..
/ ■>,

/

500'

^^/ \\

\

/

•'/ ^\

\

^>.^-<y

1

/ i- A

\

^^^.

>

^^/\ vly-

..-'■■

^^r \ V.

■■■♦•••.^.0

A-

•^r.?:>>^

^'^ \ ^

•^•^ *""••

•-••■^^^•-'^^

V A.o.

A "^A^, ^'*-'*^

'<■ A' —

~~~-^

XI XII

III IV

VI VII VIII IX

Fig. 6. Annual march of transpiration rates in mg. per gram fresh weight per hour of

desert plants.
K.rsx.- Artemisia inonosperma H..a..-Haloxylon articulatum

K.hz.- Artemisia herba alba N.m.-Noea mucronata

A.a..-Aiiabasis artiadata Z.d.-Zygophyllum dutjiosum

of the values in spring, are calculated (Table 3), it is evident that there
is no clear-cut difference between the desert and Mediterranean plants.
Apart from Zygophyllntn dumosiim which is a leaf succulent the values
are higher than 50% and for most plants range from 60 to 75%.

Table 3
Relative seasonal reduction in the transpiration of desert and Mediterranean plants

Mediterranean plants

Potcriurn spinosum 62

Cistus sali'ifolius 76

Teucrium polium 50

Thymus capitatus 72

Desert sand dune plant

Artemisia nionosperma 55

Desert plants

Artemisia herba alba 73

Zygophyllum dumosum 86

Noea mucronata 78

Anabasis articulata 68

Haloxylon articulatum 27

2l8

G. ORSHA N

VI VII VIII IX

Fig. 7. Annual march of transpiration rates in mg. per gram fresh weight per hour of

Mediterranean plants.

C.s. - Cistiis sahnfolhis Th.c. - Thymus capitatus

P.sp.-Poteriuiii spinosum T.p.-Teucrium poliwii

DISCUSSION

The data presented above clearly demonstrate that the seasonal dimorphism
of the chamaephytes examined markedly contributes through surface

SEASONAL DIMORPHISM OF CHAMAEPHYTES 219

reduction to the regulation of their total water output during the prolonged
dry summer of the Mediterranean chmate.

As seen from Table i the relative seasonal body reduction of the desert
plants examined was far higher than that of the Mediterranean ones. The
question which may arise is whether this difference is due to the effect of
the environment or to some internal characteristics in which the two
groups of plant differ from each other.

The fact that the relative seasonal body reduction of the same species
was of similar magnitude for the two successive years examined, in spite
of the striking differences in the total rainfall between them, and that no
marked differences could be found in this respect between desert and
Mediterranean plants, supports the postulate that the differences in the
relative seasonal body reduction between the Mediterranean and desert
plants is in some respects, at least, due to certain inherent characters.

Although no great differences between the values of the relative seasonal
body reduction for the years 1957 and 1958 could be found, the absolute
values of the seasonal body reduction in 1957, which was a better year,
were much higher than those in 1958 for the desert plants, but not for the
Mediterranean ones. These higher values were due to more extensive
growth in the spring of 1957, as seen from Table 3, affecting mainly the
number of dohchoblasts developed and their length. The fact that in the
Judaean hiUs no such differences between 1957 and 1958 were observed,
suggests that annual rainfall in the Judaean hiUs during the winter of
1957-58 was not a Umiting factor for growth of the Mediterranean plants.

The question which one may put forward is whether the amount of
rainfall limiting spring growth is different for desert and Mediterranean
plants.

If one considers the phenomenon of seasonal body reduction as partial
drought evasion (Orshan and Zand, 1961), one must admit that the
plasticity of the plant with regard to the extent of spring growth is more
extensive than that of the part of this growth which is being shed during
the summer. The absolute volume of the plant body which is shed during
the summer seems therefore to be more or less predetermined in the spring.

The partial drought evasion of the desert chamaephytes, however, goes
one step further than that of the Mediterranean by some kind of radial
subdivision of the plant when only a sector of it remains ahve while the
rest dies back to the roots. During the next rainy season, the sector which
did remain alive grows into a whole plant (Ginsburg, 1961).

This radial subdivision is achieved through different anatomical mecha-
nisms in various desert chamaephytes and there are some hints of its

220 G.ORSHAN

existence in a few Mediterranean ones at least. In the Mediterranean
territory, however, partial death correlated with radial sphtting of the
plant is not common.

Although the cut leaf quick-weighing method has many defects it still
seems to be the only practical method yet devised to measure transpiration
rates of intact plants in the fields. An analysis made on transpiration rate
values of a few desert plants showed that the coefficients of variance for the
daily averages were about io% and when parallel measurements were
made on 2 plants in the same stand the values were of the same order of
magnitude (Orshan, 1961; Zohary and Orshan, 1954).

These data support, although do not prove, the assumption that the
curves in Figs. 6 and 7 represent actual transpiration rates and that both
the desert and Mediterranean chamaephytes markedly reduce their trans-
piration rates during the summer. The fact that no clear-cut reduction in
the transpiration-rate values was foimd for evergreen Mediterranean trees
and shrubs while a marked reduction in the values for the deciduous ones
was observed (Poljakoff, 1945 ; Oppenheimer, 1953) is supporting evidence.

The means by which the reduction in transpiration rate during the
summer is brought about is not clearly understood. One has to bear in
mind that in the chamaephytes different leaves or stems make up the
transpiring body of the plant in different seasons. When the transpiration
rates of different leaf types were measured on the same plant in a few
chamaephytes during periods when both could be found intact, no
significant differences were found between the daily averages, although
differences in the daily march of the curves were prominent (Orshansky,
1952). This fact suggests that, while transpiration by different leaf types of
the same plant may be affected in different ways by the same factor, it is
doubtful whether these differences are sufficient to account for the striking
reduction in the transpiration rate of the chamaephytes during the summer.
It seems more probable that this reduction is simply caused by the decreas-
ing availabiUty of water in the soil.

Although it is not intended to enter in this paper into a full discussion of
the nature of the differences in the transpiration rates between the Mediter-
ranean and desert plants the much higher values of the former are worth-
while notmg. Zohary (1959) has already pointed out that our results do not
agree with the views of Maximov (1929) and others that higher transpira-
tion rates are characteristic of desert plants. The fact that most of the plants
measured by us are either stem succulents or bear more or less succulent
leaves may account in part for this disagreement.

The absence of differences between the relative seasonal reduction in the

SEASONAL DIMORPHISM OF CHAMAEPHYTES 221

transpiration rate of desert and Mediterranean plants may also partially be
accounted for by the high degree of succulence of the former.

A comparison between Tables i and 3 shows that the relative decrease
in the transpiration rate during summer and the decrease in the transpiring
body, are of the same order of magnitude, the two processes playing a
more or less equal role in regulating the water output by the plant. When
the relative reduction in the total water output is computed, the values
obtained range between 90 and 98%. These high values probably account
for the fact that chamaephytes play an important role in arid vegetation.
As partial drought-evading plants they are intermediate between the
drought-evading therophytes, cryptophytes and hemicryptophytes on the
one hand, and the drought resisting phanerophytes on the other. Among
the perennial plants persisting throughout the year they are distinguished
by combining the powers to reduce their transpiring body and their
transpiration rate. In this respect they differ from the phanerophytes,
whether deciduous or evergreen, except perhaps a few plants hke Anagyris
foetida L. and Lycinm spp.

REFERENCES

Cain, S. A. (1950) Life forms and phytoclimates. Bot. Rev. 16, 1-32.

EvENARi, M. (i960) Plant physiology and arid zone research. The Problems of the Arid

Zone, Proc. Paris Symp., UNESCO, Arid Zone Res., 18.
EvENARi, M. &: RiCHTER, R. (1937) Physiological and ecological investigations in

the wilderness of Judaea. J. Lmn. Soc. Lond, 51, 333-81.
GiNSBURG, Ch. (1961) Splitting in Desert Chawaephytes. Its Anatomy and Ecology. (MS.)
Maximov, N. a. (1929) The Plant in Relation to Water. London.
Oppenheimer, H.R. (1953) An experimental study on ecological relationships and

water expenses of Mediterranean forest vegetation. Palest. J. Bot. Rchovot, 8,

103-124.
Oppenheimer, H.R. (1959) Adaptation to drought: Xerophytism. Plant Water Rela-
tionships in Arid and Semi-arid Conditions, Reviews of Research, UNESCO, Arid

Zone Res. 15, 105-38.
Orshan, G. (1954) Surface reduction and its significance as a hydro-ecological factor.

J. Ecol. 42, 442-444-
Orshan, G. (1961). A Note on the Ecological Significance of the Cut Leaf Method for

Measuring Transpiration. (MS.)
Orshan, G. & Zand, G. (1961) Extent of Seasonal Reduction in the Transpiring Body

under Mediterranean and Desert Conditions. (MS.)
Orshansky, G. (1952) Effect of morphological and physiological factors on the

water economy of plants. Ph.D. Thesis, Hebrew University, Jerusalem.
POLJAKOFF, A. (1945) Ecological investigations in Palestine. I: The water balance of

some Mediterranean trees. Palest, f. Bot. Jerusalem, 3, 138-150.
Raunkiaer, C. (1934) Life Forms of Plants and Statistical Plant Geography. Oxford,

Clarendon Press.

222 G. ORSHAN

Shmueli, E. (1948) The water balance of some plants of the Dead Sea salines. Palest.

J. Bot. Jerusalem, 3, 117-143.
ZoHARY, D. (1953) Ecological studies in the vegetation of the Near Eastern deserts.

Ill: Vegetation map of the central and southern Negev. Palest. J. Bot. Jerusalem, 6,

27-36.
ZoHARY, M. (1952) Ecological studies in the vegetation of the Near Eastern deserts.

IV: Hydro-economical types. Symposium on the Biology ^'"^ Productivity of Hot

and Cold Deserts. London, 56-57.
ZoHARY, M. (1955) Geobotany (Hebrew) 'Sifriath PoaHm' Merhavia.
ZoHARY, M. (1959) On hydroecological relations of the Near Eastern desert vegetation.

Plant Water Relationships in Arid and Semi-arid Conditions, Proc. Madrid Symp.,

UNESCO, Arid Zone Res., 16, 199-212.
ZoHARY, M. & Fahn, a. (1952) Ecological studies on East Mediterranean dune plants.

Bui. Res. Council Israel, i, 38-53.
ZoHARY, M. & Feinbrunn, N. (1951). OutUiie of the Vegetation of the Northern

Negev. Palest. J. Bot. Jerusalem, $, 96-114.
ZoHARY, M. & Orshan, G. (1954) Ecological studies in the vegetation of the Near

Eastern deserts. V: The zygophylletum dumosi and its hydroecology in the

Negev of Israel. Vegctatio, 5-6, 341-350.
Zohary, M. & Orshan, G. (1956) Ecological studies in the vegetation of the Near

Eastern deserts. II: Wadi Araba. Vegetatio, 8, 15-37-

RELATION OF GROWTH AND DISTRIBUTION

TO WATER

ON THE PROBLEM OF THE RELATIONSHIP

BETWEEN HYDRATION OF LEAF TISSUE AND

INTENSITY OF PHOTOSYNTHESIS AND

RESPIRATION

BOHDAN SlAVIK

Institute of Biology, Czechoslovak Academy of Sciences,
Praha, Czechoslovakia

INTRODUCTION

A considerable number of papers has been devoted to the relationship
between the intensity of photosynthesis and hydration of photosynthesising
tissues. Papers will not be mentioned in the sequel which do not take into
consideration the intensity of carbon dioxide assimilation but rather the
fmal yield (of the more recent ones, e.g. Baumann, I957; Kreeb, 1958).

Concerning the lower poikilohydric plants (algae, bryophytes, hchens)
there exists a fundamental unity of view that hydration directly affects the
intensity of CO2 assimilation (BrilHant, 1924; Mayer and Plantefol, 1926;
Stocker, 1927; Walter, 1928, 1929; Smyth, 1934; Stocker and Holdheide,
1937; Stalfelt, 1937, 1938; Danilov, 1938; Kaltwasser, 1939; Ellee, 1939;
Romose, 1940; Ried, 1953; Ensgraber, 1954 and others).

On the other hand, papers where this relationship is considered in higher
dry-land homoiohydric (hydrostable) plants without interaction of the
stomata, have not reached a common basis so far. For instance, Pisek and
Winkler (1955) did not fmd in their results any experimental support for
the view that photosynthesis should decrease on water loss in any other way
than by virtue of stomatal closure. A similar standpoint is maintained by
Larcher (i960). An ehmination of the influence of the hydroactivity of
stomata is rather difficult from the experimental point of view. Iljin (1923)
worked with plants with closed stomata and he still found a relationship to
exist between water content and intensity of photosynthesis, different in
different taxons. Brilliant (1924, 1925, a review of 1949) and ChrelashviH
(1940) carried out experiments on small segments of leaf tissue after having
ascertained that the state of the stomata did not Hmit the saturation of the
tissues with CO 2 which took place through the planes of section. In addition
to a dependence of the intensity of photosynthesis on water content in the
tissue they demonstrated the existence in higher plants of an optimal water
deficit at which the intensity of photosynthesis was in some cases higher

226 BOHDAN SLAVIK

than at complete water saturation. Stocker(i954, 1956), who was concerned
with higher plants, entertained no doubt about the intensity of photo-
synthesis being dependent directly on the chemical potential of water in
the assimilating tissue. A similar view is held by Alexeev and his school
(1952, 1954) who found very significant correlations between the intensity
of photosynthesis and various indicators of the water relations of the
tissue, particularly between the colloid-bound water and the osmotic
pressure of the cell sap.

The papers mentioned represent but a few examples of the fundamental
viewpoints extant rather than an exhaustive review of all papers where the
problem in question is touched upon. Such review of papers prior to the
early forties may be found in the monograph by Brilliant (1949), another is
given by Stalfelt (i960).

The present communication should contribute to the problem from an
entirely nev/ and different point of view.

In keeping with the physiological gradients in plant organs (Prat, 1948,
195 1) it was shown earlier (Slavik, 1959a, 1959b) that sugar-beet and tobacco
possessed a definite distribution pattern of values of the osmotic pressure of
the cell sap over the leaf-blade which did not change even during a com-
plete saturation of the leaf-blade with water, i.e. at a zero diffusion pressure
deficit of tissues in situ, and which was thus associated with an identical
gradient of the turgor pressure. This osmotic pressure gradient remained
relatively unchanged both during active (supplementary saturation) and
passive (wilting) water balance. I am of the opinion that such a natural and
constant difference in the cell sap osmotic pressure under normal conditions
in a steady state of individually identical material (one and the same leaf-
blade) is very suitable for studying the relationship between hydration and
the photosynthetic or respiratory activity.

The present paper thus attempts to compare the differences in the
intensity of photosynthesis and respiration at the base and at the apex of
the leaf-blade, i.e. in those leaf-blade sections between which the greatest
natural and permanent differences in the osmotic pressure of the cell sap
are known to exist (for details see Slavik, 1959a).

MATERIAL AND METHODS

About 120-150-day-old tobacco plants [Nicotiana Sanderae hort.) in the
vegetative state with a leaf rosette of 10 to 12 leaves, grown in pots, were
used for the experiments.

For the purpose of measuring the intensity of photosynthesis the plants

HYDRATION, PHOTOSYNTHESIS AND RESPIRATION 227

were kept for 24 hours in a saturated atmosphere and then placed in a small
air-conditioned chamber of the following inner dimensions : 3 5 cm X 3 5 cm
X40 cm. The chamber was flushed with temperature- and humidity-
conditioned air with the normal concentration of carbon dioxide (i.e.
about 055 mg CO2/1000 ml). The air in the chamber had a temperature of
25 + o-2°C, relative humidity of 80 ±3%. The plant in the chamber was
illuminated from above with five incandescent bulbs, Tungsraphot B 500
W, and with four Philora 75 W Phillips, through a continuous-flow water
filter 8 cm in height, the total constant intensity being 40,000 lux (with
stabihsed mains voltage). For the experiments mature leaves of the central
insertion level were used in situ (on the plant), the apex and the base of the
leaf being covered bilaterally with leaf chambers provided with plexite
windows (photograph in Catsky, i960) which enclosed an area of 12 cm 2.
Experimental air was drawn through these horizontally placed leaf cham-
bers by means of membrane pumps at the constant rate of 10 1/hr, passing
then into an infrared COa-analyser (Infralyt, Dessau, Germany). This
analyser with a selective condenser detector was set up in a differential
circuit so that it measured directly the difference in concentration between
the experimental and control air. The measuring tube of the analyser was
alternately connected with the basal and apical leaf chamber placed on the
same leaf Control air was passed through the reference tube. A 50 ^A
recorder registered values which, during constant flow of experimental
air, were directly proportional to the intensity of photosynthesis of the
part of the leaf-blade enclosed in the leaf chamber. Sufficient rate of air
flow with a very small leaf-chamber volume ensured that no excessive
heating of the leaves occurred and that even at the highest intensities of
photosynthesis the concentration of carbon dioxide never dropped by
more than 20%. A second control infrared analyser measured the con-
centration of CO 2 in the control air. For details see Slavik and Catsky
(1961). The values of intensity of photosynthesis were expressed as mg
COg/dm^/hr.

When the intensity of respiration was measured higher accuracy was
achieved by using the conventional manometric estimation according to
Warburg. Each manometric flask contained 6 leaf discs of 15 mm in dia-
meter cut out either from the apical or from the basal part of the leaf-blade
(circles in Fig. i). Experimental leaves were chosen on the basis of criteria
common to analogous experimental plants as used for estimation of
photosynthesis and were also saturated with water prior to the experiment.

The side-arm of the flask contained i ml/ water which ensured minimum
transpiration loss from the leaf tissue discs during measurement. The esti-

228 BOHDAN SLAViK

mation was carried out at 25 °C. It was ascertained before the experiment
that different size of the discs and thus a different ratio of the total intact
area to the cut plane area had but a neghgible effect on the relative
values of respiratory intensity. These values are expressed in /xl. COg/mg.
dry weight/hr.

Parallel material was used for determining the number and size of
stomata by direct microscopy. The density of stomata was expressed as
number per i mm^ leaf area, the size as the length of the pore in /n. Under
the theoretical assumption that the stomata are of the same shape all over
the leaf-blade, i.e. that the index of length to maximum width of the
pore is the same, the pore area is proportional to the square of its length.
The product of the density and square of pore length (together with the
sum of these values for the lower and upper part of the leaf-blade) is
given as the relative index of the area of pores.

I am indebted to Mrs. Krejcarova for her skilled technical assistance.

RESULTS

Gradients of the osmotic pressure of the cell sap of a single material were the
following: during average osmotic pressure of the cell sap in the leaf-blade
apex amounting to 12-9+ 0-3 atm. the average osmotic pressure at the
base was io-6±o-32 atm, i.e. lower by 18 per cent. The difference of 2-3
± 0-20 atm is very significant statistically (see Table i).

Table i
Review of results

OP PR R ST

, <

Leaf-blade apex I2-9 + 0-3 io-8±i-3 2-4±0'o6 135-0

Leaf-blade base io-6±o-3 i2'9+i-2 2-7±o-07 139-3

Average difference

— 2-3 + 0-2

+ 2-1 + 0-4

+ 0-3 ±0-07

+ 4-3

Difference base-apex in

-18

+ 20

+ 13

+ 2-5

percentage

OP — osmotic pressure in atm.

PR — phosynthetic rate in nig. COg per dm^ per hour.

R — rate of respiration Qo, in fxl. COg per dry weight per hour.

ST — relative index of total pore area (see text and Table 2).

HYDRATION, PHOTOSYNTHESIS AND RESPIRATION 229

The photosynthesis rate was measured in 28 leaves, i.e. in a total of 28
pairs of apical and basal parts of the leaf-blade. The leaf chambers were
placed as shown in Fig. i by the rectangles. At the beginning of each
experiment the stomata were opened photoactively (previous saturation
with water took place in the dark) so that after 20 or 30 min the intensity of
photosynthesis reached mostly a steady value which was maintained for
at least one hour but usually for several hours. The plants were well watered
and the conditioned air passing through the leaf chamber had a high
humidity so that the water saturation deficit formed was reflected in a

Fig. I. Localisation of the chambers in photosynthesis determinations (rectangles) and
of the disks cut out for respiration measurements (circles).

decrease of the apparent photosynthesis only after several hours' exposure.
The water saturation deficit values at which a marked drop in photo-
synthesis could be observed on long exposure varied about the value of
10 per cent. For our results, values of photosynthesis were chosen from the
initial, completely steady measuring intervals. An important fact should be
mentioned here, however, namely that the basal part of the leaf revealed in
a separate experimental series a quite regularly higher water saturation
deficit than the apical parts. Thus the possible differences in the water
deficit could affect the difference in photosynthesis in the reverse direction
only, i.e. they could decrease the intensity of photosynthesis in the basal
part, thus diminishing (and in no case increasing) the observed difference
in the intensity of photosynthesis between the base and the apex.

The results showed that under the given experimental conditions the
intensity of photosynthesis referred to area was on the average 20-2 per
cent higher in the basal part of tobacco leaves than in the apical one. The
observed average difference d= 2-1 ±0-4. mg COg/dm^hr (the average

230 BOHDAN SLAViK

intensity at the leaf base being i2-o mg COa/dm^hr) is statistically very
significant (P^ o-ooooooi). (See Table i.)

If the differences in the intensity of photosynthesis are to be compared
with the different tissue hydration expressed as osmotic pressure of the cell
sap, i.e. if the differences are to be compared with the plasma factors of
photosynthesis it must be known to what extent our results could be
influenced by a different factor, viz. by the stomata, possible differences in
their density, size and state. The results of these estimations are shown in
Table 2.

Table 2
Number aiid size of stomata and relative index of pore area

Leaf-blade apex Leaf-blade base

_A , , A_

Upper side Lower side Upper side Lower side
Number of stomata

per mm^ 66-3 ±0-70 82-9±o-75 110-3 ±1-54 i46-9±,-59

Size of stomata (length of

pore in/i) 30-8 + 0-21 29-6±o-25 23-7+ 0-23 23-1 ±0-26

Relative index of total 63-3 72-5 61*5 77-8

pore area

V ^ / V ^_

135-0 139-3

While the number of stomata on the upper and lower side of the leaf-
blade is significantly greater at the base, the length of the pores is statisti-
cally greater in the stomata from the apical part. In order to calculate the
relative index of the true pore area a simphfying assumption must be
employed, namely that all stomata have the same relative shape or in other
words, the same ratio of length to width of pore at the given extent of
opening all over the leaf-blade area. As the pore area is proportional to the
square of its length, the product of the number and square of pore length
may be taken as the relative index of pore area. Indexes derived in such way
(as shown in Table i) indicate that the total area of pores at the base and at
the apex differs by 2-5 per cent only, in spite of the above contradictory
differences in number and size.

Statistical significance of this difference was not tested on account of
the very laborious calculation of the index separately for each field of vision.
But even if the difference is statistically significant it is insufficient in

HYDRATION, PHOTOSYNTHESIS AND RESPIRATION 231

comparison with the observed differences in the intensity of photosynthesis
to explain them.

As concerns the opening width of the stomata, it should be mentioned at
this point that in the present paper the intensities of photosynthesis are
compared during the steady initial phase of measurement when no decrease
takes place which could be ascribed to hydroactive closing of the stomata.
As was mentioned above, any possible (but not observed here) hydroactive
closing of the stomata would be reflected first at the base where regularly
higher water saturation deficits were observed. This closing would thus
act against the observed difference in the intensity of photosynthesis.

Still greater, statistically significant differences were observed in the
respiration intensity. Average differences in the intensity of CO2 produc-
tion in the dark amounted to 0-31 ±007 jj-g COa/mg dry weight and
were statistically very significant (P=^oooooi). The average intensity of
respiration of the discs cut out from the apical part of the leaf-blade was
in the same experiment 2-38 j^tg/mg dry weight, while of those firom the
base it was on the average 1 3 per cent higher (number of sample pairs
«=82) (see Table i). In the course of estimation in the Warburg
apparatus the discs acquired within 90 min an average of 5-8 per cent
water saturation deficit. There were no significant differences between the
water deficit of the discs from the apical and basal part of the leaf-blade.

In common with the intensity of photosynthesis the respiration intensity
of assimilatory tissues of the leaf-blade was signfficantly higher in the basal
part than in the apical one.

DISCUSSION AND CONCLUSIONS

Intensity of photosynthesis referred to leaf area was about 22% higher at
the base of tobacco leaf-blades than at their apical part. This statistically
very significant difference could be associated by about 1/9 only with the
greater area of stomatal pores at the leaf base where the density of stomata
is significantly higher but their area significantly smaller, so that the calcu-
lated relative index is 2-5 per cent greater at the base than at the apex.
Different opening width of the stomata affect the results only by decreasing
the observed difference (see Residts). The stomata played no role whatever
in the measurement of respiration, when they were photoactively closed.
Respiration intensity referred to dry weight was 1 3 per cent higher at the
base than in the apical part of the leaf-blade. This difference is also statisti-
cally very signfficant. It may be concluded that the observed statistically
very significant differences between the rate of photosynthesis and respira-
16

232 BOHDAN SLAVIK

tion of assimilatory tissues at the base and near the apex were not due to a
stomatal factor, i.e. neither to their different size and number nor to their
state. It should be noted here that in the experiments the effect of possible
differences in the permeabihty of the cuticle or of the whole epidermis for
CO 2 and the effect of the inner structure were not eUminated. In experi-
ments on photosynthesis the effect of possibly different chlorophyll content
could also play a role.

The osmotic pressure of the cell sap was i8 per cent lower in the basal
part than in the apical one and this difference was also statistically very
significant.

If the differences observed are correlated with differences in hydration of
the tissue expressed by diffemt osmotic pressure of the cell sap it is with the
awareness of the possibihty of an actual effect of the state of hydration as
well as of its structural consequences formed during leaf ontogeny. In other
words, the stable differences in hydration of leaf tissue cells as known from
the differences in the osmotic pressure of the cell sap represent both an actual
and an ontogenetic factor which has affected both the anatomical and
plasmatic structure of leaf tissue cells. These structures influence then the
intensity of functions, in our case of CO2 assimilation and respiration.

A distinction between the actual effect of hydration and the ontogenetic
effect on structure and thus on function is difficult to make especially, if the
question of reversibiUty of these changes is considered. Many changes in
the photosynthetic activity due to dehydration are completely reversible
but not all of them (Stocker and Holdheide, 1937; Kaltwasser, 1939;
BrilUant, i949;PJed, 1953; Stocker, 1954; Ensgraber, 1954; Stalfelt, i960
and others). The additive irreversible changes become structurally per-
manent. Therefore, even those structural changes, the effect of which
could not be ehminated during the experiments described here and which
could not be distinguished from the actual effect of hydration are in fact
the consequences of dehydration. They can thus be causally connected with
hydration, particularly in such cases where the observed differences in
hydration at different parts of the leaf-blade are permanent as is the case in
our experiments.

The observed relative differences in osmotic pressure of the cell sap are
practically independent of the tissue diffusion pressure deficit (Slavik
1959a). They persist even during complete water saturation, during
complete turgescence. The same relative differences may thus be ascribed
to the maximum cell turgor. These relative differences in the turgor pressure
are undoubtedly connected with relatively permanent structural differences.

To my mind, the observed differences in the intensity of photosynthesis

HYDRATION, PHOTOSYNTHESIS AND RESPIRATION 233

and respiration are causally connected with permanent differences in
hydration of cells of the assiniilatory tissue of different parts of the leaf-
blade. A quantitative comparison of relationships between the above values
of photosynthesis and respiration rates is quite compHcated. It must be
borne in mind, however, that the locahsation of sites for which the
intensity of photosynthesis and respiration was determined was somewhat
different from methodological reasons (see Fig. i).

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THE EFFECTS OF EXPOSURE ON GROWTH
AND DEVELOPMENT

P. H. Whitehead

Imperial College, London

The importance of wind as a factor in plant growth has long been recog-
nized. In the field of agriculture and forestry many empirical studies have
been carried out mainly associated with the design and location of 'wind
breaks'. Far less attention has been focused on the experimental investiga-
tion of effects that exposure to wind during growth may have on the
development and physiology of plants.

At the beginning of the investigations presented here it was not even
clear to what extent wind effects could determine survival or death of
plants or communities. As a preHminary to laboratory investigations field
studies were carried out on M. Maiella in the Central Apennines of Italy.
This mountain has a fairly flat altopiano near the snow line covered with
Hmestone rock detritus and with typical 'alpine desert' vegetation. It is
particularly exposed to strong winds and the various community types,
often in close juxtaposition, appeared to be associated with the degree of
shelter from wind afforded by the rock fragments (Whitehead, 195 1). The
aerodynamic parameter Zq was found to be the best measure of the degree
of shelter from wind afforded by the surface irregularities. In these alpine
communities where the vegetation is sparse and the main drag on the air
stream is caused by the rock fragments themselves this parameter is not
open to the objections which can be made against its use in relation to
most vegetation types. The average values of Zq were determined in the
field for four of the community types described in Whitehead (195 1). Four
of these communities, A, E, G, and H, representing a gradation of
exposure from most exposed to least exposed were studied in detail. It
was found that there was a clear relationship between Zq and average
plant height; average inflorescence height and annual yield (Fig. la and b).
The larger the value of Zq and thus the greater degree of shelter the taller
were the plants and the greater the annual yield.

The degree of shelter, expressed as Zq also appeared to be related to
both the number of species and the diversity of growth forms in a com-
munity (Fig. ic). The smallest number of species and least diversity of

236

F. H. WHITEHEAD

6

5

E
" U

^ 3

X 2

2^0

CM

>|,200
en
_ 160

tl20

>, 80

AO

• Inflorescence height
X Plant height

(a)

30
25

^20

"' 15
o

o" 10

A E 0-2 G OA

HO-6

(b)

• No, of growth forms . .
xNo. of species

A EO-2 G O'-i

H 0-6.

(d)

• K as % dry weight
xP

10
6-2

■ o

A E 0-2 G O-A H 0'6 A E 0-2 G 0-U

Values of Zo in relation to areas A-H

HO-6

Fig. I. Relationship of average wind speed (Zo) on mountain top to
(a) heights of inflorescences and plants (b) annual yield of dry matter
(c) number of growth forms and species and (d) uptake of potassium
and phosphorus.

growth form is found in area A and these progressively increase until in
the most sheltered area H the largest number of species and the greatest
diversity of growth form is found.

These data show a relationship between the degree of shelter and the
characteristics of the communities. If this relationship were causal then
alteration to the degree of shelter in a given area should result in changes
in the community characteristics. This simple experiment was carried out
in the field by erecting low stone walls around mapped and recorded
quadrats in the most exposed areas. After a period of time changes did
occur in the vegetation of the kind which had been predicted and are

EXPOSURE AND GROWTH AND DEVELOPMENT 237

described fully in Whitehead (1959). The experiment was set up to test, at
the same time, the alternative hypothesis that the observed effects were
due to shading. This alternate hypothesis was shown to be untenable.

The growth form of a plant is of great importance in relation to wind
effects. A rough classification of such form is considered in Whitehead
(1957). In this paper only the exposure sensitive class will be considered.
These are plants which show a marked dwarfmg when grown in condi-
tions of continuous exposure to wind. In addition to the reduction of
height which is not accompanied by a reduction of the number of inter-
nodes, there are also extensive anatomical changes. All these changes are
such that it can be said that the plant shows increased xeromorphic
characters the higher the wind speed under which it is grown. Observa-
tions made on plants grown in wind tunnels showed considerable simi-
larity to plants of the same species [Senecio nebrodensis) from areas of
increasing exposure in M. Maiella.

In earlier experiments (Whitehead, 1957) it was found that leaf saturation
deficits of plants exposed to wind for a time increased despite the fact that
the roots were in soil maintained at field capacity. Recovery took place
during a subsequent period without wind. Other species of Senecio not
found in nature in such exposed conditions, e.g. Senecio elegans appeared
to accumulate so large a leaf saturation deficit that under the conditions of
the experiment permanent wilting could be expected after a few days.

Resulting from the experiments, however, it became clear that any
genotype has some power of reacting to the environment in such a way
that the changes in development can be considered advantageous to
survival under those conditions. Accordingly experiments were carried
out to investigate the extent of change which could be produced by species
not adapted to the severe conditions of the mountains. The species chosen
were Zea mais and Helianthus annuus. The plants of Zea were grown in a
wind tunnel and their anatomy and morphology compared to control
plants not subjected to wind. The results are given in full in Whitehead and
Luti, 1962. It was found that the plants exposed to wind were much more
xeromorphic in all characters examined. The degree of difference between
the treated and control plants was large being of the order of three to six
times greater in the treated plants than the controls.

In further experiments using Helianthus annuus a growth analysis of
both treated and control plants was made (Whitehead, 1962). These
showed that the plants exposed to wind were shorter and had smaller
leaves than the controls. This dwarfmg effect increased with the wind
speed under which the plants developed.

238

F. H. WHITEHEAD

A similar increase in xeromorphy was observed. Examination of the
relative proportion of root to shoot dry weights showed that over most of
the range of the experiments there was a greater proportion of root to
shoot with increase of wind speed despite the smaller total dry weight
(Fig. 2). At wind speeds approaching 40 m.p.h. the plants failed to survive

250-

200-

C7>

E
— ' I50H

01

IOC-

SO'

• TOTAL DRY WEIGHT

© SHOOT DRY WEIGHT

O root/ SHOOT RATIO

X ROOT DRY WEIGHT

I I

10 20

Wind speed (m.p.h.)

— T—

30

o

4 2

>

3 8

■ S

Fig. 2. Graph showing alterations of dry weight accumulation over 30 days in
Hdianthus amiuus grown at four different wind speeds.

the full time of the experiment and these plants did not show an increase
in root proportionally to shoot, indicating they were unable to produce
phenotypic change with potential advantage beyond a certain critical level
of conditions. Fig. 3 shows average intemode length and average leaf
areas o£ Helianthus annuiis grown at four wind speeds. These two characters
show a marked decrease in value with increase of wind speed. Fig. 4 shows
data of the plant height and leaf area for the mountain species Senecio
nehrodensis grown for the same length of time and at a range of wind
speeds. It can be seen that the 'critical level' beyond which compensation
does not occur is much higher together with the fact that the degree of
response to any one wind treatment is greater. It would appear that
the degree of response and tolerance in mountain species is greater than

EXPOSURE AND GROWTH AND DEVELOPMENT

239

species of less exposed habitats and this attribute must be of great impor-
tance in selection and survival.

Figure 3 also shows the gain in dry weight per unit of leaf area per unit
time. There is very little difference at the four wind speeds indicating that
the dry weight gain has been proportional to the leaf area attained. The
actual photosynthetic activity of individual cells appears to have been little
affected. The effect of the wind therefore appears to be on the processes

• INTERNODE LENGTH

O LEAF AREA .

O DRY WEIGHT GAIN PER UNIT AREA/UNIT TIME

-300

260

•220 —

IN

e

ISO S

i-

a

■I40

o
o

100

10

20

Wind speed ( m.p.h.)

Fig. 3. Average leaf areas and internode length of Helianthus annuus plant grown at
I mile/h, 9 mile/h, 19 mile/h and 33 mile/h together with the dry weight increment
per unit area per unit time.

controlling differentiation and the development of leaf area rather than on
the photosynthetic apparatus itself.

The increase in xeromorphy of the treated plants would appear to be
advantageous in reducing water loss from the treated plants. Fig. 5 shows
the results of an experiment designed to test this hypothesis. Plants of
Helianthus annuus were grown for thirty days at four different wind speeds,
the soil being maintained constantly at field capacity. The soil and roots

240

F. H. WHITEHEAD

were then sealed off and all plants were exposed to a 33 m.p.h. wind. The
plants were weighed before and after the experiment and the leaf areas
measured. The loss per unit area per unit time decreases with the increase
of wind speed under which the plant developed. But the leaf area also
decreases in a similar way so that the net water loss per plant is greatly
reduced with the increase of severity of the conditions under which the
plant developed. This demonstrates that the anatomical and morpho-
logical changes are advantageous in respect of water relations.

eo

70-

60-

^ 50-

s

40

30-

_l 20-

10-

FlG. 4.

WIND SPEED Cm.p.h)
Plant heights and leaf areas of Senecio ttebrodcnsis grown at four wind speeds.

Two Other factors in nature are associated with exposure to wind,
namely precipitation and the soil moisture regime. Both these factors will
affect the water balance of the plant and the question of how far the effect
of wind operates through them requires consideration. The measurements
already described indicate relationship of leaf water saturation deficits to
the anatomical and morphological changes. If this relationship is causal
then similar changes should result from alteration in leaf saturation deficits
however produced. Water balance is, of course, the resultant between two

EXPOSURE AND GROWTH AND DEVELOPMENT 241

processes, uptake and loss. Leaf saturation deficits can be produced by an
adverse soil moisture regime. Experiments were therefore carried out in
which plants of Helianthus annuus were grown at a range of soil moisture
conditions from field capacity to one sixteenth field capacity (Whitehead,

• ISO

• LOSS IN mg/cm^/hour
O LOSS per PLANT
O LEAP AREA

E

T
10

20
Wind speed ( m.p.h.)

Fig. 5. Water loss of plants o{ Helianthus annuus in 6 hours. These four sets of plants
were grown for 30 days at i niile/h, 9 mile/h, 19 mile/h and 33 mile/h respectively.
After bringing their substrate up to field capacity they were exposed to a 33 mile/h
wind for 6 hours. The total loss per plant is shown in relation to leaf area per plant
and its loss per unit area in unit time.

1962). The results of these experiments are shown in Fig. 6. It can be seen
that anatomical and morphological changes essentially similar to those
produced by exposure to wind resulted from these treatments. Again the
main effect appeared to have been on the processes of differentiation
except that at the most adverse regime some interference with the actual
photosynthetic apparatus appears to have occurred.

The other factor associated with wind effect, i.e. precipitation, would be
expected to offset the effect of wind in lowering the water balance of the

242

F. H. WHITEHEAD

TIME TO "death" IN RELATION TO SOIL MOISTURE

O Time to "Death"
• lnt«rnod« Length
O Lea t Area

r300 £

•x

<

Ul

200 P

LU

2

Fig. 6. Leaf areas and internode lengths of plants grown at four soil moisture levels
and the time taken for 'death' of these plants to occur in a 40 mile/h wind.

plant since loss from the leaves would tend to be reduced if they are
covered with a fdm of water. The vahdity of this hypothesis was demon-
strated by growing plants of Helianthus annuus in the wind tunnel, one set
of which were kept sprayed with distilled water. The results are shown in
Fig. 7 (Whitehead, 1962). It can be seen that the extent of modification in
the sprayed plants is less than that of the controls.

EFFECT OF CONTINOUS WATER SPRAY-LEAF ARE A-INTERNODE LENGTH

5 0l

E 40

<

UJ 3 0-

cC
<

20

10

AREA WITHOUT SPRAY

APEA WITH SPRAY

GE INTERNODE LENGTH

UT SPRAY

GE INTERNODE

SPRAY

LENGTH

To"

WIND

20 30

SPEED (m.p.h.)

X

I-

UJ

_i

4 UJ
a
O

3i

Ul

H

2?

UJ

I ^
a.

Ul

>

<

Fig. 7. Leaf areas»and average internode lengths of plants grown, with and without a
continuous water spray, for 35 days at mid speeds of i, 9, 19 and 33 mile/h winds.

EXPOSURE AND GROWTH AND DEVELOPMENT 243

The foregoing experiment suggests that the anatomical and morpho-
logical changes result from interference with processes controlling differ-
entiation. Since growth substances are often involved in such processes
the experiments were repeated, treating one set of plants with various
growth substances. With /? indole-acetic acid, over a wide range of
concentration, no differences were observed (Whitehead (1963))
between treated and untreated plants. With gibbereUic acid however
highly significant differences were observed. Both in wind treated and
soil moisture regime experiments gibbereUic acid tended to reverse the
effect of these factors so that less anatomical and morphological change
was seen in the treated plants. It is interesting to note that the full range of
treatment of wind or soU moisture restriction could not be used because
the gibbereUic acid treated plants failed to survive above a relatively low
limit of severity of conditions. This is a further demonstration that the
changes have survival value.

A further test of the survival value of these changes was made in the
following experiment (Whitehead (in the Press)). Plants of Helianthus
annum grown under a range of wind conditions were exposed to an ex-
cessively high wind speed (60 m.p.h.). The time was noted that this
wind took to so desiccate the plants that permanent wilting and 'death'
occurred. The results are shown in Fig. 8. It can be seen that the more
severe the conditions under wliich the plants developed the longer they
were able to survive. The plants treated with gibbereUic acid were
relatively soon kiUed, whilst the untreated plants survived much longer.

These experiments can be summed up as demonstrating that the main
effect of wind is to reduce the water balance of the plant even if the roots
are in optimum condition for water uptake. The reduction of water
balance in the shoot whether due to excessive loss or to limited uptake
appears to upset the processes of differentiation and only in extreme cases
is the photosynthetic apparatus itself affected. This modification of
differentiation is unaffected by /? indole-acetic acid but is counteracted to
a large extent by gibbereUic acid. The anatomical and morphological
changes which result tend to produce a phenotype better adapted to
growth under xerophytic conditions. The plants are dwarfed but the
number of internodes is not affected; the leaf area is smaUer and the leaves
themselves have lower transpiration rates per unit area/unit time; the
smaUer amounts of assimilates are differently employed in that there is a
large increase of root relative to shoot; the internal anatomy of the leaves
is also affected being more xeromorphic and with increase in the number
of pahsade layers and reduction of inter-ceUular spaces ; the xylem and

244

F. H. WHITEHEAD

TIME TO "death" AT 40mph WIND

<

o

LLl

% Treated Gibbcrclllc Acid
O Untreated

Tl ME

IN

HOURS

Fig. 8. Time to 'death' of plants grown at four levels of soil moisture. One set treated
with giberellic acid and one set untreated.

phloem are more strongly developed together with the amount of fibres in
the bundles.

The genetic basis of this phenotypic plasticity, adaptative in nature,
must be of importance in species whose habitat involves exposure to wind
or drought. It is suggested that there has been positive selection during
evolution for genotypes having large potentialities for phenotypic plasti-
city of this kind. This is not the only solution that evolution has produced,
c.f the many genotypes of Cerastium (Whitehead, i959), but that it is
successful may be assumed from the occurrence of many highly plastic
species in montane regions.

My thanks are due to the Royal Society for a grant for the construction
of one of the wind tunnels used in this experiment.

REFERENCES

Whitehead, F. H. (1957) Wind as a factor in plant growth. In Control of the Plant En-
vironment. Ed. J. P. Hudson. London.

Whitehead, F. H. (1959) Vegetational changes in response to alterations of surface
roughness on M. Maiella, Italy.J. Ecol. 47, 603-606.

EXPOSURE AND GROWTH AND DEVELOPMENT 245

Whitehead, F. H. (195 i) The ecology of the Altipiano, Monte Maiella, Italy. J. Ecol.

39, 330-355-
Whitehead, F. H. (1962) Experimental Studies of the effect of wind on plant growth

and anatomy II. Helianthus atmutis. New Phytol. 61, 59-62.
Whitehead, F. H. (1963a) Experimental studies of the effect of wind on plant growth

and anatomy. III. New Phytol. 62, 80-85,
Whitehead, F. H. (1963b) Experimental studies of the effect of wind on plant growth

and Anatomy IV. New Phytol. 62, 86-90.
Whitehead, F. H. & Luti, R. (1962) Experimental studies of the effect of wind on

plant growth. I. Zea mays. New Phytol. 61, 56.

GROWTH AND WATER USE OF VEGETABLES
IN A GREENHOUSE

J.F.BlERHUIZEN

Instituut voor Cultuurtechnick in Waterhuishouding,
Wageiiingen, Netherlands

INTRODUCTION

Inside a greenhouse, temperature is higher and radiation lower than under
field conditions. Radiation therefore, shifts to a stronger and temperature
to a less limiting value for growth. For that reason yield response will be
less influenced by a variation of temperature. However, since both chmatic
factors are intimately correlated with each other, it is difficult to distinguish
the effect of each of them on growth. In spruig and autumn, vegetables are
cultivated under more or less the same hght intensities. In the autumn with
a same hght intensity, however, temperature is higher than in spring, which
is due to the phase lag between hght and temperature. Yield of vegetables
in spring as well as in the autumn have been compared, giving a relation
between yield, heat sum and total radiation. Such a relation is vahd only
if soil conditions are not Hmiting growth.

De Wit (1958) observed that in a humid chmate the ratio dry weight
yield/total water use, is more or less independent of soil factors, unless
extreme soil conditions are present. Moreover, his results obtained in
experiments with containers could be compared with those obtained in
the field.

From radiation and temperature data then a prognosis can be made on
the length of a growth period necessary for a certain yield in different
seasons. At the same time, it will be possible to calculate total water use
via the relation between the latter and total yield. From these data, values
for water use per day can be given for vegetables grown in various seasons
which might be of use for irrigation purposes. An example with lettuce
planted at different dates will be given.

MATERIAL AND METHODS

The experiments were performed in a greenhouse in the period from 1954
to i960. The plants were cultivated in containers with a surface area of
0-2 m^ and a height and diameter of 70 and 50 cm respectively. Each con-

GROWTH AND WATER USE OF VEGETABLES

247

mm /day

5

• 1957
o 1958
+ 1959
X 1960

"►o^X 0 -fc

■J^

"nT'sn

7 8

mm / day

Fig. la. Relation between pan-evaporation in mm per day and measured incoming
radiation (i?^) in cal cm-^ per day. Average values of lo-day periods.

tainer was filled with a layer of gravel (5 cm), coarse sand (5 cm) and 50 to
60 cm of a light clay-loam or sandy soil.

During the experimental period, various data on temperature, relative
humidity and pan-evaporation were measured. The daily radiation was

mm /day
5

• 1957
o 1958
+ 1959
X1960

o it

^-+

4^X X X °

L^.

100

200

300

400

500

600 - 7 00

cal in cm /day

Fig. lb. As Fig. la, but Rm'^''^ i^rri and multiplied by (A/ A + y) (where A is the
slope of temperature-maximal vapour pressure curve and y is the psychrometer
constant).

17

248 J. F. BIERHUIZEN

obtained from the Physical Laboratory at Wageningen, situated within 2
miles from the greenhouse.

From a physical point of view, it would be expected that pan-evapora-
tion and radiation are related to each other. In Fig. la, daily values calcu-
lated from periods of 10 days are represented. A curvilinear relation was
obtained in this way. According to Makkink (1957) a linear relation occurs,
plotting pan-evaporation against Rm • (A/A + y) (where Rm is radiation in
mm per day, A is the slope of temperature-maximal vapour pressure curve,
and y the psychrometer constant, for which 049 was taken). For further
details, the reader is referred to Makkink (1957) and to Rijtema (1958).
It is obvious from Fig. ib that although the curve straightened, it stiU
remains curvihncar. This apparent contradiction might be ascribed to the
fact, that extremely high values of pan-evaporaton and those below 0-5
mm per day, do not occur in Makkink's figures probably because average
monthly values were taken.

EFFECTS OF TOTAL RADIATION AND HEAT
SUM ON GROWTH

For every growth period the total radiation and the heat sum were calcu-
lated. The latter was computed by substracting the minimum temperature
for growth (4°C) from the average daily temperature and integrating all
those values over the whole growth period.

In Fig. 2 the total radiation is plotted against the heat sum. It is obvious,
that with longer growth periods both values increase. In the autumn,
however, the heat sum is much higher than in spring for the same total
radiation. This fact, as mentioned in the introduction, is due to a phase lag
of temperature behind radiation.

If temperature were the most important factor for growth, one would
expect for both seasons a similar relation with heat sum, and two distinct
ones for total radiation, according to Fig. 2, or vice versa if radiation were
the most important factor. In Fig. 3 dry- and fresh-weight yield of various
vegetables has been plotted agahist heat sum and total radiation. Autumn
yields are underlined. It is evident that, plotting against the heat sum two
different lines for weight can be distinguished, the one for spring with a
steeper slope than that for autumn. The differences between seasons nearly
disappear when using total radiation. This result indicates that radiation is
the most important factor for growth in a greenhouse.

Supposmg that the effects of radiation and temperature are linear and

GROWTH AND WATER USE OF VEGETABLES

249

fSOOr

1000

500

• SPRING
o AUTUMN

o o •*

10.000

I I I 1 I I

20.000

30.000
$ caL.cm '

Fig. 2. The relation between radiation- and heat-sum for different growth periods in

(spring (•) and autumn (o).

additive to one another, the following relation can be obtained from a
statistical analysis:

^/ =

0-0903.V +
± 0-0072 +

o-26y—
0-13

3^
±n

Zd =

0-00464X-I-
±0-00036 ±

0-0434}/-
0-0073

22
5

■■A

Txy = 0-92

rxy = 0-94

(I)

(^)

where Zf and za are respectively fresh- and dry-weight yeild and x and y,
total radiation and heat sum. The effect of heat sum (0-26 and 0-0434 with
fresh- and dry-weight respectively) seems to be higher than that of total
radiation (00903 and 0-00464 respectively). The real value of the latter,
under our circumstances, is 15 to 30 times that of the former (vide Fig. 3),
so the effect of radiation is many times larger than that of the heat sum.
In the application of heat sum and radiation it is supposed that the effect
on growth is linear and that minimum and optimum for growth are not
surpassed. Moreover, that there is no influence of day-length, whereas the
effect of day and night temperature is assumed to be the same. Though
these suppositions are not exactly true, a fairly hnear relationship was

250

J. F. BIERHUIZEN

obtained, which is at least partly due to the fact, that favourable and
unfavourable conditions balance each other over the growth period.

Photosynthesis experiments carried out by Bohnig and Burnside (1956)
and by Gaastra (1959), seem to indicate that the ratio photosynthesis/
radiation in the range of light limitation is approximately the same for

dry weight gm.
2iO-

dry weight gm
240-

X ° •
in * X

O ~ X

o .0 _
= ' o* -I

• •*• *

200 iOO 600 800 1000 1200 UOO

12 18 30 21. 29000

4cal cm,'

trtsti
2100

weight gm.

fresh weight gm.

tqo

• •

2i.m^

2000

-

If

1600

_

0

1200

h

";- X

000
LCD

-

1

&

•

X

•
•

•

• a
o

•

t

o

m

I I

A

•SPINACH
XLETTUCE

1000

o RADISH
4 ENDIUC

1200 K.00

Stemp

24 28 000

*col cm.'

' BEANS
' PEUt

■» CARROTS

» CAULIFLOWER

Fig. 3. The effect of heat- and radiation-sum on dry- and fresh- weight yield per
container of various vegetables. The data obtained in autumn are underlined.

various crops. This fact would favour the result that the dry-weight yield
of various crops are comparable with each other in accordance with the
total radiation received (Fig. 3). Calculations made on energy conversion
of radiation into dry weight seem to indicate that various crops show nearly
the same conversion values (Wassink, 1948). Further experimental details
and discussions concerning heat sum, total radiation and its practical
application have been given elsewhere (Bierhuizen, i960).

V)

g s

ID ?

4-*

P

■a O

I

.2 ^

>

t/1 - ^

.O

o

• is -9 n!

o
-o

o
z
<

t %

o
-o

8i

S

S o

0) o

u O

h. n

"4

o
o
o

o
o
o

o
o
o

o
o

D
<

o

-8

Q

z
<

in

O

7

a.

<

a.

hi

<

CD

u

o

n

I

C\J

<fl

>

n

n

<

7

a

Ul

o
o

o
o

>, o

o
o

o
o

252 J. F. BIERHUIZEN

WATER USE AND GROWTH

The experiments discussed above were carried out under conditions in
which the containers were frequently irrigated in such a way that the soil
moisture content varied between pF 2-o and pF 2-4. In another series of
experiments a constant water-level was applied by means of sub-irrigation
with a Mariotte flask. Four ground-water tables of 25, 35, 45 and 55 cm
respectively, were used for each treatment with four rephcates. From the
Mariotte flask the daily water use could easily be measured. The experi-
ments were performed in a clay-loam and in a sandy soil.

In Fig. 4, dry- and fresh-weight yield are plotted against total water use
for both soil types. For dry weight a linear relation occurs, according the
formula y — mx, (where y is dry- weight yield and x total water use). The
tangent m is approximately the same for the various vegetables treated in
these experiments, and for both soil types. It is obvious that water use
versus fresh weight shows a larger variation. This might be explained by
the fact, that for y = mx, one could write :

fresh weight times dry weight percent =100 mx
or

fresh weiffht

X

ignt . 1 . 1

— — times dry weight percent = ioo»j

which relation is a hyperbolic, as is shown in Fig. 5. It is clear that the ratio
I — j is low for vegetables with a high dry- weight percentage such

as beans and carrots, and high for a low dry-weight percentage such as

lettuce and spinach have. Moreover, a small variation in dry-weight percen-

, 1 1-1 ■ • • 1 • / fresh weight \
tage at a low value, results in a large variation in the ratio j — I

The fresh-weight yield varies considerably without a large change in total
water use {x). In an experiment with lettuce, for instance, and harvesting
under wet soil conditions, the fresh- weight yield and dry- weight per-
centage was 656 gm and 4-5% respectively, under dry conditions it was
366 gm and 5-5%. In a similar dry treatment, but irrigated the day prior
to harvest, it was 546 gm and 4-5% (Bierhuizen and De Vos, 1958). It was
evident that with the large change in fresh-weight and dry-weight per-
centage, total dry matter and water use did not change to a large extent.
A statistical analysis revealed that the various ground-water tables gave
no significant difference in dry- and fresh-weight yield. Total water use
increased, however, almost linearly with a ground-water table at depths
of 55 to 45, 35 and to 25 cm, respectively. This might be due to an increase

GROWTH AND WATER USE OF VEGETABLES

253

Dry weight »/. 55cm
45cm

15

10

o

.fo ^^^^A^y'

±

_L

_L

_L

10 15

Fresh weight / mm v/ateruse

Fig. 5. Relation between dry-weight percentage and the ratio fresh- weight/total water
use. The curves are valid for the indicated depths of the ground-water table. For key
see Fig. 3.

in direct evaporation from the soil. From the relation y = mx between
dry-weight yield (y) and total water use (x), the tangent is

}ii= o-oo3o62r +0-594
+ 0-00099 ± 0-039

where z is the depth of the ground-water level.

Some remarks might be made when comparing yield and water use in
the greenhouse with that under field conditions. From a physical point of
view, evaporation has been studied in many ways on a basis of energy
balance, in which net-radiation equals sensible and latent heat. Because

254 J- F- BIERHUIZEN

of the rather low energy consumption in growth compared with the other
terms in the heat balance, the energy consumption is not included in such
calculations. In photosynthesis experiments with algae and leaves of higher
plants, conversion yields between lo and 20% are obtained between COg-
consumption and absorbed visible radiation. In the field, energy conversion
of growth is only i to 2% (Wassink, 1948). In our greenhouse experiments
a value of 3-3% was calculated (Bierhuizen, i960). The 1-5 times larger
value in the greenhouse, still does not effect the individual terms of the
energy balance to a large extent. It is possible, therefore, that total water
use per kg dry matter produced, is 1-5 times less in the greenhouse. In our
case, for y = o-7ix, 100 mm water use produces 71 gm per 0-2 m^ or 36 kg
dry matter per 100 m^. The same amount of grass yield would necessitate
170 mm of water (Visser, 1959), which is approximately 1-5 times more
than in the greenhouse.

GROWTH AND WATER USE OF LETTUCE

IN DIFFERENT SEASONS

From the results discussed in the preceding sections, the length of growing
period and the total water use necessary for a given yield in different
seasons can be predicted. In Table i calculations are given for lettuce
planted at different dates (column i). It was assumed that harvest took place
with a head-weight of 150 gm. In our case 4 heads per container yielded,
therefore, 600 gm. From daily radiation (De Vries, 1955) and temperature
data in the greenhouse (ranging between 5° and 23°C for winter and
summer) the date of harvest (column 2) was calculated, using formula i.
Radiation data alone can be used without a large error, in order to facilitate
the calculations. In that case the total radiation is approximately 10,000 cal
cm-2 (Fig. 3). The harvest dates, calculated in this way, are confirmed by
those in horticultural practice. Total water use (column 4) could be read
from Fig. 4. The average daily radiation for each growth period could be
calculated and is approximately 10,000 cal cm^^ divided by the number of
days of growth. From this value, pan-evaporation in mm per day (colunm
6) could be read from Fig. i . The ratio water-use pan-evaporation approxi-
mates closely unity and tends to decrease in the summer months and to
rise in winter. The variation in this ratio agrees with that obtained in water-
balance studies in the field (Bloemen, i960). The steeper decrease in
summer in Bloemen's results, might be due to the fact that deeper ground-
water levels existed.

GROWTH AND WATER USE OF VEGETABLES 255

Table i

Growth and Water use of Lettuce to a head-weight of 150 gm in different

seasons

(I)

(2)

(3)

(4)

(5)

(6)

(7)

Date of

Date of

Growth

Total

Water

Pan-

Ratio

planting

harvest

period

water

use

evapora-

water-use/

in days

use in

in mm

tion

pan-

mm

per day

in mm
per day

evapora-
tion

Jan. I

March 29

89

55

0-56

0-50

I-I2

Feb. I

April 4

64

55

0-78

0-75

1-04

March i

April 15

46

55

1-09

1-20

0-91

April I

May 3

33

55

1-52

1-75

0-87

May I

May 26

26

55

1-92

2-35

0-82

June I

June 23

23

55

2-17

2-70

o-8i

July I

July 24

24

55

2-o8

2-35

0-88

Aug. I

Aug. 29

29

55

1-73

i-8o

0-96

Sept. I

Oct. 13

43

55

i-i6

1-20

0-97

Oct. I

Feb. 6

98

55

0-5I

0-40

1-27

Nov. I

March 15

136

55

0-37

0-35

106

Dec. I

March 24

115

55

0-44

0-40

I-IO

Calcu-

lated

columns

columns

columns

from

formula i

2 and I

fig- 4

3 and 4

fig. I

5 and 6

Although for practical irrigation purposes other water losses than those
calculated in Table i, column 5, may be of greater importance, the calcula-
tions made in Table i make it possible to give some indications of the
irrigation frequency to be used for a particular crop in different seasons.
Assuming a root depth of 50 cm and an available quantity of water between
field capacity (pF 2-0) and wilting point (pF 4-2) of 12% by volume, the
total amount of available water is 5 x 12 = 60 mm. If one fourth or 15 mm
can be used without decreasing fresh weight and quality of vegetables, the
irrigation frequency in different months can be given, using values of pan
or water use per day (columns 6 and 5 respectively).

SUMMARY AND CONCLUSIONS

Some relations between yield, water use, temperature and radiation in a
greenhouse were given and discussed in this paper. It appears that radiation

256 J. F. BIERHUIZEN

is far more important for growth in greenhouses than temperature. There
is a Hnear relation between total water use [x) and dry weight yield (y) of
the form y = mx, the constant m being dependent upon the depth of the
water table. Using radiation and temperature data, a prediction of a certain
yield or length of growth period can be made. It is possible, using total
radiation and heat sum, to compare yield in various greenhouses in order
to study the effect of glass-cover, soil type and other factors on growth.
The above mentioned results were obtained under optimal soil moisture
conditions. At present a study is in progress on the relation between yield
and water use, total radiation and heat sum, under various sub-optimal
soil moisture conditions.

REFERENCES

BiERHUiZEN, J.F. (i960) De relatie tussen teniperatuur en licht en de opbrengst van

verschillende tuinbouwgewassen in kassen. (The relation between temperature,

light and yield of various vegetables in a greenhouse. Dutch with an English

summary.) Med. Dir. Tuinhouw, 23 (12), 822-831
BiERHUiZEN, J.F. & Vos, N.M. DE (1958) The effect of soil moisture on the growth

and yield of vegetable crops. Report Conference on Suppl. Irrigation, Commission

VI, Int. Soc. Soil Sci., Copenhagen, 83-92. Techn. Bull. Il, 1959. Inst, for Land and

Water Management Research, Wageningen.
Bloemen, G.W. (i960) Het onderzoek naar de waterbalans van landbouwgronden

(Investigations on the water balance of agricultural soils, Dutch.) Med. Cultuur-

tcchn. Vereniging, 4 (i), 3-25.
BoHNiG, R.H. & Burnside, C.A. (1956) The effect of light intensity on apparent

photosynthesis in leaves of sun- and shade-plants. Am. J. Bot. 43, 557-56i.
DE Vries, p. a. (1955) Solar radiation at Wageningen. Med. Landbouwhogeschool,

Wageningen, 55 (6), 227-304.
DE Wit, C.T. (1958) Transpiration and crop yields. I'ersl. Landbonwk. Ondcrz. 64 (6),

1-88. Med. 59, Instituut voor Biologisch en Scheikundig Onderzoek van

Landbouwgewassen.
Gaastra, p. (1959) Photosynthesis of crop plants as influenced by light, carbon dioxide,

temperature and stomatal diffusion resistance. Med. Landbouwhogeschool, Wage-
ningen, 59 {13), 1-68.
Makkink, G.F. (1957) Ekzameno de la formulo de Penman. Neth. J. Agr. Sci. 5,

290-305.
RijTEMA, P.E. (1958) Calculation methods of potential evaporation. Report Conference

on Suppl. Irrigation, Commission VI, Int. Soc. Soil Sci., Copenhagen, 15-24. Techn.

Bull. 7, 1959. Inst, for Land and Water Management Research, Wageningen.
VisSER, W.C. (1959) Crop growth and availabiUty of moisture. Techn. Bull. 6. Inst.

for Land and Water Management Research, Wageningen.
Wassink, E.C. (1948) De lichtfaktor in de fotosynthese en zijn rclatic tot andere

miheufaktoren. (The factor hght in photosynthesis and its relation to other

growth factors, in Dutch.) Med. Dir. Tuinbomi', II, 503-514.

PHOTOSYNTHESIS AND GROWTH OF A FIVE-
YEAR-OLD STAND OF POPLAR TREES IN
RELATION TO WATER ECONOMY OF THE SITE

H.POLSTER
Institute of Forest Science, Tharandt, E. Germany

It is generally known from studies of forest yield that the water supply of
trees in the stand profoundly affects growth and yield. The growth incre-
ment in times of drought is more or less impaired according to soil con-
ditions and site cHmate. There are many references to this subject in forest
hterature. Among others is Week (1948) who found out that the height
increment of spruces [Picea ahies) and "^mtsiPinus sylvestris) may decrease to
a third of the normal value (average of ten years or longer), as a con-
sequence of dry periods. Besides a very close correlation was to be seen
between growth capacity and rainfall over longer periods. While these
correlations are quite clear there is very Httle known about the correlation
of water supply and photosynthetic efficiency of trees in forest stands. The
first ecological investigations referring to this originate from Pisek and
TranquilUni (195 1, 1954), who determined the carbon dioxide exchange
(assimilation, respiration) as weU as the transpiration of 20-m high spruces
and beeches in forest stands. They found that the assimilation in the crowns
of their rather free-standing trees depended on the climate of the stand-
especially on hght, temperature and air humidity -as well as on the water
situation. The better the internal water balance of the tree, the less restricted
was assimilation intensity in periods of strong insolation or low air humidity.
Generally the trees' assimilation and transpiration reacted very sensitively
to disturbances of their water economy, although the top crowns main-
tained their metabolic activity longer than the rest of the tree.

Together with my assistant, Dr. Neuwirth, I investigated for the first
time in 1957 the photosynthesis and growth of trees in relation to water
economy in a dense though rather small and relatively young tree stand.
For that purpose we used a planting of five-year-old black poplars, about
7 m high. In Fig. i can be seen a schematic diagram of the stand. The stand
area was 0-0075 ha and the trees were planted on a grid system with 6 trees
in the N.S. Hnes and 16 in the E.W. lines. For assimilation measurements we
used the infrared absorption recorder 'URAS'. As in previous studies the
single leaves to be investigated were enclosed in containers made of a very

258

H. POLSTER

thin foil ('Klarzell'). The soil moisture was determined by means of the
thermal conductivity method of De Vries (1952) with special measuring
aggregates, constructed by Neuwirth. The water available for plants was
calculated from the observations in per cent of the available water maxi-
mum. Soil suction forces were measured by means of plaster blocks.

North
border

South
border

5cm

Fig. I . Schematic diagram of the test stand.

During the vegetation period and especially in the course of the drought
period in the end of June and beginning of July , the measurements of soil
moisture and suction forces showed great differences between the northern
and southern border of the stand, and this appeared to affect the photo-
synthetic efficiency of the trees. As can be seen in Fig. 2, the southern border
was always much drier than the northern one, though the borders of the
stand were only 5 m apart. During the drought period the northern border
dried temporarily to 30 cm depth, whereas the southern border dried to a
depth of 60 cm and more. Before and after the drought period more than
50% of the north border's moisture content was available for plants,
whereas already by May the south border was nearly dry in its upper layers.
The heavy rainfall in the second half of July succeeded only in soaking the
southern border soil for about a fortnight, while the soil of the northern
border remained effectively water-saturated until the end of September.

By means of six figures I want to show you now the influence of these
differences in soil moisture, surprisingly high for such a small stand, on the
photosynthesis of the trees.

Under normal conditions of soil moisture, it was to be expected for a
stand of light-demanding poplars, that the trees at the south border which

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 259

IV V VI Vl! VIII IX

wvo/0^13 ^ l[Z2 MM ^^ \Mm

>95 80-95 60-&O 40-60 20-40 5 - 20

mmN
30

20-
10-
cm"

0

10-

Irt

c

' ""

20-

£.

u

a

30-

Q

40-

50

60

IV

V

VI

VII

VIII

IX

Fig. 2. Soil moisture, percentage available maximum, and soil suction, atm., at the
borders of the stand. Values of soil suction are given as isolated numbers on the
diagram.

26o

H. POLSTER

L S

8-

4-

o

2-

20

28 . 6 . 1957.

Meteorological factor

Assimi lotion

North top

North bottom

South top

South bottom

~\ r

6

n r

8

— I 1 1 T"

lO 12

— 1 r-

14

— I r

16

20h

Fig. 3. Assimilation in different crown regions at the borders of the stand. L= light
intensity in 1000 lux; S = water vapour pressure, mm mercury.

were more exposed to light than the others, would show a stronger assimi-
lation than those of the north border. As a matter of fact, the following
figure proves the contrary for the dry period in summer (Fig. 3). The tree
of the northern border, better supphed with water, shows a much more
active assimilation in its top and also in its crown base than that of the
southern border. Moreover the difference between the crown tops wliich
are almost equally illuminated, is greater than that of the crown bases,
which means that compared to the water factor the hght factor plays only a
subordinate role in the intensity of photosynthesis of the poplars during dry
periods.

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 261

10. 7. 57.

L S
-20

40

20

10

10-

8-

* 6-

O
U
01 4

E

2-

Meteorological factor

Assimilation

1st tree

2nd tree

3rd tree

4th tree

—\ —

leh

Fig. 4. Assimilation in crown tops across the stand. L and S as in Fig. 3.

If one considers not only the border trees but also the trees standing
between the northern and southern border (Fig. 4), one will find a correla-
tive ascent of the assimilation intensity corresponding to the soil moisture
from the southern border across the middle of the stand to the northern
border. As the curves show, tree No. 2, standing very close to the southern
border, is still completely under the influence of the southern border's
dryness; tree No. 3 in the middle of the stand, reaches almost the assimila-
tion eflficiency of the northern border tree in the morning, but at midday it

262

H. POLSTER

still suffers a similar assimilation depression to its southern neighbours. The
ratio of photosynthesis intensity of the south border tree compared to that
of the north border tree was on that day approximately 1:4. As the
measurements were made agaiia with leaves of equally illuminated crown

L S

-20

40--I0

20

16,7. 57.

Meteorological factor

8-

■o

O
U

4-

Assimilation

North lop

North bottor.1

South top

South bottom

— r-
8

— r—
12

— T r

14

10

16

18

20 h

Fig. 5. Assimilation in different crown regions at the borders of the stand with
sufficient water supply. L and S as in Fig. 3.

tops, it is evident that the water content of the soil is the limiting factor of
assimilation. The assimilation activity of the crowns increases with the
distance of the trees from the drier southern border and in parallel to the
increasing soil moisture of the site.
If the water content of the soil has such an important influence on the

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 263

assimilation activity of the trees, that it can become the decisive factor of
production in dry periods, it must also be shown how the hmiting effect
was again suspended, when the soil was naturally or artificially resaturated.
Eight days after the drought period the soil of the southern border was
water-saturated to a depth of at least 60 cm but the total assimilation activity
was not yet restored (Fig. 5). It can be seen that the tops of the northern
border still show the highest assimilation intensity. But they are closely
followed by the southern border base, then comes the northern border base
and finally the tops of the southern border. It is quite evident that when the
investigations were carried out the leaves of the tree on the southern border
had reached full turgidity only in the base fohage but not yet in the top
foHage.

In the course of the drought period, we interfered with the soil drying
process of some trees of the southern border by artificial irrigation. The
result of this measure is to be seen in Fig. 6. This time we measured the
assimilation intensity of the mean crown region. From June 29 to July 3 the
progressive soil drought affected photosynthesis in such a manner-upper
figure -that the incipient ascent in the morning -as a consequence of a
modest resaturation of the fohage during the night-was soon reversed.
Before the watering on June 29 the treated tree at the southern border
showed the same course of the assimilation curve, with a morning rise
after 6 o'clock, a steep fall after 9 o'clock and a continuous depression until
sunset. An intense soaking with 100 1. per square metre had already led to a
restitution of half of the assimilation activity by the next day, and to a total
one on the following day: the curve of July 7 holds the level reached at
7 o'clock in the morning-notwithstanding a httle decrease -until about
3 o'clock in the afternoon, whereupon stomatal closing and a fall in
assimilation occurred as a consequence of the great air dryness (maximum
saturation deficit 'S'). It is quite evident that in COo-absorption the hght
factor docs not play an essential role here either.

As is known, too great or too small a quantity of hght may hmit the
activity of photosynthesis, when there is a sufficient water supply. Measure-
ments with a poplar of our stand in the course of a cloudy day with hght
fluctuations between 2000 and 12,000 lux have resulted in an almost
synchronous course of hght intensity and assimilation (Fig. 7). The results
may be re-arranged to reveal an almost hnear relation between assimilation
and hght intensity, as shown in the lower half of the figure. The hmiting
effect of high radiation was revealed by measurement in the Hungarian
Alcah Steppe with single trees of the common oak and the so-called
'Zerreiche' [Quercus cerris). 1 may insert here two figures and two illustra-

18

264

H. POLSTER

Assimilation

6-

fM
O

u

2-

unwatered 29.6.1957.
2.7.\957.
3.7.1957.

—\ 1 1 1 — ■ — I 1 1 1 1 I I I 1

8 lO 12 14 16 18 20h

Assimilation

6-

o> 4-

O
O

unwatered 29 6.1957

watered 2.7.1957

3.7.1957

— 1 1 1 1 1

16 18 20h

-| 1 1 1 1 1 1 1 r-

6 8 lO 12 14

Fig. 6. Assimilation in crown tops of the south border on different days, in dry soil

and after watering. S as in Fig. 3.

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 265

tions. These trees are outposts of a natural remnant forest of the Hortobagy-
PuBta near Ujszentmargita with a tree and bush vegetation of Quercus
rohur, Quercus cerris, Acer tataricurn, Fraxiniis excelsior, Pyrus communis and
Prunus spinosa. The investigations were carried out on sunny days in August
at maximum temperatures of more than 30°C and relative air humidities of
less than 40%. Besides the carbon dioxide assimilation, transpiration was

25.7. 1957.

Light intensity

10-

? 8

O
U

2-

(b)

1 T"

5 10

Light intensity ,1,000 Lux.

Fig. 7. Assimilation in the minimum region of light: (a) daily march, (b) dependence

on light.

266 H. POLSTER

also measured by URAS instruments. During the test days evaporation on
the open steppe reached maxima of more than i-2 cc. H2O per hour. As
the accompanying photographs will show, the crown formations of the
two oak species are fundamentally different. As an 'out-post' of the steppe,
Qnerciis rohur has formed a globose crown (Fig. 8), whereas Qtiercus cerris
has a thin-fohaged, largely extended one (Fig. 9).

With both species we investigated comparatively the gaseous exchange
of the fohage of the southern crown side, of the crown's interior, and of the
northern crown side. Consider first the daily course of the thin-fohaged
Quercus cerris (Fig. 10). While in the forenoon the southern crown side is
most active in both assimilation and transpiration, it is quite the reverse in
the afternoon: at highest insolation and evaporation the leaves of the
crown interior assimilate and transpire more intensively than those of the
southern crown side. The excessive insolation together with the high
temperature lead to stomatal closing and rapidly faUing assimilation, as is
shown by the transpiration and assimilation curves of the southern crown
side. The highest assimilation rate is found in the crown interior in the
afternoon, whereas in northern, shaded, side of the crown, photosynthesis
remains at a low level during the whole day. On the other hand the thick-
foHaged common oak {Quercus rohur. Fig. 11) behaves quite differently in
these extreme site conditions. The crown interior of that species is much too
shaded for a great activity of gaseous exchange to be possible. But it is not
the southern crown side either which shows the strongest assimilation, but
the northern crown side, which is protected from insolation. As the colunms
show, neither Quercus rohur nor Quercus cerris-in 'outpost position' and
under conditions of summer chmate in the Hungarian steppe-reach their
highest assimilation rates at the southern crown side, where there is
maximum exposure to hght, but always in that part of the crown which
possesses the best metabohc activity in moderate shade. Because of the low
light required for maximum assimilation, tliis occurs in Quercus rohur on
the northern crown side which hardly receives any direct sunlight during
the whole day, whereas, with Quercus cerris, it is the interior of the crown
which profits in the light shade of its own fohage from intense side insolation
in the morning and in the afternoon.

To return to the five-year-old black poplar stand, we determined the
daily amount of assimilation in the base and top regions comparatively for
the stand borders and the stand interior, during the drought period and
after rain (Table i). The weak efficiency of photosynthesis of the southern
border trees and the liigh efficiency of the northern border ones is readily
recognised. After rainfall assimilation is generally higher but still the

WW: ■ -^

Fig. 8. Common oak {Qtiercus robiir) with dense crown in outpost position ot the
forest steppe.

[facing p. 266

Fig. 9. Qucrciis ccrris wirh thin-foliagcd crown, filled with light, in outpost position
of the forest steppe.

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 267

16 18

Bg 000000000000

i-o-

e 0-6

O

I

02-

Transpiration

10

-T

12

14

16

IB

W^

\7 south side of the crown

^ crown interior

▼ north side of the crown

Fig. 10. Assimilation and transpiration ofQuercus ccrris in different regions of the crown,
24/8/59; outpost of tiie forest steppe. S = total radiation, C3.l./cm?/imn; T=air temp,
°C; rF= relative humidity of air, percent; W=wind velocity, m/sec; Bg= cloud
cover (Bedeckungsgrad) .

268

H. POLSTER

S T

l-O

0-5

30

20

/ ..;.\

-...T rF W

' ■• I00t2-0

1 1 1 1 1 1 1 T 1 1 1 I I

6 8 10 12 14 16 I8h

Bg 0000000000000

25-8

l-O

'^e 0-6

O

I

°'0-2

Tronspiration

-1 1 1 r

8

10

12

14

I8h

AIA

/\ south side ol the crown

A crown interior

iL north side of the crown

Fig. II. Assimilation and transpiration of Quercus robur in difFerent regions of the
crown, 24/8/59; outpost position of the forest steppe. Key as for Fig. 10.

PHOTOSYNTHESIS AND GROWTH OF POPLAR TREES 269

Table i
Daily assimilation across the stand, mg COg/g/day

South

North

Day

border

2nd tree

3rd tree

4th tree

border

21-6

54-9*

48-7*

—

30-0*

36-1*

26-6

9-7
10-7

23-1
27-5
26-5

42-5*

28-1

23-4

56-1
591

8-3*

5<5-3l J . ,
63-8 ^'^"""g the
J drough period

13-7

41-9

64-0

—

—

i03-3-^

15-7

53-1

82-0

—

—

95-8 L after rain

16-7

43-2

7I-I

82-2

—

87-2]

* In crown base; other figures in crown top.

highest rate is in the northern border top. The top fohage of the stand
interior assimilates better, the closer the trees stand to the moister north
border. However, if one considers the assimilation of the base fohage, one
fmds a reverse arrangement, though much diminished, from the southern
border across the stand interior to the northern border. This is not at all
surprising, as here the hght factor dominates over the water factor. For one
thing the base fohage is always better supphed with water than the top
fohage, which leads to some diminution of the difference, and for another-
and this is the decisive fact-the hght reaching the base foliage of the stand
interior hes distinctly in the minimum range.

As has already been mentioned the assimilation measurements were
carried out during and shortly after an extreme period of drought. Two
days after the beginning of the heavy rainfall in July the soil of the whole
stand area was totally saturated to a depth of 50 cm and in spite of that, still
one week after the beginning of the rainfall, the tops of the northern border
trees assimilated twice as strongly as those of the southern border ones. As
the loamy-sand soil of the site dried up rather quickly -in the humus-
bearing upper layer a field-capacity with a water-content of 1 5 % by weight
was measured, whereas in the layers of more than 25 cm soil depth the
percentage was only 7-8%-the southern border of the stand was for the
greater part of the year drier than the northern one, which affected not only
the metabohsm but also the vigour of growth. This is quite obvious in the
concluding table (Table 2). Not only in stem height but also in stem dia-
meter (measured one metre high) the trees of the north border are superior
to those of the south border. But while the trees increase continuously in
their stem height from the south border to the north border, the stem

270 H. POLSTER

diameter of the stand interior decreases quite obviously when compared
with the border trees: a fact which is well known from forest practice,
especially when there is a greater stand density. However, we are interested
above all in the correlation between water supply, assimilation efficiency
and growth capacity, which is to be seen most distinctly with the border
trees, and about that the reported facts informed us thoroughly.

For a final observation I want to deal briefly with a problem which is of
the greatest importance for assimilation and transpiration physiologists. I
think that it emerges clearly from my results that the assimilation values
found for leaves or needles in any one crowm region, are never representa-
tive for the whole tree, and certainly are not so when the measurements

Table 2
Stem height and diameter across the stand

South North

border 2nd row 3rd row 4th row 5th row border

Stem diameter 5-2

(cm in I m height)
Stem height (m) 5*09

4-8

4-2

4-3

5-4

6-4

5-32

5-21

5-S^

6-03

6-15

maximum deviation: 0-49 m stem height,
average deviation: ± 0-33 m stem height.

have been made under extreme conditions of cHmate and site. The simple
transference of such values to the tree through multipHcation by the total
quantity of foHage is in any case faulty, if not false. Also the determination
of the difference of the carbon dioxide content in the air above the stand
and in the crown space, as performed by Huber and his collaborators, is
not reUable enough for a clear conception of the dry-matter production of
forest stands. If we wish to obtain an approximately true picture of the
dynamics of dry-matter production of trees and do not wish to renounce
determinations of assimilation as a physiological guide to the productivity
of adult trees, then- and this is how I estimate the present situation of
experimental forest ecology- there remains only a comparative determina-
tion of the assimilation efficiencies of the leaves in the different crown
regions.

This is the course we are following.

PHOTOSYNTHESES AND GROWTH OF POPLAR TREES 271

REFERENCES

DE Vrles, D. a. (1952) A monostationary method for determining thermal conductivity

of soil in situ. Soil Science, 73, 83.
PiSEK, A. & Tranquillini, W. (195 i) Transpiration und Wasserhaushalt der Fichte

{Picea excelsa) bei zunehmender Luft- und Boden- trockenheit. Physiol. Plant. 4, i.
PiSEK, A. & Tranquillini, W. (1954) Assimilation und Kohlenstoffhaushalt in der

Krone von Fichten- {Picea excelsa Link) und Rotbuchenstammen {Fagus silvatica

L.). Flora, 141, 237.
Weck, J. (1948) Forstliche Zuwachs- undErtragskunde. Radebeul and Berlin.

HYDRATURE AND PLANT PRODUCTION

K. Kreeb
Botanisches Institut, Stuttgart-Hohenheim, West Germany

MEANING OF HYDRATURE

The term 'hydrature'* was introduced in 193 1 by Walter (193 la). By it he
meant the availabiUty of water to plants. In respect to the water economy
the important thing is not the quantity of water but its chemical potential.
This point has been explained further by Walter in 1955 in a paper written
in Enghsh. As an example we can state: If we irrigate pot cultures with 1 1.
of water or with i 1. of a i mol NaCl solution, an appreciable difference
exists, even if we use same amounts of water in both cases.

The word hydrature can be used for any system containing water, for
instance solutions, soil, humidity of the air, or imbibed materials. Here
mainly the hydrature of plants will be considered, because any change in
the water factor outside a plant will be reflected in its hydrature. On the
other hand, we are able to check the water condition at a certain location by
measuring a plant's hydrature. In that case the plant itself is used as an
indicator.

Generally hydrature {hy) can be measured and expressed by the 'relative
humidity'. We say (see Walter, 1950, page 66) :

hy = —.100 = percentage relative humidity
Po

(p = actual water vapour pressure, po= saturation water vapour pressure at

* 'Hydrature' as a term should not be used interchangeably with 'hydration' as
the terms do not have identical meanings. The word hydrature can be compared with
'temperature', which means the condition not the quantity of heat. Accordingly,
hydrature does not depend on the quantity but on the condition of available water.
'Hydration is a chemical and physical term and means the state of being supplied with
water. It is the English verb "hydrate" meaning "to add water to", converted to a
noun by adding the common suffix "ion". Hydrature is the Greek noun "hydro"
(water) plus the Latin termination "ura" or "atura", much used to denote condition
of or effect of, as in juncture, aperture, temperature etc. . . . Accordingly there is a clear
parallelism in the words "hydrature" and "temperature", particularly as employed in
physiology. Temperature is measured in degrees, hydrature in osmotic pressures, . . .
but hydration by a water content determination, hence it is entirely different' (written
notice from Prof. J. C. Russel, Lincoln, U.S.A.).

HYDRATURE AND PLANT PRODUCTION 273

a certain temperature). From, hy we can compute the osmotic value* (W) :

.^. 1000. RTs, p

W= — In —

M Pq

(R= gas constant, T= absolute temperature, 5 = specific weight of water at
20°C = o-9982, M=molecular weight of water=i8.) After introducing
the constants we have :

W= — I334ln.-^ = —3071 log ^
Po Po

Because of this relation between the osmotic value of a solution and its
relative humidity (one may imagine that in closed containers there always
exists equilibrium between the osmotic value of the solution and the
relative humidity in the air space above it) we can use either the relative
humidity or the osmotic value to indicate hydrature.

For the determination of hydrature in plants we generally use the osmotic
value of the cell sap. From the equation : S= H^— Pit may be concluded that
the suction tension (5) might be the better expression for the hydrature of
plants (see Renner, 1933a and b; Huber, 1932; Fukuda, 1935; Stocker,
1954). But it can be answered that the suction tension represents only the
hydrature outside a cell, which must be considered as responsible for the
change of water from cell to cell. The osmotic value represents the hydra-

* In order to avoid confusion we shall list here abbreviations used regarding osmotic
terms :

DPD (diffusion pressure deficit) = 5 (suction tension)
OP (osmotic pressure) = W (osmotic value)

TP (turgor pressure) = P (turgor pressure)

Of the expressions mentioned above, the most erroneous is 'osmotic pressure,' as in
reality we are unable to measure such a pressure in solutions. The 'real' osmotic pressure
(in German 'osmotischer Druck') wliich actually exists, develops as hydrostatic pressure
in an osmometer for instance. Its equivalent in the cell is the turgor pressure. Both the
actual osmotic pressure and the turgor pressure act as back pressure which determines
together with the osmotic value the resulting suction tension in an osmotic system. In
order to distinguish exactly between the meanings of the equivocal term 'osmotic
pressure' (in the sense of osmotic value and actual osmotic pressure = hydrostatic
pressure) we suggest using principally the term 'osmotic value' (meaning the chem-
ical potential) instead of osmotic pressure. And because it is physically more useful
to compare only measurable quantities (diffusion pressure cannot be directly deter-
mined, see Walter, 1955), it should be obviously better to write the osmotic equation
not as: DPD = [OP — TP], but in the manner:

5= W-P

In this paper we shall use only these abbreviations and terms.

274 K. KREEB

ture inside a cell. It is in equilibrium with the hydrature of the protoplasm
(its imbibition) where hfe processes such as growth, respiration and
photosynthesis are located. Because it depends on the factors mentioned
and upon how much a plant produces, we are practically compelled to
understand by the hydrature of plants generally that hydrature inside cells,
which can be expressed as the osmotic value of the sap.

Recently Kreeb (1960b, 1961b, see also Kreeb and Onal, 1961) measured
the suction tension using the gravimetric method (Slatyer, 1958) which has
been improved and checked with solutions of known osmotic values.
Thereby it was foimd in laboratory experiments that in the case of evergreen
Mediterranean plants the suction tension may rise more than 60 atm above
the osmotic value of the sap in still-hving plants. That means a 'negative
turgor pressure' of the cells. Ecologically it does not play a very important
role (see Kreeb, 1961b). However in some cases it does exist under natural
conditions. In comiection with this we have to ask if the hydrature of living
plants can be affected by a negative turgor pressure. It is difficult to under-
stand, how this could come about, as it represents only a cohesion tension,
which probably does not change the imbibition state of the cytoplasm as
in the case of changes in the osmotic value of the sap. For that reason the
osmotic value has to be considered as the main factor determining the
hydrature of plants.

METHODS

I. Sampling. Because of daily changes in the osmotic value of plants,
samphng should always be done at precisely the same time of the day. We
prefer 12-2 a.m., in order to get extreme values. Insertion, age and general
condition of leaves should be considered, because it is very important to
have a uniform material which is easily comparable. The proper approach
appears to be to collect an average sample at a certain place, using at least
20 leaves, leaflets or leaf parts, each having the size of about 10 cm^. This
reduces the error of parallel measurements normally to less than i atm.
2. Extraction of cell sap. After samples have been collected in glass con-
tainers, sealed with rubber corks, they have to be kept in aluminium boxes.
One should ensure that the cover of the aluminium box presses the cork
well onto the glass container, and therefore prevents water losses by
evaporation. After destroying the semipermeability of the cytoplasm by
boihng the samples (i 5-20 min in the water bath), sap can be obtained using
a hydrauhc press. The press-set, after Walter, was described in 1928. By
adding a piece of thymol to the solutions they can be stored for several

HYDRATURE AND PLANT PRODUCTION 275

weeks in the refrigerator without clanger of chemical changes due to
bacteria or fungi.

3. Deteniiiiiatioiis of the osmotic values of the sap can be acconiphshed by
the 'cryoscopic method'. Thereby the freezing point has to be determined.
Because this apparatus is generally known we refer to the comprehensive
literature given by Walter (1931b) and Kreeb (1961a). Recently Kreeb
(1957)5 see also Slavik (1952) used a cryoscope without air space around the
sap container and an automatic stirring mechanism. These changes of the
apparatus have the advantage of less variation between various determina-
tions. Modern cryoscopes are fitted with a freezing apparatus and
thermostat.*

4. Calculation of the osmotic pressure can be done by the formula:
W= i2-o6 A (A = freezing point depression). Tables for direct readings are
available (Walter, 1931b; Walter and Thren, 1934).

OSMOTIC VALUE OF PLANTS AND YIELD

Initial observations regarding the relation between growth and osmotic
values (hydrature) were reported by Walter (1931a). He found that the
curves of osmotic values from plants grown at different locations {Solamim
elaeagnifoliimi) show a good relation to the height of the shoot. Later
Stieghtz (1936) worked with winter wheat and tested the production in
two different years: In 1934, which was a relatively dry year, osmotic
values were high, up to 25 atm, and the yield was only approximately 50%
(grain) of the amount in 1933 (year with normal weather). With straw the
difference was even greater.

Lobov (195 1) reports field experiments, whereby various plots, planted
with cabbage, potatoes and tomatoes have been irrigated only after a
maximum osmotic value of 8, 10 and 12 atm respectively (Table i) had been
exceeded. Generally it was found thereby, that with the rise in osmotic
values the yield docs decrease. This is not entirely true for tomatoes, as he
reported no significant diminution in the yield between 8 and 10 atm.

Yet it may be asked whether the result would not be different, if not only
fruits, but the total production had been measured. This assumption can be
made from the fact that tomatoes show a decrease in the production of
fruits under extremely moist conditions. This does not dispute the general
relationship between yield and osmotic values, but it should be considered
because not all factors which affect yield show an influence on the osmotic

* The cryoscope of Drucker-Burian-Kreeb : designed and manufactured by W.
Schulze, Heppcnheim a.d.B., Schunkengasse Nr. 7, West-Germany.

Yield in

100 kg/ 1 0,000 m^

A

r

Cabbage

A

Potatoes

217
183
152

■\

(

Var. I Var. 2
463 500
418 400
217 263

Tomatoes
530
540
420

276 K. KREEB

Table i

Maximum osmotic values, number of irrigations and yield of cabbage, potatoes and

tomatoes. After Lobov, 195 1

Number of
Maximum irrigations at
W 4 replications
8 5,3,5,5

10 3, 2, 4, 3

12 I, I, I, I

value itself. Hydrature of plants seems to be a very important condition for
plant production especially in arid countries and dry years, if not the most
important one, besides other factors such as nutrition, temperature, light,
diseases, etc.

Bauman (1955) in Canada worked with irrigation experiments using
alfalfa, wheat, barley, oats, sugar beet and potatoes. He found that time of
irrigation can be better determined by hydrature of plants than by soil
moisture measurement (Bouyoucos-block, tensio meter). Yield and average
osmotic value showed a close relationship (Table 2). Generally it can be

Table 2

Average osmotic value in atm {W) and yield of various crops (after Bauman, from

Walter, 1956; see also Walter, 1961)

Alfalfa, ist cut

W

10-6

II-5

II-9

14-7

17-2

19-8

t/acr

10-9

8-6

9-7

7-4

5-2

3-6

Alfalfa, 2nd cut

W

IO-3

10-4

10-9

13-1

14- 1

30-3

t/<Lcr

9-7

9-2

7-6

6-2

5-7

0-34

Thather wheat

W

10-5

10-7

II-7

II-9

12-3

12-8

bsh/acr

37-0

36-2

35-0

31-3

27-9

27-2

Lemlu wheat

W

10-4

ii-o

ii-i

II-3

11-4

12-2

bsh/acr

47-7

45-5

33-4

31-2

35-9

31-2

Montcalm barley

W

10-3

10-7

II-8

12-0

12-6

14-6

bsh/acr

48-3

46-3

40-2

40-7

35-9

30-7

Eagle oats

W

9-4

lO-I

10-4

10-6

II-O

14-4

bsh/acr

95-2

77-9

67-7

7I-I

66-5

62-8

Sugar beet

W

I2-I

12-6

13-2

13-6

13-6

22-4

t/acr

15-9

15-0

12-7

13-4

12-8

5-3

Potatoes

W

8-6

8-7

8-9

9-4

9-4

10-5

bsh/acr

363-0

276-0

294-0

238-0

202-0

70-0

HYDRATURE AND PLANT PRODUCTION

277

said that decreasing hydrature means diminution of yield, that is : the
higher the average osmotic value the low^er the yield.

Sprinkling experiments carried out by the author in Abu Ghraib, Iraq
(1956-58) produced identical results (Kreeb, 1957, 1961a). It was also found
that the curve of decreasing yield with increasing average osmotic values
shows the form of an e-function (see Figs, i and 2). This means, that the

0-6

06

CM

E

01

02

> •

\

straw
' • ears

0

• ^

\ . n

grams

•
°

Straw

•

X

' — — — _^^^

-0

X

13 1A 15 16

Average osmotic value in atr

17

Fig. I. Curve of decreasing yield with increasing average osmotic values in barley

(Trabot). After Kreeb, 1957.

Fig. 2. Curves of decreasing yield with increasing average osmotic values in lettuce,
turnips and horse beans. After Kreeb, 1958.

278

K. KREEB

first increase of the osmotic value above the optiniulm (=owest value
found under best water conditions and at a certain location and species)
lowers the production of plant material (vegetative and generative parts)
relatively more than at higher osmotic value levels.

Also most of the yield data given by Bauman (i955) follow the same
principle after being plotted against average osmotic values (Fig. 3). They
are calculated as mean between numerous measurements during the

12

50 10

AO 8

30 6

20 4

10 2

O O

□ 1 Sugar bezt
• 2 Alfalfa 1st cut
0 3 Alfalfa 2nd cut
4 A Mountcalm barley

A

^ 4 SEagle oats

V 7 6 Potatoes

3

100 500

SO AOO

60 300

AO 200

20 100

12

16 20 2A 28

Average osmotic value in atm

Fig. 3. Curves of decreasing yield with increasing average osmotic values in various

crops. After Bauman, 195 5-

vegetative period. The yearly curves of the osmotic values are clearly
related to the intensity of irrigation (Fig. 4) : i.e. the decreasing water
availabihty causes an increase in the osmotic value. At the termination of
the experiment we found the highest osmotic value (more than 25 atm)
at the plots (S 4) with smallest amounts of irrigation water (76-5 mm).
Plot S I with 'optimum hydrature conditions' (288 mm irrigation water)
showed contemporarily a value between 14-16 atm, and the plots S 2
(127-7 mm) and S 3 (84-2 mm) more than 16 atm and approximately 19
atm respectively at the same time.

It was interesting to observe in this experiment that the decrease of the
yield at lower hydrature conditions depends on the dinoinution of the
number of grains more than on size of the caryopsis. The seeds ripen fully
even under very poor water conditions which means that the reproduction

HYDRATURE AND PLANT PRODUCTION

i70

Fig. 4. Yearly curves of hydrature (osmotic values) of barley (Trabot) with different
water supply: Curve 81 = 288 mm; 82=127-7 nim; 83=84-2 mm; 84=76-5 mm.
After Kreeb, 1957.

5 B

/

>

0

L

a

/

y

origina

1 sap

10

/

E

/

0

in A

'v

y

/

>

y

/

^2
0

X

u
ro

I.

S 0

A 6 8

Osmotic value in atm

10

12

Fig. 5. Correlation between the osmotic value and refractometer value (percent
dissolved material) of alfalfa sap, diluted with water.

19

280

K. KREEB

of plants will be possible as long as plants are able to grow and to complete
their life cycle.

As a field method for determination of plant hydrature, Kreeb (1957,
1961a) suggested measurement of the refractive index rather than the
osmotic value of the sap. This can be simply done by a hand sugar-
refractometer, giving direct readings of dissolved material, per cent, in the
field. As long as changes in the cell concentration due only to water occur,
and not due to salts dissolved ( = active change of hydrature) a proportional
relationship exists between the osmotic value and the refractive index. This
can be seen from the data given in Fig. 5. In this case we used sap of alfalfa
which had been diluted with pure water to different levels of concentration.
From each of the prepared solutions we determined the osmotic value and
the refractive index. The correlation diagram shows very clearly the
relation between the values.

If we do not find a correlation between refractometer readings and the
osmotic value in yearly curves, we may then assume that changes in the

Fig. 6. Yearly curves of hydrature (osmotic values) compared with refractometer
values in turnips (above) and lettuce (below). Plots with optimum water conditions.
After Kreeb, 1961.

HYDRATURE AND PLANT PRODUCTION 281

amounts of dissolved materials occurred (see Fig. 6, lettuce). In this case
the refractometer values are only relatively valid. In order to avoid an
incorrect interpretation we use principally the refractometer method as a
relative method, i.e. : with tliis apparatus we only try to indicate a quahta-
tive change of plant hydrature. Yet, for many investigations and practical
purposes this is sufficient, because as soon as the refractive index rises we
do know that plant hydrature changes to less than optimum conditions.
Plants should be irrigated in that case.

The practical value of the refractometer method was tested and proved
with an alfalfa experiment in Abu Ghraib, Iraq in the summer of 1957,
after natural rainfall was over and when temperatures went up to about
50°C. Four treatments (2-4 replications) were watered after the refractive
index at the plots showed a value just higher than the optimum (= lowest
value possible), or higher than optimum +2%, optimum +4% and opti-
mum + 6% respectively. Because refractometer readings require a
minimum of time, it was possible to measure the hydrature of plants every
two days. The curves during that period (refractometer readings in
dissolved materials, per cent) can be seen in Fig. 7. All are clearly related to
the water supply, as also the curve of decreasing yield is to the average
refractometer readings for the various plots.

Also here (Fig. 8) we find the above mentioned characteristic: the
decrease in the yield is more evident initially than at higher levels of
refractometer reading.

Successful application of checking hydrature by the method of refracto-
meter determinations have been recently reported by Russian scientists
(Babuschkin, 1959; Belik, i960) for irrigation purposes.

If factors outside the plant as suction tension or soil moisture stress are
employed for checking plant production instead of the osmotic value of
the cell sap, it can be found that even then the curve of decreasing yield
shows the above mentioned characteristic: it is hke an e-fimction in shape.
For instance, Wadleigh and Ayres (1945) got a similar result with bean
plants.Recent data reported by Sands andRutter (1959) show that height of
shoots, length of needles, and dry weight o£ young Pinus sylvestris plants
produce similar curves (Fig. 9) when plotted against increasing suction
tension in soil. In addition to this even the curve of decreasing net
assimilation rate, representing the real production process, follows the shape
of an e-fimction.

Of course the decrease of yield with decreasing hydrature is appreciably
different in various crops. Those species which are relatively hygrophytic,
or even mesophytes, show a rapidly dechning yield curve. In plants which

282

K. KREEB

ia 22

MAY 1958

JUNE

Fig. 7. Yearly curves of hydrature (refractometer values) in alfalfa plots with different

irrigations. After Kreeb, 1961.

are able to endure drought to a certain extent we find a less rapid diminution
of the production. This can be seen from the following table (3).

Much affected by lack of water are horse beans, turnips, potatoes and
lettuce. Their yield decreases by approximately 30-50%, if the average

100

80

V

■>

E 60

AO

V

M 20

>-

\

"^

\

•

\

V

12 13 IA 15 16 17 18

Average refractometer value in %

Fig. 8. Curve of decreasing yield with increasing average refractometer value. After

Kreeb, 1961.

HYDRATURE AND PLANT PRODUCTION

283

2 3

Suction tension

Fig. 9. Curves showing the relation between length of shoot and needles, dry weight,
net assimilation rate and increasing suction tension in the soil. After Sands and
Rutter, 1959.

osmotic value rises by i atm. More resistant are barley, sugar beet, and
alfalfa. The accuracy of the given figures is not too great, as some of the
experiments have been made without replication. But it is conspicuous,
that in the case of barley, the data of Bauman (Canada) and Kreeb (Iraq) are

Table 3

Diminution of yield of various crops per increase of the average osmotic value (H^) by

I atm in percent maximum yield

lowest and highest

Diminution

Wat

the concerned

of yield

Author

Species

experiment

per I atm

A

(

^

Bauman

alfalfa

lO-O

30-0

4-8%

Bauman

sugar beet

12-3

22-4

6-8%

Bauman

barley

10-3

14-4

10%

Kreeb

barley

13-4

17-4

13%

Bauman

oats

9-4

II-O

17%

Kreeb

lettuce

IO-2

I3-I

32%

Bauman

potatoes

8-4

10-5

39%

Kreeb

turnips

II-8

13-5

39%

Kreeb

horse beans

10-5

I2-0

52%

284

K. KREEB

in very close agreement. The tendency concerning the water requirement
of the above mentioned crops is in hne with general observations in the
field. It may be of interest to note the fact that the abihty to resist drought is
in agreement with the salt tolerance of the plants listed in Table 3.

The effect of salts in saline soils upon plants is mainly an osmotic one
(Kreeb, 1959, 1960a), therefore we have finally to discuss how the yield of
crops will be changed if the hydrature of the soil decreases due to salt.
Relatively few data are available from field experiments under natural
conditions.

It is impossible to review here the comprehensive literature regarding
pot and solution cultures showing the effect of different salt levels on growth
and plant production. The following table (4) may give a general survey
regarding the decrease in harvested plant materials with decrease of soil
hydrature. The intensity of the effect differs with vegetative and reproduc-
tive plant parts and with different varieties of the same crop. In addition to
this a toxic effect, which will not be considered here, is found when different
kinds of salts are used in the experiments (see experiment with wheat by
Webster and Viswanath in Table 4). Because the plants were harvested 25
days after sowing, these figures may be regarded as only correct to a certain
extent. For practical purposes it is important to know the fmal effect on
harvested products.

Some interesting results were reported in mimeographs distributed by the
Development Board, Baghdad (1958), showing results found by Dutch
scientists: It can be seen with barley (Fig. 10) that increasing conductivity
of solutions prepared from saturated soil (meaning decreasing hydrature)
causes diminution of production (grains). It appears that again the first

600

o
Saoo

5^

2

200

•
ft

%••

0 \

1

O 5 10 15 20 25

Conductivity of saturation extract in mmhos/cm

Fig. 10. Curve of decreasing yield of barley (Murakish) with decreasing hydrature in
soil, expressed as conductivity of saturation extract. After Development Board Baghdad
1958.

HYDRATURE AND PLANT PRODUCTION

285

decline of the production curve is greater than later on. The same has been
found with green gram (Fig. 11). We may learn from this, that the direct
lack of water or lowered water availability due to salt depends on the same
basic fact: that is decrease of hydrature.

i:ju

\

lO'O

til
>

\

\

>

^50

\

Amoun

t of

k^

seeds

used

> •---<

t^

1

O 0-2 O-A 0-6 0-8

Salt content of soil in %

l-O

Fig. II. Curve of decreasing yield with increased salt content of the soil for green
gram. After Development Board Baghdad, 1958.

Certainly exceptions may occur, particularly if other factors are changed.
This can be illustrated by the following example (Fig. 12). If we increase
the salt content of the soil and at the same time also nutrients (nitrate) of the
soil, then no decrease in yield is found in case of barley because the fertilis-

0-1 0-5

% salts in so

Fig. 12. Yield curve of barley (Murakish) in relation to salt content in soil and nitrate
present. After Development Board Baghdad, 1958.

286

K. KREEB
Table 4

Diminution of yield, in percent, of control plants at various species by increased salt

content

Decrease

in yield

Salt content
control

A

(
Vegetative

Generative

Species

Author

-^experiment

parts

parts

Wheat

Hayward and
Uhvits*

o->4 at

25%

25%

Wheat

Webster and

0^0-4% NaCl

92-7%l

Viswanath

0^0-4% CaClj

74-0%
55-0% >

25 days

1921

o->o-4% MgCla

after

o->o-4% Na2So4

27-0%

sowing

0^0-4% MgSo4

17-0% J

(pot cultures)

Barley (8

Ayers and

o->o-9%

25%

0%

varieties)

Wadleigh*

Barley

Dev. Board

2->i8 mhos/cm

63% of

—

Baghdad, 1958

(saline land)

total yield

Tomatoes

Eaton, 1942

2 • 5 — > 6 at

73?/o

96%

Beans

Gauch and

Wadleigh, 1945

0-5 ^4- 5 at

63% of
total yield

Phaseolus

Dev. Board

0-1^1%

—

98%

mungo

Baghdad, 1958

(saline land)

Grape fruit

Hayward, Cooil
and Brown*

o-5->3-5 at

45%

■■■"

Alfalfa

Cooil and

o-5->6-5 at

var. a

Brown*

23%

var. b

28%

—

var. c

62%

var. d

64%

* After Hayward and Wadleigh (1949)

ing effect overcomes the salt effect. Above 0-5% salt in the soil however,
more fertiliser can no longer balance the salt effect, and the yield curve
declines. If the same experiment were carried out with non- salt-tolerant
crops (for instance potatoes) a typical e-function-shaped curve might be
obtained.

REFERENCES

Babuschkin, L.N. (1959) Diagnosen dcs Wasserbedarfs von Gemiisepflanzen auf
Grund der Saftkonzcntration. Fizlol. Rastctiij 6, 480-483, Russian.

HYDRATURE AND PLANT PRODUCTION 287

Bauman, L. (1955) Determination of the right time for irrigation. Phases, Periods and

Scales of Plant Hydrature. Author's mimeography.
Bauman, L. (1957) Uber die Beziehungen zwischen Hydratur und Ertrag. Ber.

dtsch. hot. Ges. 70, 67-78.
Belik, V. F. (i960) Die Bestimmung des Wasserbedarfs von Tomatenpflanzen durch

Messung der Saugspannung und der Zellsaftkonzentration der Blatter. Fiziol.

Rastenij, 7, 95-97, Russian.
Development Board Baghdad (1958) Dujailah Drainage Experiments Rep. Nr. 5.
Eaton, P.M. (1942) Toxicity and accumulation of chloride and sulfate. J. agric. Res.

64. 357-399-

FuKUDA, Y. (1935) Uber die Hydratur der Pflanzen mid eine empirische Formel der Verdun-
stung und Transpiration. G. Fischer, Jena.

Gauch, H.G. & Wadleigh, C.H. (1945) Effect of high concentrations of sodium,
calcium, chloride, and sulfates on ionic absorption by bean plants. Soil Sci. 59,

139-153.
Hayward, H.E. & Wadleigh, C.H. (1949) Plant growth on saline and alkali soils.

Advanc. Agronomy, I, 1-38.
HUBER, B. (1932) Besprechnungen Walter, H. : Die Hydratur der Pflanzen.

Bo/. 25, 631-635.
Kreeb, K. (1957) Hydratur und Ertrag, Ber. dtsch. hot. Ges. 70, 121-136.
Kreeb, K. (1959) Die Bodenversalzung als storender Faktor bei Fcldversuchen,

Wachstum und Ertrag. Ber. dtsch. hot. Ges. 72, 123-137.
Kreeb, K. (19603) Salzschadigung bei Kultur pflanzen. Pflanzenkr. Z. {Pfianzen-

pathologie) und Pjianzenschutz, 67, 375-399.
Kreeb, K. (1960b) Uber die gravimetrische Methode zur Bestimmung der Saug-
spannung und das Problem des negativen Turgors. Planta, 55, 274-282.
Kreeb, K. (1961a) Die Bedeutung der Hydratur fiir die Kontrolle der Wasserver-

sorgung bei Kulturpflanzen. Beitr. Biol. Pflanzen, 36, 57-89.
Kreeb, K. (1961b) Zur Frage des negativen Turgors bei mediterranen Hartlaub-

pflanzen unter natiirUchen Bedingungen. Planta 56, 479-489.
Kreeb, K. & Onal, M. (1961) II. Mitteilung. Die Beriicksichtung von Atmungsver-

lusten wahrend der Messungen. Planta 56, 403-415.
LoBOV, M. F. (195 1) Die Beziehungen zwischen dem Wachstum und der Zellsaftkonz.

der Pflanzen. Bot. Z. (Russian) 36, 21-28.
Renner, O. (1933a) Wasserzustand und Saugkraft. I: Erwiderung an H. Walter.

II: Berichtigung. Planta, 19, (1933b) 644-647.
Renner, O. (1933b) Zur Kenntnis des Wasserhaushaltes javan. Kleinepiphyten. Mit

einem Anhang zu den osmot. ZustandsgroBcn. Planta, 18, 215-287.
Sands, K. & Rutter, A.J. (1959) Studies in the growth of young plants of Pinus

sylvestris L. II: The relation of growth to soil moisture tension. Ann. Bot. 23,

269-284.
Slatyer, R.O. (1958) The measurement of DPD in plants by a method of vapor

equihbration. Aust. hiol. Sci. 2, 349-365.
Slavik, B. (1952) Der osmot. Wert der Holzpflanzen als Zeiger fiir ihre Standorts-

eignung. Tschechosl. Biologija, I, Nr. 2, Russian.
Stieglitz, H. (1936) BeitragezurZellsaftschemiedes Winterweizens. Z. /^(jM^reHcm.,

Diingung und Bodciik., 43, 152-170.
Stocker, O. (1954) Der Wasser- und Assimilathaushalt siidalgcr. Wiistenpfl. Ein

288 K. KREEB

Beitrag zum Xerophyten- und Halophytenproblem. Ber. dtsch. hot. Ges. 67,

288-298.
Wadleigh, C.H. & Ayres, A.D. (1945) Growth and biochemical composition of

bean plants as conditioned by soil moisture tension and salt concentration. Plant

Phys. 20, 106-132.
Walter, H. (1928) Uber die PreBsaftgewinnung fiir die kryoskop. Mess, des osmot.

Wertes bei Pflanzen. Ber. dtsch. hot. Ges. 46, 539.
Walter, H. (1931a) Die Hydratur der Pflanze. G. Fischer, Jena.
Walter, H. (193 ib) Die kyroskop. Best, des osmot. Wertes bei Pflanzen. Abderhalden.

Handb. d. biol. Arbcitsntcthodcn, Ahteil, XI, 4, 353-371-
Walter, H. (1950) Gnmdhgcn des Pfianzenlcbens. E. Ulmer, Stuttgart.
Walter, H. (1955) The water economy and the hydrature of plants. Ann. Rev.

Plant Physiol. 6, 239-252.
Walter, H. (1961) Die Hydratur der Pflanze als Indikator ihrcs Wasserhaushalts.

Handbuch der Pflanzencrndhrung; in press.
Walter, H. & Thren, R. (1934) Die Berechnung d. osmot. Wertes auf Grund von

kryosk. Messung. undderVergleichmitSaugkraftbest. J/). IViss. Bot. 80, 20-35.
Webster, I.F. &: Viswanath, B. (1921) Further studies of alkah soils in Iraq. Memoir

Nr. 5, Dep. of Agriculture (Baghdad).

A COMPARISON BETWEEN THE WATER
RELATIONS OF SPECIES WITH CONTRASTING
TYPES OF GEOGRAPHICAL DISTRIBUTION
IN THE BRITISH ISLES

Margaret S.Jarvis
Department of Botany, University of Sheffield*

INTRODUCTION

In the Sheffield region, where the experiments to be described were con-
ducted, many species of plants attain the north-western or south-eastern
limit of their range in Great Britain. The distribution of species such as
Prtinus padus L. and Saxifraga hypnoides L. corresponds with the predomi-
nantly upland part of Great Britain to the north-west; that of species such
as Thelycrania sangtiinea (L.) Fourr. (Cornus sanguinea (L.)) and Filipendula
vttlgaris Moench. with the more lowland part to the south-east. Hence there
are correlations between the patterns of distribution of the species and
various features of climate such as annual rainfall, amount of sunshine and
average maximum or minimum temperatures. Similarly, the distribution
of such species on slopes of various aspects in the Derbyshire dales can be
correlated with features of the microcHmate. Species at the south-eastern
Hmit of their range tend to exhibit preference for slopes of northerly
aspect, and, conversely, species at the north-western Hmit of their range
are restricted to, or most abundant on, the south-facing slopes.

Measureinents made with plaster-of-Paris electrical resistance blocks in
the summer of 1959 confirmed that on such south-facing slopes the soil
dried out more rapidly and to higher soil moisture tensions than the soil on
north-facing slopes. For example, after a fortnight without rain in August,
1959, the soil moisture tension at 4 cm depth was 20 atm on a slope of
south aspect and from i-i to 2-9 atm on the opposite slope of northern
aspect.

An investigation of the response of plants of these species to increases in
soil moisture tension and to low atmospheric humidity was made experi-
mentally in the course of an attempt to elucidate the factors which were
hiniting distribution. Two herbaceous species, S. hypnoides and F. vulgaris,
and two woody species. P. padus and T. sanguinea were used.

* Now at The Institute of Physiological Botany of the University of Uppsala,
Uppsala, Sweden.

290 MARGARET S.JARVIS

THE RELATION OF GROWTH TO SOIL MOISTURE

REGIME

Method. In this series of experiments the plants were grown at three
controlled soil moisture regimes. In the first the soil v/as kept watered so
that measurable soil moisture tensions did not develop; in the second and
third the soil was allowed to dry out to pre-deter mined levels of soil
moisture tension (SMT) before watering took place. Results, from field
experiments particularly, on the relation of growth of plants to soil mois-
ture conditions, have often been confused by the difficulties involved in
obtaining an integrated value of the soil moisture tension in the soil
actually exploited by the root system, and also by differences in the rate of
extension of the root system into regions of moister soil. In order to control
these factors it was considered essential that the plants used in these experi-
ments should be grown in containers, so that there would be uniform
exploitation of the whole enclosed volume of soil by the root systems and
consequent even drying-out. The containers were circular polythene
bowls, 30 cm diameter, 13 cm deep. The same type of soil was used in all
these experiments, and in all other experiments described in this paper.
This was a limestone soil, from Haydale, Derbyshire, on which all the
species grew well, so that nutrient and aeration factors were unlikely to
be limiting.

The soil moisture tension was measured daily, using Bouyoucos plaster-
of-Paris electrical resistance blocks. These had been placed in the centre of
the volume of soil in each container at the time of planting. The blocks
were calibrated in a modified form of a Richards' pressure membrane
apparatus (Richards, 1941). The structure and manufacture of the blocks
and the apparatus used for calibration have been described in detail by
Jarvis, M.S. (i960).

The experiments were carried out in the summer of 1959 in an unheated,
well-ventilated glasshouse. The position of the containers was altered daily
to minimise the effect of gradients of temperature and light. Measurements
were made at the beginning of the experiment and at intervals, for ten to
twelve weeks. Total leaf area was used as the most suitable estimate of
growth which could be made on species of different growth forms without
destroying the plants. The length of each lenfofFilipendula vulgaris, and the
length and breadth of each leaf of Thelycrania sangninea and Pmmis padus
were measured and the leaf areas were calculated from relationships
established from samples of leaves taken at the end of the experiment. The
projected area of each plant o£ Saxifraga hypnoides was measured. The num-

WATER RELATIONS OF SPECIES: COMPARISONS 291

ber of plants per container was 7 for F. vulgaris; 36 for S. hypnoides; 4 for
T. sangiiinea; and 4 for P. padns. The containers were not replicated.
Results. Results for the four species are presented in Tables i(a)-(d).

Considering first the herbaceous species, it is apparent that growth of
S. Jiypnoides was significantly reduced in moisture regime I as compared
with O ; and also in II as compared with I. In contrast, the differences in
growth of F. vulgaris in the same moisture regimes were not significant.
The significance of the differences between treatments was decreased by the
presence of one or two exceptionally small plants in each container. For all
species, to ensure that the soil would be fully exploited by roots, it was
necessary to have the plants rather close together; and it is possible that
inter-plant competition caused an increase in the between-plant variation
within each treatment. Notwithstanding, it is apparent that the growth rate
of 5. hypnoides was depressed to a larger extent in moisture regimes I and

Table i

Growth of four species in a limestone soil under three soil moisture regimes : O, soil
which was watered sufficiently often to prevent the development of measurable soil
moisture tension (SMT) (i.e., o-i to 0-2 atm) ; I, soil watered after drying-out to i atm
SMT ; II, soil watered after drying-out to 2 atm SMT. LSD = least significant difference

('P'=o-05). n.s.=: not significant
(a) Filipeudida vulgaris

Mean leaf ;

area per

plant

(cm2)

Time
(days)

A

f
0

I

II

0

3-5

4-0

5-0

31

19-0

14-5

15-0

51

38-0

29-5

25-0

85

51-0

54-0

45-0

Differences between treatments not significant,
(b) Saxifraga hypnoides

Mean plant area (cm^)

Time
(days)

J^

f
0

I

II

LSD

15

1-6

1-5

1-5

n.s.

50

3-2

1-6

i-i

0-5

73

4-0

2-3

1-3

I'O

93

5-0

2-8

1-7

I-O

292

(c) Thelycrania sangiiinea

MARGARET S. JARVIS

Mean leaf area per plant (cm^)

A.

Mean leaf

number per plant

A

(days)
12
60
84

(

69-0
260-0
568-0

I II

56-5 40-0

57-5 21-5

118-0 43-0

LSD

137

74

r "
0

41

80

112

I II

40 23
32 10
50 22

(d) Primus

padtis

Time

Mean leaf area per plant (cm^)

Mean leaf number per plant

A

(days)
0
92

r
0

50-0
87-5

I II

42-0 52-0
55-5 57-5

LSD
n.s.
n.s.

r
0

13-5
15-0

I II
12-0 13-5

lo-o II-5

II relative to the control (moisture regime O) than was that of F. vulgaris.
For T. sanguinea there were significant differences in total leaf area per
plant between treatments O and I after 60 days ; and between treatments
O and I, and I and II after 84 days: for P. padns the differences between
treatments in total leaf area per plant were not significant after 92 days.
For each of these woody species, one of the most striking effects of increased
SMT was the abscission of some of the mature leaves, so that, during the
whole or part of the period of the experiment there was a net reduction in
leaf number for plants in treatments I and II but a net gain in treatment O.
The changes in total leaf area per plant throughout the experiment, there-
fore, represent the difference between the increase in leaf area resulting
from production and expansion of new leaves and the decrease resulting
from the abscission of mature leaves. There was no such loss of leaves from
plants of treatment O for either species. The production and expansion of
new leaves at the shoot apices of T. sanguinea was continuous throughout
the experimental period, provided that soil moisture tension was not
hmiting. However, in P. padus leaf production was not continuous but
occurred in flushes, as is common for many tree species. In a second
experiment, with first-year seedhngs of P. padus, there was no further
expansion or production of leaves during three months of the three
moisture regime treatments. In treatments I and II aU leaves abscissed ; in
treatment O all leaves remained apparently healthy. (In the following spring
the plants from the three treatments grew vigorously, in soil kept watered.)

WATER RELATIONS OF SPECIES: COMPARISONS 293

It was not feasible to measure SMT iii the containers more than once
daily. The watering-to-drying cycles of treatments I and II were therefore
not necessarily to exactly i or 2 atni, unless the SMT had reached these
levels precisely at the time of measurement. Since the rate of drying-out
of the soil depended both on environmental conditions and on the trans-
piring surface of the plants in the container, it is apparent that the length of
the watering-to-drying cycles could neither be regular through the
experimental period for one species, nor precisely comparable between
species. It was therefore necessary to use some method of summing SMT
in order that comparisons between species might be made. Graphs of SMT
against time were constructed for each container and accumulated SMT
up to a level of i atm was measured, using a planimeter. This arbitrary level
was chosen on the assumption that i atm would be approximately the
SMT at which a considerable reduction in growth rate would occur. (This
assumption, and the choice of the levels of i and 2 atm at wliich the soil
was watered in treatments I and II, were based on the results obtained for
Pinus sylvestris by Sands andRutter (1959) and other results in the hterature,
quoted by these authors.) The accumulated SMT, in 'atmosphere-days' was
finally expressed as a percentage of the total number of the days in the period,
so that, for example, a resulting figure of 25 % would represent the situation
where the SMT was i atm or more on a quarter of the days of the period
or 0-5 atm for half the days of the period. The obvious disadvantage of this
method of summing SMT lies in the premise that these two situations will
have the same effect on growth. The relation between accumulated SMT
and increase in total leaf area per plant throughout the experimental period
(increase in mean plant area, for S. hypnoides) as a percentage of that for
plants growing in soil at field capacity, is shown in Fig. i. Tentative
deductions can be made from these curves. For T. sanguinea and 5. hypnoides
growth is reduced to 50% of that in saturated soil by a soil moisture regime
in which the SMT is at less than 0-5 atm for 50% of the period; and this
indicates, therefore, that leaf area increase is reduced to a neghgible amount
by a soil moisture tension of 0-5 atm or less. Extrapolation of the curve for
F. vulgaris indicates that leaf area increase would be reduced to 50% of that
in saturated soil by a soil moisture regime in which the SMT is at a level of
I atm or more for 50% of the time; hence the growth of this species is
considerably less sensitive to increases of SMT than that of 5. hypnoides or
T. sanguinea. P.^a^//^ appears intermediate in response, but the high between-
plant variation and the low rate of leaf area increase rendered the differences
between treatments not significant, so that deductions based on the curve
for this species are of doubtful vahdity.

294 MARGARET S.JARVIS

Filipendula vulgaris (85daysl

Prunus padus (92 days)

Saxifraga hypnoides (93 days )
Thelycrama sanquinea |72daysJ

10 20 30 ^O 50%

Accumulated SMT atm days, percent daily total

Fig. I. The relationship between leaf area increase and accumulated soil moisture
tension for four species grown in three soil moisture regimes. Increase in leaf area
as percentage of that for plants on soil at field capacity. For explanation accumulated

SMT, see text.

THE EFFECT OF SOIL MOISTURE TENSION ON

GROWTH RATE

These deductions as to the approximate level of SMT at which growth is
reduced were tested in a further series of experiments. The response of each
species to changes in SMT within a watering-to-drying-out cycle was
investigated, in order to determine, as accurately as possible,

(a) the lowest SMT which causes a reduction in growth rate,

(b) the lowest SMT which causes a cessation of measurable growth.

Method. The rate of increase of SMT was sufficiently rapid to necessitate
daily measurements of SMT and of growth, made at the same time each
day. Therefore a quick and sensitive method of detecting changes in
growth rate of each species was essential. Daily measurement of total leaf
length was found to be a practicable procedure; and for plants of all the
species the rate of increase in total leaf length with time was constant, in
soil where measurable SMTs did not develop. Hence, deviations from this

WATER RELATIONS OF SPECIES: COMPARISONS 295

rate were easily detectable, as changes in the slope of curves of total leaf
length against time.

All experiments were carried out in a heated glasshouse (60-70"?), with
supplementary Hghting with fluorescent tubes, during the winter of 1959
to i960. Plaster-of-Paris resistance blocks were placed in the soil at the
time of planting, and the experiments were commenced only after the
roots had grown through the whole soil volume. The blocks used were
individually calibrated to ensure the maximum possible accuracy in
conversion of block readings to atmospheres SMT. Two blocks were used
in each container.

The measuring technique varied according to the species ; either the total
leaf length of the plant, or of certain shoots, or the length of individual
leaves, constituted the basic unit measured. Leaves which had ceased to
elongate at the beginning of the experiment were not measured since it was
required only to detect changes in the rate of increase of total leaf length and
not to obtain absolute values for total leaf length.

Each container was subjected to several watering-to-drying-out cycles.
All the curves for each species were examined and the SMT corresponding
with the first decrease in slope of the curve (i.e., the lowest SMT causing a
decrease in the rate of increase in total leaf length) was determined, sub-
jectively, for each cycle. Similarly the SMT above which there was no
detectable increase in total leaf length was determined.

Results. Figs. 2-5, inclusive, show examples of the curves obtained.

There were marked differences in response between S. hypnoides and F.
vulgaris. The growth rate of the former was depressed by the smallest
SMTs measurable with the plaster-of-Paris blocks, i.e. by approximately
0-2 to 0-3 atm. There was no detectable increase in total leaf length after
drying-out of the soil to a SMT of, at the most, 0-5 atm. In contrast, no
depression of growth rate of leaves of F. vulgaris was caused by SMTs
below 0-7 or o-8 atm. Cessation of elongation occurred at i -o atm for about
two thirds of the leaves; and at 1-5 or 2-0 atm for the remainder. There
was apparently no differential effect of age of the leaf on the response of
leaf elongation rate to increase in SMT.

For P. padus the lowest SMT which resulted in a reduction in growth rate
was about 0-3 atm: the corresponding value for T. sanguinea was 0-7 atm.
This is a difference similar to that estabhshed for S. hypnoides and F. vulgaris.
There was a large variation between shoots in the SMT at which there was
apparent cessation of growth, especially for P. padus; and this masked any

20

396 MARGARET S. JARVIS

difference wliich might have existed between the species with respect to this
particular response.

Thus the resuks from these experiments supplement the conclusions
drawn from the results of the soil moisture regime experiments. The
northern species, 5. hypnoides and P. padus, were more sensitive to the effect
of increase in SMT in depressing their rate of growth than were the
southern species, F. vulgaris and T. sangiiiiiea.

120-

100-

80

V

o

Z 60

U-

<

LJ

< 40-

9

20

6 10 12 14 16 18 20 22
TIME IN DAYS (FEB. I960)

24 26 28

Fig. 2. Saxifraga liypiioidcs. The effect of soil moisture tension on the rate of increase
of total leaf length. (1-29 February i960.) For details see text. Container numbers
are at the ends of the curves. Soil water tensions (atm) are shown beside each point.
The soil was watered thoroughly at points marked W. Plants in container 6 were not
subjected to drying-out after day 8.

THE RELATION BETWEEN SOIL MOISTURE, LEAF
WATERDEFICIT AND TRANSPIRATION RATE

Differences, in response to changing SMT, in the leaf growth of different
species may arise in several ways; firstly, through different degrees of

WATER RELATIONS OF SPECIES: COMPARISONS

297

tolerance to the same loss of turgidity in the leaf; secondly, through
differences in the maintenance of leaf turgor attributable to differences in
the abihty to take up water from soil of increasing SMT; and thirdly,
through differences in maintenance of leaf turgor attributable to differences
in the ability to restrict water loss from the leaves, for example, by stomatal
closure and a subsequent low rate of cuticular transpiration. This third

100-

so-

_60-

O

z

AO-

20-

1 1 II

6 a 10 12

TIME IN DAYS (DEC. 1959)

1

14

1

16

1

18

Fig. 3. Filipaidiila vulgaris. The effect of soil moisture tension on leaf elongation.
(1-18 December 1959.) Each curve represents a single leaf Container numbers are
at the ends of the curves. Plants in container i vi^ere not subjected to drying-out.
Soil moisture tensions (atm) for containers 2 and 3 are shown beside corresponding
points on the curves. W: see Fig. 2.

possibiHty may result in maintenance of leaf turgor only at the expense of
maintenance of the photosynthetic rate.

The relation between leaf water content and SMT was compared for
the four species with the object of determining whether the greater effect
of increasing SMT on the growth rate of Saxifraga hypnoides and Primus
padus, as compared with Filipendula vulgaris and Thelycrania sanguinea, was

298 MARGARET S.JARVIS

correlated with a lesser ability to maintain leaf water content under these
conditions. Measurements of transpiration rate were concurrently made,
in an attempt to distinguish maintenance of leaf turgor by increased water
uptake from that by decreased water loss.

350

TIME IN DAYS (JUNE 1960)

Fig. 4. Thelycrania sauguinea. The effect of soil moisture tension on the rate of increase
of total leaf length. (1-18 June i960.) The container number (i, 2 or 3) and the number
of the plant in the container (i, 2 or 3) are at the ends of the curves. Soil moisture
tensions for container i are sho wit beside corresponding points of curve 1 3 ; similarly
for container 2, by 23; and for container 3, by 33. W: see Fig. 2.

Methods (a) Leaf water content. This was expressed in terms of leaf water
deficit (LWD), defined as the percentage reduction in leaf water content
below that at full turgor; a concept introduced by Stocker (1929) and
since widely used. The leaves were cut from the plant and weighed im-

WATER RELATIONS OF SPECIES: COMPARISONS 299

mediately on a torsion balance. They were then placed in a corked tube
with the cut surface of the petiole in water. After 24 hours in the dark, at
1 5°C, the leaves were blotted, re-weighed and dried in an oven. Prehminary
tests, conducted to determine the effect of age and position of the leaf on

./

X 35

lOOOi

900

800

700

z

V

0

I

tr
a

600

500

z

'^OO-

<

0

300: [■

200

w /

„„ 1-OV^ 2>x

6 10 12 1A 16

TIME IN DAYS (JUNE I960)

Fig. 5. Prunus padus. The effect of soil moisture tension on the rate of increase of
total leaf length. (1-24 June i960.) The container number (i, 2 or 3) and the number
of the shoot are at the end of the curve. Soil moisture tensions (atm) for container
I are shown beside corresponding points of curve I4; similarly for container 2, by 29;
and for container 3, by 35- W: see Fig. 2.

300 MARGARET S. JARVIS

the LWD developed, showed, for P. padtis, T. sanguinea and F. vulgaris,
that there was Httle variation between values obtained for all mature leaves,
i.e. leaves which were completely, or almost completely, expanded and
which were not obviously senescent. The youngest leaves had apparently
higher LWDs than the mature leaves, cf. Catsky (1959).

(b) Transpiration rate. Transpiration rate was measured by determining
the loss in weight of detached leaves during a standard time after cutting,
this being the most practicable method available. Preliminary tests showed,
for P. padus and T. sanguinea, that there was a constant rate of loss from
05 to 6-0 min after cutting, followed by a slight faU-off. The method was
therefore considered satisfactory for these species. The experimental pro-
cedure adopted was to determine the loss in weight from | to 4^ min after
cutting. The transpiration rate was expressed as mg loss per 100 mg (at
^ min) per min.

Measurements of LWD and of transpiration rate (TR) were made on
the plants used for the experiments on the effect of SMT on growth rate,
described above ; and on P. padus and T. sanguinea planted alternately within
the same container, to ensure that SMT was identical for the two species.
All experiments were conducted in a glasshouse, on days which were
cloudy throughout, so that fluctuations in environmental conditions were
relatively small.

Results. The results for P. padus and T. sanguinea are presented in Tables
2(a) and (b) ; and in Fig. 6. On July 15, for soil with a SMT of below 0-2 atm,
there were no significant changes in LWD through the day for either
species, and the differences between the LWDs of the species were not
significant at any time of day (Tables 2(a) and (b)). No direct comparisons
between the species for soil of higher SMT can be made, since the SMTs
obtaining were not identical. There is, however, no evidence of a major
difference in the LWDs developed at SMTs from 3 to 8 atm. For plants
in soil at '20 atm' SMT it appears that the LWDs for leaves of T. sanguinea
are larger than for P. padus. However, since these values of '20 atm' corres-
ponded with the maximum reading of the electrical resistance blocks, such
values may represent any value of SMT from 20 atm upwards. Hence, the
soil in which the T. sanguinea plants were growing may have been at a
higher SMT than that for P. padus.

In the experiment of 24 August i960 (Fig. 6), designed to eliminate these
difficulties, the LWDs of both species were smaller than for the previous
experiments. With one exception, there was no overall increase in LWD
through the day, from 7 a.m. to 7 p.m., so that water loss did not exceed

WATER RELATIONS OF SPECIES: COMPARISONS 301

10-

9-

SMT
(ATMS.)

7-

I-
Z

U 6 —

a

5—

UJ

Q

I

<

liJ

3-

MEAN TR. IMGMS,% PER MiN.)
2-15 p.m. to A-15p.nn.

0-45 ;

13 15

TIME OF DAY

I
17

^ SMT

\v (ATMS.)

NAJl 5-0 to 7
\*-'(3contai

O
iners)

3-2 to 5-0
(1 container)

BELOW 0-2
12 containers)

I
19

1 — r

6 7

Fig. 6. The effect of soil moisture tension (SMT) on leaf water deficit and transpiration

rate. (24 August i960.)

• Thelycrania sanguinea
X Primus padus

The two species were planted alternately in the containers. Values are means for at
least 10 leaves. Three containers had SMTs within the highest range of SMT (4-0 to
6-7 atm at the beginning of the experiment) ; one at the middle range (2-3 to 4-0 atm) ;
two at the lowest range (below 0-2 atm throughout the experiment). Readings of
SMT were taken from four plaster-of-Paris blocks per container.

water uptake, even for plants in soil at more than 5-0 atm SMT. Values at
7 a.m. were smaller on 25th than on the previous day, although SMT had
increased shghtly. The removal of two samples of leaves appreciably
reduced the leaf area of each plant. Hence if equilibrium between plant and
soil moisture was not achieved during the night, for plants with a normal
number of leaves, then a reduction in leaf area might result in smaller early
morning LWDs, which more closely approached the equihbrium value.
It is difficult to explain the generally small values of LWD which pre-
vailed, since environmental conditions were not very different from those
during the previous experiments, and the transpiration rates were not very
much lower than before. At 7 a.m., on both 24 and 25 August, there
were no significant differences between LWDs of the two species. At 7
p.m., in the intermediate SMT condition, the mean LWD for T. sanguinea

302 MARGARET S.JARVIS

was just significantly larger than for P. padus ('P' = o-05). In higher or
lower SMTs the differences between species, in LWD at 7 p.m., were not
significant.

There was no significant difference between the transpiration rates of the
two species, in any of the treatments.

Table 2{c) shows results for S. hyptwides.
The 7 a.m. value was significantly larger for the plants in soil at 20 atm
SMT than for those in soil from 00 to 53 atm SMT, between which there
were no significant differences. At 7 a.m. on the same day, mean LWD
for leaves of F. vulgaris, SMT 20 atm, was 26-1%; for SMT 2-5 atm,
11-2% ; and for SMT less than 0-2 atm, 5-9%. The differences between these
values were significant (for 'P' = o-05, least significant difference = 2-1%).
It was not possible to compare transpiration rates of these two species,
since rehable estimates of transpiration rate for S. hyprwides were not avail-
able. Results obtained by measuring the loss of water from detached shoots
were too variable.

Discussion. For aU four species, increased SMT was associated with
increased LWDs; and for P. padus and T. sanguinea, also with decreased
transpiration rate. Such phenomena have been described for many species
(e.g.,Rutter and Sands, 1958, for Pinus syhestris; Slatyer, 1955, for cotton
peanuts and sorghum). Despite the scantiness of the data, sufficient evidence
was obtained to show that the major differences between the two tree
species, in response of growth rate to increases in SMT, cannot be explained
in terms of differences in the relation between LWD or transpiration rate
and increase in SMT. For plants of these two species, there were no major
differences observed between LWDs or transpiration rates prevailing, at
SMTs from o-o to 20 atm, and in moderate evaporating conditions.

Such data as were obtained for F. vulgaris and 5. hypnoides indicate that
the same conclusion may also be valid for these herbaceous species. Mean
LWD values for S. hypnoides at SMTs of less than 0-2 atm and of 2-8 atm,
though not significantly different, were comparable in magnitude to those
for F. vulgaris.

DROUGHT RESISTANCE, AS DETERMINED USING
CONTROLLED RELATIVE HUMIDITIES

Resistance to reductions in growth rate resulting from low SMTs, con-
sidered previously, may be completely independent of resistance to injury

WATER RELATIONS OF SPECIES: COMPARISONS 303

Table 2

The relation between leaf water deficit (percent), transpiration rate (mg per 100 mg
per min) and soil moisture tension (atm)

(a) Prunus padus {is.7.60)

Time

of day

LWD SMT

TR

LWD SMT

TR

LWD

SMT

TR

LWD SMT TR

9.00 a.m.

7-1

<0-2

12-2

4

13-6

4

17-0

>20

12 noon

9-4

12-5*

14-6

16-5

2.30 p.m.

ii-i

15-6*

14-5

i6-o

4.00 p.m.

0-74

sd

0-40

0-24
sd

0-02

o-o6

sd

o-oi

<0*02

5-30 p.m.

9-3

lO-O*

10-7

15-5

7.00 a.m.

8-9

<0-2

10-8

6

13-8

8

20-0

>20

sd — standard deviation
* = significant difference ('P' =0-05) between consecutive measurements

(b) Thelycrania sanguinea (15 .7.60)

Time of day

LWD

SMT

TR

LWD

SMT

TR

LWD

SMT

TR

9.00 a.m.

9-0

<0-2

13-0

2-5

28-0

>20

11.30 a.m.

lO-O

14-0

31-0

2.00 p.m.

10-5

i6-o

28-0

4.00 p.m.

1-50

0-34

0-02

5-30 p.m.

8-5

13-5

27-0

7.00 a.m.

7-5

<0-2

lO-O

3-5

29-0

>20

(c) Sttxifraga hyptwides (4.4.60)

Time of day

LWE

»

f

^

10.30 a.m.

6

5

5

4

14

16

i.oop.m.

7

5

5

2

8

20

3-30 p.m.

7

9

II

8

7

13

5.00 p.m.

8

10

8

13

13

17

7.00 a.m.

9

12

8

12

II

22

SMT

<0-2

i-o

I-]

[

2-8

5-3

20

304 MARGARET S.JARVIS

in conditions of more severe drought. A method, of the type suggested by-
Levitt (1958), was designed to compare the resistance of the species to the
development of critical LWDs, in atmospheres of a range of controlled
relative humidities, at a standard temperature. (Critical LWD is the
maximum LWD from which recovery of turgidity can be made.) Detached
shoots of the species were subjected to the standard drying conditions for
a standard time. Half the shoots had the cut ends in water, so that water
uptake was not restricted : the other half were not supphed with water.
Thus the drought resistance of the species can be compared, in conditions
representing both situations where soil water is freely available and is
unavailable. The critical LWDs, and the relative humidities which induced
their development, were determined for the four species.
Methods. The drought chambers consisted of polythene bowls, 30 cm
square and 12 cm deep, covered with glass sheets. Twenty glass tubes were
stuck, at evenly spaced intervals, on to the bottom of each chamber. Up to
half of these were fdled with water. The tops of all were sealed with
'parafilm'. The relative humidity (RH) was controlled by one htre of an
appropriate sulphuric acid-water mixture. The change in this solution
during an experiment was never greater than that equivalent to a 1%
increase inRH. The experiments were carried out in growth chambers at
25°C, with a standard Hght source.

Twenty leafy shoots were used in each chamber ; half with their stems in
water : half without water and with the cut ends of the stems Vasehned.
The stems were pushed through the 'parafdm' seals into the glass tubes.
The 'parafdm' prevented direct evaporation from the water into the
drought chamber; and also supported the stems in positions arranged to
give even distribution of the leaves within the chambers.

The shoots were subjected to the controlledRHs for 20 hours; 12 hours
in the dark, followed by 8 hours in the hght. The dark period was designed
to allow RH equilibration throughout the chamber, while water loss was
restricted by stomatal closure. During the drought period the chambers
were rocked gently from time to time to ensure change of the acid-water
surface and to promote circulation of the air in the chamber. At the end
of the period the acid-water mixtures were siphoned off and replaced with
water. Samples of leaves were taken for LWD determinations. The bases
of all the shoots were re-cut and replaced in the tubes, which had all been
fdled with water. The chambers were placed in the dark for 24 hours, after
which period recovery of the leaves was estimated. Recovery of turgidity
could be assessed subjectively, or objectively by comparing the ratio of
saturated weight (i.e., the weight of the leaves after 24 hours in the dark,

WATER RELATIONS OF SPECIES: COMPARISONS 305

in an atmosphere of 100% RH, with the petioles in water) to dry weight.
The value of this ratio was significantly lower for leaves permanently
injured by the droughting treatment than for normal leaves and leaves
which recovered.

Results, (i) Prunus padus and Thelycrania sanguinea. Five experiments
were conducted; two with each of the species separately, and the fifth with
shoots of the two species arranged alternately in the same drought
chambers. It was thought likely that the apparent differences in response
of leaves of a single species on successive occasions might be attributable
to differences in environmental conditions, such as would arise if there
were incomplete control of RH. Experiments using more than one species
per chamber ensured that the results would be comparable.

In no experiment was there drought injury to leaves on shoots whose cut
ends were in water. After the drought period, at allRHs, mean LWD for
such leaves was less than 5%. Results for shoots to which water was
unavailable, are presented in Tables 3 and 4.

Table 3 shows the difference in the abihty of the two species to recover
from the droughting treatments. The RH which could be tolerated was

Table 3

The recovery (as a percentage of the total number of leaves) of leaves on detached
shoots of Primus padus and Thelycrania sanguhiea after subjection to atmospheres of
various relative humidity, at 25°C, for a 12-hour period in the dark followed by an
8-hour period under a standard light source of 400 ft candles ; water was not supplied

Recovery (as percentage 1

of the total number of leaves)

X

RH

r-

T. sanguinea

P. padus

A

^

^ r ■

^

6.

10.59

22.6.60

13.7.60

I4-9-59

10.5.60

13.7.60

100

100

100

100

100

100

95

100

100

87

100

100

100

76

66

100

100

30

100

66

67

40

0

59

0

0

56

0

0

51

0

0

below 50

0

0

0

0

0

0

3o6 MARGARET S.JARVIS

Table 4

The mean leaf water deficits (LWD) developed by leaves on detached shoots ofPrunus
padiis and Thelycrania sanguinea after droughting. Same experiments as Table 3. LWDs
for leaves which did not regain turgor when left overnight in a saturated atmosphere
with their petioles in water, after the droughting treatment, were calculated by using
a value for the saturated weight obtained from the ratio of mean saturated weight to
dry weight for those leaves, in the same experiment, which recovered. The value for
critical LWD (the largest LWD from which turgidity can be regained) is between the
largest LWD from which recovery occurred and the smallest from which recovery

did not occur

Mean LWD

developed (with standard

deviations)

j-^

(

~^

RH

T.

sanguinec

A

P. paAus

A

(

\

1

"^

6.10.59

22.6.60

13.7.60

I4-9-59

10.5.60

13.7.60

100

36

13

24

17

16

95

24

20

87

38

40

24

78

61

46

44

45

35

35

67

60

48

59

87

79

56

52

66

51

67

54

62

48

84

85

43

77

77

35

68

25

94

89

80

Critical leaf water deficit

A

(

^

58-77

57-70

53-54

<36

43-51

29

slightly lower for T. sanguinea than for P. padus. This conclusion is based
on the results of the experiment where shoots of the species were droughted.
together. All the leaves of T. sanguinea, compared with 66% of leaves of
P. padns, recovered from the effect of 78%RH; and 40% of the leaves of
T. sanguinea recovered from the effect of 67%RH, while no P. padns leaves
did so. However, this difference is of the same magnitude as that obtaining
between leaves of the same species collected from different locaHties, or of
different ages, e.g., only 30% of leaves of P. padns collected from a Norfolk
fen (experiment of 14.9.59) recovered from the effect of 78% RH, com-
pared with 100% of leaves collected in Sheffield (experiment of 10.5.60)
and 66% for the same tree, two months later (experiment of 14.7.60).

WATER RELATIONS OF SPECIES: COMPARISONS 307

Both, mean LWDs developed as a response to the treatment, and critical
LWDs, were generally larger for T. sanguinea than for P. padus (Table 4).
There was some variation between the successive experiments, notably for
P. padus from the same tree. In May and July LWDs developed were
similar on the two occasions but the critical LWD was 29% for the older
leaves and between 43 % and 51% for the younger leaves collected in May.
Hence there was a higher percentage recovery in May, as mentioned above,
indicating that drought resistance may change through the season.

Thus, although the critical LWD and the LWD developed at any RH
was larger for T. sangtiinea than for P. padus, there was insufficient evidence
to demonstrate any appreciable difference in drought resistance, as
measured by the abihty of leaves to recover turgidity.

(2) The herbaceous species. For shoots whose stems were in water the
LWDs developed were not related to the RH prevailing during the
droughting treatment.

In four experiments with Saxifraga hypnoides from different locahties
there was 100% recovery by the shoots whose stems were not in water,
after allRH treatments, down to 25%RH. Comparing results for samples
from different localities, it is apparent that at the lower RHs larger LWDs
were developed by plants from Cressbrook Dale, Derbyshire (24.9.59)
than by plants collected from the Wimiats, Derbyshire, both three weeks
later (14.10.59) and in the following year (3.8.60) (Table 5). The reason for

Table 5

The mean leaf water deficit of Saxifraga hypnoides after droughting. Conditions as for

Table 3

RH

8.9.59

24.9.59

14.10.59

3.8.60

100

16

10

86

22

77

28

31

27

67

Not

28

61

determined

33

34

54

42

34

48

52

38

41

50

36

25

63

32

35

N.B. In all four experiments, after all RH treatments, there was 100% recovery of
turgidity by the shoots.

3o8 MARGARET S. JARVIS

this marked difference was not investigated; it might be attributable either
to genetical differences or to differences in the preceding environmental
conditions. Results for Filipendula vulgaris and Pimpinella saxifraga were in
striking contrast (Table 6).

No leaves from F. vulgaris recovered from any treatment except that of
100% RH: for P. saxifraga there was only 50% recovery from 86% and
78%RHs, and no recovery from lower RHs. In comparison with the other
species tested, the LWDs developed, and the critical LWDs, in these
species were remarkably large. Hence, in this respect, they may be regarded
as being very much more drought sensitive than S. hypnoides.

Table 6

The mean leaf water deficit (LWD) developed and the percentage recovery of leaves
o{ Saxifraga liypnoides, Filipendula I'ulgaris and Piiiipiiiella saxifraga subjected to drought-
ing conditions. Droughting conditions as for Table 3. LWDs of leaves which did not
recover were calculated as for the tree species (Table 4). Date of experiment 3.8.60

S. hypnoides F. inilgaris P. saxifraga

r ' . , ^ . < ^

RH Mean LWD Recovery Mean LWD Recovery Mean LWD Recovery
developed (%) developed (%) developed (%)

100

10

100

43

100

30

100

86

23

100

85

0

67

50

78

27

100

89

0

77

50

67

28

100

92

0

89

0

53

34

100

95

0

93

0

25

35

100

94

0

95

0

Critical LWD

j^

f

N

>47%

53-

-78%

64-

-75%

DISCUSSION

The results presented above demonstrate physiological differences between
the species in response to conditions of increasing water stress. Growth of
Saxifraga hypnoides was depressed, in comparison with growth in soil at
field capacity, more than that of Filipendula vulgaris, by soil moisture
regimes where the soil was allowed to dry to i or 2 atm SMT before re-
watering. Confirmation of this difference was obtained from the experi-
ments investigating the effect of increasing SMT within a watering-to-
drying-out cycle. Similar differences, though not so large, were apparent

WATER RELATIONS OF SPECIES: COMPARISONS 309

between Pniniis padus and Thelycrania sanguineci.K.esu\ts of the soil moisture
regime experinients were inconclusive for these two species because of the
slow rate of increase of leaf area and the high between-plant variation for
P. padns. In day-by-day correlation of growth with increase in SMT,
reduction of growth of P. padus occurred at a lower SMT than that of
T. sanguinea. It was not possible to make a distinction between the two in
the SMT at which there was cessation of leaf elongation, because of the
large variation between shoots in this respect, particularly for P. padus.
There was no growth of either species at SMTs above 2-3 atm at the most.
There was cessation of measurable growth of S. hypnoides at about 0-5 atm
SMT and of F. vulgaris at 2-0 atm or below. In contrast, Wadleigh and
Gauch (1948), studying the effect of increasmg total soil moisture stress
on the daily elongation of cotton leaves, during several irrigation cycles,
found that elongation ceased at a narrow range of stress values, close to
15 atm. Slatyer (1957) found for privet and cotton that growth and elonga-
tion continued up to the point where DPD at dawn (27 and 34 atm, respec-
tively) corresponded with zero turgor pressure in the leaves, i.e., at the
permanent wilting point for the species. In the experiments described
above, measurable leaf elongation of the four species ceased at SMTs
considerably lower than those which caused wilting of the leaves at dawn.
This point was not precisely determined but it certainly did not occur at
SMTs lower than 10 atm.

It must be noted that these low values represent only the soil moisture
tension (SMT) component of the total soil moisture stress (TSMS) ; and
that the osmotic component cannot justifiably be neglected since it may
be of comparable magnitude. Slatyer (1957) illustrated the relationship of
both SMT and TSMS to soil water content for a 'sandy clay loam' soil, to
which a complete fertiliser mixture had been added. For SMT values from
0 to 2 atm corresponding TSMS values were 2 to 3 atm higher. Russell
(1950) quotes values of 0-2 to i atm for the osmotic pressure of the soil
solution from field capacity to the wilting point, for 'normal leached
agricultural soils'. The values for SMT presented throughout this paper,
may therefore be up to about 2 atm lower than the corresponding TSMS,
but probably not more than i atm. This difference in magnitude of the
absolute values does not, of course, affect the comparisons made between the
species, since the same soil was used throughout.

There was apparently no difference between the relation of SMT and
LWD, or of SMT and TR for P. padus and T. sanguinea; or of SMT and
LWD for 5. hypnoides and F. vulgaris. The marked difference in sensitivity
of growth rate to increasing SMT can possibly be explained not in terms

310 MARGARET S.JARVIS

of a difference in ability to control water loss by stomatal closure, or in
ability to take up water from soil of increasing SMT, but as a difference in
sensitivity of the metabolism of the cells of the leaf to increasing LWD.

The results of the experiments in which detached shoots of the species
were subjected to atmospheres of controlled relative humidity (RH) for a
standard time vmder standard conditions, are particularly interesting, in
that they emphasise the possibihty of independence of different aspects of
drought resistance. For the species used in the present investigation, the
resistance of the leaves to desiccation at low RHs and with soil water
unavailable was independent of the resistance of the plant to reduction of
growth rate as a result of increasing SMT and concomitantly increasing
LWD. The growth rate of F. vulgaris and Pimpinclla saxifraga was much less
sensitive to the effect of increasing SMT than was that of 5. hypnoides; yet
the resistance of the leaves to desiccation was very much lower. Similarly
for the tree species; the growth rate of T. sanguinea was less affected by
increases of SMT than was that of P. padus; but there was no clear differ-
ence between the species in resistance of the leaves to desiccation.

This type of experiment demonstrates the differential ability of plants
of the species tested to prevent water loss to a lethal level by stomatal
closure and by low rates of cuticular transpiration. The threshold RH that
causes injury can be determined, but, unless sufficient time is allowed for
equihbrium to be reached, and this was not so in the present experiment,
such values may correspond not only with drought tolerance but also with
drought avoidance of the leaf tissues. The results of such experiments can
probably justifiably be applied to field conditions where soil water avail-
abihty is negligible. Thus, where soil water is unavailable both to 5.
hypnoides and to F. vulgaris in the field, and similar atmospheric conditions
prevail, plants of the former species will survive for a longer period.
However such a comparison does not take into account the size and extent
of the root system or the capacity of the roots to grow into region of soil
of lower SMT; i.e., the capacity of the plant to avoid the condition where
soil water is unavailable to it. Such factors may be of overriding importance
where the drought resistance of a species in the field is concerned. The root
system of F, vulgaris is more extensive than that of S. hypnoides, for plants
growing on the slopes of the Derbyshire dales.

It is therefore difficult to apply to field conditions the results of experi-
ments reveaHng physiological differences between species in their response
to soil or atmospheric drought.

It is possible that the reduction in growth rate of S. hypnoides which
ensues in response to shght drying-out of the soil may be an important

WATER RELATIONS OF SPECIES: COMPARISONS 311

factor controlling the distribution of the species. The competitive abihty
of plants of this species must be severely hmited in habitats where the soil
is not continuously moist. However, other factors, such as the effect of
high soil temperature on vegetative growth or of SMT and temperature
on flower initiation and seed production may play an equally important
roleQarvis, M.S., i960).

Similarly for Pniuiis padus it is possible that spread of the species south-
wards, or on to south-facing slopes at the south-eastern hmit of its range,
may be Hmited by soil moisture factors. Under identical conditions of soil
moisture availabihty vegetative growth of the southern species, Thelycrania
sanguinea, would certainly be faster.

AU such conclusions must be extremely tentative. The Hmitation of
distribution of a species, in the comparatively simple case where only
chmatic factors are of importance, may be caused by any one, or any
combination of factors acting at any one, or any combination of stages in
the Hfe cycle The most important effect may be a continuous reduction of
the competitive abihty of the species throughout the hfe cycle; or an
occasional catastrophic effect at the seedling stage or the flower or fruit
production stage, for example.

ACKNOWLEDGMENTS

It is a pleasure to express my thanks to Dr. C. D. Pigott for his interest
and supervision during the course of this work; to Professor A.R. Clapham,
F.R.S., for the facihties of his department; and to the Department of
Scientific and Industrial Research whose award of a Research Studentship
made the work possible.

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21

312 MARGARET S.JARVIS

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Stocker, O. (1929) Das Wasserdeficit von Gefasspflanzen in verschiedenen Klima-

zonen. Planta, 7, 382-387.
Wadleigh, C.H. & Gauch, H.G. (1948) Rate of leaf elongation as affected by the

intensity of the total soil moisture stress. Plant Physiol. 23, 485-495.

THE EFFECT OF SOIL TYPE ON THE RELATION
BETWEEN SOIL WATER REGIME AND GROWTH
OF SEEDLINGS OF QUERCUS PETRAEA (MATT.)

LIEBL.

P.G.Jarvis
Department of Botany, The University of Sheffield*

INTRODUCTION

A LARGE amount of literature now exists on the relation between soil
water regime and the growth of many different plants (for reviews, see
Stanhill, 1957; Veihmeyer, 1956). In many of these experiments, compari-
sons have been made between the responses of different species and types of
plants to well-defmed soil water regimes. However, most of the critical
experiments have been carried out on one, or more rarely two, different
soil types. The experiment described here demonstrates the need for a
prehminary investigation to determine the comparative suitabihty of a
range of soils for the growth of each species to be investigated, before an
attempt can be made to compare the physiological responses of different
species to defined soil water regimes.

As part of an investigation into the growth response of seedlings of
Quercus petraea to certain factors of possible ecological importance, an
experiment was carried out in which seedlings were grown under three
different defined soil water regimes on five soils of different character.
Since the response to similar soil water regimes was very different on the
different soil types, as much information as is available is given for each
soil used.

METHOD

The soils were collected (in April, 1959) directly into the large polythene
bowls (35 cm mean diam. x 15 cm deep) in which the plants were grown.
Eight acorns were planted per bowl and the seedlings were subsequently
thinned to leave 6 or 7 of similar size. The acorns were all obtained from
one parent tree and were selected to be of uniform size. The bowls were
regularly watered so that no soil moisture tensions (SMTs) occurred imtiJ
the seedlings had all developed one whorl of leaves. The cotyledons were

* Now at : Institute of Physiological Botany of The University of Uppsala, Uppsala,
Sweden.

314

P. G. JARVIS

removed at this stage in order to accelerate any effects which the different
soils might have on seedling performance.

Shortly after planting, plaster resistance blocks (modified Bouyoucos
type; Jarvis, P.G., i960) were inserted with the long axis vertical, so as to
have as much soil [c. 4 cm) above as beneath them.

Three different soil-water regimes were practised on each soil. In one
(treatment i) the bowls were watered 3 or 3 times a week, depending on
the weather, and (with the exception of one occasion) no measurable
SMTs (i.e. no SMTs above 0-2 atm) were allowed to develop. In the other

L

r
Q-0

03

i?>

-1
' I

^--'1
/ I

A' 'A A^' A ^^-'A \ A

SH

/ I

.^ \ -AA .n : /I,-'

:--A .

A

' I

1A.7.59.

17.10.59.

20 Days

Fig. I. The soil moisture tensions (SMTs) in atmospheres which were allowed to
develop in the five soils during the course of the experiment. The broken line represents
moisture treatment 3 ; the sohd line, treatment 2 ; and the blacked in area, treatment i.
Vertical lines indicate watering.

two treatments (treatments 2 and 3) watering took place, as closely as
could be arranged, when SMTs had reached i-2 and 2-5 atm respectively.
The actual range of SMTs over which watering took place can be seen
in Fig. I. Watering was with deionised water (Elgastat) which was always
added until the soil was thoroughly saturated throughout.

The experiment was conducted in a cold fully-ventilated glasshouse. The
leaves were removed from the plants on 17 October 1959, to prevent an
unnaturally long growing season, and the plants were subsequently
harvested. *

SOIL TYPE, SOIL WATER REGIME AND GROWTH 315

Table i
Field characteristics of five soils

Code Cover Soil type

Horizon

Colour

D—Deschampsia; H=Holciis

Apparent
density
pH gm/cc

BL D.flexuosa Iron-humus Ao, 10-25 cm Grey 3*2 2-1

podsol

SH H. mollis Oligotrophic (B), 5-25 cm Brown 4-1 1-3

Endyinion brown earth

BR D.flexuosa PodsoHsed (B), 5-25 cm Red- 3-6 1-7

brown earth brown

D D.flexuosa PodsoUsed Ag, 0-8 cm Black 2-9 0-38

brown earth

H Oak leaf PodsoHsed A 0, 0-12 cm Black- 3-0 0-35

litter browii earth brown

Table 2
Characteristics of the soils (treatment i) at the end of the experiment

Exchangeable

; ions

Apparent

mg / 1 00 cc

density
g/cc

T-TnTTJii*;

X

Soil

g/ioo cc

Ca

K

ODR

BL

1-8

6-8

0-38

0-12

13-5

SH

1-3

13-4

0-84

0-17

II-5

BR

1-9

13-9

0-42

0-14

lO-O

D

0-36

33-2

1-84

0-24

20-0

H

0-34

33-6

1-69

0-26

16-5

N.B. pH determined with glass electrode; soil :water= 1:1 by volume. 'Humus'
determined from 'loss on ignition' at 550°C. Apparent density determined from
volume displacement of toluene (after c. 10 sec) by natural clods, followed by filtering
and dry weight determination of the clods. Exchangeable Ca and K extracted by
shaking with 2 successive quantities of 0-5 N NH4NO3; estimation by 'Versenate'
titration and flame-photometer respectively. Oxygen diffusion rate (ODR) deter-
mined with platinum electrode (Poel, i960); in g x lO"^ of oxygen per sq. cm per
min.

For complete descriptions of the methods, seejarvis, P.G., i960.

3i6 P. G. JARVIS

SOIL CHARACTERISTICS

All the soils were obtained from a fragment of sessile oakwoocl (Padley
wood, Grindleford) on the Millstone grit to the west of Sheffield (Pigott,
1956).

With the exception of soil SH, the soils were obtained from over the
gritstone ; SH was from a nearby area of shales, with which the grit is
inter-bedded. The soil in the SH area was a good brown earth with active
htter incorporation. It had a high clay content as compared with the

10 20 30 AG 50 60 100 200 300 400 500

Soil moisture content as a % of dry weight

600

Fig. 2. The relation between soil moisture tension (in atmospheres) and soil moisture
content (as percentage of dry weight), for the five soils. Soils D and H are plotted on
the larger scale for moisture content. Values determined in an experiment in which
seedlings of sessile oak, growing on the soils in sealed cans containing plaster resistance
blocks for SMT determinations, dried out the soil (Jarvis, P.G., i960).

sandy gritstone soils. It also supported a richer flora and better growth of
oak trees.

The relation between soil water content and soil moisture tension for the
five soils is shown in Fig. 2. Large differences exist in the absolute amounts
of water removed from the difTerent soils for equal changes in SMT. If
the soil water content is recalculated on a volume basis, these differences
remain large (Table 3).

RESULTS

Representative seedhngs from each treatment are shown in Plate I. On all
the soils, except BL, the roots were found to occur throughout the whole

>

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u
n

6fi

4J

J2

o

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2 °
^ £ -^

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5 ^^

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o "^ I

^ a o

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D- <-ti lii

[facins p. ^i6

SOIL TYPE, SOIL WATER REGIME AND GROWTH 317

Table 3

The changes in moisUire content of the five soils, for changes in SMT from 0-5
atmospheres, expressed on a weight and on a volume basis

Changes in moisture

Soil

content

r

■>

g/ioo g

g/ioo cc

BL

18

35-1

SH

32

41-6

BR

28-5

51-3

D

267

98-8

H

475

164-0

soil volume. On BL about ^ to | of the root system was found at the soil-
container junction, and much of the soil was unexploited.

Relative growth rate (RGR) is calculated from the formula of Fisher
(1921):

\0gelV2-l0geW1

RGR =

h-h

where ^2-^1 is the length of the growing period in weeks, taken here to be
the time between appearance of the first whorl of leaves and harvest, i.e.
16 weeks. W2 is the mean dry weight per plant at harvest. W^ equals
(A — C), where A is the mean dry weight at planting of cotyledon pairs,
and C is the mean dry weight per treatment of cotyledon pairs removed
at the one whorl stage.

The results are presented in Table 4, where other indices of performance
are also explained. 'Significant' assimilation is of ecological significance,
since it does not include the leaf weight, which is not carried forward to
the next growing season.

The significance of the differences between values for certain of the indices
given in Table 4 was estimated from analyses of variance. The results are
presented in Table 5. Similar analyses could not be applied to the values
for aU the indices used because, for some of them, much larger variances
occurred in the treatments supporting good growth.

There is considerable evidence that the growth of many plants is severely
reduced by SMTs between 0-5 and i-o atm (for examples see Sands and
Rutter, 1959), and studies within single drying-out cycles have shown that
for some plants growth ceases completely at SMTs of less than i atm

3i8

P. G. JARVIS

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rt

t-l

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4->

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t5

u

9

u

tJ

S

j:3

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u

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<5

a,

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<*J

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rt

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a

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t/l

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u-l

(^

o

rt

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C/1

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;-!

rt

p

•«->

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bo

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u

CO

m
u
a,

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a

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N m M (<) r«i M rj

M rl rn t-H r^ ro

0\ oo i^

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+1

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O rn >/-^ \0 M •^

O O

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<i^ o O
VC ro »/-i

m (S M

t~~ oo

■^ oo

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r) 6 M

r^ 00 r<^ \0 m Q\

6 ch 00 ^ :^ r>

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r~- OO OO

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c
o

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6

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•>^ -^ -^ 2 2=^

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f^ 00 \o l> » o\

0\ "^

t> 1-1

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t--

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vi

6

M

6

o

"?

<^

CO

CO

c\

oo

rq 00

•/^ 0\ </-!
rq ^r '^

6

NO

6 6

bt)

r-'

P

iH

i^

■:i 1

1?

•S hJ

(/) 1

rt 1

(J

U " —

S 11

4->

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00

X

>

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-d

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Id

SOIL TYPE, SOIL WATER REGIME AND GROWTH 319

Table 5

Least significant differences (LSD) and standard errors (s.e.), determined from analyses
of variance of the experiment as a whole, for certain of the indices of performances

presented in Table 4.

LSD

A

(

^

'P'=o-05

o-oi

o-ooi

s.e.

RGR

22

29

37

7-5

R/S

I-3I

I-7I

2-19

0-47

Height

2-8

3-7

4-7

i-o

(Jarvis, M. S., 1963). In order to obtain estimates of the amounts of effective
SMT experienced by the seedhngs, the areas beneath the dr)dng-out curves
in Fig. I were summed up to a SMT of 0-5 atm. It was assumed that any
short-term drying-out of the soil, which occurred above the SMT at which
growth ceased, would have no additional effects. Some evidence for this,
for other species, is provided by Jarvis, M. S. (1963). The total number of
'atmosphere-days', experienced by the plants in the different treatments,
up to 0-5 atm SMT, are given in Table 6.

Table 6

The amount of drying-out, represented as number and percentage atmosphere-days
(for explanation, see text) occurring in the various soils and treatments

Treatment

Number

of atmosphere-days

0/
/o

atmosphere-

-days

Soil^^

r
I

2

1

3

f
I

3

3

BL
SH

0-30
0

20-l6

18-39

34-22
31-78

0-63
0

42-4
38-7

72-7
66-9

BR

0

20-12

30-03

0

42-3

63-2

D

0

20-84

32-57

0

43-9

68-5

H

0

12-00

17-22

0

25-3

36-2

The second part of the table contains, for each treatment, the number
of 'atmosphere-days' expressed as a percentage of the total theoretical
number of 'atnaosphere-days' possible if the SMTs had remained at
0-5 atm throughout.

The relation between RGR and 'percentage atmosphere-days' is pre-
sented graphically in Fig. 3 .

320

p. G. JARVIS

1A0^

20 40 60

% Atmosphere days

80

Fig. 3. The effect of the five soils on the relation between the average relative growth
rate (of seedlings of sessile oak over a 16-week growing season) and the amount of
drying-out of the soil (summed as percentage atmosphere days, up to a SMT of 0-5
atm) which was allowed to develop.

DISCUSSION

Large differences occur between the maximum RGRs of seedlings on the
different soils. Since only five soils are involved, it is not possible to make
any far-reaching correlations between plant performance and a particular
soil character. However, it may be noted that better growth is associated
with the following soil characters: higher humus content, higher base
status, higher oxygen diffusion rate, lower apparent density, and greater
moisture content (gm/ioo cc of soil) held between 0-5 atm SMT, i.e.
larger pore volume.

The response to the different soil water regimes is very different on the
different soil types. Only on leaf litter (H) and Deschampsia humus (D), the
soils which supported the highest RGRs, are there marked decreases in
RGR in response to the drying-out treatments. On both the soil from the
bleached horizon (BL), and the clayey soil from the shale band (SH), the
RGRs show significant positive increases with drying-out. The brown
earth soil (BR) shows no significant response in RGR; it is possible, for this
soil, that the optimum soil-moisture regime Hes between treatments i and 2.

SOIL TYPE, SOIL WATER REGIME AND GROWTH 321

This is also a possibility for D, since other experiments have shown that
it is an unsuitable growing medium when saturated. The ecological
impHcations of the growth attained on Deschampsia humus in this experi-
ment are particularly meaningless, since, in all three treatments, appreciable
surface drying and shrinkage occurred. The good growth of the seedlings
probably resulted from the extensive minerahsation (Birch, 1958). As far
as could be ascertained the other humus and soils were not appreciably
altered.

Sands and Rutter (1959) have pointed out the difficulties involved in
attempting to apply growth analysis methods to experiments of this sort,
in. which a variable number of drying cycles may be included in one samp-
ling period. These difficulties are especially serious when soils with different
rates of drying-out are to be compared. However, by making several
assumptions and taking the growing season as the unit of time, it is possible
to calculate approximate figures for net assimilation rate (NAR) (Table 7).
These figures can be used to show that some of the differences in RGR
result from the effect of water-regime and soil type on NAR.

Table 7
Approximate mean values of NAR (g/m^/week) for a 16-week period in summer

1959

SMT

treatment

BL

SH

BR

D

H

I

i6-6

21-9*

27-1

23-2*

25-8

2

22-2

23-6

25-6

23-5

20-2

3

23-8

30-4

24-0

27-1

20-0

* Some leaves lost as the result of infection by oak mildew, i.e. figures probably
too high. The values are based on the following assumptions: f leaf area at harvest =
mean leaf area; leaf area/leaf wt. ratio is a constant.

There are several estabhshed examples of excessive irrigation causing
reduced growth (Bergman, 1959), but in almost all experiments of this
type maximum growth has occurred in the most frequently watered
treatment (Stanhill, 1957). An exception to this is an experiment by
Kenworthy (1949) with young apple trees. Maximum growth occurred
when the plants were watered at c. o-i atm SMT. A 9% reduction in rate
of growth occurred when the plants were watered at either 005 or 0-24 atm
SMT. Similarly, in heavy soils maximum rates of photosynthesis have
been found to occur at SMTs just above field capacity (Schneider and

322 P. G. JARVIS

Childers, 1941, with apple; Negisi and Satoo, 1954, with Pinus densi flora).
These results are, however, rather less striking than those described here.

Considering performance on the five soils in this experiment, it can be
seen that seedlings respond similarly, and in an inverse direction to that
usually reported, on soils BL and SH. On both these soils RGR and NAR
(and on BL,R/S also) increase with increasing drying-out, demonstrating
the greater suitability for growth on the drier soil. Seedling performance
on soil H is of the expected pattern, i.e. RGR and NAR decrease with in-
creasing drying-out, but the figures forR/S ratio are irregular. It is possible
that a 'small amount' of drying-out (treatment 2) stimulated root produc-
tion at the expense of the shoot. Performance on BR also varies in the
expected direction, but the differences are mostly small and not significant :
NAR, RGR and R/S tend to decrease with increasing drying-out. Per-
formance on D is remarkable in that RGR decreases and NAR increases
with increasing drying-out. This difference may be related to the occur-
rence of mineraHsation, or to some other factor such as the stability of
toxic substances in the different moisture treatments.

Part of the differences in growth, between the different soils, in response
to the water regimes may result from apparently similar water regimes
causing different degrees of water stress in the different soils. This could
be caused by differences in the osmotic pressure of the soil solution, and in
the permeabihty of the soil.

The osmotic component of moisture stress will raise the total soil
moisture stress above the SMT by a characteristic amount for each soil.
Such an effect would tend to accentuate responses, of the type occurring on
H, to water stress in nutrient-rich soils, but could not account for the pattern
of response on soils BL, SH and BR, which are anyway low in nutrients.

The method used for measuring SMT did not measure tensions develop-
ing at the root surface. When plants are transpiring rapidly, these tensions
may be greatly in excess of those in the soil short distances away. The
magnitude of tliis difference in tension will partly depend on the rate of
movement of water to the root, i.e. on the permeabihty of the soil (Slatyer,
i960). Hence, similar SMTs measured in soils of different permeabihties
do not necessarily indicate that the plants are experiencing similar moisture
stress. However, the greatest difference between actual stress and measured
stress should occur in the least permeable soils, and hence this effect cannot
be responsible for the pattern of response on soils BL, SH and BR.

Since, on soils BL and SH, RGR, NAR and R/S (on BL) increase with
increasing drying-out of the soil, it seems probable that the conditions of
aeration in these soils are hmiting growth. Inverse relations between soil

SOIL TYPE, SOIL WATER REGIME AND GROWTH 323

water content and oxygen content are well established (Furr and Aldrich,
1943; Boynton andReuther, 1939; Vine, Thompson and Hardy, 1942).
Boynton and Reuther were able to relate the performance of apple trees
to the influence of pore size on aeration; and Taylor (1949) showed that
oxygen diffusion in soil is greatly influenced by the degree of compaction
and water content of the soil, through their effects on the available air-
fdled pore space. No estimates of pore size were made for these soils, but
the estimates of apparent density, oxygen diffusion rate and water avaU-
abihty provide some relevant information about their physical properties.

The apparent densities of the soils BL and BR are close to or above the
upper hmit of 1-9, above which Veihmeyer and Hendrickson (1946, 1948)
state that, for most soils, no roots of any description are found. Mechanical
impedence apparently restricted root growth on BL, since, for all treat-
ments on this soil, only a part of the soil volume was exploited. However,
theR/S ratio increases with increasing amounts of drying-out, indicating
the interaction with aeration. It would also be expected, as noted by
Veihmeyer and Hendrickson, that the lower apparent density of the fmer-
textured soil SH would have as great an inhibiting effect as the higher
apparent densities in the coarser-textured soils.

It can be seen from Fig. 2 and Table 3 that the three soils BL, SH and BR
differ greatly from the humus soils in the amounts of water held between
o-i and 1 5 atm SMT. Hence, small reductions in water content will produce
large increases in SMT and consequent reductions in growth (Richards and
Wadleigh, 1952). However, the very small amounts of water held in these
soils may be taken to indicate very small pore volumes and hence deficient
aeration in the moist soils. Improvements in aeration as a result of drying-
out are apparently more important than the removal of water or increases
in SMT. Tliis would be expected if the conditions of aeration were restrict-
ing water or nutrient uptake.

The oxygen diffusion rates (Table 2) were obtained in connection with
another experiment and are for soils at 'field-capacity' only. They demon-
strate general differences between the soil types, but emphasise that,
although it is possible to interpret the results for any one soil in terms of
aeration and SMT, the differences in growth between soils result from
interactions of physical and nutritional factors.

It can be concluded from the results on leaf Htter that, when growth is
good and not severely restricted by other soil factors, assimilation by
seedlings is considerably reduced by low SMTs. RGR is reduced by half
by a SMT of 0-5 atm acting for 62% of the growing period (assuming
proportionahty of effect).

324 P. G. JARVIS

There are inherent difficulties in attempting to use data from experiments
of this type in field situations (Sands andRutter, 1959). The conditions of
root growth in a restricted exploited soil volume and the technique of
watering the whole soil mass back to saturation are essentially artificial.

During germination, seedlings of oak produce a very long tap-root from
their acorn reserves. Hence, they are largely insulated from the effects of
drying-out of the upper part of the soil profile by shaUow-rooted her-
baceous plants. However, as a result of the intensive exploitation of the
rooting volume in an estabhshed wood, SMTs, which arise from the drying
action of tree roots, are usually uniformly distributed, at least in the upper
parts of the profile (Boggess, 1956; Jarvis, P.G., i960). Such conditions
are not unlike those in a container.

In sessile oakwoods in the region west of Sheffield, SMTs develop only in
exceptionally dry summers, e.g. 1959. Reductions in growth as a result of
increases in SMT are likely to be of greater importance in less moist areas,
such as the New Forest. This experiment does, however, demonstrate the
probable normal occurrence of unsuitable conditions for root growth in
certain oakwood soils.

ACKNOWLEDGMENTS

This experiment was carried out as part of an investigation into the factors
influencing the growth and regeneration of sessile oak in the Sheffield
region. I should hke to thank Dr. CD. Pigott for his interest and super-
vision, and Professor A.R. Clapham, F.R.S., for the facihties of his depart-
ment during the course of this work. I am also grateful to the Department
of Scientific and Industrial Research for a Research Studentship which
made this work possible.

REFERENCES

Bergman, H.F. (1959) Oxygen deficiency as a cause of disease in plants. Bot. Rev. 25,

417-485.
Birch, H.F. (1958) The effect of soil drying on humus decomposition and nitrogen

availabiUty. Plant and Soil, 10, 9-31.
BoGGESS, W.R. (1956) Weekly diameter growth of shortleaf pine and white oak as

related to soil moisture. Soc. Amer. Foresters Proc. 83-89.
BOYNTON, D. & Reuther, W. (1939) Seasonal variation of oxygen and carbon dioxide

in three different orchard soils during 1938 and its possible significance. Amer. Soc.

hort. Sci. Proc. 36, 1-6.
Fisher, R.A. (1921) Some remarks on the methods formulated in a recent article on

'The Quantitative Analysis of Plant Growth'. Ann. appl. Biol. 7, 367.

SOIL TYPE, SOIL WATER REGIME AND GROWTH 325

FuRR, J.R. & Aldrich, W. W. (1943) Oxygen and carbon dioxide changes in the
soil atmosphere of an irrigated date garden on calcareous very fine sand loam soil.
Amer. Soc. hort. Set. Proc. 42, 46-52.

Jarvis, M.S. (1963) A comparison between the water relations of species with con-
trasting types of geographical distribution in the British Isles. The Water Rela-
tions of Plants Sywposiuni No 3 of The British Ecological Society.

Jarvis, P. G. (i960) The growth and regeneration of Querciis petraea (Matt) Liebl.
in the Sheffield region. Ph.D. Thesis, Sheffield.

Kenworthy, a. L. (1949) Soil moisture and growth of apple trees. Amer. Soc. hort. Sci.
Proc. 54, 29-39.

Negisi, K. & Satoo, T. (1954) The effect of drying of soil on apparent photosynthesis,
transpiration, carbohydrate reserves and growth of seedlings of Akamatu {Pimts
densijiora Sieb. et Zucc). Japan. For. Soc. J. 36, 66-71.

PiGOTT, CD. (1956) Vegetation, in Sheffield and its Region. Sheffield.

PoEL, L. W. (i960) The estimation of oxygen diffusion rates in soils.J. Ecol. 48, 165-175.

Richards, L.A. & Wadleigh, C.H. (1952) Soil water and plant growth; in B. T.
Shaw (ed.). Soil Physical Conditions and Plant Growth, Agronomy 11, New York.

Sands, K. & Rutter, A.J. (1959) Studies in the growth of young plants of Pinus
sylvestris L. II: The relation of growth to soil-moisture tension. Ann. Bot., Lond.
N.S. 23, 269-284.

Schneider, G.W. & Childers, N.F. (1941) Influence of soil moisture on photo-
synthesis, respiration and transpiration of apple leaves. Plant Physiol. 16, 565-583.

Slatyer, R.O. (i960) Absorption of water by plants. Bot. Rev. 26, 331-392.

Stanhul, G. (1957) The effect of differences in soil moisture status on plant growth: a
review and evaluation. Soil Sci. 84, 205-214.

Tayxor, S. a. (1949) Oxygen diffusion in porus media as affected by compaction and
moisture content. Soil Sci. Soc. Amer. Proc. 14, 55-6i.

Veihmeyer, F.J. (1956) Soil moisture, in W. Ruhland (ed.). Encyclopedia of Plant
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Veihmeyer, F.J. & Hendrickson, A.H. (1946) Soil density as a factor in determining
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Veihmeyer, F.J. & Hendrickson, A.H. (1948) Soil density and root penetration.
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Agric. 19, 215-223.

FORMULAE FOR THE ECOLOGICAL REACTION

OF CROP YIELDS

W.C.VlSSER

Instituut voor Cultuurtechniek en Waterhuishouding,
Wageniiigen, Netherlands

Many investigations dealing with the influence of growth factors on crop
yield will profit from the description of the result by a growth function.

The flexibihty of freehand curves through scatter diagrams or of poly-
nomials, fitted through the data, may be narrowed down by taking into
account the mathematical properties of a growth formula. If the yield has
to be described as the result of a complex system of productivity parameters,
the description will never be very exact without the help of a formula.
The modern technique of processing observations with electronic calculat-
ing machines requires a functional expression. A growth function based on
biologically acceptable principles may be valuable, particularly if the
growth factor has to be described by a comphcated system of plant, soil
and moisture parameters as is the case with moisture.

In the past, growth functions have attracted much attention, but interest
has decreased in later years. This may be due to insufficient integration of
mathematical reasoning and plant physiological insight. An extension of
already known formulae seems possible to make up for imperfections.

Growth functions are often considered to be entirely empirical and of no
fundamental value. As will be shown, the best known formulae, of entirely
different origin, have so much in common that one will have to consider
whether the assumptions behind these formulae have not a value exceeding
the quahfication 'empirical'.

Whatever the situation may be, it will be valuable to have a model
available describing in principle the activity of a growth factor with respect
to the maximum yield and the interaction between a number of growth
factors.

THE GROWTH FUNCTION

The oldest formula, but still the best known, is that of MitscherHch. The
most important of his ideas was, that the increase in yield per unit increase
in growth factor should bear an expHcable plant physiological relation with

ECOLOGICAL REACTION OF CROP YIELDS 327

the ecological properties and that the activity constants in the formulae
should not be influenced by any other magnitude than the nature of the
productivity factor. It v^^as not considered to be necessary that in the growth
function itself the plant physiological basis should be easily recognisable.
It has not been possible to prove these theories. This raises the questions
whether the formula was not right or v/hcther it was not apphed in the
right way.

The fundamental equation will have to express as general statement, that
the differential equation can only be a function of the yield and of the
growth factor. This may be described by

Three formulae will be discussed as examples of this general formula.

The Mitscherlich Equation

In the Mitscherhch equation the differential quotient was supposed to be
only dependent on the yield. The following equations resulted :

differential equation growth function typical form

^^ -^ (i.i) q = A{i-c-^^^^)'c) (I.,) log^^= -^ (1.3)

Multifactorial equation
ist solution

^ = A(i-e-<^-«'i)/'^i)(i-e-<2/-«'2)/c2)(i_e-(3-&3)/c3) ... (1.4)

2nd solution

q = A(i — e-i^-h)/ci-(y-b2)c2-(.z-b3)c3 . . .) (1.5)

The solutions of eqs. 1.4 and 1.5 are represented in Figs, i and 2.

Discussion

In I.I the increase in yield is a function of the deficit with respect to the
highest attainable yield A. The maximum increase for ^ = o is equal to A/c.
It seems questionable that the yield increase for q = o should be a function of
the maximal yield A. The equation 1.3 shows that the logarithm of the
yield deficit in parts of the maximal yield is a linear function of the level of
the growth factor. This is an important property for graphical treatment.

328

W. C. VISSER

Growth tactor X

Growth factor X

Fig. I. Shape of the growth curves according to the law of diniimshing returns, or
Mitscherhch equation, for two growth factors x and y. Exponential approach to
asymptote. All curves have same shape if expressed in percentage of maximum yield.
Fig. 2. Second solution of the differential equations of the Mitscherhch assumption.
Yield equation for substituting, or antagonistic, factors. All curves have same shape
but are shifted to the left.

In formula 1.4 the logarithm of the yield is an additive function of the
influence of any separate growth factor. In formula 1.5 the same is true for

the yield deficit.

The curves in Fig. i depicting formula 1.4 may be derived from each
other by vertical change of scale. The curves in Fig. 2, depicting formula
1.5, may be derived by horizontal translation of any of these curves.

The Projective Yield Function
The projective function is often considered as an empirical formula. It may
be proved, however, that the formula is based on the assumption that the
yield increase is directly related to the yield deficit and inversely related to
the level of fertiHty.

The following equations result :

differential equation growth function

x+B

(2.1)

q^A

x—c
x+B

(2.2)

typical form
A X . B

A-a B-c B-c

(2.3)

Multifactorial equation
ist solution

= A ^

y-c^z—c^

x+Bj^ Y+B2 2-+B3

(2.4)

ECOLOGICAL REACTION OF CROP YIELDS
2nd solution

= aL

329

(3.5)

i {x+B^){y+B^){z+B,)...
The eqs. 2.4 and 2.5 are depicted in the Figs. 3 and 4

Discussion

In formula 2.1 the yield increase is supposed to increase in relation to the
yield deficit and inversely with the level of fertility. The growth equation
is a projective function and the inverse value of the yield deficit bears a
linear relation with the growth factor as given in 2.3. In the multifactorial
formula the logarithm of the yield or the yield deficit is, as in the Mitscher-
hch equation, the sum of the logarithms of the influences of every growth
factor separately as appears from the first and the second solution. This
property is important for a graphical analysis of the effect of a number of
growth factors on the yield.

The curves in Figs. 3 and 4 offer a picture of the relations given by the

Growth factor X

Growth factor X

Fig. 3. Shape of growth curves for projective law of plant growth. The curves are
somewhat steeper for low yields and give a somewhat more gradual increase in
yield at high fertility levels than the exponential curves of Fig. i. The part valid for
practical yield levels may approach the exponential curves very closely. The yields in
per cent of the maximum give the same curves for different values of the y-factor.
Fig. 4. Second solution of the differential equation to be compared with the curves
in Fig. 3. The curves may be derived from one single curve by expanding it in a
vertical and horizontal way by means of two multiphcation factors. Shape of growth
relation often found in field experiments.

formulae 2.4 and 2.5. The curves in Fig. 3 may be derived from each other
by changing the vertical scale, the curves in Fig. 4 by changing the hori-
zontal scale. If instead of the horizontal scale of .v, the curves are plotted

330 W, C. VISSER

against logx, than the curves are transformed into the type of curve of the
Mitscherhch equation.

The Equation for Limiting Factors

The productivity equations just discussed are not able to reproduce the
consequences of the assumption that the growth factor is taken up by the
plant in a fixed ratio to the amount of yield produced. If more of the growth
factor is present than the plant needs for the production of its substance a
part of the amount of nutritive material will not be taken up, or will be
used for luxury consumption. The functions discussed before, deal mainly
with this improper use of the nutritive material. The following assumption
takes also into account the fixed relation between the yield and the amount
of nutritive material that is necessary for plant growth.

The formulae are the following :

differential equation growth function

^ = ^+'(3.1.) or ^='p5+i,(3.:6) {..-^)(A-,) = D
dq A— a a dq A—q a

(3.2)

Multifactorial equation

ist solution

{ax-q){hy-q){cz-q)...{A-q) = D (3.4)

2nd solution

{{ax-B) + {by-C) + {cz-E) + ...}{A-q)=D (3.5)

The eqs. 3.4 and 3.5 are represented in Figs. 5 and 6.

Discussion

The yield increase is assumed to be constant and equal to ija, provided that
no other factor is Hmiting growth, nor should the growth be inhibited by
the hmit of expansion A of the plant. The differential equation may assume
two shapes, which may be derived from each other. Formula 2.1a is a
direct and logical expansion of the formulae i.i and 2.1. For x and q zero
the yield increase in the formula 3.16 is not dependent on the optimum
yield A. This seems more acceptable than the resulting value for the
formulae i.i, 2.1 and 3.1 a where the differential quotient for the minimum
yield depends on the optimal yield.

In the multifactorial eq. 3.4 a new property is met. If only a few factors
are taken up the equation takes for each factor separately a shape which

ECOLOGICAL REACTION OF CROP YIELDS

331

differs from the solution in which a larger number of factors are given a
place. For two growth factors the formula is of the third power and for
every growth factor added the power increases by one unit. In the formulae
I.I and 2.1 the expression for a factor is not changed if other factors are
taken up or left out. The formula implies that to solve an ecological problem,
every factor should be accounted for, and the result obtained with a

q
100

' (x- q)(y-q) (100 -q) =2000
Q=100 y

y = l50

y = lOO

y = 60

so

/^

y = 30

/ \ 1 1 1

0

SO

100

ISO 200

X

Fig. 5. Shape of the growth curves according to the law of Hmiting factors. The
approach to the asymptotes is closer if more growth factors are taken into account. The
curves are all of a different shape with a bend sharper, the higher the maximum yield.

Fig. 6. Second solution of the differential equations of the type of 3.1 a where the law
of Hmiting factors is assumed. Case of substituting, or antagonistic, factors.

selection of the growth factors may not be considered equivalent to the
result for the full solution.

The eqs. 3.4 and 3.5 are depicted in Figs. 5 and 6. The curves in Fig. 5
bear no simple relation to each other. The curves in Fig. 6 are shifted in a
horizontal direction.

332 W. C. VISSER

The Use of the Growth Equation

The correct use of the growth equation requires careful consideration about
the nature of a growth factor and of the different solutions of the equation.
Soil properties, as clay content or soil structure, are not growth factors.
They are only in some ways related to them. Rainfall, for instance, is in
itself not a growth factor, but it may constitute a part of the factor water.
We will call these empirical productivity characteristics growth para-
meters. A definition of what a growth factor is seems hard to give. We will
understand the meaning of such a designation here as an outside influence
expressed in such a way that irrespective of the level of any other growth
factor it exerts the same significance for the crop yield.

The aim of the construction of a growth equation is to describe how the
level of a growth parameter, determined outside the plant, defines the
actual importance of the factor as it acts inside the plant. If the observations
of the value of the growth factors are made inside the plant, then the
formulae may serve to defme the activity of such factors. A further aim is to
define how a growth factor influences the effect of other growth factors.

A growth factor now may be a function of the growth parameter and
the growth parameter may constitute a part of the growth factor. Further,
the growth parameter may bear a complex relation together with other
parameters to the growth factor, but also the parameter may contribute to
more than one growth factor.

If the parameter is indicated with p and the factor with/ then in the
formulae the following expressions may have to be used to obtain a good
representation of the yield function. These linear or functional expressions
should fit from a mathematical as well as from a plant physiological
standpoint :

f=S{p){4.i) f=ap^+bp^{4.2) f=gi{pi)+S2{P2)+gz{P3) + --- (4-3)

fi-gi{Pi)+g2{P2)+ ■••] (,A

f2=sM+sM+---y ^^'^^

An instance of formula 4.1 with the factor a function of the parameter,
might be the groundwater depth. The logarithm of that productivity
parameter fits better into the growth equations than the depth itself If this
logarithm is inserted in formula 1.2, this changes into formula 2.2.

Formula 4.2 represents cases as the combined influence of natural rain
and sprinkhng, where the artificial rain will be given in dry spells only and
will be more efficient as a productivity factor, shown by a higher constant
a, whilst natural rain is less effective because it also falls in wet periods and
has to be given a lower constant b.

ECOLOGICAL REACTION OF CROP YIELDS 333

Formula 4.3 may depict the growth factor water with parameters as
clay and humus content, depth of water table and rainfall, each with its own
characterising units and functions to express the part of the moisture factor
which they each represent if their activity is expressed in the same scale of
the growth factor.

Formula 4.4 represents the general case with empirical growth indicators
where none of the parameters represent a theoretically pure growth factor.
An instance is the optimum curve, which may be given by a formula :

q = A{i- e-Oi<Pi^) (i - e-P+02(Pi))

Here a stimulating factor •^^=^l(Pl) is correlated positively with the para-
meter pi, and an antagonistic growth factor dy= — p +^2(^1) ^^ correlated
negatively with pi. Other growth parameters may be added or subtracted
to the functions of p. Instead of a formula of the type of 1.4, formulae of the
type of 2.4 or 3.4 might just as well have been used here. The point to be
stressed is, that if for one growth parameter an optimum curve is found,
this means that two growth factors x and y are behind such a type of
reaction, and that each of the formulae given can easily depict such an
optimum reaction.

If two plant physiologically independent growth factors are influencing
the yield, they may, however, comprise the same parameter. Humus, for
instance, may bind nutritive cations as well as water. Now a yield,
influenced by water and cations, may assume the following shape :

q = A(i — e-9i(Pi)-g2(P2)-'"\ U — e-g3iPi)-gi(P3)-"-\

Here we see the expressions according to case 4.3 and 4.4 combined, as
humus represented by pi appears in two factors. In each of them humus is
combined with another parameter, with p^ representing rainfall in the
moisture factor and p^ representing artificial manure in a nutritive factor.

The type of growth function depends on four considerations being,
(i) what assumption is made with respect to the growth formula, (2) what
expectations exist as to the component parts, which build up the separate
growth factor, (3) what knowledge is available as to the functions, which
reduce the parameters to the same scale and (4) what is the value of the
constants? These considerations should be mathematically, physically and
physiologically sound. The number of parameters in ecological investiga-
tions may be very large. The number of growth factors, however, is much
more restricted. It will be important to study how the parameters should
add up to the relevant growth factor and how the growth factors co-operate
in the yield.

334 W. C. VISSER

Some Instances

From field observations concerning the relation between groundwater
depth and yield, during a number of years, collected on different soil
profiles, a graphical representation was made for advisory use. It was
considered necessary to control whether the graphical representation agreed
with the growth equations and growth functions as far as this might be
expected from the superficial indications available.
In the inserted graph in Fig. 7 the curves are given, which represent all

Yield depression In °/o
O

120 1 50 200

15 20 30 40 50 60 70 80 90IOO I40 I80

Mean ground-water level in cm- surface during growth period

Fig. 7. The yield curves for increasing groundwater depth (see inserted graph) were
constructed with all data available in the Netherlands. By plotting against the
logarithm of water depth the curves become to a certain extent parallel, pointing to
formula i . 5. The horizontal distance is a measure of the influence of water availability
not related to grouiadwater depth.

the information then available on the relation of the yield to the ground-
water depth. The convergent left-hand part of the curves seems to indicate
that formula 2.4 might be applicable, or formula 1.4 with a logarithmic
scale for the groundwater depth. This logarithm furnishes a close parallel
with the pF-concept for soil moisture and seems plausible. The logarithmic
scale leads to the main curves of Fig. 7. The parallel left-hand ends of the
curves suggest the additive solution of formula 1.5, expressing that the soil
moisture in the profile and the logarithm of the groundwater depth may
be considered as additive parameters. By shifting the curves horizontally,
they will coincide as far as they depict the influence on the yield of the
growth factor which is described by the combined effect of ground water
depth and profile type.

ECOLOGICAL REACTION OF CROP YIELDS

335

By this horizontal shift the curve for the influence of the air is found as
the envelope A of the curves for the seven profiles. Because, however, not
only a horizontal, but also a vertical shift is necessary, a relation with the
second growth factor has to be taken into account. This relation is given
by formula 1.4 which shows, that the logarithm of the yield has to be taken
as vertical scale in order to obtain an additive relation between two growth
factors.

The difference between the right-hand end of the curves and the envelope
in Fig. 8 now gives quantitative information with respect to the second

Yield differences

Variation in ground-water level

Fig. 8. The envelope A of the curves, after shifting to part coincidence, depicts the
influence of lack of aeration. The deviating branches, depicting the influence of water,
give the influence of the factor water separately if subtracted from the envelope when,
according to formula 1.4, the yield is first plotted logarithmically.

growth factor, which obviously is the factor water. These curves are given
in Fig. 9. In order to fmd out whether in this case also an additive relation
according to formula 1.5 is present, the logarithm of the yield deficit,
represented in Fig. 9, was plotted against the logarithm of the water depth.
Figure 10 depicts the result. If here the water depth was the exact growth
factor, than the hues should, according to formula 1.5, not only be parallel,
but also straight. The first is true, the second point, however, is not. By
shifting the hne in an oblique way they coincide fairly accurately. The
reaction curve B shows how the growth factor water correlates with the
logarithm of the water depth. If the logarithm of the vertical co-ordinates
of curve B is determined with the horizontal asymptote of line B as zero
point, and plotted against the logarithm of the Vv^ater depth, then a straight
line is obtained, showing that the growth function for water is an exponen-
tial function of the groundwater depth. This means that a close parallel
exists with the capillary movement, which might be expected.

336

W. C. VISSER

The logarithm of the vertical co-ordinate of curve A in Fig. 8, with the
horizontal asymptote as zero line, also approaches a straight line and shows
that there exists a close parallel between the growth factor governing the

Yield depression
O

15 20

40 60 80 lOO I40 200

Ground- woler level in cm-surtace

Fig. 9. The influence of the factor water, derived by the subtraction of the logarithms
of the yields, plotted against the numerical value of the yield.

Yleld^ depression in %

50-
70-

20

40 60 80 120

Ground-water level in cm-surface

Fig. 10. The deficit in yield of Fig. 9, plotted logarithmically against the logarithm of
the water depth, shows parallel hnes pointing to the applicabihty of formula 1.5.
The curves may be shifted to coincidence, giving curve B for the influence of the
groundwater depth.

left-hand side of the curves and the air content in the soil profile, as is
found by comparmg with pF-curve.

The relation between the yield and the groundwater depth, as derived
from the available field observations, is not in contradiction to the yield
formulae nor to experience with respect to soil physics and plant physiology.

ECOLOGICAL REACTION OF CROP YIELDS

337

A second instance deals with the influence of sprinkling irrigation and
nitrogen supply on the number of grazing days of cattle on perennial
grassland. The original data were not very accurate and a rehable fitting of
the yield curves was only possible if the functional relation between the
yield, the nitrogen and the appHed amount of water was given in advance
(Fig. ii).

pQ^Production grazing days

800

700-

600

500

400

lOO

200 300 400 500

mm overhead irrigation

900

800

700-

600

500

400

Production

grazing days

-"'^ZtO'H

/^^

280w

^

2IOw
Ow

1 L.. ..1 1 1

ICO 200 300 400 500
kg/ ha nitrogen

Fig. II. The influence of sprinkling irrigation and nitrogen on grazing days can best
be described with formula 3.4 for the law of the limiting factors. The result for a dry
year was found as depicted above.

It is well known that the yield function for the growth factors water and
nitrogen may often be approximated by a straight line if quantities of
water, nitrogen and yield are plotted against each other. This suggests that
the law of limiting factors applies and formula 3 . 4 in the shape

(x+A-rt^) (y+B-^ {Q-q) = D

may be used. The constants A and B mean that part of the moisture and
nitrogen, used by the plant, originate from rainfall, combined with soil
moisture and from nitrification respectively. For the dry year, the value
of .4 was found to be 350 mm whereas a appeared to be 500 1 water per kg
dry material. B was found to be 400 kg and h equal to 20 kg dry material
per kg N. The values for A and B correspond well with what might be
expected. The rainfall may accoimt for 220 mm of the value o£A, and
130 mm extracted water from the profile is not in contradiction with the 6
to 14 sprinklings given with an average of 28ommappHedwater(Fig. 11).
It would have been difficult to fmd the relation between the yield and
the two growth factors without an assumption as to what kind of relation
might be expected. Reasoning about the model of the yield function to be

338 W. C. VISSER

considered, valid leads to the formula for the law of hmiting factors. Curve
fitting without such a formula would not easily lead to results acceptable
from a plant physiological standpoint. It should be mentioned here, that
the exact mathematical treatment of the equation for the hmiting factors
does lead to considerable difficulties, if the aim should be to determine the
unknown constants a, h. A, B and C.

Summary and Conclusion

Growth functions should be constructed with regard to plant physiological
reasoning. Differential equations, giving the increase in yield per unit of
the growth factor, supply the basic relations. Simple assumptions for the
relation between the yield increase, the yield and the growth factors already
give useful formulae for the yield patterns, but increased refinement of the
assumptions are needed to obtain the flexibihty to depict the different
relations which may be encountered.

The growth equations are able to handle any number of ecological
variables and allow the description of complex productivity situations.
It is, however, necessary to know how these empirical productivity
magnitudes should be inserted into the formulae. There are only a restricted
number of growth factors, but only seldom will it be possible to obtain
quantitative observations of a theoretically correct, uncontaminated growth
factor, for which alone the simple solutions of the differential equations are
vahd. The value of the theoretically correct growth factor has to be built
up from the values for the relevant ecological parameters.

This reconstruction of the value of the real growth factor may be attained
by using a function of the ecological factor instead of the value itself. Also
it may be necessary to construct the growth factor using a number of
different yield parameters or the same parameter may be necessary to
describe different growth factors. This makes the equations very flexible,
but it may be rather difficult to give empirical yield parameters their correct
place in the equation.

It seems that the assumption 3.1 provides the most acceptable basis for a
yield equation, because the law of limiting factors is more easily justified
than the law of diminishing returns, described by formula i.i. Also
equation 3 gives a better account of what might be physiologically expected
with regard to the interaction between growth factors.

The main problem in ecological research is, however, to translate the
description of the ecological situation with many values into a description
of the restricted number of well-defined but complex growth factors.
Every growth factor should be constructed using the relevant ecological

ECOLOGICAL REACTION OF CROP YIELDS 339

parameters and the proper function of each parameter should be deter-
mined. To find the functions of the parameters, often a reverse reasoning
will as well be valuable. The object in that case is, given the yield and the
growth equation, to construct the function of the combined ecological
parameters in such a way that the observations fit well in the growth
equation. The observation that the combination of functions of the
parameter produces a relation similar to the simple growth equation, shows
that the solution arrived at cannot be far from correct. In this way an
insight into the interaction and the activity function of the parameters may
be obtained.

THE GROWTH RESPONSE OF SUGAR BEET TO

SIMILAR IRRIGATION CYCLES UNDER

DIFFERENT WEATHER CONDITIONS

B. Orchard
Rothamsted Experimental Station, Harpenden, Herts.

INTRODUCTION

Owen and Watson (1956) reported that when prolonged drought was
broken by hght rainfall, unirrigated sugar beet had a greater relative growth
rate than irrigated controls and Gates (1955) reported a similar phenomenon
in young tomato plants growing in pots. Tliis paper describes an attempt
to reproduce and analyse these effects by controlled watering of small field
plots protected from rainfall by a static Dutch-hght structure. Three similar
experiments (two in summer and one in autumn) were done on the same
variety of sugar beet growing on the same plots in three successive years so
the effects of radiation and other weather factors on the development of
the drought response and the recovery from it can be considered.

EXPERIMENTAL

General

Two treatments in which irrigation was withheld for a period, brief
drought (B) and continued drought (C) were compared with a freely
available moisture treatment (A). Before the drought and throughout
treatment A the plots were maintained near field capacity by frequent
watering. The plots were on a heavy clay loam, formerly a garden. The
moisture content- pF relationship was determined by the method of
Monteith and Owen (1958). Field capacity was about 28-30% of the oven
dry weight and the permanent wilting percentage (pF 4-2) I3"8%. The
moisture content at pF 4-2 was greater than for a typical Rothamsted soil,
possibly because of residual salts from tap-water used in previous irrigation
experiments.

Sugar beet seed (Sharpe's Klein E) was washed for two hours in aerated
running water, planted in soil blocks and covered with sand containing
'Harvesan' (120 mg per kg). One seedling per block was retained, and when
the seedhngs were well estabUshed the blocks were planted at a spacing of
I ft X I ft in plots of 14 ft X 9 ft. The soil was dry at planting and afterwards

GROWTH RESPONSE OF SUGAR BEET 341

was watered, freely. Metered quantities of tap-water were applied, with a
hand-rose in Exp. i and with a mobile overhead sprayhne in later experi-
ments. Soil moisture was determined routinely on samples from the 0-12 in.
layer. Flints made sampling at lower levels impracticable.

The crop was sampled on six occasions in Exps. i and 2 and on four
occasions in Exp. 3. In Exps. i and 2, one 3 ftx 3 ft area of crop (nine
plants) and in Exp. 3, two 2 ft x 3 ft areas (six plants each) were taken at
each sampling.

The plants were separated into roots and tops, and the tops were sub-
divided into laminae and stem plus petioles. The fresh and dry weights of
each part, the total leaf area and the number of Hving leaves were then
determined. Leaf area was estimated by the method of Owen (1957) in
Exp. I, and by the scanning planimeter (Orchard, 1961) in Exps. 2 and 3.

Details of Experiments

Experiment i (1958) and Experiment 2 (1959)

These experiments were similar in design and will be discussed together.
The plots received 10 cwt/acre of a compound fertihser containing 7% N,
7% P2O5 and 10-5% KgO. The seed, was sown in mid- April. In 1958,
seedlings were planted on the plots 21 days after sowing, butini959 plant-
ing was delayed 14 days, so that an attack by Rhizoctonia spp. could be
controlled. The A plots were maintained near field capacity throughout
and no water was apphed to the C plots after June 25, except for i in.
between the fifth and sixth samphngs in 1958. These treatments were
comparable in the two experiments, but the B treatments differed (Table
i). The 1958 regime was intended to produce water stress but no wilting;
the plots were rewatered as soon as the soil moisture content reached 15%.
Two drought cycles of this type did not affect growth, and a third, more
severe, cycle was given, so that the recovery from drought could be
studied.

In 1959, therefore, drought was continued until growth was significantly
affected. The drought was then broken by ^ in. of water, but there was no
further watering for 8 days ; the plots were then returned to field capacity.

The three treatments were repHcated in four randomised blocks.

Experiment 3 (Autumn, i960)

The stubble left after an experiment on barley was burnt with a flame-gun
and rotary cultivated. No fertihser was added. Before sowing the barley, 2
cwt/acre of a compound fertihser containing 13 % P2O5 and 13 % KgO was

343

B. ORCHARD

Table i

Details of droug]

It regimes

Water

applied (in.)

Date

A

(
To

To treated

Expt.

Treatment

Cycle

From

To

A plots

plots

I

B

I St

27. 5.58

12. 6.58

2-4

1-4

B

2nd

12. 6.58

3- 7.58

3-0

i-i

B

3rd

3. 7-58

30. 7.58

3-4

2-0

2

B

ISt

2. 6.59

I. 7-59

5-7

(0-57)

B

2nd

I. 7-59

13- 7-59

2-9

3-4

3

BL

8. 9.60

3. 11.60

1-7

(0-29)

BH

8. 9.60

3. II. 60

1-7

1-67

BL,BH

3. II. 60

4. 1. 61

nil

nil

I

C

24. 6.58

23. 9.58

9-6

(0-5 + 0-5*)

2

C

25. 6.59

18. 9-59

14-5

nil

3

C

8. 9.60

4. 1. 61

1-7

nil

The beet were transferred to the plots on 8.5.58, 22.5.59, 12.8.60 respectively.
Applications of water insufficient to return the plots to field capacity shown in brackets.
* On 3.9 and 8.9.58.

applied to all plots and 1-5 cwt/acre of nitro-chalk (21% N) to half of each
plot. Seed was sown in soil blocks in latejuly and seedlings were transplanted
22 days later. Treatments A and C were the same as in Exps. i and 2. The
B and C treatments started simultaneously in mid-September. In the B
treatments the drought was broken in early November but half the plots
(BH) were then held at field capacity, while the others (BL) received only
I in. of water and were not irrigated again.

Samphng was arranged so that the residual effects of the differential
nitrogen treatment apphed to the barley could be estimated. The number of
plants per sample was decreased to six to provide four pairs of samples per

plot.

The four water treatments were repHcated in three randomised blocks.

WEATHER
Weather conditions differed during the three experiments. The total daily
radiation (Kipp radiometer), hours of sunshine and evaporation from the
standard i/iooo acre water surface showed similar time changes and only
data on total daily radiation will be presented (Table 2). The radiometer

GROWTH RESPONSE OF SUGAR BEET 343

Table 2

Mean Regression of radiation on time

radiation , — ■ '^ -■ — ^

Year Cal/cm^day Cal/cm^/day/day %/day

1958 317-4 -1-75 -0-55

1959 401-2 -1-75 -0-44
i960 ii3"i —2-25 —2-00

measured the radiation incident on the glasshouse, and the figures are not
corrected for the transmission of the structure (about 70%). The daily-
radiation fell significantly throughout each experiment.

During 1959 the experimental period had the greatest mean daily radia-
tion and the smallest relative rate of decrease; 1958 had a smaller mean
radiation and the same absolute rate of change as 1959. Although these
time changes were significant they were not large and did not greatly
change the growing conditions during the experiment. In i960 the experi-
ment was done later in the year when the mean radiation was still less, and
the change with time was greater; the growing conditions therefore
changed appreciably during the experiment. In the fmal sampHng interval
temperature and illumination was unfavourable for growth.

Soil Moisture

As only the top 12 in. of soil was sampled, the change in soil water content
does not represent the total water loss during drought, when the relation-
ship between the various soil layers was unpredictable. Under treatment A,
soil water moves more freely, so that when the 0-12 in. layer is at field
capacity the entire profile will usually be equally moist and changes in the
0-12 in. layer can then be used as a rehable guide to water requirements.

The water consumption of the A plots, which can be used as an estimate
of the maximum deficit in the B and C plots, was about twice the amount
of water required to regain field capacity in Exps. i and 2, but in Exp. 3
the amounts agreed to within 2%. At least part of the discrepancy was
caused by restriction of transpiration during drought on B and C plots.
In i960 transpiration was already low and therefore insensitive to drought.
The average moisture content of the A plots was higher in 1958 than in
1959 so that there was more risk of drainage and the difference in water
used (Table i) may underestimate the difference in transpiration.

23

344

B. ORCHARD

1-5

CM
E lO

a>

OS

B.
.Watered

Expl. I. 1958

Tc.

Started

I 1. L_

Expt. 2. 1959

B.
Watered

C Started

I . ' 1 — ,_

05

Expt. 3. I960

025

B.Walered
i

Julv

Aug

Sept

July I Aug I Sept Oct I Nov I Dec

Fig. I. Total dry weight of plants. Circles -treatment A, squares -treatment B (BH)
(open squares treatment BL), triangles -treatment C. A-frequent watering, B -inter-
mittent drought, C-continuous drought, as detailed in Table i. Vertical lines, least

significant differences (P<o-05).

RESULTS

The results of Exp. 3 are given as means of the two nitrogen levels. The
nitrogen residues from the previous experiment had no important inter-
action with water regime, although they increased the dry weight and
leaf area of the plants significantly they had no effect on the relative growth
rates in the experimental period.

Effects of treatments have been expressed as percent of the value for the
A plots.

Dry Matter Production

Dry matter production was significantly affected by drought in only one
of the three experiments; in 1959, treatment B (Fig. i) decreased the yield
by 38% after 23 days without watering. The corresponding treatment C
caused a similar decrease but the relative response was smaller (10%). The
increase in dry weight during the second moist period of treatment B
was only sHghtly greater than with treatment A, and the difference in dry
matter yield between A and B persisted for over 9 weeks.

The 1958 B plots gave no sign of a drought effect but the decreased dry
weight of the C plants at the final harvest was almost significant. This was

GROWTH RESPONSE OF SUGAR BEET

345

mainly because dry matter was suddenly lost from the tops possibly as a
response to the i in. of water appHed during the last sampling period, and
not because of a steadily mounting drought effect. The treatments had no
significant effect in Exp. 3 ; the large differences were the result of initial
variation between plots. The relative growth rate was not affected except
during the last interval when it was decreased by treatment B.

The dry matter contents of the various parts of the plant were not equally
affected by drought. In Expts. i and 2 the top/root dry weight ratio (Fig. 2)

Expt I. 1958

ExDt 2 1959

Expt 3 I960

3 -

IT

B. Watered

T

C. Started

July I Aug I Sept

Jul

Aug I Sept Oct

Nov

I Dec I

Fig. 2. Top/root dry weight ratio. Symbols as Fig. i.

and the lamina/petiole dry weight ratio (Fig. 3) fell uniformly with time.
The effect of drought was small and acted oppositely on the two ratios.
The decreased yields were entirely in the tops ; the weight of roots was
unaffected, so the decrease with time in top/root ratio was accentuated. In
contrast, the time trend in lamina/petiole ratio was decreased by drought,
the yield of lamina being decreased less than the yield of petioles. The
results of the two experiments were consistent but in 1958 the drought
effects were not significant. In 1959, whereas the effect of the C treatment
was only just significant, treatment B had a highly significant effect on the
top/root ratio, and increased the lamina/petiole ratio significantly during
the recovery phase.

In Exp. 3 the top/root ratio fell at first and then became almost constant,
the lamina/petiole ratio fell a httle and then rose slightly. The lower growth
rate of the BL plots during the fmal interval was not accompanied by

346

B. ORCHARD

changes in either ratio. The differences between experiments in the
changes in dry matter distribution with time was probably caused by
differences in the weather. Radiation and temperature were particularly
unfavourable for growth during the final sampling interval in Exp. 3.

Leaf Area (Fig. 4)

The changes with time in leaf area index (L) were similar in all experiments ;
L reached a maximum when the plants were 3-4 months old and then
decreased. Maximum L was shghtly less in 1959 (5-3) than in 1958 (6-3) and

15

O

O 5

Expt I. 1958

T t

B Watered
TC. Started

Expt 2. 1959

I Sept

Expt 3. I960

July I Aug I Sept I July 1 Ajg I Sept Oct I Nov I Dec I

Fig. 3. Lamina/petiole dry weight ratio. Symbols as Fig. i.

much less in i960 (1-3). Area per leaf was similar in Exps. i and 2, so the
smaller maximum L was caused by a lower leaf number. In Exp. 3 low
temperature and radiation decreased both leaf expansion and, less severely,
leaf production. In all experiments the fall from the maximum was the
result of decrease in area per leaf, and leaf number continued to increase
with time (fig. 6).

Maximum L was less than that reported by Owen (1958) (78) for beet
growing on the same plots but greater than that of sugar beet grown in
the field atRothamsted in 1958 (Orchard and Monteith, unpubUshed) or in
previous years (Watson, 1947). Maximum L was attained sUghtly earher
under glass than in the open.

All drought treatments decreased L. The treatment B had the greatest

GROWTH RESPONSE OF SUGAR BEET 347

Expt. I. 1958 Expt. 2. 1959 Expt. 3 I960

J a Watered
C. Started

. TT

I B. Watered
C Started

1 L 1 1 1 ' ■ ' ■ I I I I I 1 1

July 1 Aug I Sept I July I Aug I Sept Oct I Nov I C -c

Fig. 4. Leaf area index. Symbols as Fig. i.

Expt. I 1958

Expt. 2 1959

Expl. 3 I960

I July I Aug I Sept | July | Aug Jsepl Oct | Nov | Dec |

Fig. 5. Relative leaf growth rate. Symbols as Fig. i.

348

B. ORCHARD

effect (54%) in 1959 and the least (25%) in i960. The effect in i960 was
not significant, probably because of the large initial differences between
plots but there was however a significant, positive correlation between L
and plant moisture content at the first sampling. Treatment C had very-
similar maximum effects upon leaf area index in different years (30, 36 and
35% respectively). After watering, the decrease in L from treatment B
disappeared within 21 days. The high relative leaf growth rates (Fig. 5)
during the recovery period were transient and the B plots never attained a

D

a

Q.

40

30

20 ■

Expl. I. 1958

t T

y B.Watered
C. Started

I I I L.

Expt.2. 1959

J I I 1 1-

Expt 3 I960

I July I Aug I Sept 1 July I Aug I Sept Oct I Nov I Dec I

Fig. 6. Leaf number per plant, (i960 treatments B, C, not shown). Symbols as Fig. i.

significantly greater L than the A plots. Recovery from the BL drought in
i960 was incomplete and temporary, as the leaf area decreased at the final
harvest to that of treatment C. The water appHed during the eleventh week
of treatment C in 1958 checked the decrease in L.

In 1958 and 1959, both treatments B and C decreased the area per leaf
but only C decreased the leaf number significantly (Fig. 6). Leaf number
also increased rapidly after watering and occasionally sHghtly exceeded that
of treatment A, as in 1959 when with treatment B leaf number made a
transient but just significant contribution to recovery.

60r

GROWTH RESPONSE OF SUGAR BEET 349

Expt. I 1958 Expt. 2 1959 Expt. 3 I960

I July I Aug I Sept I July I Aug |Sept Oct | Nov | Dec |

Fig. 7. Net assimilation rate. Symbols as Fig. i.

Net Assimilation Rate (Fig. 7)

The net assimilation rate (E) differed significantly between experiments,
and was greatest in 1959 and least in i960, in accordance with the observed
differences in total radiation. E was not depressed consistently by water
shortage. The 1959 drought did, however, have a significant after effect on
E; when the drought was broken by ^ in. of water, E was increased signifi-
cantly. This increase persisted for a second 14-day period during which
the plots were returned to field capacity.

Moisture Content (Fig. 8)

The moisture content fell with time, more slowly in Exp. 3 in which the
mean moisture content was slightly less than in Exps. i and 2. The moisture
content of the tops was greater than that of the roots and was affected more
by treatment. The drought effect (relative to the A value) was similar in all
three experiments ; drought decreased the moisture content of the plants
by 26-30% and restoring the plots to field capacity restored the moisture
content to within 10% of the A value before the next samphng occasion.

I July I Aug I S«pt I July I Aug jSepl Oct | Nov | Dec |

Fig. 8. Moisture content, (i960 roots, treatments B, C, not shown.) Symbols as Fig. i.

The action of small applications of water on moisture content was small
even on the 1959 B plots where it affected leaf growth rate considerably.

The moisture content changes were almost certainly not correlated in a
simple manner with turgor changes. The different response of tops and
roots to treatment, and the small effect of hght watering, indicate a change
in composition of the dry matter of the plant rather than reversible loss of
water.

DISCUSSION

The most interesting effect of weather was on the large stimulation of
growth by watering after drought (after effect) which apparently required
high radiation for its expression. The relative leaf growth rate during the
recovery from drought was significantly greater than that of the A plots in
both 1958 and 1959, but the effect on net assimilation rate (E) was significant
only in 1959 (Table 3). The increase in E, however, was associated with a
decrease in L and was insufficient to increase the crop growth rate. The
absence of a significant effect on E in 1958 might be explained by the small
effect of drought on leaf area in that year. This does not, however, explain
the absence of the phenomenon from the experiment in 1957 of Owen
(1958). Owen's treatment B had almost the same effect on L as the 1959
treatment but it had no after effect on E. Owen's B plants had twice the leaf
area but received less radiation than the 1959 B plants. Although it is possible

GROWTH RESPONSE OF SUGAR BEET 351

Table 3

The effects of watering on the growth of previously droughted sugar beets (B) in
comparison with freely watered plants (A)

Leaf area index

Relative

Net

(leaf area/ground area)

leaf

assimila-

X

growth
rate

tion
rate

Mean

(

14 days

radiation

Before

after

%/

g/mV

cal/cm2/

Year

Treatment

watering

watering

week

week

day

1955

A

2-3

2-6

5

34

\ ,

(Owen &

B

i-o

1-6

20

96

^>48o*

Watson)

S.E.

±0-12

±0-17

±6

±14

J

1957

A

5-0

6-3

II-5

30

\ .

(Owen)

B

2-5

4-3

27-0

38

\ 298

S.E.

+ 0-12

±0-39

—

±6-5

J

1958

A

6-4

5-3

-8-9

7

\

B

4-8

6-0

II-O

14

" 273

S.E.

+ 0-34

±0-39

±4-9

+ 5-1

-

1959

A

3-1

4-1

13-3

32

\ .

B

1-4

2-3

24-0

54

\ 482

S.E.

+ 0-1 1

±o-io

±1-5

±3-9

J

i960

A

I-I5

1-30

2-2

12

\

B

0-88

1-07

4-5

17

\(>o

S.E.

±0-088

±0-175

± 3-0

±2-7

* Assuming transmission of glasshouse = 70%.

that the difference in leaf area may have been important (the after effect has
only been observed in crops with L less than 2-5), it cannot be the main
factor otherwise a large after effect would have been observed in i960
(maximum L 1-3).

The maximum after effect of the 1959 B treatment on E (112%) was
somewhat smaller than that originally described by Owen and Watson
(1956) (182%), although L, the drought effect on L, and the effective
radiation (taking the transmission of the glasshouse as 70%) were closely
similar in the two experiments.

Owen and Watson's plants were growing in an open field on hght,
sandy soil and so are not strictly comparable with those in my experiments.
Further, the hght transmission of the Dutch-hght structure was not
accurately known and may have been overestimated, so the large after-
effect they obtained may have been caused by a greater radiation intensity.

352 B. ORCHARD

The cause of the after-effect on E is still not clear; it is too large to be
accounted for by the effect of L on E (Watson, 1958). Drought may permit
something to be stored which later promotes growth or the rapid expansion
of the plant when the moisture content is increased may provide a sink for
assimilates and so promote assimilation. Gates (1955) suggested that tomato
plants become more juvenile as a result of wilting and so reversed the
general trend for growth rates to fall with age, but this explanation does not
apply to sugar beet in which the trend is small (Thorne, i960). Gates (1957)
later suggested that changes in phosphorus metabolism were important.
The after-effect of drought on E implies that E is at least partially restricted
by internal factors and that it should be possible to increase crop yield by
increasing E.

The decrease in growth rate during drought (the direct effect) was only
influenced by weather when the plants were small (L< i), although the
effect itself was observed in the larger plants. The weather factor almost
certainly operated through transpiration, which controls both the time
required to remove the Treely available' water from the root zone and
the proportion of the soil moisture which is freely available (Bierhuizen,
1959; Kuiper and Bierhuizen, 1959). The effect of plant size is not
unexpected considering the known interrelations between root growth,
transpiration and water supply (Slatyer, i960). Water moves very slowly
in unsaturated soils and root extension is essential to the maintenance of
the water supply. Once the demand exceeds this supply, the plant turgor
and hence root growth wiU fall, further restricting the supply. The larger
the active root system and the greater the initial soil moisture content, the
greater the water demand the system can sustain.

In 1959, treatment B decreased both leaf area and dry matter production,
but in i960 the same treatment appHed to plants with a similar number of
leaves had no effect on dry matter production and only a small effect on
leaf area. In 1959 transpiration was evidently rapid enough to exceed the
critical demand and severe water stress developed. In i960, transpiration was
much slower and did not exceed the critical rate.

The significant positive correlation between plant moisture content and
leaf area on the first sampling occasion in Exp. 3 indicates that the high initial
variabihty of the plots was due to differences in soil moisture (remaining
from the previous experiment). These appeared to interfere with the early
growth of the plants and may have influenced the moisture content at the
first sampling indirectly, either by decreasing the amount of stored water
in the soil and so slightly hastening the onset of drought, or by affecting the
composition of the plant. The significant negative correlation between

GROWTH RESPONSE OF SUGAR BEET 353

moisture content at the first sampling and the subsequent relative leaf
growth rate may indicate an after-effect of drought of the type already
discussed. The water suppHed before the start of the drought was probably
enough to reheve the water stress (without completely abohshing moisture
content differences) but the weather did not permit the stunted plants
to grow rapidly enough to overcome the check.

Weather may influence the drought response even when changes in root
growth are not important. Bierhuizen (loc. cit.) showed that when trans-
piration is rapid, variation in soil moisture stress can influence transpiration
rate at stresses as low as pF 2, although under conditions giving slow
transpiration the rate is uninfluenced by soil conditions. According to
Philip (1957) the permeability of the system must change. Although
transpiration rate tends to a constant value independent of atmospheric
conditions, at high soil moisture tension the change in permeabihty, and
presumably the physiological change causing it, must increase when
atmospheric conditions favour increased transpiration rates. Growth is
usually more sensitive than transpiration to water stress so the growth of a
plant in dry soil should interact with atmospheric conditions. This was not
observed in my experiments; the effects of treatment C on L, net leaf
number and moisture content were not significantly greater in 1959 than
in 1958 despite a 50% greater transpiration potential as estimated from the
water consumption of the A plots.

There was no evidence that net assimilation rate (E) was decreased by
drought; the C plots had almost the same dry matter yield as the A plots,
despite considerable differences in the leaf area index which imphes that
drought increased E. This does not require a change in the internal physio-
logy of the leaf Watson (1958) showed that the rate of dry matter produc-
tion (crop growth rate) of sugar beet increases with increasing L and is
greatest when L is between 6 and 9, considerably above the values observed
in my experiment. If the leaf area of the A plots was near or above the
optimum, small changes in L would have no effect on dry matter produc-
tion. Below optimal L, dry matter production is restricted because the crop
fails to intercept all available radiation and above the optimum dry matter
is lost by respiration of the leaves in heavy shade. At high levels of direc-
tional illumination (as on a clear summer day) dry matter production is also
restricted because the upper leaves intercept Ught energy more rapidly
than they can use it in carbon assimilation (the photosynthesis of sugar beet
leaves reaches saturation at 0-3 of full simhght, Gaastra, 1958). Watson and
Witts (1959) ascribe the high optimum L (6-9) of cultivated beet as com-
pared with wild beet or kale (optimum L 3-4) to its erect habit. Sunlight

354 B. ORCHARD

Strikes the erect beet leaves obliquely and its effective intensity is brought
to a level at which it is used efficiently and, at the same time, more leaf area
can be illuminated by a given area of hght beam. This mechanism, how-
ever, does not operate when the incident level does not greatly exceed
saturation or when the Hght is difflise, and the optimum for cultivated beet
should then be the same as for kale. The Dutch-hght structure intercepted
at least 30% of the incident radiation and introduced some diffiision, and
the optimum L for sugar beet should be considerably lower than in the
open field.

In the first two experiments the L of the A plots was probably near the
optimum, hence the decrease in L caused by drought did not influence dry
matter production significantly.

In the third experiment L was below the optimum but the effect of the
drought was obscured by the large experimental errors.

REFERENCES

BiERHuiZEN, J.F. (1959) Some observations on the relation between transpiration and

soil moisture. Nether., J. agric. Sci. 6, 94-98.
Gaastra, p. (1958) Light energy conversion in field crops in comparison with the

photosynthetic efficiency under laboratory conditions. Meded. LandbHoogesch.

Wageningen, 58, 1-12.
Gates, C.T. (1955) The response of the young tomato plant to a brief period of

water shortage. II: The individual leaves. Aust.J. biol. Sci. 8, 215-230.
Gates, C.T. (1957) The response of the young tomato plant to a brief period of water

shortage. Ill: Drifts in nitrogen and phosphorus. Aust.J. biol. Sci. 10, 125-146.
KuiPER, P.J. & BiERHUiZEN, J.F. (1959) The effect of some environmental factors on

the transpiration of plants under controlled conditions. Meded. LandbHoogesch.

Wageningen, 58, 1-16.
MoNTEiTH.J. L. & Owen, P. C. (1958) A thermocouple method for measuring relative

humidity in the range 95-100%. J. Sci. Instmm. 35, 443-446.
Orchard, B. (1961) An automatic device for measuring leaf area. J. cxp. Bot. 12, 458-

464.
Owen, P.C. (1957) Rapid estimation of the areas of the leaves of crop plants. Nature,

Lond. 180, 6x1 only.
Owen, P.C. (1958) The growth of sugar beet under different water regimes. J. agric.

Sci. 51, 133-136.
Owen, P.C. & Watson, D.J. (1956) Effect on crop growth of rain after prolonged

drought. Nature, Lond. 177, 847 only.
Philip, J. R. (1957) The physical principles of soil water movement during the irrigation

cycle. C.S.LR.O. Inter. Coinm. Irrigation Drainage, 125-154.
Slatyer, R.O. (i960) Absorption of water by plants. C.S.LR.O. Div. Land Res. Reg.

Survey, Australia, }ii--ii9.

GROWTH RESPONSE OF SUGAR BEET 355

Stanhill, G. (1957) The effect of differences in soil-moisture on plant growth: A
review and analysis of soil moisture regime experiments. Soil Sci. 84, 205-214.

Thorne, G.N. (i960) Variations with age in NAR and other growth attributes of
sugar beet, potato and barley in a controlled environment. Ann. Bot. Lond. N.S.

24, 356-371-
Watson, D.J. (1947) Comparative physiological studies on the growth of field crops.

I. Variation in net assimilation rate and leaf area between species and varieties,

and within and between years. Ann. Bot. Lond. N.S. II, 41-76.
Watson, D.J. (1958) The dependence of net assimilation rate on leaf area index.

Ann. Bot. Lond. N.S. 22, 37-54.
Watson, D.J. & Witts, K.J. (1959) The net assimilation rates of wild and cultivated

beets. Ann. Bot. Lond. N.S. 23, 431-439.

CROPPING PATTERN AND WATER RELATIONS

W.C.VlSSER

Instituut voor Cultuurtechniek en Waterhuishouding,
Wageningen, Netherlands

Aim of the Investigations

Water relations in the field not only influence the yield of crops, but also
the kind of crops the farmer wiU grow. On dry soils rye is planted fre-
quently. But if the water relations are improved and a larger yield per ha
is obtained, there is, however, a good chance that the total amount of seed
produced on the farm will decrease. If the field is better provided with
moisture, this will induce the farmer to grow less rye and to increase the
acreage sown with beet and potatoes. If one tries to predict the result of
an increase in fertihty of the soil, it will not only be necessary to predict
the yield per unit area, but also the percentage of the area occupied by each
crop. This proportion of the different crops in the total farm area will be
called the cropping pattern.

Nature of Problem

Within rather wide Hmits the farmer is free to decide on what area of any
crop should be planted. For that reason the frequency of occurrence of a
certain crop is governed to a greater extent by the law of probability than
by some more definite agricultural rule or necessity. Since the ecological
situation will not be equally favourable however, not every crop will be
grown to a same percentage and with a same probabihty. The less optimal
this situation for a certain crop is, the smaller will be the probability of tliis
crop bemg chosen by the farmer.

Generally it wiU be rather difficult to collect enough data to determine
the frequency of occurrence of the crops accurately. Every field gives only
one observation a year. Data for a number of years will be needed. But
the crops grown in earlier years are often not too well remembered and the
frequency data therefore will be less reHable. Moreover, cropping patterns
of former years are Hable to restrictions in comparability due to changes in
the economy of agricultural production. Data from more than five years
ago may become of suspect uniformity.

The number of data for calculation of the frequency decreases still more,

CROPPING PATTERN AND WATER RELATIONS 357

because the unit of decision for the cropping pattern is not the field but the
farm. The study of the influence of moisture relations on the cropping
pattern will have to account for disturbiag factors such as farm size,
availabihty of labour, accessibUity of the field, etc. A great many data of
separate fields from a large number of farms will be needed. But the large
number of farms may cover such a vast area, that the comparabihty of the
farms to be included in the survey may be impaired, due to economic
influences such as distance to markets or railheads.

This means that the data have to be collected from a relatively small
area. The cropping pattern to be described has to be based upon a restricted
number of observations, which are by their nature moreover, of a restricted
accuracy. Therefore a method of treatment of the observations has to be
devised, which enables a condensation of the information contained in the
data as much as possible, and the elimination of random deviations as far
as possible. This means a general formula has to be devised that is vahd for
every crop and fertihty factor and requires the minimum amount of
constants.

The Formula for a Cropping Pattern

An acceptable assumption is, that for every crop within the cropping system
an optimal value for the production parameter wlU exist. The more the
actual fertihty level diverges from this optimum, the less frequently the
crop will be planted. If the assumption is made that the frequency of
occurrence is linearly related to the difference x — Xq between the actual
and the optimal level of the production parameter x this means that the
probabihty of occurrence F% of the crop is governed by the normal
probabiHty distribution :

This may be written as

hiF% = - a%x- Xo)2+ In^ (2)

Formula 2 expresses that by plotting the logarithm of the frequency
against the production parameter a part of a parabola will be found, which
is described by three constants, two of which — Irt^ and Xq — may be
accounted for by shifting the co-ordinate axes.

The value of Xq and hA depends on the crop and the production
situation. If the value o(a were constant, then, by shifting the co-ordinate
axes, the curves of every crop might be brought to coincidence with the
curve for any other crop.

358 W. C. VISSER

The constant Xq indicates at what level of the production parameter the
optimum frequency is found. This optimum is the result of the combined
effect of all the competing crops together within the farm economy. The
constant ^ indicates with what frequency the crop is planted under optimal
conditions and depends therefore on the importance of the crop within the
farm organisation and the farm economy.

The constant a points out how the farmers react to decrease in profits
and increase in costs under sub-optimal conditions and may be considered
as a more sociological parameter. Can this parameter be independent of
the soil and the crop ?

Considering that according to the yield equation for the law of diminish-
ing returns the yield depression D may be described with

D = ^^-^(^-c) (3)

and considering that b is claimed to be constant, it may be assumed that the
yield decrease for different soils and crops will not differ much by variation
of the growth factor and it seems not too bold a step to assume that a
same size of yield decrease will induce the farmer to react in the same way.
If t in formula 3 is near constant for the same growth parameter it makes
sense also to take a in formula 2 as constant for the same production
parameter. This assumption is the more acceptable, because constancy or
inconstancy cannot be proved statistically, due to the restricted accuracy of
the data commonly available.

The Clay Content and the Cropping Pattern

The clay content is a useful parameter to indicate the moisture available in
the soil profde. It governs rather strongly which crops will be grown.
Potatoes and rye, for instance, are typical crops for dry profdes with low
clay content.

To study the relation between cropping pattern and clay content the
crops over five years of 2000 fields were collected. For successive groups
of clay content the frequency of occurrence of the different crops was
estabhshed. The logarithm of the frequency percentage, plotted against
the clay content, yielded curves as given in Fig. i.

These curves now have to be fitted around a paraboHc curve. This
parabola is only partly covered by the longest curve which is possible in
view of the variation in clay content. The relative unimportance of the
value of the constant a clearly results from the inaccurate determination of
the degree of curvature, due to the relative shortness of these partial curves.
The probabihty that the reaction curve is a parabola must to a greater

CROPPING PATTERN AND WATER RELATIONS 359

extent be derived from reasoning about fundamental relations than from
statistical evidence.

If for all the crops the curves are fitted around the parabola by applying
a horizontal and a vertical shift, the partial curves comcide with the
parabola and the frequency observations appear as a scatter of dots around

Frequency */o«
lOOr- V +

CANARY GRASS (•)

Fig. I. If the logarithm of the frequency of occurrence of a crop within the cropping
pattern is plotted against the silt content, this gives curves of different shape, which
may be considered as parts of parabolas.

the parabola. The result is given in Fig. 2. The object of interest now is
not centred any more on the curve, but on the parameters .Vq and A which
appear in the graph as the distance of shifting of the co-ordinate axes.
Figure 2 represents the entire cropping pattern of this clay soil and the
effect of the clay content on this pattern.

If it were desirable to distinguish between more than one production
parameter the formula to be used would be that of the normal multiple
correlation. It may be mentioned that the sum of a number of single or

24

36o

W. C. VISSER

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CROPPING PATTERN AND WATER RELATIONS

361

multiple correlation functions in fact does not make up the full 100% for
every value of the production parameters. The appHcation of these formulae
must be considered as an approximation.

ThePjeliability of the Results

If the reasoning about the fundamental properties of the cropping pattern
is not convincing, then still a fitting of curves through the scatter diagrams
remains, in v^hich Xq and A give some information with respect to the
position and slope of the curves, irrespective of any parabohc relation.

If the result of different areas is compared, thi? proves something about
the reahty of these parameters of the curves. In Fig. 3 for two areas the

CANISVUETPOLDEB. ZEEUWS- VLAANDEREN
Frequency '/•
30 1-

26
22

IB
14

^•BEETS
^•^HEAT
• BARLEY

• P(5tatoes

^•'peas ©oats

• FLAX

/

•
•

•Ieguminosae

•trade

CROPS

• RYE

I III

Frequency •/•

I I I I I

4 6 8 12 16 20 26 30

LAND VAN HEUSDEN EN ALTENA

Fig. 3. The vertical component of sliift log A, expressed in a frequency scale, plotted
against the same constant for another area, can apparently be determined rather
accurately.

values for x^ and log A are plotted against each other. The graph shows
that within the margins of accuracy that may be expected in these investiga-
tions, the sliift parameters A and x^ show in each area the same mutual
relation.

This result shows that the parabola, as a principle to bring order in the
independent choice of the crop to be grown by individual farmers, works
out well, even if there exists a distinct difference in the type of farming in
the two areas.

362 W. C. VISSER

Groundwater Depth and Cropping Pattern

In areas with a shallow water table, the question arises what influence the
raising or lowering of the water table will have on the crops which one
may expect will be grown.

In a sandy area differences in groundwater level promised workable data
for an intended investigation. The crops grown on the fields of some 70
farms during the last five years, as well as the water table in summer, were
estabhshed. These data suppHed the frequency curves for each crop. In
Fig. 4 the curves for a number of crops, plotted against the groundwater

Frequency*/'
70

RYE (+)

Mean depth of ground-water table in summer

J I ly o I

250cm minus soil surface

Fig. 4. For sandy soil and small farms the crop frequency has been determined and
plotted against the groundwater depth in summer. Grass is clearly a wet-land crop,
rye grows on dry fields and potatoes have an intermediate position.

depth are given. The difference in position of the crops in the cropping
pattern is apparent and a change in groundwater depth will influence the
type of farm considerably.

The data are fitted around a parabola by horizontal and vertical shifts.
In Fig. 5 the result is given. For each crop the horizontal axis is given with
endpoints 50 cm and 250 cm groundwater depth and this axis is drawn at a
frequency value of 10%. Where the shifted horizontal axes are situated
well above the parabola, this means that at optimum conditions the
frequency of occurrence remains below 10%. The cropping system with
respect to the influence of water is for every crop given by the parabola

CROPPING PATTERN AND WATER RELATIONS

363

and the origin of the co-ordinate system for every crop separately. In Fig. 5
the horizontal axes are given to clarify the appHcabihty of the graph, but
they are superfluous because only the distances of shifting log A and Xq
matter.

The logarithmic scale may be changed back and the shifts undone to
obtain a readable representation of the cropping pattern The frequency, is

REST CROPS (D)

PEAS <P)

'VorPREQUENC •;.
60 ■
50

40

l20

POTATOES (A)

-® ©'

FODDER BEETS (Fb)

0 ^

OATS/ BAR L£Y ^-O®

TEMPORART LEYSCTD^-^'-^N.

®

@

®

100 150 200 250cm minus soil surface

"Tt / Mean depth of

®

ean depth of ground -water
tabic in summer

PERMANENT PASTURE (Pp)

Fig. 5. The cropping pattern parabola gives the relative position of each crop clearly.
The shifted co-ordinate axes are given in full for rye. It w^ould be sufficient to give
only the origin of the co-ordinate axes if a description of the cropping pattern is
desired which is readily readable.

then plotted against the same co-ordinate scale for the groundwater depth.
In Fig. 6 the result is given. The well-known facts that the wetter land is
used for grassland and that also fodder beets increase in acreage and that
cereals are crops for dryer soils is apparent. The continuous transition of
the crop frequency curves point at a continuous change from cattle rearing
to cereal culture.

Summary and Conclusions

The cropping pattern is a complex indication of the type of farming, de-
scribed by the kind of crop and the percentage of occurrence. Important

364

W. C. VISSER

is a dynamic representation, in which the properties that influence the
cropping pattern are variable. The type of farming depends on a great
many internal and external factors, economic, organisational as well as
physical. This complex relation may as a first approximation be described
as a multiple probability distribution. Eventually skew chance distributions
might be needed, but the nature of the data with respect to their restricted
accuracy often make it unnecessary to introduce this comphcation.

Frequency "U
70r-

60-

20

m

depth

gr w t

sumnner

1

Crops

20-40

40-70

70-100

100-140

140-200 >200|

Perm, past

61,7

56,3

46.1

32.4

16,9

6,5

Temp, leys

160

16,4

16.0

14.2

10,4

5 0

Rye

4,1

65

10.7

16,9

27.3

37 2

Potatoes

3.6

4.9

6.7

8.3

9,8

9.3

Oats/Barley

1.4

2,4

4,2

7 0

12.1

18.2

Oats

2.5

3.S

5.7

8.3

11.6

13,5

F beets

7.1

7 3

7,2

6.7

5.0

2.5

Corn

0.1

0.3

0,5

09

1.9

3.5

Div

0.6

07

1.0

1.0

1.0

1.0

Peas

0,0

ao

0.1

03

0,7

18

OATS/BARLEY MIX

OATS
POTATOES

75

125 175 225 275cm minus soil surface

Mean depth of ground-water
table in summer

Fig. 6. The parabola for the cropping pattern makes possible a reconstruction of the
frequency percentage -groundwater depth diagram by changing back the logarithmic
scale aiid reversing the horizontal and vertical shifts. The graphical and numerical
results of the influence of groundwater depth on the frequency of occurrence of each
crop is given above.

One single probabihty distribution diagram is able to comprise the
frequency curves for all the crops by choosing for every crop separately
the right situation of the co-ordinate system for the frequency and for the
production parameter. But this apphes only if the logarithm of the
frequency is used. Logarithmic plotting of the probability percentage
transforms the frequency distribution curve into a parabola. The multiphca-
tion factor a^ in the parabola -see formula 2- may be assumed to be con-
stant for a certain area. This constant represents the reaction of the joint
farmers to a decrease in productivity due to sub-optimal circumstances.

CROPPING PATTERN AND WATER RELATIONS 365

The close relation between the probability distribution and the formula
for diminishing returns as yield equation and the claim that the growth
factor b -see formula 3- is constant makes it plausible to assume also the
constancy of a^ in formula 2.

By fitting the parabola through the frequency curves of the crops a
representation of the cropping system is obtained, depicted by the parabola
and the origin of the co-ordinate axes. Herewith the cropping pattern is
condensed to a maximum of information with a minimum of constants.
This will increase the accuracy of the result or reduce the quantity of needed
data.

The curves show the well-known preference of different crops for
hghter or heavier soils or lower or liigher groundwater levels. The graphs
may be useful for the prognosis of the change in farming type due to
improvements in the ecological, organisational or economic situation.
They also may be used for comparing cropping patterns in different areas
after correcting for one or more factors that influence the cropping pattern
most strongly.

The parabola method gives a fair basis for the study of the changes in
crop frequency as a result of changes in the environment of agricultural
production.

WATER RELATIONS OF FOREST TREES

E. E. Gaertner

Professional Agrologist, Petawawa Forest,
Chalk River, Ontario, Canada

Seventy years have passed since R. Hartig (1891) in his Anatomic und
Physiologic der Pjianzcn considered the factors influencing the amount of
growth in a tree. Under 'soil' he recognised depth, moisture, and mineral
content ; under 'cHmate', temperature and the humidity of the air ; next was
the area for crown and root development; the occurrence of seed years,
and finally the inherited characteristics of the individual trees. Today we
can still, to a degree, follow this outline to plot the relationship between a
tree and its environment. In the present contribution we shall concentrate
on the water relations of forest trees.

It is well recognised that water is an essential component of all living
matter, yet its overall effect on the growth of forest trees is still not com-
pletely comprehended. It can be said that trees, through their nature, are
subjected to a greater variety of water stresses than any other plants, often
more devastating because, due to their size, several of these stresses can be
active simultaneously. While their roots are active in soil where the drying
cycle acts slowly, the shoot tip, often fifty metres or more in the air is
subjected to a rapidly changing environment.

Russell (i960) in the study of flow phenomena in plants has aptly pointed
out the difficulties involved in this study. The technique of accurate mea-
surements of the flux of material past a given point or of the space distribu-
tion of potentials in the flow system still remains to be developed, even
for the flow of water through a single plant part such as a root, stem or a
petiole.

Each species requires its own specific water supply for most favourable
conditions of growth, and the quantity of water in the soil has a greater
influence than any other factor on the distribution of plant species (Bow-
man, 191 1). This statement suggests in part, the vast variety of conditions
affecting the relationship between the water content of the soil and the
individual tree. It has been of concern not only to the forester, but also to
the horticulturist and to those concerned with watershed management and
irrigation.

WATER RELATIONS OF FOREST TREES 367

When considering the various sources of moisture to the tree, we might
think of them in terms of ground water, or as precipitation which in turn
becomes available to the plant through the roots, when it permeates the
soil. The various types of soil moisture have been outlined by Kramer
(1944). The alternative is moisture that becomes directly available from
the atmosphere in the form of dew. Krecmer (195 1) and Stone (1957a)
have recently reviewed the hterature on dew as an ecological factor. Stone
and several co-workers explored the survival value of dew, though their
experimental work has been restricted to seedling material of ponderosa
pine [Pinus ponderosa Dougl.), (Stone and Powells, 1955 ; Stone, 1957b) and
coulter pine [Pinus coulteri D. Don.), (Stone, Went and Young, 1950). They
considered that dew and fog prolonged survival of trees in soil at or near
the wilting point by causing a re-saturation of leaf tissue and concomitant
reduction of moisture removed from the root system. Waisel (1958) in a
study of dew absorption by evergreen trees and shrubs of arid zones stated
that there was a negative correlation between soil humidity and dew
absorption, but the amounts of dew taken up were completely inadequate
to balance the daily transpiration loss.

The distribution and growth of tree species may be influenced by per-
sistent dew and fog in areas of relatively low annual precipitation. The
location o£ Sequoia sempervirens (Lamb.) Endl. along the foggy part of the
Cahfornia coast and of S. washingtoniana (Winsl.) Sudw. on the misty
slopes of the Sierras in inland southern California, is attributed to this
cHmatic factor (Harlow and Harrar, 1941).

Although it is usual to think of fog in terms of moisture, Wilson (1948),
while studying the increased apparent photosynthesis on Camellia japonica
and Ligustrum lucidutn, came to the conclusion that it was the 20-25%
increase of carbon dioxide in the air on foggy days that was responsible for
favourable plant growth.

Tree species may be found over a range of soil moisture sites which vary
with latitude and altitude. For example beech's [Fagiis grandifolia Ehrh.)
amplitude is fairly wide in southern Ontario, but not as wide as in the
southern United States where the population is also more diverse genetically
(Camp, 1950). Frequently a species is hniited to edaphic conditions by its
intolerance to shade when it fits into niches where competition is less
severe. Jack pine (Pinus banksiana Lamb.) is usually associated with dry soils
although it does occur on very wet situations with black spruce [Picea
mariana (Mill.) B.S.P.) as a codominant in areas south-east of Nighthawk
Lake in northern Ontario. Similarly the same black spruce, which is
usually found on wet soils, occurs on dry sites in north-western Ontario

368 E. E. GAERTNER

as a codoniinant with jack pine (Fraser, 1954). In both cases it may be
partly intolerance to shade that forces each species to edaphic extremes.

Soil moisture classification (Briggs, 1897J includes gravitational, capillary
and hygroscopic types as well as the vapour phase (Lebedeff, 1928), the
first two classes of which are available for tree growth. Condition of
aeration (telluric and stagnant water (Hills, 1953)) merits a special con-
sideration for it is important not only for growth but even for selection of
the tree species on different sites (Clements, 1 921). In north-eastern North
America yellow hivch.{Betula lutea Michx. f.) and black ash {Fraxinus nigra
Marsh.) are usually found on wet soils abundant with telluric (aerated)
water, but they are replaced by black spruce and tamarack (Larix laricina
(DuRoi) K. Koch.) if the soil water is stagnant with low oxygen content
(Fraser, 1954)-

Earher workers have been interested in tolerance of trees both to light
and water. Fricke (1904) showed that competition for moisture by roots of
older trees could cause death of young growth under the shade of mother
trees. His experiments were in a 70- to loo-year-old Scot's pine [Piuus
sylvestris L.) stand on a dry sandy soil. Trenches 25 cm deep were cut
around groups of ten-year-old 40 cm pines under this stand to isolate them
from the mature trees. In the first year after trenching the young pines in
the isolated groups doubled their terminal growth of the previous year.
Similar changes were noted in the ecesis of a rich ground vegetation.
Fricke (1904) found the soil moisture conditions in the experimental
trenched plots two to three times greater than in untrenched areas.
Bjorkman (1944-45), Surmac (1958), and others considered root competi-
tion for moisture and nutrients an important factor in Hmiting growth of
tree seedlings in a closed stand. In other instances light was considered
the limiting factor, for Moore (1926) showed that the addition of moisture
to plots under the shade failed, in white pine [Pinus strohns L.), to counteract
the shade effect. The seed in the experimental flats in shade showed markedly
better germination than those in the open, because the soil surface was
prevented from drying. However, the growth of the survivors in the open
was many times that of the shaded seedlings in spite of ample moisture.
Trenched and untrenched plot experiments were also conducted by
Korstian and Coile (1938), who demonstrated that competition between
individuals of the forest vegetation for soil moisture is a highly significant
factor in growth, development, and reproduction of loblolly and short-leaf
pine in the Piedmont plateau.

Burns (1923) pointed out the variability of annual ring width in New
England forest trees, and stated that there was no direct correlation between

WATER RELATIONS OF FOREST TREES 369

rainfall and radial growth; rather, site conditions were of primary impor-
tance and Diller (1935) substantiated this conclusion by saying that soil
moisture observations were better than precipitation records since the
variable factors of run-off and seepage would be eHminated. Usually
drought affected growth of the following year, whereas in wet years
increase of growth occurred the same season. If trees are growing where
drought or soil wilting conditions may occur, there may be a direct cor-
relation of growth with precipitation. Bogue (1905) reported that this
occurred in sugar maple [Acer saccharum Marsh.) where the effect of ab-
normally large or small precipitation on radial growth is evidenced the
folio whig year. Lodewick (1930) also correlated ring width of the long-
leaf pine [Finns pahistris Mill.) in Florida with precipitation during the
March-October period. He indicated that vigorous trees were the best
indicators with dry years useful for cross-identification. Various tests for
rehabihty included the relative production of spring wood to summer
wood.

The radial growth of short-leaf pine [Pinus cchinata Mill.) and white oak
[Quercus alba L.) was studied with a dial gauge dendrometer by Boggess
(1953) who followed soil moisture at different depths (down to 60 cm),
rainfall mside and outside of the stand, air and soil temperature as well as
evaporation. He found that both pine and oak completed 80% of their
basal growth by the end of June, when available moisture through the
profde became exhausted. The sporadic periods of diameter increase inter-
spersed with periods of stem shrinkage in the latter part of the growing
season were then directly related to the availabihty of soil moisture which
becomes a hmi ting factor in diameter growth during most seasons, although
other factors might affect the final cessation of growth (Boggess, 1956).

In the relative utihsation of soil moisture by various species. Shear and
Stewart (1934) found that water was removed from the soil most rapidly
by all species, white pine excepted, at about the time new foHage is pro-
duced. Larch, white oak and white pine removed more water from the
first four feet of soil during the growing season than green ash [Fraxinus
pennsylvanica var. lanceolata (Borkh.) Sarg.) and silver maple [Acer sacchari-
num L.). Soil moisture was affected to a depth of three and a half metres
under white oak, three metres under larch, two and a half metres under
maple and white pine and two metres under green ash. The water table
fluctuated from about one metre dov^oi to these depths, thus the trees had a
constant source of water from the water table.

Concerning the utihsation of soil water, Schopmeyer (1939) working
with seedlings of short-leaf and loblolly pine [Finns taeda Linn.) found that

370 E. E. GAERTNER

short-leaf pine absorbed more water from the soil than loblolly pine and
at the same time maintained higher total water content in its leaves even
when soil moisture was Hmiting. Short-leaf pine also maintained a higher
solute concentration when recovering froni the effect of drought; that is
when 30% soil moisture was restored. Schopmeyer's data indicate that the
greater drought resistance of short-leaf pine cannot be attributed to an
abihty to conserve water either by retarding transpiration or by forming
bound water, or having a higher osmotic pressure. Yet the rate of trans-
piration of loblolly pine gradually diminished over a period of six weeks
as decreased soil moisture approached and passed the 'wilting coefficient'.
At the end of six weeks the transpiration rate was only 16% of that at 30%
soil moisture. This does not agree with Veihmeyer and Hendrickson's
(1936) data on fruit trees. Wilhelmi (1957) presented terminal growth data
of young broad-leaved and coniferous trees growing on irrigated and
control plots. His best species included Popiihis angiilata and Salix purpurea,
both considered suitable for dry sites, but both growing better on the
irrigated site. Young conifers growing in the Rocky Mountains at low
altitudes stand the lack of growth water for longer periods and their roots
have a more rapid rate of penetration than those trees growing at high
altitudes (Daubenmire, 1943).

Lyon (1940, 1943) has studied the correlation of growth with seasonal
rains and temperature in various conifers as well as red oak [Quercus borealis
Michx.) ; only in red oak was there no correlation between the rain of the
previous season and growth, though some effect of rains falling during the
growing season was noted. His conclusions stressed the effect of variation
of water supply on radial growth fluctuations. He found that white pine
growth is sensitive to water supplied by rainfall. In white pine, terminal
growth of the primary and secondary axes had the closest correlation with
the amount of rainfall from the 'storage' May-November season of the
preceding calendar year (Motley, 1949). Red pine did not show the same
correlation but perhaps the material was too young and not yet estabhshed.
Since food used for apical growth is manufactured the previous year
(Kienholz, 1934; Kozlowski and Ward, 1957), one would expect apical
growth to be correlated with the preceding summer's rainfall when the
efficiency of photosynthesis could be affected by abnormal weather con-
ditions. This is especially true in the temperate regions where an adequate
supply of soil moisture is usually available from melting snows in spring
and early summer when growth first occurs. Growth-rainfall trends in six
species of hardwoods were studied by Friesner (1950) to obtain a growth-
rainfall trend coefficient. He found a definite correlation between rainfall

WATER RELATIONS OF FOREST TREES 371

and growth regardless of species concerned. The site under scrutiny had a
niinimuni run-off and the rainfall data used were taken 20 kilometres from
the experimental area.

Though we usually think of moisture in terms of availability , it should
be remembered that an excess can be just as detrimental to most species.
Soil aeration is intimately connected with soil moisture since surplus of the
latter partly excludes the former. As previously indicated, the amount of
oxygen to roots can become of paramount importance to healthy root
survival. However, Kramer (1950) considers that soil aeration is seldom a
serious problem in forests because natural selection tends to ehminate the
trees not well adapted to poorly aerated (usually very wet) habitats. Such
is the case in the great Clay Belt of northern Ontario (Fraser, 1954), where
black spruce predominates in areas of high water table and represents an
edaphic cUmax (Weaver and Clements, 1938).

Cannon and Free (1917) showed that roots of mesquite cease to grow
when oxygen is lacking or where there is more than 25% carbon dioxide.
On the other hand, willow is very resistant to lack of oxygen in the soil
atmosphere. In Java, the oxygen requirements of root systems in several
hundreds of species of trees, shrubs, and herbs, were investigated by
Verhoef(i943).

The gley horizon underlying the constantly or temporarily submerged
soils in the forest of Chaux, at less than 3 5 cm, can be penetrated only by
alders, willows and American red oak [Quercus borealis v. maxima)
(Lachausee, 1950). This oak has a powerful tap root which pierces the gley
horizon which the native Q. robin camiot do. The latter dies back at 80 to
100 years.

White (Picea glauca (Moench.) Voss.) and black spruce, red (Pinus
resinosa Ait.), white and jack pine, as well as balsam fir {Abies balsamea (L.)
Mill.) in naturally flooded areas, were both measured and classified
according to health (Ahlgren and Hansen, 1957). Black spruce and balsam
fir showed the greatest endurance and abiHty for recovery, although all
trees were affected to a various degree. This varied not only with the
species, but age of the tree as well as the duration of flooding. The 30- to
6o-cm class was most seriously affected and damage appeared to decrease
progressively with size within the individual species. Some of the trees
lost all their needles during flooding, but disease did not become evident
in any of them until two years later. After 60 days of flooding, all sizes of
balsam fir showed 80 to 100% mortahty, and 4-5 m high white spruce
showed 100% mortahty; even 29 days of flooding affected the 30- to 60-cm
high white spruce. Of the hardwoods observed, paper birch was affected

372 E. E. GAERTNER

the most. Mikola (1950) in data from several hundred Scots pine and spruce
(Picea abies (L.) Karst.) in central Finland, showed that in the 1 8 years of
agricultural crop failure since 1800 there was a correlation between these
failures and tree growth, wherever crop failure was due to excessive
moisture or frost (resulting in a cooler summer), but not where drought
caused failure. Duruag these 1 8 periods the radial growth of these two species
averaged 18% less than the growth in the preceding year. The floods in
the marshy forests near Gabcikovo in July 1954 were described by Farsky
(1957). Most of the younger plants were killed and the older ones lost their
leaves when the flood water became warm and stagnant. Those species
most severely affected included Fraxinus excelsior, Quercus rohtir, Robinia
pseudoacacia, Primus avium, Tilia cordata, Aesculus hippocastanum znd Acer spp.

Finally, Day (1946), commenting on root diseases in conifers, suggests
that fungi might be of secondary importance as compared to adverse soil
conditions of both drought and water-logging, which stimulate abnormal
root growth consisting of unhgnified collapsed tracheids. On a lesser scale,
excess of seasonal moisture at Chalk River, Ontario, was found to retard
growth of yellow birch {Betula lutea Michx, f ) (Fraser, 1956, 1961). After
extensive flooding in New Orleans, Bonck and Penfound (1944) measured
terminal growth in two species of willow, sand bar willow [Salix interior
Rowlee) and black willow {Salix ni^ra Marsh), pecan (Crtryrt ilUnoensis
(Wang.) K. Koch) and hackberry [Celtis mississippiensis Bose). They have
recorded that these species grew more rapidly during the April flood than
at any other sector of their growth period, but elongated very little during
the June flood. It is probable that the floods had Uttle or no effect on the
normal growth pattern of any of the four species studied.

It has been stated (Russell, 1932) that an occasional extreme drought might
affect vegetational boundaries more than normal climatic conditions. Late
spring drought in Pennsylvania in 1935 and 1936 appeared to have caused
stunted terminal growth and shorter needles in white pine (Craighead,
1941). Day (1950) on the other hand has found no injury to pine, but
cracking of the stem, or dieback of younger trees of Sitka [Picea sitchensis
(Bong.) Carr.) and Norway spruce [Picea abies (L.) Karst.) after a drought
during the growing season in Wales and Scotland. These drought cracks
result from internal shrinkage or collapse of wood as the water is with-
drawn from the main stem and occur only in trees which are about 20 years
old. The affected spruces were distinguished by low specific gravity of the
wood produced and the marked absence of well-thickened late wood. A
partial death of the root system appeared to be comiected with the condi-
tion, wliich occurs on fertile but shallow soil where the rooting space is too

WATER RELATIONS OF FOREST TREES 373

limited for the potential need of the tree. In trees younger than 20 years,
dieback rather than cracking, occurs.

It is obvious from the forgoing discussion that occasional drought
affects trees differently at various stages of their development, and that we
are dependent on natural occurrence for our data; exact duplication w^ith
mature material is nearly impossible without root disturbance. An excep-
tion to this might be found in the work of the sahnity laboratory at
Riverside, California, where, due to minimal rainfall, the water conditions
of any tree under investigation can be closely regulated.

Many aspects of water relations of trees have been discussed by Kramer
(1952). He has stated that, in winter, except during warm periods, transpira-
tion of conifers is almost as low as that of bare branches of deciduous trees,
probably because of the cold soil hindering water absorption. The question
whether soil moisture is equally available between field capacity and wilting
point has been approached by Stanhill (1957) who, in his comprehensive
review, concluded that, in 80% of the experiments scrutinised, growth was
affected by differences in the amounts of available water.

It is generally agreed that transpiration is affected by factors such as
Hght intensity, humidity, temperature and species selection as long as soil
moisture is above the wilting point (Pisek, 1950 ; Veihmeyer and Hendrick-
son, 1955 ; Ladefoged, 1956). This is shown by an increase in sap flow from
a morning low to a midday height, with further checking by sudden
drops of temperature or showers (Huber and Schmidt, 1937; Schubert,
1941; Kuntz andRiker, 1955). The maximum transpiration rate in July
with a gradual subsequent decrease, would point both to the high tem-
perature and long days as influential. Of course, even water availabihty
might be affected by the physical characteristics of the tree studied, i.e.,
by the type and length of its root systems (Ladefoged, 1956). Kramer
(1952) quotes Wiggans who recorded apple trees in Nebraska drawing on
water to a depth of ten metres. An extreme of cHmatic effects on evapo-
transpiration is suggested by Wilm (1957), who beheves the dwarf 'rain
forest' of the Puerto Rican mountains to be caused by suppressed tran-
spiration rates in the saturated atmosphere.

The relation of forests to run-off and water storage in the soil was
extensively reviewed by Zon (1927). Stalfelt (1944) studied water con-
sumption of spruce and found that interception of precipitation by spruce
crowns amounted to over 50%. A much smaller, yet significant rainfall
interception was found in forest stands at Chalk River (Fraser, 1956).
Stalfelt (1944) also reported on considerable cuticular absorption, par-
ticularly where water in the soil was deficient. It is significant that younger

374 E. E. GAERTNER

trees consumed more water than older ones. This fact should be particularly
pertinent to species estabhshment.

Adequate moisture and subsequent growth optimum might not be in
the best interest of the tree if longevity is so considered. According to
Schulman (1954) trees with great tolerance grown under adverse conditions
and with extremely small annual increment (4-6 mm radial mcrement per
century o£Fitzroya aipressoides (Molina) Johnston) hve the longest.

The humidity aspects of the water cycle have been most thoroughly
investigated by meteorologists (Geiger, 1950). However, Thornthwaite
and Hare (1955) approached the problem from a chmatological point of
view and 'expressed the hope that the conceptual framework of forest
ecology will approach that of the chmatologist more closely in the future'.
Thornthwaite (1948) and Penman (1948, 1956) have independently de-
veloped methods of calculating potential evapotranspiration from meteoro-
logical records. Whereas Penman (1956) in his approximations utihses
diuration of bright sunshine, air temperature, air humidity, and wind speed,
Thornthwaite (1948) calculates the potential evapotranspiration using
nomograms derived from average temperatures and latitude. Fraser (i957»
1961) reported on fluctuations in soil moisture and potential evapotrans-
piration over a decade and indicated that although total annual rainfall at
Chalk River, Canada, always exceeded potential evapotranspiration,
periods of drought did occur in certan years when the evapotranspiration
in summer months exceeded current rainfall. Consequently there was a
gradual depletion of stored soil moisture with a resultant decrease in
growth (Fraser, 1958) of trees on sites that usually have adequate water.
Trees on wet sites with seepage water were not affected to the same extent
except where the root systems were shallow. Zahner (i955) hi a study of
soil water depletion by pine and hardwood stands duruig a dry season,
noted httle difference in the rate of loss of soil moisture between the two
stands in southern Arkansas. His work supports the contention that evapo-
transpiration within a given climatic area is independent of the type of
forest cover.

Daily and seasonal moisture changes in the leaves of yellow birch were
elucidated by Fraser and Dirks (1959) in their study of the internal water
relations of that species. They noted that wood moisture decreased from
almost 100% ui May to about 60% in late June when the leaves were
fully unfolded. Relative turgidity of leaves was usually less durmg the
day and during periods of drought it decreased even at night. Fraser and
Gaertner (1959) outlined micro-environmental research in Canadian
forests and emphasised the importance of usmg physiological techniques to

WATER RELATIONS OF FOREST TREES 375

evaluate the effect of various phases of the water cycle on tree grov^th.
Although this paper has dealt almost exclusively with mature trees
rather than seedling material in their relation to water economy and its
effects on growth, it should not be forgotten that natural distributional
patterns are often governed by factors affecting seed germination (Moore,
1926) or seedhng tolerance as studied and discussed by Daubenmire (1943).
Knowledge of such Hmiting factors, although essential in any forest
management, does not necessarily prevent the cultivation of such trees.
For now many of our agricultural or horticultural crops would have to be
abandoned in many regions if natural regeneration was expected.

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Print. Off., Wash. 106 pp.

MARINE

BIOLOGICAL

LABORATORY

LIBRARY

WOODS HOLE, MASS.
Ik/ u n I

AUTHOR INDEX

The figures in bold type indicates the page on which the complete reference

is given.

Ackley, W. M. B. 102, 107, iii
Ahlgren, C.E. 371,375
AitkenJ. 37,54
Aldrich, W.W. 3^3,325
Alexeev, A. M. 226, 233
Allerup, S. 121, 122, 125
Alvin, P.deT. 17,18
Amer, F. A. 173, 189
Anderson, A. B. C. 59, 64
Andersson, N. E. 172,188
Angus, D.E. 43.54
Arisz, W.H. 86,95,99
Arvidsson, I. 53, 55, 102, 107, III
Ashbel, D. 46, 54
Ashton, P. S. 169, 188
Aulitzky, H. 156, 157, 161, 162, 166
Ayres, A.D. 281,286,288

Babuschkin, L. N. 281,286

Barrs, H. D. 98, 99

Bartos, J. 108, 109, III

Bauman, L. 225, 233, 276, 278, 283,

287
Belik, V.F. 281,287
Berger, E. 153, 165, 167, 187, 188
Berger-Landefeldt, U. 159, 166
Bergman, H.F. 321,324
Bernstein, L. 86, 99
Beskow. 81
Beydemen, I. N. 9
Bierhuizen, J. F. 250, 252, 254, 256,

352, 353, 354
Birch, H.F. 321, 324
Bjorkman, E. 368, 375
Bloemen, G.W. 254,256
Boggess, W.R. 3:^4.324,369,375
Bogue, E. E. 369, 375
Bohnig, R.H. 250,256
Bonck.J. 372,375
Borhidi, A. 9
Bosian, G. 184, 185. 188
Bowen, I. S. 24, 35

Bowman, I. 366, 375

Boynton, D. 323, 324

Boysen-Jensen, P. 198, 198

Brawand, H. 66, 82

Brewig, A. 97, 99

Briggs, L.J. 368, 375

BriUiant, V. A. 225, 226, 232, 233

Brouwer, R. 97, 100

Brown. 286

Burgy, R.H. 138,140

Bums, G. P. 368,375

Bumside, C. A. 250, 256

Cain, S. A. 206, 221

Camp, W. H. 367, 375

Camion, W. A. 371,375

Carr, D.J. 98, 100

CartelHeri, E. 125, 125, 159, 166, 167

Catsky, J. loi, 102, 103, HI, 227,

233, 234, 300, 311
Chaptal, L. 45, 81
Childers, N. F. 322, 325
Chrelashvili, M. N. 225, 233
Clements, F. E. 368,371,375
Coile, T. S. 368, 376
Cooil. 286

Craighead, F. S. 372, 375
Currie, J. A. 63, 64

Damagnez, J. 52, 55

Danilov, A. N. 225, 233

Daubenmire, R.F. 370, 375, 375

Day, W. R. 372, 375

Deacon, E. L. 28, 30, 32, 35, 46, 55

De Lavison, J. de R. 86, 100

Delfs, J. 132, 138, 140

Deming, J. M. 64

Development Board, Baghdad 284,

285, 286, 287
Diller, O.D. 369,376
Dirks, H.T. 374.376
Dixon, H. H. 99, 100

38o

AUTHOR INDEX

Doring, B. 162, 166
Dreibelbis, F. R. 42, 55
Duvdevani, S. 42, 43, 53, 55
Dyer, A.J. 20, 36

Eaton, P.M. 286, 287

Edlefsen, N. E. 59, 64

Eger, G. 119, 125

EUee, O. 225, 233

Ensgraber, A. 225, 232, 233

Evans, G.C. 170,188

Evenari, M. 44, 56, 184, 188, 206, 221

Fahn, A. 206, 222

Farsky, O. 372, 376

Feinbrunn. 207

Fisher, R. A. 317,324

Folkes, B. F. 168, 189

Fowells, H. A. 367, 378

Frankenberger, E. 49, 55

Fraser, D.A. 368, 371, 372, 373, 374,

376
Free, E.E. 371.375
Fricke, K. 368, 376
Friesner, R. C. 370, 376
Fritz, M. 109, III
Fukuda, Y. 273, 287
Funk, J. P. 22, 35
Furr,J.R. 323,325

Gaastra, P. 250, 256, 323, 354

Gaertner, E. E. 374, 376

Gaff, D. F. 98, 100

Gates, C.T. 340,352,354

Gates, D.M. 39,55

Gauch, H. G. 286, 287, 309, 312

Gaussen, H. 9

Geiger, R. 65, 79, 80, 82, 374, 376

Gilead, M. 46, 55

Ginsburg, Ch. 219, 221

Glueck, N. 45, 55

Golubic, S. 9

Hahn, H. 54, 55
Halevy, A. 102, 109, III
Hansen, H.L. 371,375
Hardy, F. 323, 325
Hare, F. K. 374, 378

Harlow, W.M. 367,376

Harrar, E. S. 367, 376

Harrold, L. L. 42, 55

Hartig, R. 366, 376

Hatfield, H. S. 23,35

Hayward, H.E. 286,287

Heath, O.V.S. 173, 174, iSj, 188

Heilig, H. 79,82

Helder, R.J. 86, 95, 99

Hendrickson, A.H. 323. 325, 370,

373, 378
Hertz, C.H. 172, 188
Hillel, D. 44, 56
Hills, G. A. 368,376
Hiltner, E. 44, 55
Hitier, H. 45, 55
Hofler, K. 164, 165, 166
Hofmann, G. 37, 42, 43, 44, 45, 46, 55
Holdheide, W. 225, 232, 234
Holzman, B. 19, 26, 29, 30. 35, 41, 56
Hope-Simpson, J. F. 168,189
House, G.J. 33, 34, 35, 4i, 55
Huber, B. 273, 287, 373. 376
Hiilsbruch, M. 85, 1 00
Hygen, G. 168, 170, 171, 172, 184,

186, 188

Iljin, W. S. 101,111,225,233

Jackson, J. E. 94, 99, 100
Jarvis, M.S. 290,311,311,319,325
Jarvis, P.G. 311, 3 U, 31 5, 31^', 324, 325
Jones, R.L. 43,55

Kaltwasscr, J. 225, 232, 23J.
Katti, M. S. 52, 56
Kausch, W. 66, 73, 82, 202, 204, 205
Keilhack, K. 81, 82
Kekkonen. 81
Kenworthy, A. L. 321,325
Kienholz, R. 370, 376
Kittredge, J. 132,140
Kohnke, H. 66, 82
Korczagyn, A. A. 9
Korstian, C. F. 368, 376
Kozlowski, T. T. 370,376
Kramer, P.J. 86, lOO, 184, 188, 367,
371, 373, 376

AUTHOR INDEX

38 r

Kraus, G. 79, 82

Krecmer, V. 367, 377

Kreeb, K. 225, 233, 274. -75. 279,

280,283, 284, 287
Kubin, S. 108. 109, ill
Kuiper, P.J. 352, 354
Kuntz.J.E. 373,377

Lachausee, E. 371, 377

Ladefoged, K. 373, 377

Larcher, W. 161, 164, 165, 166, 167,

225, 233
Law, F. 131, 136, 140
Lebedeft", A.F. 66, 80, 81, 82, 368, 377
Lehniann, P. 53, 55
Lejeune, G. 46, 55
Levitt, J. 85, 100, 304, 311
Lieth, H. 9
Lindner, H. 66, 82
Linke. 44

Livingston, B. E. 153, 166
Lloyd, F.E. 173,188
Lobov, M.F. 275, 287
Lodewick, J. E. 369, 377
Loftficld. J.V.G. 178,185,188
Loneragan. 201
Long, LF. 37,47,48,55
Longhead, H.J. 132, 140
Low, P. F. 59, 64
Luti, R. 237, 245
Lyon, C. 370, 377

MacDowal!, L 22, 35
Magyar, P. loi, 102, 107, III
Makkink, G. F. 248, 256
Maximov, N. A. 220, 221
Mayer, A. 225, 233
Mazurak, A. 132, 140
Mcllroy. 50

Mees, G. C. 86, 95, 97, lOO
Meusel, H. 197, 198, 198
Migsch, H. 164, 165, 166
Mikola, P. 372, 377
Milthorpe, F. L. 172, 185, 188
Mohrmann, J. C. J. 15, 18
Monteith, J.L. 38, 40, 47, 49, 55, 58,
64, 340, 346, 354

Montford, C. 54, 55
Montgomery, R. B. 29, 36
Moore, B. 368, 375, 377
Morris, E.G. 25,35,41,55
Motley, J. A. 37°, 377
Miiller-Stoll, W.R. 79, 82, 102, iii

Nagel, A. 45, 55

Negisi, K. 322, 325

Nie, R.van 86, 95, 99

Niederhof, C.H. 131, 136, 140, 141

Nienian, R. H. 86, 99

Nutman, F.J. 185, 188

Oksbjerg, E.B. 142, 144, 145, 152

Olberts, M. 81

Onal, M. 274, 287

Oppenheinier, H. R. 109, ill, 153.

167, 184, 188, 220, 221
Orchard, B. 341, 346, 354
Orshan, G. 206, 207, 219, 220, 221, 222
Orshansky, G. 206, 207, 221
Owen, P.O. 58, 64, 340, 341, 34<5,

350, 351, 354

Pannier, F. 9

Pappenheimer, J. R. 95, 100

Parker, J. 119,122,125,172,188

Pasquill, F. 20, 27, 28, 35

Paterson, S. S. 9 >.

Penfound, W. T. 372,375

Penman, H.L. 32, 35, 37, 47, 48. 5^,

147, 152, 374, 377
Philip, J. R. 59, 64, 64, 353, 354
Pigott, CD. 316,325
Pisek, A. 9, 125, 125, 153, 159, 164,

165, 167, 187, 188, 225, 233, 257, 271,

373, 377
Plantefol, L. 225, 233

Poel, L.W. 315,325

Poliakoff, A. 220, 221

Pomeroy, C.R. 138, 140

Prat, H. 226, 233

Priestley, C.H.B. 24, 29, 35, 46, 48,

49, 55, 56
Priestley, J. H. 86, 100
Prutzer, E. 157, 167

382

AUTHOR INDEX

Ramdas, L. A. 52, 56

Rathschiiler, E. 154, 167

Raunkiacr, C. 206, 221

Rawitscher, F. 122, 125

Renner, O. 273, 287

Reuther, W. 323, 324

Richards, L. A. 59, 64, 290, 311, 323, 325

Richter, R. 184, 188, 206, 221

Rider, N.E. 25,27,29,30,31,33,34,

35, 36, 41, 55
Ried, A. 225, 232, 234
Rijtema, P. E. 248, 256
Riker, A.J. 373, 377
Robinson, G. D. 25, 30, 36
Robinson, R.A. 62, 64
Romose, V. 225, 234
Rosenan, N. 46, 55
Rossby, C. G. 29, 36
Rottenburgh, W. 164, 165, 166
Rufelt,, H. 172, 188
Russel, J. C. 272
Russell, Sir J, E. 309,311
Russell, M. B. 366, 377
Russell, R.J. 372, 377
Rutter, A.J. 102, 103, m, 122, 124,

125, 125, 187, 188, 281, 283, 287,

293. 302, 311, 312, 317, 321, 324, 325
Rychnovska-Soudkova, M. 196, 197,

198, 198

Sabinin, D. A. 86, 95, lOO
Salisbury, E.J. 180, 188
Sands, K. 102, 103, ill, 125, 125, 187,
188, 281, 283, 287, 293, 302, 311, 312,

317, 321, 324, 325
Satoo, T. 322, 325
Savomin, J. 46, 55
Sayre,J.D. 178, 185, 189
Schanderl, H. 53, 55, loi, 112
Schmidt, E. 373, 376
Schneider, G.W. 321,325
Schofield, R. K. 58, 59, 64, 64
Schopmcyer, C. S. 369,370,377
Shcubert, A. 373, 377
Schulman, E. 374, 377
Scott, J. F. 134
Scott, L. I. 86, 100
Setlik, I. 108, 109, III

Shanan, L. 44, 56

Shaw, R.H. 43, 56

Shear, G.M. 369,37?

Shmueli, E. 206, 222

Simonis, W. 202, 205

Simpson, G. C. 46, 47, 56

Slatyer, R. O. 51, 52, 53, 56, 186,

189, 274, 287, 302, 309, 312, 322, 325,

352, 354
Slavik, B. 102, no, 112, 226, 227, 232,

234, 275, 287
Smith, W. O. 66, 78, 82
Smyth, E. 225, 234
Sohm, H. 159, 167
Spencer, E.J. 172, 185, 188
Stalfelt, M. G. 120, 121, 122, 125, 125,

126, 157, 167, 185, 189, 225, 226,

232, 234, 373, 377
Stanhill, G. 313, 321, 325, 354, 373,

377
Stewart. 129
Stewart, W. D. 369, 377
Stieghtz, H. 275, 287
Stocker, O. 54, 56, loi, 102, 103, 104,

107, 112, 118, 126, 170, 189, 196,

198, 225, 226, 232, 234, 273, 287,

298, 312
Stokes, R. M. 62, 64
Stone, E. C. 52, 53, 56, 367, 378
Strugger, S. 85, lOO
Surmac, G. P. 368, 378
Suzuki, C. 44, 56
Swinbank, W. C. 20, 32, 35, 36, 46, 55

Tadmoor, N. H. 45,56
Tantraporn, W. 39, 55
Taylor, R.J. 20, 36
Taylor, S. A. 323,325
Thompson, H. A. 323,325
Thome, G.N. 352,355
Thornthwaite, C.W. 19, 26, 36, 41,

56, 374, 378
Tranquillini, W. 125, 125, 156, 161,

167, 257, 271
Trenel, M. 66, 79, 80, 81, 82
Thrcn, R. 275, 288
Tugwell, C. P. 33, 34, 35, 41, 55
Turner, H. 155, 156, 157, 158, 160, 167

AUTHOR INDEX

383

Uhvits. 286

Vassiljev, I.M. loi, 1 12

Veihmeyer, F.J. 65, 66, 72, 82, 313

323, 325, 370, 373, 378
Venema, H.J. 39, 56
Verhoef, L. 371, 378
Vine, H. 323, 325
Visser, W.C. 254,256
Visvvanath, B. 284, 286, 288
Voigt, G.K. 128, 136, 140
Volk, O.H. 79,82
Vos, N.M.de 252,256
Vries, D. A. de 39, 56, 258, 271
Vries, P. A. de 254, 256

Wadleigh, C.H. 281, 286, 287, 288,
309, 312, 323, 325

Waisel, Y. 53, 54, 56, 367, 378

Walter, H. 9, 9, 65, 66, 79, 80, 82,
144, 152, 153, 157, 167, 200, 205, 225,
234, 272, 273, 274, 275, 288

Ward, R.C. 370,376

Wassink, E. C. 250, 254, 256

Watson, D.J. 340, 346, 351, 352, 353,

355

Weatherley, P.E. 86, 94, 95, 97, 98,

99, 99, 100, 102, 108, 112, 170, 189
Weaver, J. E. 317,378
Weaver, L. R. 59, 64
Weber, H. 66, 82

Webster, I. F. 284, 286, 288

Week, J. 257, 271

Welten, M. 102, 112

Went, F.W. 41,52,56,367,378

Whitehead, F.H. 235, 237, 241, 242,

243, 244, 244, 245
Wicht, C.L. 136,140
Wiggans. 373
Wilhelmi, T. 370, 378
Wilkins, F.J. 23, 35
Williams, W.T. 173, 174, 189
Willis, A.J. 102, 105, 109, 112, 168,

170, 173, 174, 175, 189
Wilm, H.G. 131, 136, 138, 140, 141,

373, 378
Wilson, C. 367, 378
Winkler, E. 187, 188, 225, 233
Wit, C. T. de 246, 256
Witts, K.J. 353, 355
Wormer, Th.M. 102, II2

Yemm, E.W. 102, 105, 109, ill, 168,

170, 173, 174, 189
Young, C. L. 52, 56, 367, 378

Zahner, R. 374, 378

Zand, G. 207, 219, 221

Zibold. 45

Zohary, M. 206, 207, 220, 222

Zon, R. 373, 378

SUBJECT INDEX

Abies hahainea, resistance to flooding, 371

Acer, killed by flooding, 372

Acer sacclmrinuiii, removal of water from
soil, 369

Acer sacchantni, 369

Acer tatriciiin, 265

Achensee, precipitation, 158

Achnagoichan, potential water deficit
and surplus, 12

Aesculiis liippocastafimii, killed by flood-
ing, 37=

Alectorietum, distribution in relation to
snow cover in Alps, 160

Alder, roots penetrating gley horizon,

371
Alfalfa, hydrature, 282

osmotic value, 279, 281

osmotic value and yield, 276, 278,

283

salt content and yield, 286

Algae, 225

Allgau, precipitation, 158

Alpine desert vegetation, 235-237

Alpine rose, distribution in relation to

snow cover in Alps, 160
injury delay and drought stress,

165 '

water content, 165

water loss, 166

Alps, climate, 154

dew, 159

potential water deficit, 1 5

Asniitopliila arenaria, 183

transpiration, 183

Anabasis articiilata, 207

life cycle, 212-213

seasonal body reduction, 215

transpiration, 217

■ ■ weight of transpiring body,

213, 216
Aiiagyris foediid, 221
Anatolia, 3, 4, 7, 8
Anemometers, 25, 33
Ankara, 3, 4, 8

climatic diagram, 4

Apemiines (Italy), 235-237

Apple, growth, 321, 322, 323

using water from great depths, 373

Artemisia canipestris, transpiration, 184
ArteDtisia lierba alba, 207

life cycle, 210-211

seasonal body reduction,

215

transpiration, 217

weight of transpiring

body, 213, 216
Artemisia moiwsperiua, 207

life cycle, 212

seasonal body reduction, 215

transpiration, 217

weight of transpiring body,

213,216
Ash, distribution in North America, 368
removal of water from soil, 369

(see also under Fraxiiins)
Atmospheric turbulence, 20-21, 26-29
Australia, dew in Victoria, 50

Eucalyptus forest, 200-201

Austria, climate at Obergurgl, 154
Azalias, distribution in relation to snow

cover in Alps, 160
injury delay and drought stress,

165

water absorption, 166
water content, 165

Baghdad, 284

Baltic coast of Germany, dew, 43

Barley, cropping pattern, 360, 361, 363,

osmotic value and hydration, 279

osmotic value and yield, 276, 277.

278

salt content and yield, 286

Beans, 253

condensation on, 45

cropping pattern, 360

osmotic value and yield, 277, 283

radiation and growth, 205

salt content and yield, 286

water lack, 282-283

water use and growth, 251, 252

386

SUBJECT INDEX

Beech, distribution in Ontario and

U.S.A., 367
Berlin, condensation in soil, 79
Bettila lutea, Distribution in North

America, 368

growth, 372

Betiila pubescens, stomatal closure, 1 87
Birch, distribution in North America,

368

effect of flooding, 371-372

growth, 372

moisture changes in leaves, 374

Blanket bog, 13, 17

Bodensee, precipitation, 158

Brachyblasts, 208-212

Brassica napus, water saturation deficit,

103, 107

wilting, 108

Brassica oleracea, water saturation deficit,

103, 104, 107

wilting, 108

Braunton Burrows, (North Devon),

sand dune plants, 168-187

temperature, 177, 179

British Isles, factors influencing distri-
bution of certain species of plants,

289-311
Bryophytes, 225

Cabbage, osmotic values and yield,

275, 276

water saturation deficit, 103, 104,

107

wilting, 108

Cairo, rainfall, 199

root penetration of desert plants,

204
California, distribution of Sequoia, 367
Caltha palustris, dew and photosynthesis,

54
Cambridge, evaporation and dewtall,

25

surface energy balance, 22

Camellia japoiiica, photosynthesis, 367
Canary grass, cropping pattern, 359,

360
Carex arenaria, 183
transpiration, 183, 186

Carrots, 253

radiation and growth, 250

water use and growth, 251, 252

Carya illiuoensis, growth and flooding,

372
Cauliflower, 253

growth and radiation, 250

water use and growth, 251

Celtis inississippiensis, growth and flood-
ing, 372
Ccntaurea aegyptiaca, root penetration, 204
Cerastiuni, 244

Ceratonia siliqua, absorption of dew, 54
Chamaephytes, seasonal dimorphism,
206-221

transpiration, 215-218

Cistus salvijolius, 207

seasonal body reduction, 215

— - transpiration, 217, 218

weight of transpiring body,

214, 216
Climatic diagrams, 3-9
Climatic types, 7
Coffea arabica, stomatal closure, 185

transpiration, 122

Coffee, moisture stress and flowering, 1 7
Condensation, 37-46

in soil, 65-82

Convolvulus lanatus, root penetration, 204
Corn, cropping pattern, 363, 364
Cornus sanguinea, 289

(see also under Thelycrania sanguinea)
Coryncphorus canescens, 196

stomatal closure, 197

transpiration, 190-191, 193-

195

water content, 193-195

Coshocton, Ohio, dewfall, 42
Cotton, 54

transpiration, 302

Crimea, large heaps of stones as dew

collectors 45
Crop yield, 326-339
Cropping patterns, 356-365
Cwm Dyli, potential water deficit

and surplus, 16
Cyanide, effect on permeability coeftici-

ents of tomato roots, 96-98

SUBJECT INDEX

387

Cytioglossiim officitwlc, 169, 174, 178-180

Stomatal aperture, 179, 185

transpiration, 179, 184, 186

Czechoslovakia, psammophytes, 190-
198

Dakar, dew collectors, 46

Deep percolation of water in the soil, 12

Denmark, spruce growth in Jutland,

142-152
Derbyshire, 289, 290, 307, 310
Desert chamaephytes, 206-221
Desert plants, 199-205, 206-221
Desert:., rainfall and run-off, 204
Dcschampsiafiexuosa, 315, 320
Dew, 25, 34, 37-54

absorption by plants, 53-54, 367

on grass, 41

in relation to photosynthesis, 54

on sugar-beet, 41

on wheat, 41

Dew^ collectors, 45
Dewfall, definition, 47
Dew gauges, 37, 42-44
Dew-point, 37
Diffusion cell, 59-63
Diffusion pressure deficit, 51
Distillation, definition, 47
Dolichoblast, 208-219
Douala, 7

climatic diagram, 5

Drought damage to oak, 152
Drought injury to spruce, 143, 144, 145
Drought resistance, 57, 302-308
Drought stress, 165

Eddy diffusivity, 21, 28, 31
Enchytraeid worms, movements in

relation to potential water surplus

and deficit, 17
Endive, 253

growth and radiation, 250

water use and growth, 251

Endymion, 315
England, dew, 43, 50

potential water deficit, 1 5

Epipactis paliistris, 182

Erica caniea, osmotic values, 159

Eucalyptus, forest, 200-201
Eucalyptus astriugeus, 201

diversicolor, 201

— — inarginata, 201

redunca, 201

Euphorbia cornuta, root penetration, 204
Europe, water balance regions, 16
Evaporation, 6, 12, 19-35, 37

in Alps, 157

measurement, 1 70

in oats, 29

in relation to radiation, 247, 248,

254

at Straznice-Pfivoz, 192

Evapo-transpiration, 3, 10, 11, 12, 16, 147

measurements, lo-ii

Exposure and plant growth, 235-244

Fagonia arabica, root penetration, 204
Fagus grandifoUa, distribution in Ontario

and U.S.A., 367
Farsetia callosa, root penetration, 204
Festuca dominii, stomatal closure, 196
transpiration, 190-191, 192-

193, 195
Festuca domitiii, water content, 192-193
Fcstucetum halleri, distribution in re-
lation to snow cover in Alps, 160
Field-balance (Morris's), 25, 26, 41
Filipendula ulmaria, 182

transpiration, 183

Filipendula vulgaris, 289

drought resistance, 302-308

growth, 290-296, 297, 310

transpiration, 296-302, 309

Finland, crop failure of pine and

spruce, 372
Fir, resistance to flooding, 371
Fitzroya cupressoidcs, longevity, 374
Flax, cropping pattern, 360, 361
Flooding, effect on trees, 371, 372
Fog, absorption by Pinus, 367

in Alps, 159

Fog precipitation, 45

France, dew collectors, 45-46

— — dewfall, 43

Fraxinus excelsior, in Hungary, 265

killed by flooding, 372

388

SUBJECT INDEX

Fraxiiiii.< nigra, distribution in North

America, 368
pcimsyhanica, reinoval of water

from soil, 369
Frost injury, spruce, 142

Geranium, condensation, 45

Germany, dewfall, 43

Gibberellic acid, effect on growth of
Hi'liaiithus, 243-244

Gobabis, climatic diagram, 4

Grape fruit, salt content and yield, 286

Grass, yield in relation to rainfall, 254

Grassland, cropping pattern, 362, 363

productivity in relation to rain-
fall, 199-200, 202

Greenhouse growth of vegetables, 246-
256

Groundwater depth in relation to
cropping pattern, 362, 364

yield of crops, 334, 335, 336

Growth function, 326-339

Gurgler valley, wind velocity, 157

Guttation, 37

Hackberry, growth and flooding, 372
Halophytes, 204
Haloxyloii nrficiilatiini, 207

life cycle, 213

seasonal body reduction, 215

— - transpiration, 217

weight of transpiring body,

213, 261
HcliaiitlicinuDi clwiiuiccistus, transpiration,

184
Helianthuf aiiniiiis, growth in wind

tunnel, 237-243
Heliclirysiini cirenaritiin, stomatal closure,

197
transpiration, 190-191, 194-

195, 196, 197

water content, 194-195

Helens mollis, 315

Hungary, Alcali Steppe, Querais cerris,

263, 265-266, 267
Hydrature, definition, 272

and plant production, 272-286

Hydnnotyle vulgaris, 169, 184

Hydrocotyle vulgaris, stomal behaviour,

181, 182
transpiration, 173, 180-182,

185, 186

Incident precipitation, measurement,

136-137, pi. I

on woodland, 136-138

India, water vapour uptake by soil, 52
Indole -acetic acid, effect on growth of

Heliaiithus, 243
Innsbruck, osmotic value in plant

communities, 159
Interception of precipitation, in spruce

stand, 1 1 7-1 19

in woodland, 127-140

Iraq, 277, 281

Ireland, potential water deficit, 15

Irrigation and grazing, 337

effect on sugar beet growth,

340-354
Israel, 207, 208

dewfall, 43

stone heaps (dew collectors) in

Negev, 45
Italy, 235-237

Jamaica, dewfall, 43

Java, oxygen requirements of tree roots,

371
Jerusalem, rainfall, 207, 213

Kabul, climate, 8

Kaiserstuhl (S.W. Germany) temperature
gradient in soil, 79

Kale, growth, 353

Kompedal (Denmark) soil moisture,
149-151

soil profile, 149-150

Kraighgau, (S.W. Germany), tempera-
ture gradient in soil, 79

Larch, removal of water from soil, 369
Larix laricina, distribution in North

America, 368
Leaf tissue, hydration in relation to

photosynthesis and respiration, 225-

233
Legumes, cropping pattern, 360, 361

SUBJECT INDEX

389

Lettuce, 253

ijsmotic value, 280, 281

osmotic value and yield, 277, 283

radiation and growth, 250

water lack, 282-283

water use and growth, 251, 252, 255

Lichen, 225

in relation to snow cover in Alps,

160

Ligtistrtim lucidtnn, photosynthesis, 367

Loendal (Denmark), soil moisture in
spruce stand, 151

temperature and rainfall, 142-143

Loiselenria proaitubeits, injury delay and
drought stress, 165

water absorption, 166

water content, 165

Loiseleurietum, distribution in relation
to snow cover in Alps, 160

Lycium, 221

Lycopsis arvcnsis, 183

Lysimeter, 42

used to measure potential evapora-
tion, 10- 1 1

Maple, growth, 369

removal of water from soil, 369

Marram grass, 183

transpiration, 183

Matric potential, 57, 61

Mediterranean chamaephytcs, 206-221

Melon, 54

Meniscus as semi-permeable membrane,
57,60

Mesquite, cessation of growth, 371

Meteorological data in relation to
plant climate, 8

Mitscherlich equation, 326-328, 330

Moltkia callosii, root penetration, 204

Montpellier (France) dew collectors,
45-46

dewfall, 43

Moor House Nature Reserve, Westmor-
land, 17

Moravia, dewfall, 43

psammophytes, 190-198

Mpscow, dewfall, 43

Munich, dewfall, 43

Negev, Dewfall, 46

rainfall, 207

stone heaps as dew-collectors, 45

Netherlands, ground-water depth and

crop yield, 334, 335, 336
New England, 368
New Forest, 324
Nicotiatm sanderae, photosynthesis and

respiration, 226-233

stomatal size, 228, 230, 231

Noca mucrouata, 207

life cycle, 212

seasonal body reduction, 215

transpiration, 217

weight of transpiring body, 213,

216
Norway, potential water deficit, 15,

16

Oak, 263, 265, 266, 267, 268, 271

-drought damage in Denmark, 152

growth, 370

penetration of gley horizon by

roots, 371

radial growth, 369

(see also under Qxiercus)
Oats, cropping patterns, 360, 361, 363,

364

evaporation, 29

osmotic value and yield, 276,

278, 283
Obergurgl, chmate, 154

precipitation, 158

snow cover, 160

Odessa, 6

climatic diagram, 4

Olca ciiropca, average saturation deficit,

53-54
Orchis practemiissa, 182
Onion, stomatal closure, 185
Osmotic potential, 58
Osmotic value, 273-281, 283, 284

determination, 275

pine needles, 163

and yield, 275, 276

Otztal, precipitation, 158

Oxford, throughfall in spruce woodland,

127-140

390

SUBJECT INDEX

Patschcrkofel, sub-alpine plants — water

content, 165
Pea, 67, 71-78

cropping pattern, 360, 361, 363, 364

growth and radiation, 250

growth of seedHngs, 201-202, 203

Peanuts, transpiration, 302

Peat, in Scotland, 13, 14

Pecan, growth and flooding, 372

Pelargoiiiiiin, stomatal behaviour, 173

water movements in leaf, 90-93

Pennsylvania, growth of trees and

drought, 372
PhaseoUis nitmgo, salt content and yield,

286
Photometer, 169-170
Photosynthesis and growth of poplar,

257-270

hydration of leaf tissue, 225-233

radiation, 250

stomatal closure, 225

Picva abies, crop failure in Finland, 372

dieback and drought, 372

growth, 257

growth in Denmark, 142-152

throughfall beneath, 127

Picea excelsa, injury delay and drought

stress, 165
precipitation in stand, 1 1 5-

125

sub-lethal water content, 165

Picea glatica, resistance to flooding, 371
Picea inariana, distribution in North

America, 368

Ontario, 367-378

Picea sitchemis, dieback and drought, 372

throughfall beneath, 131

Pimpitiella saxifraga, growth, 210

Pine, drought and growth, 372

soil water depletion in Arkansas,

374

(see also under Piiitts)
Pineapple, 54

Pinus, absorption of dew, 54
Piiius banksiana, distribution in Ontario,

367-368
Pinus cembra, injury delay and drought

stress, 165

Pinus cembra, osmotic value of needles,

163
snow cover and water bal-
ance, 162-166

temperature of needles, 156

Pinus coultcri, survival value of dew, 367

water vapour uptake, 52

Pi}uis (iciisifiora, growth, 322
Pintis cchiiiata, radial growth, 369

water vapour uptake, 52

Piinis halepcnsis, average saturation defi

cit, 53-54
Pinus palustris, ring width, 369
Pinus potiderosa, survival value of dew,

367
Pinus resinosa, resistance to flooding, 371

throughfall beneath, 128

Pinus strobus, shade effect, 368

transpiration, 122

Pitnis sylvestris, competition for moisture,

368

crop failure in Finland, 372

growth, 257, 281, 283, 293

leaching in podsol beneath.

129

transpiration, 122, 302
water consumption, 124, 187
water uptake by dwarf shoots,

102
Pinus taeda, in Piedmont plateau, 368

transpiration, 370

utihzation of soil water by

seedlings, 369-370
Piswn sativum, 67, 71-78
Pituranthus torttiosus, root penetration,

204
Poplar, photosynthesis and growth,

257-270
Populus angulata, growth, 370
Popnlus candicans, water movements in

leaf, 90-93
Potatoes, cropping pattern, 356, 359,

360, 361, 362, 363, 364
osmotic values and yield, 275,

276, 278, 283
water lack, 282-283

Potential evaporation, 10, 11, 12, 16
• measurement, lo-ii

SUBJECT INDEX

391

Potential water deficit and surplus, 10-18

at Achnagoichan, 12

in Scotland, 15

Potentilla anscrina, 183
Poterium spinosum, 207

life cycle, 209-210, 211

seasonal body reduction, 215

transpiration, 217, 218

weight of transpiring body,

214, 216
Potsdam, temperature gradient in soil, 79
Precipitation, Distribution: in Alps,

157-158

in spruce stand, 1 15-125, 127-

140

Precipitation distribution above wood-
land, 136-138, pi. I.

Pmmis avium, killed by flooding, 372

Primus padus, 289

drought resistance, 302-308

growth, 290-296, 299, 309,

310

transpiration, 296-302, 303,

309
Prwuis spiiiosa, 265
Psammophytes, in Czechoslovakia, 190-

198
Puerto Rico, dwarf rain forest, 373
Pyms communis, 265

Qticicus alba, radial growth, 369

Qucicus borealis, growth, 370

roots penetrating gley hori-
zon, 371

Qucrcus cerris, 265, 271

assimilation, 266, 267

growth, 263

transpiration, 267

Quercus petraea, growth, 313-324

Qucrcus robtir, 371

assimilation, 266, 268

drought damage in Den-
mark, 152

killed by flooding, 372

transpiration, 268

Radiation, 3

at Obergurgl, 155, 156

Radiation, at Wien, 155, 156

in relation to growth, 248-251

Radiometers, 22

Radish, 253

radiation and growth, 250

water use and growth, 251

Rape, water saturation deficit, 103, 107

wilting, 108

Remscheid Dam (Germany), precipita-
tion in drainage area, 81

Revivim, rainfall, 207, 213

Rhizoctoiiia, on sugar beet. 341

Rhododendetum ferruginei, distribution
in relation to snow cover in Alps, 160

Rliododetidnvi ferrugineum, injury delay
and drought stress, 165

water content, 165

water loss, 166

Ribcs sanguineum, water movements in
leaf 90-93

Richardson number, 20, 21, 27, 28, 29, 30

Robiiiia pseudoacacia, killed by flooding,

372
Rocky Mountains, growth of young

conifers, 370
Rosenholm (Denmark), soil moisture

in spruce stand, 148

soil profile, 149

Rostock (E. Germany), soil moisture, 81
Rothamsted, absorption of water vapour

by soil, 52

dewfall and distillation, 49

growth of sugar beet, 340-354

weather, 342-343

Rumania, dewfall, 43

Rye, cropping pattern, 356, 359, 360,

361, 362, 363, 364

Salix atrocinerea, 182

transpiration, 183

Salix interior, growth and flooding, 372
Salix nigra, growth and flooding, 372
Salix purpurea, growth, 370
Sand dune plants, 168-187
Sarcostemma australis, 205
Saxifraga liypnoides, 289

drought resistance, 302-308

growth, 290-296, 310

392

SUBJECT INDEX

Snxifraga hypiioidcs, transpiration, 296-

302, 303, 309
Scirpus boloschoeiitis, 182
Scotland, 12, 13, 14, 16, 17

distribution of arable land, 14

Senecio elegaiis, 237

Senecio jacohaea, 169, 180, 181

stoniatal aperture, 174, 175,

177, 178, 185, 187
transpiration, 171, 172, 177,

184, 186

water relations, 176-178

Senecio nehrodensis, growth in relation

to wind speed, 237, 238
Sequoia seuipervireus, distribution in

relation to fog in California, 367
Sequoia washingtoniana, distribution in

relation to fog in California, 367
Silkeborg Sonderskov, oak and drought

damage, 152
soil moisture in spruce stand,

151-152
Snow cover — influence on water rela-
tions, 159-166

at Obergurgl, 160

Soil-balance (Morris's), 25, 26, 41
Soil flux plates, 22, 23, 24

in poplar stand, 258, 259

Soil moisture in relation to throughfall,

129

in spruce woodland, 147-152

Solaiuiiu elaeagnifoliuin, osmotic value,

275
Solarimeters, 22
Solute potential, 58
Sorghum, transpiration, 302
South-West Africa, plant cover, 199-200
Spinach, 253

radiation and growth, 250

water use and growth, 251, 252

Spruce, crop failure in Finland, 372

dicback and drought, 372

distribution in North America,

368

distribution in Ontario, 367-368
effect of flooding, 371
growth, 257
growth in Denmark, 142-152

Spruce, growth in Ontario, 371

injury delay and drought stress, 165

interception of rainfall, 11 5-125,

127-140, 373
stemflow, 128-129, 134. 136, 137,

138, 139

— stomatal regulation of transpira-
tion, 125

— sublethal water content, 165

Stemflow, measurement, 134, 136
in spruce in relation ia incident

rainfall, 128-129, I37. 138, 139
Stomatal aperture, Cyiioglossuni, 179

Nicotiana, 228, 230, 231

Senecio, 174, 175, 177, 178,

185, 187
Stomatol behaviour, Hydiocoiyle, 181,

182

Pclargoiiiiiiii, 173

Stomatal closure, 187, 196, 197
Stomatal closure, and photosynthesis,

225
Stomatal regulation of transpiration in

spruce, 125
Stuttgart, 6

climatic diagram, 4

Straznice-Privoz (Moravia), 190-192

climatic conditions, 191-192

evaporation, 192

humidity, 192

temperature, 192

Sub-alpine region, chmate, 153-166

Sublethal deficit, 153, 154

Succulents, 205

Sugar-beet, 226

cropping pattern, 356, 360, 361,

363, 364

growth and irrigation, 340-354

osmotic value and yield, 276, 278,

283
Surface energy balance, 19-35
Surface tension, 57
Sweden, spruce stands and precipitation,

115-125
Switzerland, 16

Table Mountain, fog precipitation, 45

SUBJECT INDEX

393

Tamarack, distribution in North

America, 368
Temperature, of pine needles, 155, 156,

161

of soil beneath snow, 161, 162

of spruce needles, 145-147

measurement, 145

Temperature gradients in soil, 65-82
Teucrium chamaedrys, transpiration, 184
Teucrium polimti, 207

hfe cycle, 208-209, 210

seasonal body reduction, 215

transpiration, 217, 218

weight of transpiring body,

214, 216
Thelycrania sanguinea, 289

drought resistance, 302-308

growth, 290-296, 298, 309,

310

transpiration, 296-302, 303,

309

Theodosia (Crimea) large heaps of

stones as dew collectors, 45
Thermocouples, wet and dry bulb, 25, 26
Throughfall, in forests, 127-140

measurement, 131, 136

Thymus capitatus, 207

hfe cycle, 208, 209

seasonal body reduction, 215

transpiration, 217, 218

Weight of transpiring body,

214, 216
Tilia cordata, killed by flooding, 372
Tobacco, photosynthesis and respiration,

226-233

stomatal size, 228, 230, 231

Tomato, irrigation and growth, 340, 352

osmotic values and yield, 275, 276

salt content and yield, 286

water movements in roots, 94

Transpiration, 31-32, 85-99

measurement in detached leaves,

170

in psammophytes, 191

Trifolium incarnatum, growth, 202-204
Tsuga canadensis, throughfall, 128
Turgor pressure, 273
Turkey, 3. 4. 7. 8

Turnip, osmotic value, 280

osmotic value and yield, 277, 283

water lack, 282-283

Tyrol, cUmate, 154

U.S.S.R. dewfall, 43

Vaccinietum, distribution in relation to

snow cover in Alps, 160
Vaccinium vitis-idaea, transpiration, 186
Vegetation regions, in relation to

climatic types, 8
Verbascum thrapsus, 174
Viviafaha, stomatal closure, 187
Victoria (AustraUa) dew, 50
Vietnam, condensation, 79
Viola hirta, transpiration, 183
Von Karaman's constant, 20

Wales, potential water deficit, 15, 16
Water absorption, 153

by spruce at low temperatures, 162

Water consumption, Pinus, 124

by spruce trees in relation to

precipitation, 123-125
Water content of soil, Braunton

Burrows, 175-176
Water deficit, estimation in leaves, 170
Water loss, reduction, 153
Water movements, effect of dissolved

salts, 57-64
Water movements in roots and leaves,

85-99
Water potential of soil, 57-58
Water saturation deficit, in leaves, loi-

III
Water use and growth, 251-256
Water vapour, absorption by plants,

50-53

movement in soil, 65-82

Wheat, cropping pattern, 360, 361

osmotic value, 275

and yield, 276, 284

salt content and yield, 286

transpiration, 121

Willow, 182

growth and flooding, 372

394

SUBJECT INDEX

Willow, resistance to lack of oxygen in

soil, 371

roots penetrating gley horizon, 371

transpiration, 183

Wilting, 108

in relation to water saturation

deficit, loi-iii
Wind and plant growth, 235-244
Wind tunnel — growth of Zea and

Helianthus, 237-243
Wind velocity, in Gurgler valley, 1 56, 1 57
World Atlas of CUmatic Diagrams, 7,

8,9

Wiirzburg (Germany) temperature gra-
dient in soil, 79

Zea mats, growth in wind tunnel, 237
Zilla spinosa, root penetration, 204
ZUlertal, precipitation, 159
Zygophyllum dumosum, 207

Hfe cycle, 212

seasonal body reduction, 215

transpiration, 217

weight of transpiring body,

213, 216