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THE STUDY OF
THE DISTRIBUTION

OF

BRITISH PLANTS

BEING THE REPORT OF THE

CONFERENCE

HELD IN 1950 BY

THE BOTANICAL SOCIETY OF
THE BRITISH ISLES

EDITED BY

J. E. LOUSLEY

Price 10/-

Printed by T. Bcncle & Co. Ltd., Market Place, Arbroath,

for the

BOTANICAL SOCIETY OF THE BRITISH ISLES AND
OBTAINABLE FROM THE SOCIETY, c/o DEPARTMENT
OF BOTANY, THE UNIVERSITY, OXFORD.

THE BOTANICAL SOCIETY OF THE BRITISH ISLES

Membership is open to all persons, whether amateur or pro¬
fessional, interested in British botany. Societies, Libraries,
Museums, Botanical Gardens and similar Institutions may be¬
come Subscribers. Subscription rates are: 1 guinea per annum
for Ordinary Members and Subscribers; 10s 6d for Junior Mem¬
bers (under 21 years of age). The journal Watsonia (three or
four parts a year) and the Year Book are issued free to members
and subscribers, who are also entitled to other valuable privileges.
Full details of these are given in the prospectus to be obtained
from the Honorary General Secretary, 7 Penistone Road,
Streatham Common, London, S.W.16.

UNIFORM WITH THIS VOLUME

British Flowering Plants and Modern Systematic
Methods. Being the report of the Conference on The Study oj
Critical British Groups arranged by the Society in 1948. Edited
by A. J. Wilmott. This book of 104 pages with 18 half-tone
plates and other illustrations is an important contribution to
the study of British plants and should be in the hands of every¬
one interested in the subject. Copies may be obtained at 10s 4d
post free from Mr. J. H. Burnett, Dept, of Botany, The Univer¬
sity, Oxford.

THE STUDY OF
THE DISTRIBUTION

OF

BRITISH PLANTS

THE STUDY OF
THE DISTRIBUTION

OF

BRITISH PLANTS

BEING THE REPORT OF THE

CONFERENCE

HELD IN 1950 BY

THE BOTANICAL SOCIETY OF
THE BRITISH ISLES

EDITED BY

J. E. LOUSLEY

May 14th, 1951

Printed by T. Bunclk tfc Co. Ltd., Market Place, Arbroath,

for the

BOTANICAL SOCIETY OF THE BRITISH ISLES AND
OBTAINABLE FROM THE SOCIETY, c/o DEPARTMENT
OF BOTANY, THE UNIVERSITY, OXFORD.

sa-itfi.

hUi

1" E LONG

Fig. 1.

The Watsonian Vice-Counties of England, Wales and Scotland (numbered 1 to
112) and the Irish County-Divisions (numbered 1 to 40 and prefixed with “H”

when cit^d) as in use to-day.

With acknowledgment to “ The New Naturalist.”

CONTENTS

Page

Editorial Note ... ... ... ... ... ... ... 7

Programme of the Conference ... ... ... ... 8

List of Botanists who attended the Conference ... ... 10

Introductory Remarks by the President ... ... ... 12

The Study of Plant Distribution. S. M. Walters ... ... 12

The Watsonian Vice-County System. J. E. Dandy ... 23

Maps of the Watsonian Vice-Counties. (Exhibit). J. E.

Dandy ... ... ... ... ... ... ... 30

The Watsonian Vice-County System in Practice. J. E.

Lousley ... ... ... ... ... ... 30

Maps showing Plant Distribution in Britain and European

Countries. (Exhibit). J. E. Lousley ... ... 13

Maps of the Distribution of Vascular Plants in N.W.

Europe. (Exhibit). E. Hulten ... ... ... 48

Mapping the Distribution of Species. W. T. Stearn ... 48

The Study of Plant Distribution in Holland. A. W. Kloos 64

Problems of Distribution raised in the Compilation of a

County Flora. J. G. Dony ... ... ... ... 69

The Distribution of Bunium Bulbocastanum. (Exhibit).

J. G. Dony ... ... ... ... ... ... 74

Distribution Maps of Kent Plants. (Exhibit). F. Rose ... 76

Distribution Maps of Lincolnshire Plants. (Exhibit).

Miss E. J. Gibbons ... ... ... ... ... 79

The Distribution of Primula elatior. (Exhibit). Doris &

Harry Meyer ... ... ... ... ... ... 81

Geographical Distribution and Isolation in some British

ecospecies. D. H. Valentine ... ... ... 82

The Geographical Distribution of the British species of
Thymus, and a brief illustration of the application
of Distributional Studies in Ecology. C. D. Pigott 91

A historical approach : Some Late-glacial Species from the
Lower Tees area and their present distribution.
Kathleen B. Blackburn ... ... ... ... 96

Page

The sequence of the Pliocene and Pleistocene Bramble
Floras in Periglacial S.E. England. (Exhibit).

W. C. R. Watson . 102

The Distribution of the Digitalis purpurea complex. (Ex¬
hibit). V. H. Heywood ... ... ... ... 104

The Topocline in TJlmus coritana. (Exhibit). R. Melville 105

The Antarctic Origin of some British “Carices”. (Exhibit).

E. Nelmes ... ... ... ... ... ... 108

Distributional Studies and Generic Segregation in Lepturus

sensu Bentham. (Exhibit). C. E. Hubbard ... 110

A Proposal for Mapping the Distribution of British Vas¬
cular Plants. R. Clapham ... ... ... ... 110

General Discussion ... ... ... ... ... ... 118

Brains Trust ... ... ... ... ... ... ... 121

Concluding Remarks by the President ... ... ... 124

Field Meeting to Quendon Wood ... ... ... ... 124

Postscript ... ... ... ... ... ... ... 125

Index ... ... ... ... ... ... ... ... 120

%

EDITORIAL NOTE

The purpose of this volume is to make available to a wider
public the papers read during the two crowded days of the second
Conference arranged by the Botanical Society of the British Isles.
Its contents deal wTith a subject of growing importance in con¬
nection with recent developments in the study of the taxonomy,
ecology, recent palaeobotany and even the cyto-genetics of the
British flora. They appear at a time when it is appropriate to
review past work and to consider future requirements. Much of
the information in the papers is not easily available elsewhere
and some of it is new. These collected contributions should thus
provide a useful account of the various approaches to the study
of plant distribution in Britain and opportunities for comparison
with the methods used in neighbouring European countries.

No more suitable subject could have been chosen for a Con¬
ference arranged by the Botanical Society of the British Isles.
It provides ideal opportunities for collaboration between amateur
and professional botanists, since the bulk of the records are pro¬
vided by the former and much of their interpretation is under¬
taken by the latter. Moreover the subject is one in which the
Society has long played a leading part by collecting and publish¬
ing records.

In 1839, in the first publication of the Botanical Society of
London, from which we claim descent, the Council in inviting
communications from members asked particularly for those on
botanical geography. Later a leading part in the affairs of our
forerunners was played by H. C. Watson whose name is men¬
tioned repeatedly in the following pages. After the issue of his
Cybele in 1847-49, records in our publications were often given
as additions to that work. Later his Topographical Botany be¬
came the standard and records extending the known distribution
of British plants became regarded as of increasing importance in
the Society. For the last forty years “ New County and other
Records”, now known as “Plant Records”, have appeared regu¬
larly in our annual Report and Wat sonia : they provide the most
important single source of recorded additions to British “ geo¬
graphical botany ”.

The papers and descriptions of exhibits as published in this
book have been rearranged in a sequence more suitable for read¬
ing and reference. The order in which they were given can be
seen from the Conference Programme as printed on the next two
pages.

The success of the Conference was due to the energy and en¬
thusiasm of Dr. J. G. Dony, Honorary Field Secretary, and Mr.
W. R. Price, Honorary Assistant Secretary of the Society, and
to the other officers and members who assisted in the organisa¬
tion. We are indebted to Miss M. S. Campbell for approaching
the British Council for the grant which made it possible to invite
Dr. A. W. Kloos. Thanks are also due to all the other people and
bodies who assisted.

I should also like to take this opportunity of acknowledging
the assistance of all those who kindly gave permission for repro¬
duction of maps or base maps used in connection with the illus¬
trations.

J. E. Lousley.

CONFERENCE PROGRAMME

1950

AIMS AND METHODS IN THE STUDY OF
THE DISTRIBUTION OF BRITISH PLANTS

FRIDAY, March 31st

10.30 a.m. Introductory Talk

The President : Mr. J. S. L. GILMOUR

10.45 The Study of Plant Distribution

Mr. S. M. WALTERS

11.45 Geographical Distribution and Isolation in some

British Ecospecies

Dr. D. H. VALENTINE

12.45 p.m. Interval for Luncheon

2.15

2.45

3.35

4.15

5.00

The Watsonian Vice-county System
Mr. J E. DANDY.

The Watsonian Vice-county System in practice
Mr. J. E. LOUSLEY

Problems of Distribution raised in the compilation
of a County Flora

Dr. J. G. DONY
Interval for Tea
EXHIBITION MEETING

Maps of the Watsonian Vice¬
counties

The Distribution of Bunium Bulbo-
castanum

The Distribution of the Digitalis
purpurea complex

Distributional Studies and generic
segregation in Lepturus sensu
Bentham

Maps showing Plant Distribution in
Britain and abroad

The topocline in Ulmus coritana

Primula elatior

Mr. J. E. Dandy.
Dr. J. G. Dony.

Mr. V. H. Heywood

Mr. C. E. Hubbard

Mr. J. E. Lousley

Dr. R. Melville

Miss D. and Mr. H. Meyer

8

The Antarctic origin of some British
Carices

The Ecological and Geographical
Distribution of the British species
of Thymus

Distribution Maps of Kent Plants

The History and Distribution of
some Brambles of S.E. England

Mr. E. Nelmes

Mr. 0. D. Pigott
Mr. F. Rose

Mr. W. C. R. Watson

SATURDAY, April 1st

10.00 a.m. *The Importance of Mapping in Ecology

Capt. C. DIVER

10.30 Some Late Glacial Species from the Lower Tees Area

and their present Distribution

Dr. K. B. BLACKBURN

Some Notes on Mapping the Distribution of Species
Mr. W. T. STEARN

Interval for Luncheon

The Study of Plant Distribution in Holland
Dr. Ir. A. W. KLOOS, Jr.

A Review of the Work of the Conference
Prof. A. R. CLAPHAM
followed by a General Discussion

4.15 Interval for Tea

5.00 BRAINS TRUST

Question Master — Mr. J. S. L. GILMOUR

Mr. J. P. M. BRENAN Dr. J. M. LAMBERT

Dr. R. C. L. BURGES Dr. W. B. TURRILL

Mr. R. A. GRAHAM Prof. T. G. TUTIN

11.30

12.30 p.m.
1.45

2.45

6.30

Closing Remarks by the President.

SUNDAY, April 2nd

FIELD MEETING TO QUENDON WOODS, ESSEX
TO STUDY THE OXLIP ( Primula elatior )

Leaders: Dr. D. H. Valentine, assisted by Miss D. & Mr. H. Meyer

* As Capt. Diver was prevented from attending t lie Conference, Mr. C. D. Pigott
read the paper printed on pp. 91-95, which was prepared at very short notice.
With this exception the Programme was carried out as printed

9

LIST OF MEMBERS AND GUESTS ATTENDING THE CONFERENCE

March 31 and April 1, 1950

D. E. Allen

A. H. G. Alston
G K. L. Alvin
G B. W. Anderson
G. M. Ash
G O. E. Balme

E. B. Bangerter
G Miss G. Barkley

Miss F. M. Barton
P. R. Bell

F. J. Bingley

Dr. K. B. Blackburn
G B. J. Bows
R. A. Boyd
J. P. M. Brenan
Dr. M. G. Calder
Miss M. S. Campbell
G T. H. Catchpool
Miss B. M. Chalk
G J. E. W. Chalkley
G V. H. Chambers
Dr. S. E. Chandler
Prof. A. R. Clapham
Dr. W. A. Clark
G I. Clifford
G A. J. Coel

C. L. Collenette
G M. W. Cornish

Miss W. J. Cornwell
G G. F. Creber
G A. J. Crosby-Browne
J. E. Dandy
Miss E. W. Davies
G P. R. Day
G D. Dent
G Miss C. I. Dickinson
Dr. J. G. Dony
Miss E. J. Drew
G R. B. Drummond
G Prof. K. Faegri

Mrs. P. R. Farquharson
G M. E. Fox
G D. H. Friend
Miss L. W. Frost
G A. Garrard
G A. R. Gemmell
Miss E. J. Gibbons

Mrs. A. N. Gibbv
G D. G. Gill

J. S. L. Gilmour
G M. A. Graham
R. Graham

R. D. Graham
P. S. Green

J. D. Grose
Mrs. B. Hassall
F. N. Hepper
G V. H. Heywood
G J. Holroyd
G P. B. Hort

C. E. Hubbard
G R. M. Hughes

Miss M. M. Hyde

S. T. Jermyn
G C. J. Kelsall

D. H. Kent
G J. Kerslake
G G. C. King

G Dr. Ir. A. W. Kloos, Jr.
Dr. J. M. Lambert
Miss C. E. Longfield
J. E. Lousley
Prof. R. C. McLean
Miss M. M. Marriott
Rev. W. Keble Martin
Dr. R. Melville
G Miss D. Meyer
H. Meyer

E. Milne-Redhead
G B. Molesworth

Miss B. M. C. Morgan
J. K. Morton
Miss C. W. Muirhead
E. Nelmes
G Miss S. Nelmes
P. M. Newey
G J. D. Ovington
G M. M. Parker
C. D. Pigott
G J. V. Poore
M. E. D. Poore
W. R. Price
C. T. Prime
W. Ramsden

10

Miss E. Rawlins
R. C. Readett
B. W. Ribbons
Mrs. M. Richards
Miss C. M. Rob
G D. H. Robertson
F. Rose

Miss E. M. Rosser
N. Y. Sandwith
G Miss R. G. Shove
N. D. Simpson
G R. C. Sinfield
G D. C. Smith
G J. D. Spink
G W. T. Steam
G D. G. Stygall

V. S. Summerhayes
G H. M. Swallow
E. L. Swann
G A. C. Tallantive
P. Taylor
G M. Tindale

Dr. W. B. Turrill
Prof. T. G. Tutin
Dr. D. H. Valentine

G

P. F. Vernon
Mrs. W. Verschoyle
G B. C. Vincent

A. E. Wade

E. C. Wallace
S. M. Walters

Dr. E. F. Warburg

B. T. Ward
W. E. Warren
Mrs. W. Boyd Watt
Dr. E. V. Watson
W. C. R. Watson
Mrs. B. Welch

A. W. Westrup
G D. S. White

F. N. Whitehead
Miss M. M. Whiting
Miss C. Wickham

G Prof. R. van der Wijk
G J. Wilkinson

Miss A. F. Wood
J. E. Woodhead
G D. A. Wright
G P. L. Wright
Dr. D. P. Young

Guest

11

INTRODUCTORY REMARKS BY THE PRESIDENT

The President, Mr. J. S. L. Gilmour, opening the Conference,
referred to the great loss suffered by the Society and by Botany
in general through the recent death of Mr. A. *J. Wilmott, who
was to have given the opening paper. He asked those present to
stand as a tribute to his memory.

Mr. Gilmour then extended a warm welcome to the guests
from overseas — Dr. Ir. A. W. Kloos, Jr. (Holland), Professor R
van der Wijk (Groningen), and Professor Knut Faegri (Bergen).
He read a letter from Capt. C. Diver, Director-General of the
Nature Conservancy, regretting that he could not be present and
expressing the hope that close co-operation would be established
in the future between the Conservancv and the Societv. This
suggestion was warmly welcomed by the Conference, and the
President said it would be referred to the Council for action.

The President then outlined briefly the scope of the Confer¬
ence, saying he would leave a more detailed treatment of the
subject to Mr. S. M. Walters in his opening paper on the “ Study
of Plant Distribution.”

THE STUDY OF PLANT DISTRIBUTION

S. M. Walters.

In this paper I intend to survey in a general way the study
of the distribution of higher plants, wdth particular reference to
the British Flora ; and will content myself with a mere mention
of those specialised fields which are to be elaborated by later
speakers at this Conference. It would be best, I think, to begin
with a consideration of the concept of distribution. Every species
of plant or animal — indeed every higher taxonomic unit also —
occupies only a limited proportion of the Earth’s surface. It is
common for biologists to speak of the range or area of a species;
and the simplest way by which such a range may be indicated is
by an outline on a map enclosing all the known occurrences of
that species. Any species, genus, or family having two or more
clearly separated areas is said to exhibit a discontinuous or dis¬
junct distribution ; any group completely confined to a relatively
small area is said to be endemic to that area. Clearly no species
can be continuously distributed over the whole of its range in the
sense that the individuals occupy all the available space; even
in those types of vegetation where a single species is dominant
over a very considerable area — as in parts of the northern conifer¬
ous forest in. for example, Scandinavia, where Pinus sylvestris

12

may be the only dominant — local physiographic features (steep
rocks, rivers, lakes, etc.) must interrupt the uniformity. In prac¬
tice, of course the term discontinuous is restricted to those ex¬
treme types of disjunction where the species is completely absent
from a considerable area of territory between any two areas in
which it occurs. As we shall see later, the phenomena of discon¬
tinuous distributions are of the utmost interest and significance
to plant and animal geographers.

The study of plant distribution — indeed, of plant geography
in general — is commonly assumed to date from the end of the
18th century, and more precisely, perhaps, from the publication
in 1792 of Willdenow’s Grundriss der Krauterkunde, followed in
the early 19th century by the works of Wahlenberg, von Hum¬
boldt, De Candolle, and others. In these early works the general
features of the distribution of species emerged, and the correla¬
tion of distribution with climatic factors was recognised. A
period of considerable activity followed, in which the study of
distribution went hand in hand with that of svstematics. In
Britain the scientific study undoubtedly begins with Watson,
whose first work, Outlines of the Geographical Distribution of
British Plants, appeared in 1832. Before Watson’s time, British
botanists had been content with vague and often inaccurate
generalisations on the occurrence of species in Britain, and no
serious attempt had been made to systematise the rapidly grow¬
ing knowledge on the distribution of the British flora. Although
Watson was clearly familiar with the work of the Continental
plant geographers — thus he refers to Wahlenberg, De Candolle,
and others — he did not attempt to base his distribution types of
the British flora on the general European range of the species,
but only on their ranges within the British Isles. Before the
publication of Watson’s main work (the first volume of the Cybele
Britannica appeared in 1847), Forbes had published his soon
famous paper, based upon an address to the British Association
in 1845, “ On the connexion between the distribution of the exist¬
ing fauna and flora of the British Isles and the geological changes
which have affected their area ”. In this paper Forbes classified
British plants into five so-called “ Floras ” according to their
general European distribution; and further set forth clearly the
historical interpretation of the facts of geographical distribution.
It is important to realise the nature of this hypothesis, advanced
by Forbes some years before the publication of Darwin’s Origin
of Species, as it is still generally accepted and lies at the basis of
all interpretative comparative plant geography. Forbes postulated
the existence of what he called “specific centres ” — that is, that
every species has had one single centre of origin from which it
has spread to occupy its present area, and that cases of discon¬
tinuous distribution are due to historical causes which have
brought about the separation of originally more or less continuous
populations, by destruction of parts of those populations. To
quote his own words : — “ The specific identity, to any extent,

13

of the flora and fauna of one area with that of another, depends
on both areas forming, or having formed, part of the same specific
centre, or on their having derived their population by transmis¬
sion, through migration over continuous or closely contiguous
land, aided in the case of alpine floras by transportation on float¬
ing masses of ice He considered another possible interpreta¬
tion of discontinuous distributions, namely that these were to be
attributed to accidental long-range dispersal, but decided that
this hypothesis was quite inadequate to explain the peculiar
features of such discontinuous ranges. Darwin of course was to
incorporate a considerable amount of data on plant and animal
distribution of this type in his Origin of Species, using the facts to
support his hypothesis of evolution through Natural Selection.

To return to Watson. Perhaps the clearest indication of the
soundness of Watson’s work is to be seen in the titles of papers
before this Conference, over a century after the publication of
the first volume of the Cybele. British Botany has in fact used
virtually unchanged as a basis for the recording of plant distri¬
bution within the British Isles the system invented by Watson;
and although it will be argued — and in my opinion rightly argued
— that for many purposes the vice-county system [see p. 23]
is inadequate, there can be no doubt that by means of it a firm
foundation of fact was built and the study of comparative plant
distribution made possible in Britain. I do not propose to
discuss the system any further here — we are to consider it in de¬
tail this afternoon — but may conveniently use it to illustrate a
general principle which I must now discuss.

This concerns the relation between the aims of our study of
plant distribution and the methods which we adopt — the two
halves of our subject, in fact, as expressed in the Conference title.
By methods I mean here not only the making and collection of
records of the occurrence of species — the basic field work — but
also their representation by means of mapping and in other ways.
By aims I understand the use of the collected data for the testing
or establishment of theories to explain the distribution of plants
in terms of the environment in its widest sense, past and present,
and in terms of the genetic capacity of the plants themselves.
In one way the method may be independent of any aim — thus
there is always a place for simple accurate observation and record
of any phenomena of natural history, and the constant recording
of the occurrence of species in Britain has been and still is a most
important work, largely done by the amateur naturalist through
such societies as our own, providing the essential basis of fact.
In another sense, however, the method adopted depends, or
should depend, on the aim ; thus, if one wishes to study the rela¬
tion between soil factors and the distribution of a species, it is
immediately obvious that some more accurate measure of distri¬
bution than the vice-county system is required. This dependence
is even more obvious when the representation of distribution on
maps is undertaken — in the choice of a suitable projection, or

14

the conventions to be adopted, etc. As several speakers realised
at a recent symposium on mapping of biological distributions
organised by the Systematics Association and the Royal Geogra¬
phical Society, there is a distinct danger involved here in this de¬
pendence of methods on aims — namely that the methods of
mapping, etc., used may well be chosen, perhaps more or less
subconsciously, to bring out with false clarity the particular point
necessary to support a theory. I do not wish to pursue this — it
will probably arise in our discussion of methods; it is of course
simply a particular case of a danger to which every scien¬
tist is exposed — the danger of selecting facts to suit a precon¬
ceived idea ; and Darwin’s remedy, which was roughly to be aware
of this weakness of the human mind and to make a special note
of any inconvenient fact before the mind conveniently forgets it,
is probably as good as any.

Let us turn back now to the interpretation of the facts of
distribution, and this can perhaps most easily be done by con¬
tinuing the history of the study of British distributions. As I
said earlier, the first workers in this field were soon impressed by
the broad correlation of distribution with climatic factors. Wat¬
son himself, for example, wrote (1835, Remarks ....): “ It might
be expected that the countries nearest to Britain, in geographical
position and climate, would exhibit the closest resemblance in
their floras, and this accordingly is found to be the case ”. There
was soon, however, a tendency by Continental workers to over¬
simplify the relations between climate and distribution, and to
think, for example, that, if a range of mean January temperatures
could be found to be closely correlated with the distribution of
a species, then the range of that species could be explained in
terms of that one factor only. Further reference will be made to
this. The realisation by Forbes and De Candolle of the historical
factors in distribution was of course a step of very great im¬
portance, and such interpretations received great impetus from
the publication of the Origin of Species and the general acceptance
of the evolutionary theory. In Britain, however, we find that
the second half of the 19th century produced little in the way of
comparative study of distribution ; and we are well into the pres¬
ent century before interpretations of the distributional pheno¬
mena are debated and discussed. The main interest has tended to
centre particularly round two or three groups of British plants
which exhibit highly discontinuous distributions over their whole
range, particularly the so-called Lusitanian element in the Irish
flora, and the rather loosely termed Arctic-alpine element mostly
in the mountains of Britain. These two groups are roughly two
of Forbes’ five Floras; he suggested that the Lusitanian species
were our oldest ones, having survived the Ice Age which had
destroyed them elsewhere in N.W. Europe, whilst the Arctic-
alpines he interpreted as having had a widespread distribution
in Europe at the time of the Ice Age, and to have become re¬
stricted to their present habitats as the climate improved. Pro-

15

blems such as these were considered from a new angle as a result
of the researches of Clement Reid into the sub-fossil floras of
various ages before and during the Glacial period; and Reid’s
paper to the British Association in 1911, “The relations of the
present plant population of the British Isles to the Glacial
period ”, put forward the general thesis that the flora of Britain
was virtually completely exterminated during the Ice Age, and
that our present flora represents the results of re-immigration
from the Continent. Since that date a good deal of discussion,
which many would think to have been based on too little fact to
have been of great value, has gone on as to what proportion, if
any, of the British flora can be supposed to have survived the
various glaciations which are now distinguished within the Glacial
Period. The hypothesis of per-glacial survival on ice- free so-
called “ nunatak ” areas was introduced into this country by
Woodhead in 1929, and has been used by several workers to ex¬
plain the remarkable assemblages of species such as are found in
Upper Teesdale. It is onty very recently that, with the extremely
rapid and fruitful development of the methods of peat strati¬
graphy and pollen-analysis throughout N. Europe, we can
feel we have much more solid evidence by which to test hypo¬
theses of this type. This kind of evidence as to the constitution
of the British flora at more or less accurately defined dates since
the Glacial period will be presented by Dr. Blackburn in her
paper to-morrow. I should like however to put forward briefly
towards the end of this paper some of the revised and extended
interpretations of distributional phenomena which seem clearly
to arise out of this work.

In considering modern studies in Britain, those of Salisbury,
Matthews and Good should be mentioned — work with which I
am sure many of you will be familiar. In 1932 appeared Salis¬
bury’s East Anglian Flora, a most valuable analysis of the flora
of East Anglia from the point of view of the European distribu¬
tion of the component species; and this was followed by a very
full review of the whole subject of the “ Geographical Relation¬
ships of the British Flora ” in the Presidential Address given by
Matthews to the British Ecological Society in 1937. In this,
Matthews, acknowledging his debt to Salisbury’s work, classified
the British flora into 15 elements, and discussed each of these in
turn, giving a comprehensive species list for all types of distribu¬
tion except those of wide range (that is about half the British
flora). The contributions of Good have been in two directions,
which are well represented by his recent books; — one is a general
account of plant geography based on the w7hole world flora, whilst
the other is a most valuable detailed study of distribution of
plants within a single British county — namely, Dorset. In this
latter type of work, as in Salisbury’s studies, we see the modern
approach to problems of distribution which has gained much from
the development of plant ecology as a special division of Botany.
It is, however, more particularly with Good’s attempts to state

16

general principles of plant geography that I wish to concern my¬
self in a little more detail now; these principles, embodying the
so-called Theory of Tolerance, were set out by Good in 1931, and
there is an interesting discussion of a modified form of them in
the book by the American plant geographer, Cain, Foundations
of Plant Geography , published in 1944. Briefly, there seems to
be general agreement among plant geographers on the following
points :

1. That the climate, in its widest sense, is the primary factor
controlling the distribution of plants.

2. That soil factors are important, but in a subsidiary man¬
ner — i.e. within the general climatic limitation.

3. That great climatic and physiographic changes have oc¬
curred in the past, and have left their mark on the present-
day distribution of organisms.

4. (In a sense modifying the first three) That the relation be¬
tween environmental factors and plant distribution can
never be reduced to a simple cause-and-effect relation —
I mentioned this earlier when discussing the early work
showing correlations of distribution with meteorological
data — although of course the demonstration of such cor¬
relations can be of great interest and significance.

5. That every species has a definite tolerance which limits its
range and which has a genetic basis in a manner analogous
to the genetic basis of the morphological characters used
to define the species.

6. That the range of a species is subject to continuous varia¬
tion, which may in certain cases — e.g. the Lizard Orchid
in this country — be obvious, or may be so slow as to be
imperceptible by the normal direct methods. Three fac¬
tors are involved in this: firstly, the continuous changes
in the environment; secondly, “migration” of the species
in response to these changes, through new colonisation in
some areas and extinction in others ; and thirdly, the slow,
more fundamental genetic changes within the species.

These principles seem to be well supported by observation,
and offer together a reasonably satisfactory explanation of the
facts of plant distribution; though detailed experiment on the
tolerance of species is sadly lacking. I want to go on to discuss
a further principle which is rather more difficult to formulate,
and is in a sense included in the environmental factor, namely
that concerning the inter-relations of different species. We have
not so far mentioned the existence of more or less clearly defined
plant communities. In two ways, however, the ecologist’s study
of plant communities concerns us: firstly, because an entirely
proper study of distribution would be that of the plant com¬
munity as opposed to the single species; and secondly, because
it becomes increasingly obvious that the complex interrelations

17

between species which we recognise when we speak of competition
factors are of the greatest significance in the interpretation of
distributional phenomena. We must, I think, omit any further
consideration of plant sociology or the study of floristically-
defined plant communities, as this would take us into too wide
a field ; but I must enlarge a little on the interrelations of species,
and particularly the competition factor.

Salisbury, in The East Anglian Flora, draws attention to the
importance for many species of the “ open ” habitat where com¬
petition with other plants is slight or absent, suggesting, for
example, that a number of our common weeds appear to be native
plants of naturally open communities such as sand dunes, alluvial
washes, steep rocky slopes, etc. The studies of the Late Glacial
flora, a preliminary account of which has been published recently
by God wan in the Journal of Ecology and of which we are to hear
to-morrow, are abundantly confirming the view that a consider¬
able proportion of our flora, including many species exhibiting
marked discontinuities of range, is to be interpreted as having
been widespread in the Late Glacial, and suffered enormous re¬
striction of range through the spread, firstly of closed forest, and
then, especially in the west and north, of blanket peat. This view
reconciles opposing positions earlier taken up with regard to the
Teesdale and other locally rich areas — such floras are relict, not
by per-glacial survival, but by post-glacial survival in perman¬
ently open habitats. A great field of investigation is opened up
by this view. One curious feature which is satisfactorily ex¬
plained, I think, is the association of elements of different distri¬
bution types in these same areas — e.g. the Teesdale arctic-alpine
Juncus alpinus, the continental Viola rupestris, and the “ alpine ”
Gentiana verna, or the Irish (Co. Clare) Mediterranean Neotinea
intacta, with arctic-alpine Dry as octopetala and continental Viola
stagnina. To a surprising extent, indeed, species which would be
called without hesitation “ continental ” by a central European
or Scandinavian botanist — i.e. those which have their main area
of distribution in the steppe regions of E. Europe and Russia
and become more and more local and discontinuous in W. Europe
— are found to exhibit remarkably varied patterns of distribution
in the British Isles and many are by no means confined to East
Anglia, which climatically is our “ continental ” area. One of the
most striking examples is Astragalus danicus (cf. distribution
maps, figs. 2, 3 and 4); but there are others equally impres¬
sive — the familiar example of Potentilla fruticosa, which is so
obviously a steppe plant in Scandinavia and E. Europe that it
is difficult to persuade many Scandinavian botanists that it can
possibly be native in W. Ireland! — and rather less well-known
ones such as Aster Linosyris (a steppe species which, on the basis
of its British distribution only, wyould be called Atlantic by Wat¬
son), and Inula salicina, with a solitary locality in Ireland and
absent from Britain, yet a widespread steppe species with a strik¬
ing disjunct distribution in W. Europe. A group of continental

18

19

6LongitudeVfet 4 of Greenwich 2 0 Longitude East 2 of Grctomd* 10 8 6 Longitude Wfet 4 of Greenwich 2 0 Longitude East 2ofGreenwich

Fig. 2 Fig. 3.

Astragalus danicus Retz. Comparison of the two maps shows that the very
largely coastal distribution in the north is obscured by plotting by vice-counties

as in Fig. 3.

Fig. 4. Astragalus danicus Retz.— world distribution (partly after Meusel, H.,

Yergleicliende Arealkunde, K3e).

N.B.— Tlie N. American plant is A. goniatus Nutt., of which Fernald (Gray’s
Manual of Botany, Ed. X, 1950, p. 912) says “ Related to and perhaps refer¬
able to the Eurasian A. danicus Retz.”

species shows marked discontinuity in the British Isles between
south-eastern habitats (usually fen or dry chalk) and western ones ;
these include Teucrium Scordium, Viola stagnina, Liparis Loeselii.
In the case of Liparis there is varietal differentiation between the
eastern fen and the western dune slack populations; and this is
even more evident in the case of Veronica spicata. This
species, which is usually quoted as an example of the steppe
element in the East Anglian flora, is represented in scat¬
tered limestone cliff localities up the west coast of England
by the so-called V. hybrida. Salisbury and others have argued
that here is an example of a species pair, one eastern and contin¬
ental, the other western and oceanic. In fact, however, outside
Britain there is no evidence that “V. hybrida” is anything more
than an ecotype of the widespread variable Eurasiatic V. spicata
(Fig. 5), which in East Anglia is represented by a smaller eco¬
type of chalk grassland, more nearly resembling the commonest
European plant. A number of commoner British species show a
similar restriction to habitats of reduced competition, but have
apparently been able to take advantage of the extension of such
habitats through human activity. Such are many calcareous
grassland species, e.g. Filipendula hexapetala; some of these, to
judge from the range of habitats in which they occur, are almost
certainly ecotypically differentiated — e.g. Serratula tinctoria,
which occurs on dry chalk and limestone grassland, in fen, and in
open borders of woods. Good’s comments on this and other
species which show a rather wide range of types of habitat in
Dorset are very interesting.

Clearly the only factors common to all the habitats of these
continental species in Britain are the high base status of the soil
and the reduced competition factor: these are apparently the
conditions of much of the widespread Late Glacial flora, which
included a great mixture of elements of different origin — arctic-
alpine, steppe, S. European.

20

o

Fig-. 5. Veronica spicata L.— world distribution (Eurasiatic) (partly after Huber,

A., in Die Pflanzenareale , 2, 4, K34).

N .B— Veronica hybrida L. is included.

This interpretation assumes, as Forbes assumed, that recent
“ accidental ” long-range dispersal is not an important factor in
creating these marked discontinuities. Our knowledge of the
introduction and spread of many species within very recent years
should, however, make us a little cautious of ruling out the pos¬
sibility of long-range dispersal. It is clear that for a variety of
reasons a species cannot be occupying the whole of its theoretical
tolerance range; and the establishment of a chance seed intro¬
duction in an open habitat is likely to be very much easier than
in a closed one. To take one or two examples : there is consider¬
able suspicion that Arenaria gothica is a 19th century introduc¬
tion on Ingleborough, whether accidentally or deliberately; there
is reasonable doubt whether Veronica praecox could have been
missed in the Breck had it been there throughout the 19th
century ; whilst in the case of Scutellaria hastifolia, recently found
in a Breckland wood and apparently spreading very rapidly by
vegetative means, the evidence in favour of its very recent arrival
is very strong. The stability of many of the discontinuous popu¬
lations is certainly an argument in favour of a relict rather than
a recent status; and cultivation experiments to see how far such
plants are represented by specialised ecotypes, distinguishable
from other populations of the same species, wTould be extremely
useful. Of course there is no reason to suppose that any such
ecotypic differentiation has taken place since the isolation of the
relict; a much more likely hypothesis is that these formerly
widely-distributed species had already at the time of their wide
extension produced ecotypes, and that there has been selective
survival and elimination of these, until we are left with odd
remnants in scattered localities.

21

The acceptance of this hypothesis does not mean, of course,
that we can interpret all the cases of discontinuous distribution
in terms of post-glacial vegetation changes. The distribution of
such plants as Arenaria norvegica, and, more strikingly, the vari¬
ous species in the so-called N. American element of the Irish flora,
seem to require some type of per-glacial refuge theory. A recent
paper by J. Heslop Harrison (1947) is of considerable interest in
connexion with this problem.

I should like to conclude by suggesting ways in which useful
investigations might be made in the light of our present know¬
ledge. There is a tremendous field here for the keen naturalist,
much of which requires no special technique or apparatus.
Firstly, there is our lamentable ignorance of the autecology of
species — do they set good seed regularly in nature? what is the
life of the individual plant? etc. Any species, common or rare,
studied from this point of view would provide the kind of data
which we need to explain its distribution, particularly its small
scale distribution. Secondly, cultivation experiments on variable
species, and especially on these local populations, to find the
amount of ecotypic or subspecific differentiation, would be very
revealing. [Cf. pp. 82-90]. Thirdly, careful recording of the
spread of alien species (e.g. Senecio squalidus ) can yield much
valuable data on the relation of distribution to dispersal methods,
climate, soil and other factors. Fourthly, though I am aware
that this is not everyone’s taste, the study of critical groups and
the ranges of the segregates, many of which are as yet very far
from being fully worked out. In all these ways we can contribute
useful observations, and help to correct that tendency to specu¬
late on the significance of the facts of distribution with a mini¬
mum of factual basis.

References.

Cain, S., 1944, Foundations of Plant Geography. New York.

Forbes, E., 1846, Mem. Geol. Surv. U.K., 1, 336-432.

Godwin, H., 1949, The spreading of the British flora considered
in relation to conditions of the Late Glacial period,
J. Ecol.y 37, 1, 140-7.

Good, R., 1931, A theory of plant geography, New Phyt., 30, 149-
171.

- , 1947, The Geography of the Flowering Plants. London.

Harrison, J. Heslop, 1947, Recent Researches on Flora and
Fauna of the W. Isles of Scotland and their Bio-
geographical Significance, Proc. Belfast Nat. Hist.
& Phil. Soc., Ser. 2, 3, 2, 87-96.

Matthews, J., 1937, Geographical Relationships of the British
flora, J. Ecol., 35, 1, 1-90.

Meusel, H., 1943, V ergleichende Arealkunde. Berlin.

Salisbury, E., 1932, The East Anglian flora, Trans. Norf. Norw.
Nat. Soc., 13, 191-263.

22

Watson, H. C., 1832, Outline of the Geographical Distribution of
British plants. Edinburgh.

- , 1835, Remarks on the Geographical Distribution of British

plants. London.

- , 1847, Cybele Britannica, 1.

- , 1873-4, Topographical Botany, 1 & 2.

Woodhead, T., 1929, History of Vegetation of S. Pennines, J.
Ecol., 17, 1-34.

During the discussion on this paper Mr. Rose drew attention
to the absence of various widespread calcicoles from the chalk of
S.E. England and instanced Astragalus danicus. Mr. Walters
replied that this was also true of Anemone Pulsatilla, and Miss
Gibbons added that in Lincolnshire this species was not found on
chalk but only on (older) limestone.

THE W ATSON I AN ViCE-COUNTY SYSTEM

J. E. Dandy.

Introductory.

The Watsonian Vice-county System, for the recording of the
horizontal distribution of plants in Britain, may be said to date
from 1852 when Hewett Cottrell Watson, at the end of the third
volume of his Cybele Britannica, gave a list of 38 sub-provinces
and 112 vice-counties into which he proposed to divide the
country. This list was illustrated by a map. In the main body
of the Cybele he had not used the Vice-county System but had
analysed the distribution of the British flora on the basis of a
division into eighteen provinces and 82 counties. As he explained
in the fourth volume of the Cybele (1859), the object of the Vice-
county System was to provide a set of unit areas more even in
size than the counties, whose extreme inequality of size was
“ most inconvenient and objectionable ”. In this fourth volume
Watson elaborated the scheme and provided definitions of the
Vice-counties. (It may be mentioned here that Watson at first
usually restricted the term “ vice-counties ” to the portions of
divided counties, retaining the term “ county ” for the undivided
ones; but this inconvenient distinction has long since disap¬
peared.) The principle of his scheme was to divide the larger
counties into two or more vice-counties, and to merge the smallest
counties into larger neighbours. Thus Yorkshire was divided into
five; Argyll into four; Hampshire and Perth into three; and
numerous counties like Cornwall, Norfolk, Northumberland and
Sutherland were divided into two. Of the smallest counties, Rut¬
land was merged with Leicestershire, Kinross with Fife, Clack¬
mannan with Perth, and Naim with Inverness. The result was a.

23

system of 112 vice-counties, numbered consecutively from 1 (West
Cornwall) in the south-west to 112 (Zetland) in the extreme north.

The system was actually brought into use by Watson in the
closing chapters of the fourth volume of the Cybele, for example
in the “Summary of Distribution” and the “Census of Species”.
But it was in his classic Topographical Botany (1873-74) that
the system was first really used on a full scale. With the pub¬
lication of this work, and its later edition (1883) and supplements,
the Vice-county System secured general adoption by British
botanists. The forerunners of this Society, together with the
Botanical Record Club and the Watson Botanical Exchange Club
(both now defunct), early adopted the system and played a great
part in developing its use, which culminated in the production of
the Comital Flora in 1932 by the late George Claridge Druce while
Honorary Secretary of this Society. Some British zoologists, not¬
ably the conchologists, also adopted the system; and other
groups, including the ornithologists, have lately shown an in¬
terest in it.

In view of the increased interest in the system, and of the
fact that there were some discrepancies in the vice-county boun¬
daries as used by different workers and shown in different maps,
a joint committee was set up just before the recent war by this
Society and the Association for the Study of Systematics, to
examine the question of vice-county boundaries. The war unfor¬
tunately intervened when the committee had met only once. But
during the war investigations were carried out by the late Mr. A.
J. Wilmott and myself, and reached such an advanced stage that
when the war was over a sub-committee of the Systematics Asso¬
ciation was formed to complete the work. This sub-committee
has now made its decisions and practically completed its investi¬
gations, with the result that the Ray Society has undertaken to
publish a guide to the vice-counties illustrated with maps on the
scale of ten miles to one inch and incorporating the decisions of
the sub-committee. The guide is now in course of preparation.

Advantages of the Vice-county System.

By dividing Britain into unit areas of suitable size we can
conveniently record, or index, our information about the horizon¬
tal distribution of plants and animals within the country ; and we
are provided with a simple means of portraying the distribution
either by maps or formulae. The unit areas must, of necessity,
have arbitrary boundaries, as have the vice-counties, and the
question arises whether some other system, such as a system of
grid-squares, would better meet the requirements. This question
was anticipated, and in large measure answered, by Watson him¬
self, who in discussing his system in the Cybele (vol. iv, 129-130)
made the following remarks.

“ These old political divisions of Britain (i.e. the counties)
were found to be little suitable for the objects of phyto-geography.
As a first step downward, in subdividing the three ancient king-

24

doms of England, Wales, Scotland, they were found to be incon¬
veniently numerous. Their extreme inequality of size was also
most inconvenient and objectionable; the largest of them being
more than a hundred fold the size of the smallest. Other divisions
or sections of the surface were required instead, more equal in
their dimensions, and bearing some better relation to the physical
geography of the surface. By utterly disregarding the old comital
divisions, and tracing out an entirely independent series of dis¬
tricts, the required objects might have been met very completely.
But the advantages thereby gained would have been attended
with disadvantages so great as to become practically insuperable.
An entirely new set of boundary lines would have been necessary,
not in accordance with those laid down in existing maps; and
which would thus have necessitated new maps, on a large scale,
for tracing them out satisfactorily. Most of the local Floras and
other lists of species, with arrangements and specifications of
localities, have been made in reference to county limits; so that
a large portion of our printed records would have been rendered
much less available, by the adoption of other divisions which dis¬
regarded the old comital boundaries.

“ These and other considerations made a general adherence to
the long-established county limits practically unavoidable, when
fixing upon other sections to be used instead of the counties
themselves, or jointly with them. Larger and fewer districts
could be formed by uniting counties into provinces. Smaller and
more numerous sections could be formed by dividing the great
counties into vice-counties . . .

One of Watson’s points — about the necessity for an entirely
new set of boundary lines if counties were disregarded — has of
course now been met by the introduction of the grid; but even
so it must be remembered that only some of the most modern
maps bear the grid, whereas all maps of Britain show the county
boundaries and the other features, such as rivers and highroads,
used by Watson in delimiting his vice-counties.

Watson’s other point, about the relation of his system to the
counties, is of paramount importance. British botany and zoo¬
logy have traditionally been worked out to a very great extent
on a county basis, as is shown by the long array of county floras
and county lists, many of them prepared by county natural his¬
tory societies whose members take great pride in recording the
plants or animals of their native county. The Vice-county Sys¬
tem, with its county basis, links up admirably with this work and
its attendant literature.

Connected with this point there are two others in favour of
the Vice-county System as opposed to some purely arbitrary
system such as a grid. Firstly, county boundaries are commonly
discernible in the field, very often being related to some physical
feature such as a stream, a footpath or even a hedgerow ; whereas
grid lines, as we used to be told of the Equator, are imaginary
and cannot be seen in the field. Secondly, every Briton has some

25

idea of the counties and their arrangement on the map ; and those
who as botanists or zoologists are capable of remembering hun¬
dreds or thousands of generic and specific names should have
little difficulty in memorizing a sequence of 112 vice-counties.
Who, however, could be expected to memorize the positions and
references of grid-squares?

Finally there is another most important point in favour of the
Vice-county System. Whatever its merits or demerits, the fact is
that for nearly eighty years, ever since the publication of Topo¬
graphical Botany , British plants have been recorded on the Vice-
county System. A large proportion of the records, especially
those in Topographical Botany itself, cannot be translated into
any other system because precise localization within the vice¬
counties was not given. Unless we are to jettison these records,
the valuable results of so much painstaking work, the Vice-county
System must remain.

Difficulties of the Vice-county System.

It must not be supposed from the foregoing that there are no
difficulties attached to the use of the Vice-county System. There
are in fact two sources of difficulty: changing county boundaries
and lack of precision in some of Watson’s definitions.

Changes in County Boundaries. The county boundaries ac¬
cepted by Watson were of course those of his time; in fact, as
indicated in the Cybele (vol. 5, 139), his boundary lines were
adapted to the maps of England and Scotland in an atlas pub¬
lished in 1844 by the Society for the Diffusion of Useful Know¬
ledge. Copies of these maps are still available, so that we know
just what he meant. Watson, however, appears to have taken
no account of the fact that county boundaries are subject to
occasional modification, and certainly he did not visualize the
considerable changes which were to come about as the result of
the industrial revolution with its attendant increases and shift-
ings of human population. Before the end of last century Local
Government Acts made many boundary changes (among other
things the County of London and the first of the County Boroughs
were formed), and the process has steadily been going on especi¬
ally in the neighbourhood of expanding cities like Birmingham,
Bristol, Manchester and Sheffield which are situated near the
edge of their original counties and gradually absorb territory from
adjoining ones. It seems certain, too, that more and far-reaching
changes will be made in the not too distant future. Obviously
the Vice-county System cannot be worked on a basis of changing
boundaries. The system must have stability by means of fixed
boundaries, and if the great accumulation of records built up
under it by Watson and his successors is to have permanent value
these fixed boundaries must be the same as those used by him.
This was the first decision made by the Joint Committee which
met before the war, and it was endorsed by the Systematics Asso-

26

ciation Sub-committee set up after the war. Difficulties existed,
however, because the scale of the maps used by Watson was not
large enough for his county boundaries to be worked out in de¬
tail. During the war Mr. Wilmott, in order to overcome these
difficulties, consulted the Ordnance Survey who readily agreed to
help; the result was the preparation of a set of modern parish
diagram maps on which the Survey marked the changes since
Watson’s time so far as they could be ascertained. These maps,
which are deposited at the British Museum (Natural History),
have been compared with the maps used by Watson and found
to show close agreement. The Sub-committee has accordingly
agreed that this set of marked maps should be accepted as the
standard by which to interpret Watson’s county boundaries.

While on the subject of county boundaries it is important to
consider the question of enclaves, i.e. detached minor portions of
counties separated by land and surrounded by the territory of
other counties. To-day only five such enclaves remain, but in
Watson’s time they were very numerous and ranged in size from
large areas like the Dunbarton enclave to tiny plots of land too
small to be marked in detail on a half-inch map. Watson made
no general statement about enclaves, but it is clear from his oc¬
casional references to them in his text, and from his maps, that
he took the commonsense course of merging them all into the
territory of the counties surrounding them; for example, the
Worcestershire (Dudley) enclave is merged with Staffordshire.
Thus the only enclaves which presented any difficulty in inter¬
pretation were those which were sandwiched between two or more
counties, like the Dunbarton enclave which lies between Stirling
and Lanark. Fortunately it has been found possible, from a study
of Watson’s maps and other considerations, to decide the position
of all the “ sandwich ” enclaves. The Dunbarton enclave, for
example, is merged with Stirling, as Kidston and Stirling long ago
decided.

Unprecise Dividing Lines. Where Watson divided a county
to form two or more vice-counties he usually chose and stated a
dividing line which is not in doubt. These definite lines included
rivers (as in Lancashire, Yorkshire, Perth) ; canals (Wiltshire,
Yorkshire, Argyll) ; highroads (Cornwall, Hampshire, Sussex) ;
arms of the sea (Hampshire, Argyll, Inverness) ; watersheds (In¬
verness, Ross, Sutherland) ; administrative boundaries (York¬
shire Ridings); and a meridian of longitude (Suffolk, Norfolk).
All these lines are readily discernible on a map, and most of them
are obvious in the field. In some cases, however, Watson’s defini¬
tion of a dividing line is not precise enough for clarity, for example
in Devon, where he cites not the actual watershed over Dartmoor
but “ an imaginary line, adapted to the water-shed ” ; in Somer¬
set, where he describes a line simply as “ curving round ” from
Ilchester to the northern extremity of Dorset; and in Yorkshire,
where he divides the county by the rivers Humber, Ouse and

27

Wiske but omits to complete the line northwards to the Durham
border. The Sub-committee has decided each of these cases on
its merits. If an imprecise line (as in Devon and Northumber¬
land) has been satisfactorily defined in print by local workers
the definition has been accepted. If no such definition has been
published the Sub-committee has, where possible in consultation
with local workers, decided on a line. In conclusion, I may men¬
tion some particular cases where confusion has arisen in the past.

The Great Ormes Head is in Caernarvonshire and was so in
Watson’s time; yet his vice-county maps in the Cybele Britannica
and in Topographical Botany show it as in v.-c. 50 (Denbigh).
This was an accident due to a misprint in the map published by
the Society for the Diffusion of Useful Knowledge (the basis of
his own maps), which correctly showed a dotted boundary across
the Great Ormes peninsula but failed to mark it in red like the
rest of the county boundaries. The Great Ormes Head is in
v.-c. 49 (Caernarvon), as made clear in Topographical Botany
under Cotoneaster.

Watson divided v.-c. 88 (Mid Perth) from v.-c. 87 (West
Perth) by the watershed dividing the tributaries of the Tay from
those of the Forth ; but he failed to mention the small area in the
south-west of the county drained by tributaries of the Clyde.
Druce’s map in the Comital Flora places this area in Mid Perth,
but it is clear from Watson’s maps that its correct place is in
West Perth.

The line dividing Cornwall was defined by Watson as traced
along the highroad from Truro through St. Columb to the inland
extremity of Padstow Creek. But there are two highroads from
Truro to St. Columb, one through St. Erme, the other through
Ladock. Watson’s maps suggest the former, but Davey’s Flora
of Cornwall takes the latter. The question is settled by reference
to the map published by the Society for the Diffusion of Useful
Knowledge, which shows only the western (St. Erme) road. This
is therefore the line to be accepted.

This was discussed by Miss Longfield, Mr. Brenan, Mr. Nelmes,
Mr. Rose and Mr. Whitehead.

Mr. Nelmes stated that a recent work had treated part of
Somerset round Brislington and south of the Avon as belonging
to Gloucestershire and he enquired whether this area should be
regarded as part of v.-c. 6 or v.-c. 34 following Mr. Dandy’s re¬
searches.

Mr. Dandy replied that the boundary between v.-c. 6 and
v.-c. 34 should be as shown in the map accompanying the recently
published Flora of Gloucestershire. A small area of the city of
Bristol, south of the Avon and of Floating Harbour, is to be in¬
cluded in v.-c. 34. The larger area referred to by Mr Nelmes,
which includes Brislington and has been added to Bristol in re¬
cent times, is to be treated as part of v.-c. 6, i.e. North Somerset.

28

Miss Longfield asked how boundaries were traced where
they ran out to sea and hence how islands were allocated to the
appropriate vice-counties.

Mr. Dandy answered that administrative boundaries rarely
run out to sea, but where they do so they are followed. In gen¬
eral, islands are allocated to the counties to which they belong for
administrative purposes (e.g. Steep Holme to Somerset and Skok-
holm to Pembroke) ; but in some cases, as in the Hebrides, islands
are specially grouped by Watson and he is of course to be fol¬
lowed. Such insular vice-counties are not separated by definite
boundaries like the .county boundaries on land, but are separated
by imaginary lines following, say, the middle of a main channel.

Mr. Rose enquired how the line of longitude one degree east
employed by Watson as the boundary between East and West
Suffolk (v.-cc. 25 and 26) and between East and West Norfolk
(v.-cc. 27 and 28) could be fixed on one-inch and other maps used
by botanists in the field.

Mr. Dandy replied that this is one of the least satisfactory
boundaries chosen by Watson and serves to show the difficulties
that would arise if a system entirely based on such lines (e.g. a
grid system) were adopted in place of the Vice-county System.
Botanists working in Norfolk and Suffolk should, if near the line
of longitude one degree east, use extra care in localizing and, if
in any doubt about the vice-county, consult maps on a bigger
scale such as the six-inch.

Mr. Whitehead suggested that much of the difficulty in using
a grid for plotting distribution depended on the choice of scales
of maps used for work in the field.

Mr. Brenan asked whether there would be inset maps on
larger scales included in the Ray Society publication and pointed
out that these would be extremely useful in certain areas which
included special difficulties.

Mr. Dandy replied that this depended on limitations imposed
by the selection of a convenient size for the book. If it proved
impossible to include such inset maps the description of detailed
boundaries would be expanded in the text.

Finally Mr. Dandy expressed his willingness to help with pro¬
blems arising over the interpretation of vice-county boundaries
and reminded members that this is one of the subjects covered
by the Society’s Panel of Specialists.

29

MAPS OF THE W ATSON I AN VICE-COUNTIES

(Exhibit)

J. E. Dandy.

The following were exhibited throughout the Conference to
illustrate the above paper:

(1) H. C. Watson. Cybele Britannica. Vol. 3. 1852.

(2) Atlas issued by the Society for the Diffusion of Useful
Knowledge in 1844.

(3) Two manuscript maps prepared for *the projected Ray
Society publication.

(4) Map of the Biological Subdivisions of Ireland, Ed. 2, on
the scale of 50 miles to the inch showing the Hibernian
vice-counties and recently published by the Ordnance
Survey Office, Dublin.

(5) One of the maps prepared by the Ordnance Survey to
show changes in boundaries since Watson’s time and de¬
posited at the British Museum (Natural History). The
map exhibited showed Worcestershire with modern
boundaries shown by red lines and the boundaries in
Watson’s day where different by green.

THE WATSONIAN VICE-COUNTY SYSTEM IN PRACTICE

J. E. Lousley.

The state of British geographical botany when Watson first
became interested was, as he pointed out (1847, p. 20), chaos
rather than science. The best handbook was Turner and Dill-
wyn’s Botanist's Guide, which was little more than a guide-book
for collectors arranged in alphabetical sequence of counties.
“ Arrangement is the first effort of science,” and Watson soon
found the need for a framework, or grid, for the purpose of mar¬
shalling and arranging the available records. In his first work
(1832) he divided England and Wales into four districts and Scot¬
land into two. In 1843 he divided England and Wales into 12
districts and Scotland into 6. In 1847 and onwards he re-named
these as 18 Provinces, and divided them into 38 Sub-provinces
and eventually into 112 vice-counties. It was not until the first
edition of Topographical Botany in 1873-74 that he recorded the
actual distribution of species under these vice-counties, wilich he
introduced into his studies incidentally, and for the purpose of
arranging the detailed records supporting his more generalised
statements. Watson thus found a need for smaller and smaller
units for his framework — first Districts, then Provinces, then Sub¬
provinces, and finally Vice-counties (Fig. 6).

30

ASCENDING 10 WE S.

1 . fl III lftd..S>ip«r JtfrtMa

rv v y\ ini*#. »*..

•» Sy M r MfcLaAi to ilh**lr#<» taa E«Uuuc«i Works ,1*5?

MOUCCD BV THE t LCCTRO MINTING BLOCH C1(Amn—) FROM THE OB 'CINAL MAP IN THCCYBCLE BRlTPNNlCA

Fig. ().

H. C. Watson’s map, showing his 18 provinces, 38 sub-provinces, and 112 vice¬
counties, as reproduced in Topographical Botany, Edition 1, and reduced from

the original map in Cybele Britannlca.

31

He died in 1881, and at the request of Bernard Quaritch, the
publisher, a second edition of Topographical Botany was hurriedly
prepared by J. G. Baker and W. W. Newbould and published in
1883. This was based on Watson’s interleaved copy of the first
edition, and has served as the basis for our records ever since.
The work was continued in the quinquennial summaries of the
Botanical Record Club, and in the supplements to Topographical
Botany issued by Arthur Bennett in 1905, and by Bennett, Sal¬
mon and Matthews in 1929-30.

Watson’s work did not include Ireland. Records of flowering
plants and ferns in that island were first arranged under Dis¬
tricts corresponding to and continuing Watson’s 18 Provinces
(Moore & More, 1866), and later under County-divisions corre¬
sponding to Watson’s vice-counties. The records as given in
Praeger’s Irish Topographical Botany (1901) and supplements
(1906, 1929, 1934a, 1939) arranged under these County-divisions
are the basis of our present knowledge of the distribution of the
Irish flora. It should be added that there have been several
minor alternative schemes (see Praeger, 1934b, p. 77) and that
Dr. Praeger has this year (1950) handed over the responsibility
for future supplements to Professor D. A. Webb.

The records, both for Britain and Ireland, were summarised
by Druce in his Comital Flora of the British Isles, which was pub¬
lished for our Society in 1932. For quick reference, when a general
idea of the British distribution of a species is required, this work is
extremely useful. It is the one on which are based indications of
New County Records in the Plant Records section of Wat sonia,
and the Society has a heavily corrected official copy kept up to
date for this purpose. I have also an annotated copy of my own
which was first corrected from the late P. M. Hall’s copy (which
became the official one) and has since been altered independently.
It must, however, always be remembered that the printed text of
Comital Flora gives no authorities for the records it includes and,
to this extent, it is not part of the system of scientific recording of
plant distribution in Great Britain. It is essential that summaries
of vice-county records should be based on references which can be
followed up and checked, and it is desirable that further supple¬
ments to Topographical Botany and Irish Topographical Botany
should precede a fresh edition of Comital Flora. In practice it
has proved impossible to discover the source of some of the en¬
tries in Dr Druce’s work and in such cases they cannot be ac¬
cepted until proper evidence is forthcoming.

For Ireland there is a summary on rather similar lines in the
Census List towards the end of Dr. Praeger’s The Botanist in Ire¬
land (1934b), but in this case supporting evidence for entries can
be found in his other works already mentioned. A useful sum¬
mary of records for the Principality appears in Hyde and Wade’s
Welsh Flowering Plants (1934) where many of the supporting
records are cited and the evidence for others can be obtained by
writing to the National Museum of Wales.

32

The Accuracy of the Records.

The value of the results obtained from any system of record¬
ing plant distribution is obviously dependent on the accuracy of
the facts on which it is based. Both Watson and Praeger were
very well aware of this, and showed careful discrimination in the
records they accepted.

Watson’s standards were explained at great length in the
second edition of Topographical Botany, and may be summarised
as giving priority to personal evidence of which he rated his own
observations highest of all. For our purpose the records he gives
fall under the following five headings: —

1. Herbarium material. This included specimens in his own
collection which is now at the Royal Botanic Gardens, Kew, and
in addition gatherings which had at various times passed through
his hands. Most of this material is still available for examination.

2. Local catalogues marked by his correspondents. Many
of these may still be seen at Kew and usually consist of copies of
the London Catalogue of British Plants of various editions in
which the species supposed to have been seen are marked. It is
notoriously easy for even the best botanists to make errors in
work of this kind, and without independent confirmation such
records are of little value.

3. Personal observations by Watson. In spite of the very
high standard of accuracy which he set himself, it is on record
( loc . cit., p. 587) that he knew that some of these were errors as
printed, and in addition corrections will have become necessary
owing to advancing knowledge since his time. Confirmation is
desirable.

4. Manuscript notes sent by correspondents. To these the
same objections apply with additional risk of error.

5. Published literature. Watson professed that he placed
little reliance on printed records but nevertheless he included a
very large number of records without authority, which indicates
that he accepted published records for the counties concerned.
Unfortunately he refused to include the appropriate references
owing to foolish and short-sighted contemporary insistence on
book references being given in extenso — which for practical rea¬
sons was impossible. It is still possible to trace most of the book
references he had in mind, and in many cases they supply further
evidence which can be followed up.

The supplements to Topographical Botany give authorities,
or references, for all the records included. These provide a simi¬
lar assortment of evidence of varying value but lack the advan¬
tage of having been subject to the refining influence of Watson’s
ruthless pruning.

Praeger ’s work appeared nearly 30 years later and attained a
much higher standard than Watson’s. For most county-divisions
he gives more than one authority; often he paired a personal or

33

manuscript record with a printed one. Dates were added and
also statements of frequency. I should like to take this oppor¬
tunity of expressing my admiration of this fine book which the
veteran Irish botanist completed nearly half a century ago.

The imperfections which exist in our accounts of vice-comital
distribution based on the sources just given may be summarised
as follows: —

a. Errors in identification. Some of these determinations
were wrong at the time they were made, as in the case of Cheno-
podium urbicum L., for which variations of C. rubrum L. have
often done duty. Similarly Rumex maritimus L. and R. palustris
Sm. have been frequently confused. Other determinations have
been correct, as far as they went, at the time they were made, but
have become inaccurate or misleading owing to advances in the
knowledge of taxonomy or nomenclature — or both. For example,
it would now be almost impossible to disentangle all the records of
Orchis latifolia L. which has been used in wide and also restricted
senses and for different plants. Investigations such as those by
Walters (1949) on Aphanes, and by Howard and Manton (1946)
on Nasturtium , which substitute twro species for one in the British
list, necessitate re-examination of all the records of the plant re¬
placed. Such cases emphasise that an ideal system of recording
would be based on herbarium material, properly cited, and always
available. It would be a practical proposition to indicate with ap¬
propriate signs the vice-counties for which supporting specimens
could be seen at say the Natural History Museum, Kew, Edin¬
burgh, Oxford, Cambridge, Dublin and Cardiff and thus account
for the majority of the records. In Denmark, localities vouched
for by specimens in the Botanical Museum of Copenhagen are in¬
dicated with a special sign on their distribution maps.

b. Errors in status. A very large proportion of our plant
records include no assessment of the status of the species at the
locality concerned. In the case of plants which are regarded as
native anywhere in the British Isles it is too commonly assumed
that additional stations must also be native, and the results are
extremely misleading. A good example is Iberis amara L. This
may well be native in chalk districts in central England, and
particularly in the Chilterns, where it is found in fields and woods
and on chalky banks with a continuous distribution over a limited
area. In other parts of Britain it is found under varying condi¬
tions which often give clear indication that it is adventive. Some¬
times the garden plant, Iberis umbellata L., is likely to be the
species actually found. Nevertheless, in at least one instance, all
this hotch-potch of records has been used for the preparation of
a map purporting to show the distribution of the species in
Britain, and totally obscuring the true position.

Similar errors arise in the case of far more species than is
generally supposed. For example, Rumex Hydrolapathum Huds.

34

and R. maritimus L. are probably, or even certainly, introduced
in some of the vice-counties for which they are claimed. Clematis
V it alba L. is a plant for which it is not at all easy to work out the
exact distribution towards the margin of its area in the north.
It is likely that many undisputed natives get carried by accident
or design by human agency to places where they do not naturally
grow. Assessment of status is a difficult exercise in judgment
for which long experience is desirable, but if recorders would
make a regular practice of noting their impressions we should
eventually amass data which might lead, in the case of some
species, to surprising conclusions.

c. Lack of veracity on the part of recorders. This, fortun¬
ately, is responsible for only a very small fraction of the mislead¬
ing records but some of these are of exceptional importance.
When such falsehoods are detected or suspected it still remains
necessary to repeat them in each new publication with reasons
why they should not be accepted. The detection of a single deli¬
berate mis-statement in a botanist’s work very properly throws
doubt on all his other publications, and it cannot be over¬
emphasised that the few people who have behaved in this way
are not only a nuisance to science, but also their own worst
enemies.

d. Incorrect assignment to vice-counties. Difficulty in this
connection arises in two ways. First, there is the fact that some
records are not localised with sufficient accuracy for it to be pos¬
sible to ascertain with certainty the vice-county to which they
should be assigned. Second, there has been much difficulty in
the past in determining the precise boundaries of Watson’s vice-
counties. The book which Mr. Dandy has in preparation for the
Ray Society will make it very much easier in the future to allocate
records correctly, and doubtful cases already published should
be re-examined.

e. Neglect of the time factor. The inclusion of this as a
source of imperfection in our records may perhaps be a little con¬
troversial and may be illustrated by a straight-forward example.
Diotis maritima Cass, has been recorded from 11 English, 2 Welsh,
and 2 Irish vice-counties and also from Jersey, and at present it
is only certainly to be seen in Ireland. Yet these records (two
of which may be errors) were collected over a period of some 350
years and it is unlikely that it was ever possible to see the plant
in more than three or four vice-counties at any one time. It may
well be a case of a Mediterranean species making repeated at¬
tempts to establish itself at the northern limit of its range and
each fresh colony may have only a limited life until destroyed by
extreme climatic conditions which only occur at intervals. How¬
ever that may be, it is extremely misleading to telescope all tiie
recorded occurrences without differentiation into one map. The
time of the records should be indicated as well as their distribu¬
tion.

35

The importance of time is obvious in the case of aliens — the
spread of Senecio squalidus L., Cardaria Draba (L.) Desv., and
Veronica persica Poir., are well-known examples where it must
be indicated on maps showing the extension of their range. But
it is to supposed native rather than alien species that I wish to
draw attention in this connection.

It is not unlikely that there is an ebb and flow in numbers
and area of many of our native plants. There is evidence of this
in the case of Himantoglossum hircinum (L.) Spreng. (Good,
1936) which on account of certainty of identification, rarity, and
public interest, offers exceptionally good opportunities for studies
of this kind. More detailed studies are likely to reveal that the
distributions of many native species are less static than is often
supposed.

f. Failure to incorporate records in the general works. Both
Watson and Praeger cast their nets widely and overlooked sur¬
prisingly few records but the compilers of the supplements to
Topographical Botany were less thorough in their work. Many
records scattered through the literature of the last half-century
or so have still to be incorporated although we have made an at¬
tempt in this Society in recent years to include those noticed in
Plant Records, or in special papers listing additions to be made
from particular local floras.

The total number of errors and imperfections arising from
these six sources is large — perhaps very large — but I should like
to make it clear that they affect only a small percentage of the
enormous number of county records which have been accumu¬
lated. Their incidence is heavy only in the case of certain species,
and our published studies are in general sufficiently accurate to
give a reasonably true picture of the distribution of most of the
plants concerned. In spite of its shortcomings in detail, the work
done in Britain must be regarded as a very creditable perform¬
ance by comparison with most of that done abroad.

Having considered the reliability of the facts (i.e. the records)
it is necessary to discuss the framework by which they are
arranged.

The Framework of Vice-counties.

Systems for the arrangement of plant records fall broadly into
two classes — irregular frameworks based on political boundaries
and arbitrary and regular grids.

The Watsonian system is an example of the first-named class,
for Watson accepted political county boundaries as laid down at
the time and introduced certain subdivisions in order to obtain
vice-counties of very approximately equal area (average 850
square miles). The main disadvantage of the system in practice
is that considerable research has proved necessary to determine
the precise political boundaries he had in mind and these are no
longer those used on the maps in the hands of recorders. Also

36

the vice-counties vary in size too much for accurate comparison
on a statistical basis.

On the other hand the system has great practical advantages.
Political boundaries are those selected for most works on floris-
tics, and this is particularly true in Britain where most local
floras are on a county basis. Even with the changed boundaries
to-day there is not the slightest difficulty in allocating the great
majority of the records. Once the average educated user knows
that Surrey is v.-c. 17, he can allocate nearly all the appropriate
records to v.-c. 17 without difficulty, and often without reference
to maps and books. Similarly it has been customary in neigh¬
bouring countries to base most botanical work on political boun¬
daries and their publications can usually be correlated easily with
our own. An example is Good’s comparison of the floras of Kent
and the Pas de Calais (1928).

The alternative is a grid by which horizontal and vertical
parallel lines on the map produce arbitrary squares. The best
examples are the kilometre grids used in Holland and Belgium.
In this country we could adopt the 5 kilometre grid marked on
our One-inch Ordnance Survey maps, much as has been done in
the German system on exhibition. The great advantage of such
an arrangement is that all squares are of exactly the same size
and they can all be compared statistically. Moreover, it is possible
to make indefinite subdivisions of each square and equally to
collate the system to larger squares. Thus the varying demands
of the ecologist, who often works on a metre square, and the world
plant geographer, who is likely to require say 100-kilometre
squares, can be served. There is no doubt that this is a much
more scientific method. Nevertheless, the grid-system suffers
from the great practical disadvantage that much labour and care
must be expended on assignment of records to the correct squares,
and the results can only be read back by reference to maps. It
does not lend itself to setting out distribution in simple formulas
like those in Comital Flora.

Single Records for Each Vice-county.

Watson, as a pioneer, accepted a single record for each vice¬
county. Provided the record was accepted as reliable his system
called for no further attention to that particular vice-county and,
incidentally, led to keen competition among amateur botanists
for “N.C.R.’s” (New County Records). While the study of distri¬
bution in Britain was in its infancy this was adequate, but it is
insufficient for modern research.

Distribution maps showing whole counties blacked-in or
shaded from the lists in Topographical Botany and its supple¬
ments or, worse still, from Comital Flora, are reproduced even
to-day. If intended to show general distribution in relation to
that elsewhere, and if the scale used is not larger than about
1 : 15,000,000 (i.e. John o’ Groats to Land’s End about 2\ inches)

37

they are not seriously misleading. On larger scales they cannot
be condemned too strongly. Such maps fail to show: —

A. Dependence on special habitats. The most obvious ex¬
ample of this is to be seen in maritime plants. Many of these are
restricted to the coast and it is absurd to show them as growing
far from the sea in counties which include large inland areas as
well as a stretch of coast. To do so obscures the very special con¬
ditions which some require (e.g. Obione pedunculata (L.) Moq.
and Eleocharis parvula (Roem. & Schult.) Link), and also
the fact that some also grow inland (e.g. Glaucium flavum Crantz,
Spergularia salina J. & C. Presl, Spartina Townsendii H. & J.
Groves, Puccinellia distans (L.) Pari.) under very different con¬
ditions.

Similarly plants growing by or in rivers or estuaries ( Scirpus
triqueter L. — see maps, p. 44), or ponds (e.g. Cyperus fuscus L.),
or restricted to high altitudes (e.g. Luzula arcuata (Wahlenb.)
Wahlenb., Lactuca alpina (L.) Hook, f.) or to bogs (e.g. Erio-
phorum gracile Roth) should certainly not be shown over areas
which include habitats where they would be unlikely to occur.
Much the same applies to species confined to certain soil types
like Anemone Pulsatilla L. and Cirsium tuberosum (L.) All. which
are restricted to calcareous soils.

Much greater detail than is provided by marking in whole
vice-counties on the basis of single records is required to show
the relationship of species to topography, soil and other factors.

B. Frequency. For the study of plant distribution it is
almost as important to be able to compare frequencies as it is to
have a record of the mere fact that species occur in certain areas.
When the southern botanist goes north he is likely to be im¬
pressed by the much rarer occurrences, as well as absences, of
some of the species he regards as common at home, and conversely
by the abundance of plants he seldom sees in the south. As an
example of this I am exhibiting a map of the distribution of
Antennaria dioica (L.) Gaertn. which is plentiful in many northern
counties, but only found in some of the southern ones in tiny
patches of uncertain appearance. To mark in all vice-counties
in which it has been found without differentiation fails to give a
true picture of the distribution.

There are similar contrasts in frequency within the range of
very many British plants. Watson’s system made no provision
for its study. Praeger in his Irish Topographical Botany gave
brief and most useful statements on frequency for many of his
county-divisions.

The Dot Method.

It is evident that the Watsonian Vice-county System in its
essential form does not provide sufficient detail and that maps
should show actual occurrences. The signs used for the latter I
will refer to as “ dots ” for want of a better term, although in

38

practice they may take many forms other than simple specks on
the map. Whatever form they take, frequency is automatically
indicated. Where they coalesce or are very close together the
area may be shaded to show continuous distribution.

Such a system can be grafted on to the Watsonian plan. We
already have a very large number of local floras covering one or
more vice-counties which will provide information about detailed
localities. They also include notes on status and other matters.
The localities they provide can be plotted without difficulty on
outline maps showing the vice-counties on which the irregular
boundary lines serve to pin-point almost any localities. In prac¬
tice the chances of error are less than those likely in plotting on
a mechanical grid.

Some of the maps issued in the Biological Flora have been
based on information collected in this way to show plants re¬
stricted to the coast or by different shading of the vice-counties
to indicate the dates of the first records, or changes in frequency
(cf. maps on pp. 85 and 116). They are a great improvement on
maps shaded in without differentiation but would gain in accur¬
acy in some cases by the plotting of actual localities.

It should be noted that “ dots ” have the advantage that they
can be varied to give much information in addition to frequency.
Such important facts as dates of occurrence, the whereabouts of
herbarium material and supposed extinctions can be shown with¬
out difficulty. In this connection the Danish scheme in which
“ dots ” of various kinds are skilfully combined with shading, is
worth very careful examination.

SUB-DI VISION OF V ICE-COUNTIES .

In spite of the ease with which localities can be plotted in the
present vice-county outlines, there is still need for smaller divi¬
sions in some connexions. One such need arises in the compila¬
tion of county floras and the difficulties which Dr. Dony will
describe in his paper are representative. They arise chiefly from
the fact that vice-county boundaries are political rather than
botanical. Even the boundaries invented by Watson, such as the
lines dividing v.-cc. 25 and 26 and v.-cc. 27 and 28, are arbitrary
and form no natural areas. In these circumstances it is not sur¬
prising that writers of the floras of the larger counties are some¬
times tempted to carry their divisions across the vice-county lines.
This practice makes it difficult for their publications to be used
to check the distribution for Britain as a whole, and I would
thoroughly endorse the late Mr. Wilmott’s protest against it. In
his paper (1944) he shows clearly how a more satisfactory sub¬
division of the particular Scottish vice-counties concerned could
be made.

This question of the sub-division of vice-counties arises when¬
ever it is necessary to create smaller areas for individual workers.
The high standard to which Watson in his lifetime raised our
recording on the “ single record for a vice-county ” arrangement

39

shows how much can be achieved by having people interested in
particular areas. Now that further detail is required we might
follow the example of the Danes and sub-divide our political areas,
though our parishes are less suitable (Lousley, 1942) for the pur¬
pose than their Herreder. But some sort of sub-division is essen¬
tial for the organisation of any investigation of the flora calculated
to ensure that all parts of the country eventually receive examin¬
ation on a more or less uniform standard. One of the advantages
of the grid as used in Holland and Belgium is that an attempt
can be made to list all the plants of any given square kilometre
and maps can be prepared showing which squares still require
attention. The Watsonian system has not only failed to provide
sufficient detail but in late years it has also suffered from hap¬
hazard attention to some of its divisions and neglect of others.
The efforts of our field workers could be more effective if proper
organisation were provided.

Conclusion.

In the early part of this paper I reviewed the compilation of
records under the “ single record ” system inaugurated by Watson
and indicated sources of inaccuracy in those records. I then
tried to show that the standards of Watson’s time are inadequate
for modern purposes and that botanists are already obliged to
supplement the records accumulated by the strict Watsonian sys¬
tem by more detailed information from local floras. Some of my
comments have been controversial, and I should like to conclude
by suggesting some possible developments as headings for dis¬
cussion.

First I would suggest that we should set up a permanent com¬
mittee charged with the organisation, revision and extension of
the work of collecting records. In this we should follow the
example already set in Denmark, Holland and Belgium. The
committee should seek reasonable publicity and collaboration
from local botanists.

They should undertake a revision of the existing records to
produce a new Topographical Botany in which the whereabouts
of herbarium material supporting vice-county records should be
indicated wherever possible. They should appoint local obser¬
vers in each vice-county — our own Society’s local Recorders
might be the basis of this list — and charge them with the ener¬
getic revision of records. As a further step the sub-division of
vice-counties into smaller areas might be considered. As an in¬
terim measure the divisions already in use in many county floras
might be added to the vice-county numbers as a suffix separated
by an oblique line. Thus v.-c. 4/1, North Devon: Barnstaple;
v.-c. 4/2, North Devon: Okehampton, etc. Even in the counties
where such divisions are available they sometimes include parts
of more than one vice-county (e.g. Flora of Gloucestershire ), and
are of very unequal size. A better and uniform method might
be devised with the co-operation of local botanists.

40

The procedure by which our method of keeping records might
be improved is a matter for discussion but there can hardly be
doubt about the necessity for greater energy and enthusiasm than
has been apparent in the last few decades. I hope that this will
be one of the results of the present Conference.

References.

Baker, J. G., 1883, On the Present State of our Knowledge of the
Geography of British Plants, Naturalist for 1883.
Bennett, Arthur, 1905, Supplement to Topographical Botany,
Ed. 2, J. Bot., 43, Suppl. (and issued separately,
1906).

Bennett, A., Salmon, C. E., & Matthews, J. R., 1929-30, Second
Supplement to Watson’s Topographical Botany,
J. Bot., 67, 68, Suppl. (and issued separately, 1930).

Botanical Record Club (otherwise the Botanical Locality
Record Club), Reports, 1873-1886.

Druce, G. C., 1932, The Comital Flora of the British Isles. Ar¬
broath.

Good, R. d’O., 1928, Notes on a Comparison of the Angiosperm
Floras of Kent and the Pas de Calais, J. Bot., 66,
253-264.

- , 1936, On the Distribution of the Lizard Orchid (Himan-

toglossum hircinum Koch), New Phyt., 35, 142-170.

Howard, H. W., & Lyon, A. G., 1950, The Identification and Dis¬
tribution of the British Watercress Species, Wat-
sonia, 1, 228-233.

Howard, H. W., & Manton, I., 1946, Autopolyploid and Allo¬
polyploid Watercress with the description of a new
species, Ann. Bot., N.S. 10, 1-13.

Hyde, H. A., & Wade, A. E., 1934, Welsh Flowering Plants. Car¬
diff.

Lousley, J. E., 1942, Flora of Devon (Review), B.E.C. 1939-40
Rep., 385-390.

Moore, D., & More, A. G., 1866, Contributions towards a Cybele
Hibernica. London.

More, A. G., Colgan, N., & Scully, R. W., 1898, Contributions
towards a Cybele Hibernica, Ed. 2. Dublin.
Ostenfeld, C. H., 1931, The Distribution within Denmark of the
Higher Plants . . . ., Kgl. Danske Vidensk. Selsk.
Skrift., Ser. 9, 3, 1-15.

Praeger, R. L., 1901, Irish Topographical Botany. Dublin.

- , 1906, Supplement to I.T.B., 1901-1905, Proc. Roy. Irish

Acad., 26 B, 13-45.

- , 1929, (Second) Supplement to I.T.B., 1906-1928, Proc.

Roy. Irish Acad., 39 B, 57-78.

- , 1934a, Third Supplement to I.T.B., 1929-1934, Proc. Roy.

Irish Acad., 42 B, 5, 55-86.

41

- , 1934b, The Botanist in Ireland. Dublin.

- , 1939, A Further Contribution to the Flora of Ireland,

Proc. Roy. Irish Acad., 45 B, 10, 231-254.

- , 1946, Additions to the Knowledge of the Irish Flora,

1939-1945, Proc. Roy. Irish Acad., 51 B, 3, 27-51.

Turner, D., & Dillwyn, L. W., 1805, The Botanist's Guide . . . .
London.

Walters, S. M., 1949, Aphanes microcarpa (Boiss. & Reut.)
Rothm. in Britain, Watsonia, 1, 163-169.

Watson, H. C., 1832, Outlines of the Geographical Distribution of
British Plants. Edinburgh.

- , 1835a, Remarks on the Geographical Distribution of British

Plants. London.

- , 1835b, The New Botanist's Guide . . . ., Vol. 1. London.

- , 1837, The New Botanist's Guide . . . ., Vol. 2. London.

- , 1843, The Geographical Distribution of British Plants,

Vol. 1 (all published). London.

- , 1847-1859, Cybele Britannica or British Plants and their

Geographical Relations, Vol. 1 (1847), Vol. 2 (1849),
Vol. 3 (1852), Vol. 4 (1859). London.

- , 1860, Supplement to the Cybele Britannica. London.

- , 1870, Compendium of the Cybele Britannica. London.

(Parts published privately in 1868, 1869 and 1870
and reissued.)

- , 1872, Supplement to the Compendium of Cybele Britan¬
nica .... Thames Ditton (published privately).

- , 1873, Topographical Botany, Part 1. Thames Ditton

(privately printed).

- , 1874, Topographical Botany, Part 2. Thames Ditton

( privately printed ) .

- , 1883, (Edited Baker, J. G., & Newbould, W. W.), Topo¬
graphical Botany, Ed. 2. London.

Wilmott, A. J., 1944, Vice-counties, B.E.C. 1941-42 Rep., 524-526.

There was no discussion on this paper.

42

MAPS SHOWING PLANT DISTRIBUTION IN BRITAIN AND

EUROPEAN COUNTRIES
(Exhibit)

J. E. Lousley.

This exhibit was arranged to illustrate the preceding paper
by demonstrating maps, prepared to show distribution in the
British Isles, which were misleading in various respects, and maps
illustrating various schemes initiated in other European countries
with commendable features.

(1) British Isles.

(a) Scirpus triqueter L. A map was exhibited on which the
distribution had been marked strictly according to
Comital Flora as published, and another for comparison
marked with “ dots ” showing individual localities on a
modification of the Danish scheme (see below). The
first map was faulty in showing: — (a) A species re¬
stricted to estaurine mud as occurring over whole vice¬
counties. (b) A vice-county marked for which it has
since been shown that the record was an error and two
other vice-counties marked as doubtful for which the re¬
cords are now discredited, (c) No distinction between
extant stations and those where the plant is believed to
be extinct. The second map was based on herbarium
material but is subject to the criticism that the “ dots ”
cover much larger areas than the species occupies.
(See Figs. 7 and 8.)

(b) Antennaria dioica (L.) Gaertn. A map with the whole
of each vice-county from which the plant is recorded
blacked in. This failed to show the great contrast in
frequency between southern vice-counties where the
species is extremely rare and certain northern vice¬
counties where it is common.

(c) Anemone Pulsatilla L. A map showing whole vice¬
counties from which the species has been recorded was
shown for comparison with one plotted with actual
localities and indicating at which of these the plant was
believed still to exist. The first map exaggerated the
distribution and failed to indicate the association of the
species with calcareous soils which was very evident on
the second.

(d) Various Base Maps. Of particular interest was one pre¬
pared by Dr. Otto Stapf just prior to 1914 in connection
with his work on the relationship of the British and
European floras, of excellent design and well printed on
good quality paper.

43

Scirpus trlqueter L. Distribution plotted by vice-counties as printed in Comital
Flora. The whole of the vice-counties for which it is there given as recorded
with certainty are shown in black; those given there in square brackets as

doubtful are hatched.

Scirpus trlqueter L. Distribution plotted from localities checked against speci¬
mens and recent information. Full circles indicate places where the species
still grows; rings where it is believed to be extinct. The principal inaccuracy
of this method arises from the necessity of making the rings and circles extend
over a greater area than the plant occupies in order to make them prominent

in the reproduced map.

With acknowledgment to “ The New Naturalist

44

(2) Belgium and Holland.

In Belgium, maps showing the distribution of the higher
plants are prepared by the Institut pour la floristique de la
Belgique (I.F.B.) which was founded in 1942. The base map is
covered by a grid with 16-kilometre squares (each called a carve)
which are subdivided into 16 1 -kilometre squares (each known as
a case). There are 2072 carres.

The method of investigation is to make a list as complete as
circumstances permit of the species to be found in each kilometre
square. A master map shows which of these have been exam¬
ined. The map exhibited showed the distribution of Himanto-
glossum hircinum (L.) Spreng.

The Dutch system of the Instituut voor het Vegeta tie-
onderzoek van Nederland (I.V.O.N.) is being described fully by
Dr. Kloos, but examples of the maps as published in Nederlandsch
Kruidkundig Archief were exhibited for comparison with the
Belgian map. It was evident that the two-colour printing of the
Dutch maps showed up much better than the monochrome of
those of Belgium. The Dutch example, showing the distribution
of Galinsoga parviflora, employs different markings for records
before and after 1920. It is a matter for regret that in the later
Belgian scheme it was not possible to adopt the 1 : 2,500,000 scale
used for the Dutch maps.

(3) Denmark.

The maps exhibited were from one of the publications of the
Danmarks Topografisk-Botaniske Underscgelse of the Dansk
Botanisk Forening. The detailed investigation of the distribution
of the higher plants was initiated in 1904 and the country was
divided into 53 Districts, of which those numbered 13, 22, 39 and
(an added) 54 were later subdivided into two for convenience. The
boundaries chosen were those regarded as “most accessible to the
local investigators ” and were mainly based on Herreder (ad¬
ministrative areas comprising several parishes). In this respect
the scheme closely resembles our own Watsonian vice-county
system.

The records are incorporated in a Card Catalogue and there
is careful distinction between localities based on material in the
collection of the Botanical Museum (Copenhagen), manuscript
lists from the local investigators, and those based on published
information.

Most of the maps published have been in accounts of taxo¬
nomic groups which have appeared in Botanisk Tidsskrijt and
the letterpress has included valuable details of the distribution of
the plants. The following signs are used: —

Solid dot = a locality from which the plant is represented in the
herbarium of the Botanical Museum of Copenhagen.
Circle with small dot in centre = a locality not represented in
the herbarium but published in the literature or included
in a manuscript list.

45

Circle = a locality from which the species is said to have dis¬
appeared.

Shading with continuous lines = indicates that the frequency of
the species is characterised as “ fairly common ” or “ com¬
mon

Shading with broken lines = indicates that the frequency of the
species in the particular area is characterised as “ here and
there

(4) Germany.

The exhibit illustrated the method of plotting at present in
use in west Germany. The German maps equivalent to our
Ordnance Survey are marked with a kilometre grid, each square
having sides 2 cm. long. Further accuracy in marking is obtained
by superimposing grids of 16 squares marked on transparent
paper. The position of the locality within the appropriate square
of the 16 on these smaller grids is recorded. Thus the localities
are plotted with great accuracy.

The observations are transferred to a printed Katalogblatt
of which one is prepared for each species for every map-sheet in¬
vestigated. Each Katalogblatt has an outline grid corresponding
to the kilometre grid of the maps, with the sub-divisions printed
in thinner lines, and on this the occurrences are plotted as dots.
On the second leaf of the Katalogblatt the observer is asked to
give precise map references and habitat notes for each station,
and general observations.

The sheets exhibited wTere provided by the Naturliistorischer
Verein der Rheinlande und Westfalen s which is carrying on the
scheme initiated by Prof. Dr. Mattfeld and Dr. Fritz Mattick in
1922 for the whole of Germany. Unfortunately the great amount
of work carried out before the War was lost when the relevant
Katalogblatter were destroyed at Dahlem when the Botanical
Museum there was burned out. Some idea of the immense size
of the undertaking may be gathered from the facts that in 1936
about 850 botanists wTere assisting in the scheme and that
3,179,000 reports of the type exhibited would be required to
cover all the 3179 species listed for Germany by Mansfeld. As a
first target Mattfeld and Mattick aimed to cover about 600-800
species only but even so the undertaking is a remarkable example
of German thoroughness and capacity for organisation.

(5) Poland.

The maps exhibited wTere part of a world-wide scheme or¬
ganised by Dr. Tad. Wisniewski for the Archives of Plant Carto¬
graphy (Archiwum Kartografu Botanicznej). An important fea¬
ture of the scheme was insistence on all maps being on scales
which could easily be related to one another. Reproduction was
inexpensive.

The signs used in marking maps were as follows : —

46

Solid dot = isolated and boundary localities.

Circle = uncertain localities.

Vertical cross = extinct localities.

Solid dot crowned with a “ T ” = Type specimen locality.

Continuous distribution was shown by vertical hatching. Boun¬
dary lines of distribution areas known with certainty were shown
by continuous lines and boundaries approximately known by
dotted lines.

REFERENCES.

Brockhaus, W., 1949, Die pflanzengeographische Kartierung
Westdeutschlands, Natur & Heimat, 9, 12-15.
de Langhe, J. E., 1944, Sur la Dispersion Geographique du Loro-
glossum hircinum (L.) L. C. Rich, en Belgique, Bull.
Soc. Bot. Belg., 26, 20-30.

Gr0ntved, J., 1939, Polygonaceernes Udbredelse i Danmark, Bot.
Tidsskr., 45, 10 58.

Stapf, O., 1916, A Cartographic Study of the Southern Element
of the British Flora, Proc. Linn. Soc., 129, 81-92.
van Soest, J. L., 1941, De Verspreiding van Galinsoga in Neder¬
land, Ned. Kruidk. Arch., 51, 288-301.

I should like to express my gratitude to Herr Wilhelm Brock -
haus (Luedenscheid) and to the Secretary of the Dansk Botanisk
Forening for assistance in connection with the preparation of this
exhibit.

47

MAPS OF THE DISTRIBUTION OF VASCULAR PLANTS IN

N.W. EUROPE
(Exhibit)

E. Hulten.

The exhibit consisted of specimen maps and proof of the Eng¬
lish summary of Professor Hulten’s magnificent atlas of maps
showing the distribution of vascular plants in North-West Europe
which has since been published under the title Atlas over Karl-
vaxterna i Norden (Stockholm, 1950).

The work of collecting together the vast number of records of
Scandinavian plants was commenced about 1935 and three years
later the task of transferring these to base maps was started.
Arrangements for publication were made in 1945 and since then
the manuscript maps have been checked, revised and prepared
for the printers.

Critical groups receive special treatment but apart from these
there are separate maps for all wild and many naturalised species
occurring within the area. The maps are reproduced on the scale
of 1 : 20,000,000, four to the page. The topographical features are
printed as a blue-grey base-map with the distribution overprinted
with reddish dots for isolated localities and reddish hatching of
two intensities to indicate areas where the plants are more fre¬
quent. The lines of the hatching are broken in districts where
records are fewer than usual. In addition there are maps showing
altitude, geology, meteorological statistics, phenological data,
phytogeographical groups, etc.

MAPPING THE DISTRIBUTION OF SPECIES

William T. Stearn.

The object of these notes is not to summarize the results of
research into the distribution of plants but to discuss briefly the
means by which these results can be expressed visually. Ascer¬
taining and mapping the ranges of species and infraspecific taxa
are essential procedures in modern phytography. The distribu¬
tion of a genus (Fig. 9) being the sum of the areas occupied by
its constituent species, a knowledge of these thus forms the basis
of any discussion of the wider problems of plant geography. The
area occupied by an organism and its abundance within that area
indicate how successfully it has met the challenge of its environ¬
ment. Its past history, its inherited potentialities, the oppor¬
tunities for colonization presented by changes in the environment,
the impact of adverse factors, all these affect the range of an
organism and any investigation of them necessarily involves an
investigation of its range as well. This needs no further discus¬
sion here. For working purposes species and subspecies must be

48

Fig. 9. Distribution o f the genus Cyclamen. Map with hatching over combined
areas of species (based on maps by O. Schwarz in Gartenflora, N.F., 1938).

49

defined by their morphological characteristics, i.e. the differences
between populations which the taxonomist finds easiest to observe
and describe, but the genetical differences they express are usually
also reflected in differences of distribution. In other words,
although the differences, which best suit the convenience of taxo¬
nomists drawing up keys and descriptions are not necessarily
those which matter most to the organisms as living creatures and
hence regulate their distribution, all seem to be so intimately
linked that they postulate one another. Much taxonomic pro¬
cedure rests upon the probability of such correlation. Thus a
systematic botanist often begins his study of a difficult group by
sorting the available herbarium material on a geographical basis
and noting how closely the incidence of certain morphological
characters is associated with this. The pattern becomes clearer
if he charts the provenance of his specimens. The work com¬
pleted, he can make the results more easily available through the
use of maps showing the general or detailed distribution of the
members of the group. Such maps form an essential part of a
good modem monograph.

A map is, of course, an attempt to do what cannot be done
precisely, as it aims to express three dimensions in two
and to give information simply about what is really complex and
large. It succeeds in being useful only because its conventions
and limitations are generally understood and accepted. Much
can be learned quickly from a sketch-map illustrating plant-
distribution, provided that it has been based on reliable data and
has been drawn with care, but too much should not be expected
of it.

In dealing with the flora of so self-contained an area as the
British Isles, it should be constantly remembered that the British
distribution of a plant often constitutes only a small part of the
total range (cf. Figs. 10, 11 and 13); to a monographer, its interest
often lies primarily in its relation to the total range. The follow¬
ing notes give a few suggestions arising out of monographic work
on genera such as Epimedium, V ancouveria, Paeonia, Tofieldia
and Narthecium , of which few or no species grow wild in Britain.
The author is accordingly unable to deal from personal experi¬
ence with the range-mapping of more than a few British plants.
Moreover, some of the best as well as the worst examples of
botanical cartography occur in publications only slightly if at all
concerned with the British flora. They are mentioned here be¬
cause the best techniques can be usefully applied to the flora of
any area.

The distribution of an organism, like its morphological fea¬
tures, can be expressed verbally and pictorially in a variety of
ways. All depends on how much is known and how much needs
to be put on paper. Thus gardeners are as a rule content with
the information that a plant grows wild somewhere in China but,
if it inhabits a more accessible region, e.g. the Alps, they often
desire more precise localities. One botanist may be interested

50

primarily in the distribution of a species as compared with that
of related species. Another may wish to know the distribution
of certain characters over an area. For others, the interest of the
distribution of a plant may lie in its being, say, the host of cer¬
tain pests or diseases or in its relation to climatic and other en-
vironai factors ; plants with a limited tolerance may serve as
indicators of special conditions. Obviously such diverse needs
call for different degrees of precision in mapping; the extent to
which they can be satisfied depends largely upon the herbarium
material available.

The tendency, as in all science, is, of course, towards greater
precision and more and more detail. Thus Linnaeus (1707-78) in
his Species Plantarum of 1753 described the distribution of E pi-
medium alpinum in twTo lines, recording it from three localities,
of which one has proved erroneous ! However, for his time that
was good enough. Augustin Pyramus de Candolle (1778-1841)
in his Regni vegetabilis Sy sterna naturale of 1821 took nine lines
to enumerate localities for the same species. In the present
author’s monograph of Epimedium published in 1938 (J. Linn.
Soc. London , Bot., 51, 409-535) the account of the distribution of
E. alpinum, as ascertained from the study of material in forty-
two herbaria, supplementary data obtained from seven other
herbaria and statements in the literature, occupies 145 lines. In
such an account the distribution has to be treated analytically,
the range .being broken into parts and the localities listed under
convenient geographical headings, just as a description, though
concerned with the plant as a whole, has nevertheless to deal with
it analytically organ by organ. However good the description, the
characters of the plant can be grasped more easily and swiftly if
they are portrayed in a good illustration. Distributional maps
bear the same relation to lists of localities ; whenever possible both
should be provided, as in the monograph mentioned. The lists
show the evidence on which the maps are based. If a choice has to
be made, good maps are preferable, as observed by E. N. Munns
(The Distribution of important Forest Trees of the United States,
U.S. Dept. Agr. Misc. Publ. 287: 1938), “because of the greater
accuracy, simplicity and detail possible in this form of presenta¬
tion. Even the most detailed published descriptions of species
distribution are found to be too broadly generalized when an
attempt is made to plot the ranges on maps.”

Alphonse de Candolle (1806-1893) seems to have been the first
to use maps to illustrate the distribution of plants. The tw7o maps
in his Geographie botanique (1855) are marked with the northern
limits in Europe of a number of unrelated species. The emphasis
of this work being climatological rather than taxonomic, it does
not attempt to use maps as a tool for the study of related species ;
indeed the extensive herbarium collections necessary as a base
for good maps of the ranges of species did not then exist. An¬
other pioneer contribution to botanical cartography was made a
few years later by the Austrian botanist and geologist, Dionys

51

Fig. 10. Distribution of Old World species of the genus Arbutus. Map with
boundaries of species areas outlined. (By courtesy of J. R. Sealy, from J. Ecol.,

37 : 379; 1949.)

52

Rudolf Josef Stur (1827-1893), in his “ Beitrage zu einer Mono-
graphie der Gattung Astrantia ” ( Sitzungsb . Math.-Nat. Akad.
Wiss. Wien, 40, 469-524; 1860); here coloured areas on a map re¬
present the areas of related species. Stur’s method of coloured
shading — an elaboration of A. de Candolle’s simple outlining of
the boundaries — was adopted by another Austrian, Anton Kerner
von Marilaun (1831-1898), later the author of the perennially in¬
teresting Pflanzenleben (1887-91) or Natural History of Plants
(1894). Kerner was an outstanding many-sided biologist keenly
interested in the inter-relations of plants with their environment.
He was also a critical taxonomist who attempted to define micro¬
species geographically as well as morphologically. It is thus sig¬
nificant that he illustrated with maps his paper of 1869 ( Festschr .
zur 43. Versamml. Deutsch. Naturf. und Aerzte zu Innsbruck,
1-48) on the correlation of plant-form, climate and soil and that
he took as a basis the geographical distribution, etc., of Cytisus
sec. Tubocytisus. The maps themselves are drab, the areas be¬
ing coloured dull yellow and green, but serve their purpose.
Kerner’s star-pupil and son-in-law, Richard Wettstein von Wes-
tersheim (1863-1931), followed him as professor of botany at the
University of Vienna and developed his ideas further by taking
up the study of critical genera like Euphrasia, Gentianella (Gen-
tiana sect. Endotricha), etc. Wettstein promoted the geographical-
morphological method, which is now so thoroughly part of modern
taxonomy as to be taken for granted, and he likewise illustrated
his works with maps employing either coloured outlines as in his
Monographic der Gattung Euphrasia (1896) or coloured specific
areas as in his “ Die europaischen Arten der Gattung Gentiana
aus der section Endotricha Froel.” in Denkschr. Math.-Nat.
Akad. Wiss. Wien 64: 309-382 (1896) and his Grundziige der
geographisch-morphologischen Methode der Pflanzensystematik
(1898). Maps of the latter kind illustrate other Austrian mono¬
graphic works, e.g. A. Jakowatz’s “ Die Arten der Gattung Gen¬
tiana sect. Thylacites ” in Sitzungsb. Math.-Nat. Akad. Wiss.
Wien, 108, 305-356 (1899), J. von Sterneck’s “ Monographie der
Gattung Alectorolophus ” in Abh. Zool.-Bot. Ges. Wien, 1 H. 1
(1901) and A. von Hayek’s “ Monographische Studien iiber die
Gattung Saxifraga : Die Sektion Porphyrion” in Denkschr. Math.-
Nat. Akad. Wiss. Wien, 77, 61 1-709 ' (1905). Such maps are
pleasing and clear provided they represent few species and the
ranges of these overlap but little. When numerous species with
overlapping ranges are involved, then coloured boundaries will
be found more satisfactory; as in F. von Schwerin’s “Mono¬
graphie der Gattung Sambucus” in Mitt. Deutschen Dendrol.
Ges., 18, 1-56 (1909) when red, blue and green lines are used.
The high cost of colour printing restricts the use of such methods
of overprinting in colour; if maps are to illustrate every revision
of a genus, cheaper methods must be used.

Plain black and white maps have the great advantage that
they can be printed as text-figures and their cost is little higher

53

than that of the equivalent space of text. They can represent
distribution in five ways: — (1) by outlining the area, a boundary
line running through or around the outermost points; (2) by
shading, hatching or blacking in the area; (3) by dots indicating
the stations; (4) by a combination of hatching and dots; (5) by
a combination of boundary lines and dots. Each method has its
advantages ; choice depends on the information available and the
aspect to be emphasized. All have been used to express the dis¬
tribution of plants in Britain.

Hitherto the shading, etc., of vice-counties has found most
favour with British botanists, because so much of the results of
floristic work in Britain for the past hundred years has been re¬
corded under these and by means of them can be easily utilized.
Mapping by vice-counties provides a quick and convenient method
for getting an impression of the general distribution of a species
within the British Isles. You look up the species in G. C. Druce’s
Comital Flora of the British Isles (1932) and shade every vice-
county listed; those from which the species is not recorded are
left blank. The chief objection to this rather crude method is
that it exaggerates the area. Thus a species which just manages
to cross the vice-county border or which occupies a limited area
and has a specialized habitat is represented as if it grew all over
the whole vice-county. Most British counties and vice-counties
display considerable diversity in geology and topography and it
is probably true that in almost every one, as It. Good has ob¬
served after mapping the distribution of plants within the county
of Dorset (vice-county 9), no species “ is completely and evenly
distributed. Even the commonest plants are absent from some
small areas and are of more or less than usual frequency in many
others, while at. the other end of the scale there are certain rare
species known only from a single spot and in very small quantity.”
This geographical segregation is well illustrated by the dot maps
in Good’s Geographical Handbook of the Dorset Flora (1948).
Under the vice-county system all have to be treated as if they
extended evenly over the whole vice-county. Another objection
is that some vice-county records accepted by Druce are erroneous.
An improvement of this method is to black in the vice-counties
where the species is common and hatch variously the vice¬
counties where it is less frequent. Even so the distribution of
uncommon species may be grossly misrepresented. Many ex¬
amples of the mapping of distribution by vice-counties are to be
found in the “ Biological Flora of the British Isles ” now being
published in J. Ecology, and in E. J. Salisbury’s “The East Anglian
Flora” (Trans. Norfolk & Norwich Nat. Soc., 13, 191-263; 1932).
Mapping by the blacking in or marking of grid squares can be
considered a variant of the vice-county method and has been
used by a number of Continental botanists dealing with local
distribution. Its degree of precision depends, of course, on the
size of the areas represented by the grid squares on the map.

54

Fig. 11. European distribution of 1'ofieldia pusilla ( - general boundary;

• localities represented in British herbaria). General distribution of Tofxeldia

calyculata ( - general boundary; + localities represented in British herbaria).

Map combining outlines and dots (from J. Llnnean Soc. Bot., 53 : 196; 1947).

55

The dot method goes to the other extreme. In this method
each station or group of adjacent stations, according to the scale
of the map, is indicated by a dot, cross or other distinctive mark.
As the author, unless dealing very thoroughly with a very small
area, cannot know every station, such a map is necessarily in¬
complete and likely to under-state the distribution. The appeal
of a dot map lies in its honesty. It makes clear how much the
author knows; it may also indicate how much remains to be
learned. When the species is fairly common over a well-investi¬
gated region the dots will tend to touch and coalesce and the
result will then be a more or less solid black area marking out
the range. Maps of this type will be found in many publications,
notably in E. N. Munns’ “ Distribution of important Forest
Trees of the United States ” (1938) which summarizes the results
of over thirty years’ intensive work by the United States Forest
service. The information available about such economically
important, easily observed and identified plants as forest trees is
naturally very detailed and is reflected in maps like those of
Salix nigra where the thick black sinuous lines recording the
occurrence of this species chart the main river system of the
eastern United States. After looking at such a map one is not
surprised to learn that the species inhabits “ banks of streams,
shores and rich low woods ”. The distribution of many other
species is indicated by a simple unrelieved large black area, im¬
plying a more even occurrence. If more than one species had to
be represented as growing in the same region, obviously this
method could not be used, but boundary lines would serve the
same purpose.

For a species wTith limited occurrences the dot method of
mapping (Fig. 11) is the best; for species which occur abundantly
and fairly evenly over an area, hatching may be preferable. A
species may be common in some areas, rare in others, e.g. Nar-
thecium ossifragum, which is widespread and abundant over some
areas in the Highlands of Scotland but rare in East Anglia. For
such plants a combination of the two methods, with hatching
over the areas of abundance but dots elsewhere, would seem the
best procedure. It has been effectively employed in K. Jessen’s
“Distribution of the Liliales within Denmark” in Bot. Tidsskr.,
43, 71-113 (1935) and E. Hulten’s Atlas of the Distribution of
Vascular Plants in N.W. Europe (1950). Good dot maps are to
be found in numerous monographs and revisions. E. Anderson
and R. E. Woodson’s “The Species of Tradescantia indigenous to
the United States” ( Contrib . Arnold Arb. 9; 1935), M. L. Fer-
nald’s “The Linear-leaved North American Species of Potamo-
geton, Section Axillares ” in Mem. Amer. Acad. Arts. & Sci.,
17, pt. I (1932), R. Nordhagen’s “ Om Arenaria humifusa ” in
Bergens Mus. Arbok Naturvid. 1935, Nr. 1 (1935), E. Hulten’s
“ Flora of Kamtchatka ” in Kungl. Svensk. Vet. Akad. Handl
JII. 7, 8 (1927-30), the memoirs in Acta Phytogeographica Sue-
cica such as R. Stemer’s “Flora der Insel Oeland ” (op. cit. 9;

56

1938), G. Samuelsson’s “Die Verbreitung der Alchemilla-Arten
aus der vulgaris-Gruppe in Nordeuropa ” (op. cit. 16, 1943) and
S. Ahlner’s “ Utbredningstyper bland nordiska Barrtradslavar ”
(op. cit. 22, 1948) are but a few of the many excellent American
and Scandinavian works employing dot maps. Various refine¬
ments can be introduced into such maps, e.g. a special mark or
letter to indicate the type-locality; when dealing with distribu¬
tion over a small area places where the species once occurred but
is now extinct can be marked differently, e.g. by rings or crosses.
In maps intended to illustrate differences of range between cyto-
logically distinct plants, large dots may be used to mark the
localities from which the plants have been cytologically examined
and the smaller dots the localities for plants presumed on mor¬
phological grounds to be the same; see for example Baldwin and
Speese’s map illustrating the cytogeography of Saururus cernuus
(Bull. Torrey Bot. Club 76, 213-216, 1949).

In many monographs the range is indicated by boundary lines ;
these lines enclose the area in which the species occurs. This
method (Fig. 10) is especially useful when the overlapping ranges
of several or many species have to be represented on the same
map and when the region is a very large one and the scale con¬
sequently small. The range of one species may be distinguished
from that of another by the employment of different kinds of
boundary lines ; a thick unbroken line can serve for one, a broken
line for another, and so on, according to the number of species
and the ingenuity of the author. A few examples are :

ooooooooooooooooooooo

+ + + + + + + + + +

o — o — o — o — o — o — o —

In the text of a monograph all species should be numbered and
infraspecific taxa given letters a, (3 , y, 8, etc., A, B, C, D, etc. The
same numbers and letters should be placed against the boundary
lines of the species, etc. This system, which is employed in the
present writer’s monograph of Epimedium , is a convenience to
the reader who can turn straight from the description to the map
itself without having first to study an elaborate explanatory cap¬
tion. If these numbers are used, such diversely fashioned
boundary lines as those indicated above may prove unnecessary.
Even better, when space permits, is the addition of the names of
the species (Fig. 10). Good examples of the use of the boundarv
method are to be found in the German periodical Pflanzenareale
(1926 et seq.), which is devoted entirely to maps of the general
ranges of plants. The base maps are blue, with the plant
boundaries printed black. The disadvantage of this method is
that it gives no information about the occurrence of the species

57

within the area enclosed. It tells the systematist what species
are to be expected among the material from a certain area but
it does not tell him from which localities they are known ; it gives
no indication as to whether a species is evenly spread over the
area or occurs only at isolated localities. Moreover, the drawing
of the boundary line itself is essentially subjective. A great
variety of patterns can be made by drawing a line through or
round the outermost of a number of scattered dots representing
the localities from which a species is known (Fig. 12). The
smoother the curves and the more regular the outlines become,
the more they please the eye by simplifying the map; unfor¬
tunately so much the more do they depart from the facts. A
consideration of the topography may help to indicate how the
boundary should be drawn. Thus if a montane or alpine species

\

Fig. 12. Distribution of a species of lichen expressed by dots, hatching and out¬
lines. all based on the same data.

58

occupies a series of mountains separated by wide lowland regions
in which it does not occur, the boundary connecting the dots
might well follow the general outline of the mountainous areas
instead of cutting across the lowlands.

Some maps compiled by the author of this paper and pub¬
lished in J. Linn. Soc. London , Bot., 51, 430, 433 (1938; 53, 196
(1947) and in F. C. Stern’s Study of the Genus Paeonia 18, 20, 22,
30 (1946) combine dots and boundary lines, the localities known
to the author through herbarium material being marked by dots,
crosses and small circles while a line outside these gives the
general range as indicated by apparently trustworthy literature
(Fig. 13). This method has many advantages. Scattered dots and
crosses, especially if many occur on the same map, tend to dis¬
tract the attention; an enclosing line focuses attention on the
range as the whole.

Boundary lines are probably of more scientific use for the
study of generic than of specific distribution. This subject lies out¬
side the field of the present paper, since no genus of flowering
plants is endemic to the British Isles, but it may be of interest
to call attention to a method devised by W. Rothmaler and used
in his papers on Alchemilla sect. Calycanthum (Fedde, Repert.,
Beih. 100, 89-91, 1938) and Ulex (Engler, Bot. Jahrb. 72, 78,
1941). It provides monographers with a means of comparing the
morphological diversity of a genus in different parts of its area.
A grid is superimposed upon a map of the generic area, thus
dividing it into a large number of squares, on each of which
the number of species of the genus occurring within the souare
is marked. It thus calls for very detailed and precise information
as a working basis. Lines are then drawn to connect the squares
with the same number of species. They thus form boundary
lines, called by Rothmaler isopores (Isoporien) and analogous
with isotherms, enclosing areas with the same number of species :
within a wide area with few species will probably lie smaller and
smaller areas with more and more species. The map will then
emphasize the areas where the greatest number of species occur.
In one the species may be numerous but closely allied, manifest¬
ing many combinations of a few characters; such an area is prob¬
ably one where conditions in the past favoured a few variable
populations which mingled and then broke up into smaller units.
In another the species may be morphologically very distinct,
probably representing very old types for which the area has been
a refuge. To distinguish the two kinds of areas Rothmaler’s
method evaluates the degree of morphological diversity by draw¬
ing boundary lines termed isopsenheres ( Tsopsepheren ) enclos¬
ing areas wherein the species exhibit the same number of diag¬
nostic characters though not necessarily the same characters.
This too calls for very detailed and precise information. The
method is thus one which only a monographer can apply. In¬
vestigation of the genus as a whole may show that, say, twenty
characters can be utilized for the distinction of species. If only

59

one species occurs in the area, 20 can be taken as the number of
morphological characters represented in that area. If two species
agreeing in fifteen of these but differing in five occur within the
area, then the number will be 25. The same grid as mentioned
above is then superimposed upon the map of the generic area,
thus dividing this into squares, on each of which the number of
characters represented within the square is recorded. Lines are
then drawn to connect the squares having the same number.
Within the area enclosed by a low-number isopsephere will
probably lie areas of greater and greater morphological diversity
with higher and higher numbers. The map will thus emphasize
the areas where the most diverse species occur and may enable
distinctions to be drawrn between areas of refuge (characterized
by high numbers) with very heterogeneous relict species and prim¬
ary and secondary centres of specific differentiation (with lesser
numbers). Such a method cannot be fruitfully applied to all
genera; indeed to a genus like Narthecium with no overlapping
species it cannot be applied at all wrhile in some genera it would
merely confirm what wras already obvious. Critical genera like
Euphrasia and Thymus and probably Crepis might yield in¬
formation of considerable phytogeographical interest tackled from
this aspect.

Constructing a map of distribution, whatever the aim and
method, is rarely a simple task. Apparently the first thing to
ascertain is where the species occurs, but this necessitates being
quite clear as to its morphological limits and may call for mono¬
graphic study of the whole group of species. First-hand informa¬
tion derived from the correct identification of the specimens in
as many herbaria as possible is thus of prime importance; with¬
out such a backing the value of literature records cannot be as¬
sessed; indeed, unless the species lacks any close ally within the
area, with which it might be confused, unsupported records are
best ignored when making maps of distribution. The basic pro¬
cedure is first to sort all the specimens available into morpho¬
logically defined groups and then to sort the specimens of each
morphological group into geographical groups, i.e. by countries,
provinces, counties and vice-counties. The specimens should
next be listed under these geographical headings and each record
numbered. Each locality represented can now be marked in
pencil on a suitable base-map by a dot and the reference num¬
bers of the specimens. If later investigation reveals that some
material has been misidentified, these reference numbers will en¬
able the erroneous records to be quickly found on the map. Care
should, of course, be taken to place the dots correctly. A map
inaccurately drawn or based on inaccurate records and misidenti-
fications may easily become a source of long-standing error and
confusion, in addition to being the target for such criticism and
advice as M. L. Fernald gave in Science, 68, 145-149 (1928) to
the editors of Pflanzenareale, namely, “ they must make sure that
the distinguished authors of the maps have at least an elemen-

60

tary knowledge of geography and, passing this test, that they
take a real interest in presenting the facts without distortion ” !
It is surprising how many different places possess the same name;
moreover the data and handwriting on herbarium labels are not
always as clear and precise as they should be. If only collectors
stated on their labels the latitude and longitude of the places
named or gave their distance and direction from a well-known
place, how much time-consuming and tedious poring over maps
they would save the conscientious student of their material ! The

ties; type-region: //// area of abundance; - unverified (from J. Linnean

SOC. Bot., 53 : 195; 1947).

61

monographer of a genus almost invariably comes across speci¬
mens which he can identify but nevertheless cannot chart on his
maps because their provenance is ambiguously or vaguely stated.
If the specimens are dated it may be possible to localize them by
reference to the collector’s diary or an account of his travels.
Thus for collections made in China last century, E. Bretschneider’s
History of European botanical Discoveries in China (1898) pro¬
vides invaluable help. The enterprise of A. and D. Love in dis¬
tributing their specimens of Icelandic plants with labels having
the provenance of the specimen clearly marked on an outline
map is much to be commended.

The choice of a suitable base map raises problems. It should
be simple enough not to obscure the botanical information but at
the same time adequate to give this precision. The courses of
rivers and lines of latitude and longitude supply the best indica¬
tors of position. As a rule the outline maps published by com¬
mercial map-makers for school exercises are not good enough for
botanical purposes. In the United States, the University of
Chicago publishes Goode’s copyrighted outline maps which are
used by many American botanists, and excellent base maps of
Scandinavia and the Northern Hemisphere, centred on the North
Pole (Fig. 13), have been printed for the use of Scandinavian
botanists. Unfortunately comparable British maps seem not to
be available at the present time. The author of a paper is thus
driven to tracing the outline from a suitable atlas map of the
right scale, which is not always easy to find, or to employing a
professional cartographer. The first procedure is tedious and the
second may be costly. Avoid maps on cylindrical projections
(e.g. Mercator’s and Gall’s) wrhen charting the ranges of northern
plants especially if they are circumpolar; for these plants a cir¬
cular map centred on the North Pole (cf. Fig. 13) is the best.
Cylindrical projections may, howTever, be convenient when deal¬
ing with more southern plants of a wide Mediterranean or Eura¬
sian distribution; the map of the Old World range of Paeonia in
F. C. Stern’s Study of the Genus Paeonia, 32 (1946) provides an
example. Most maps of specific distribution cover too small an
area for the projection to matter much. Murdoch’s Third Conical
Projection, enthusiastically sponsored by A. R. Hinks, is used
in that masterpiece of beautiful cartography, British Council Map
No. 1, Europe and the Middle East (Royal Geographical Society,
1941). As regards the British flora the Botanical Society of the
British Isles might well give support to the publication of a set
of outline maps of the British Isles for the use of botanists and
zoologists. The coast-line should be boldly shown, with the vice-
counties and chief rivers lightly indicated on one set and contours
of, say, 500ft., 1000 ft. and 1500 ft. on another set. In this way
there could be two maps of the British Isles as a whole on, say,
the same scale as the map (which measures roughly 20 in. by
11 in.) in Druce’s Comital Flora, two maps of Ireland, two of
Britain south of, say, Edinburgh, two of Britain north of, say,

62

Middlesbrough, making eight base-maps in all. It would also be
useful to have a smaller outline map of the British Isles, say 6 in.
by 9 in., with only the vice-counties shown.

If no cheap and suitable base maps are available, it is econo¬
mical to work first with squared paper, the lines being taken to
represent meridians and parallels and the coast-lines and political
or administrative boundaries being temporarily ignored. Make
a chart for each species, giving a reference number to each dot
corresponding to a locality mentioned on a herbarium specimen or
in trustworthy literature. Comparison of the charts will then
make it simpler to decide upon the best method of presentation.
Thus, if the species are found nowhere to overlap in range, an
outline around the outermost stations of each species may tell all
that is necessary. If, however, their ranges overlap and especially
if they hybridize, these simple outlines will probably not suffice
and a system of dots, stars, crosses, triangles, small squares and
circles may more effectively portray the facts. The grids of the
squared paper will help to ensure accuracy when transferring the
data to the final map intended for printing. Avoid trying to put
too much on one map. Such a confusing tangle of overlapping
and imperfectly differentiated lines as occurs on the maps in It.
Schulz’s Monographische Bearbeitung der Gattung Phyteuma
(1904) and B. Stefanoff’s “ Monografiya na Roda Colchicum ” in
Sbornik na B’lg. Akad. Nauk (Sofiya), 22 (1926) detracts greatly
from the value of the work. R. E. Woodson’s monograph of
Apocynum in Ann. Missouri Bot. Gdn. 17, 17-136 (1930) in¬
geniously succeeds in charting the ranges of 22 species and varie¬
ties on one small-scale map by employing a great variety of bold
outlines, but they could have been more clearly and pleasingly
represented on several maps.

To ensure maximum accuracy, maps intended for reproduction
should be drawn larger than they will be when published. In¬
dian ink should be used. To counteract the effect of reduction
the dots and boundary lines should be drawn boldly. Imper¬
fectly aware of this I once drew a large map of the distri¬
bution of Epimedium alpinum but made the dots too small;
reduced to about a twentieth of their original size they appear
like pin-pricks in J. Linn. Soc. London, Bot., 51, 474 (1938). A
reducing lens will be found a help in avoiding such an error of
judgment. The lay-out of the map deserves consideration. Thus
if the latitude and longitude is given, the map will look best if
one meridian runs vertically through the centre ; the parallels and
the meridians east and west of the one chosen will then balance
symmetrically. After the outlines or dots, etc., have been in¬
serted, a few place-names may be added. Small capitals can be
used for the whole of the names of seas, countries, states and
provinces, upper and lower case letters for the names of towns,
mountains, lakes and rivers. Italic lettering pleasantly distin¬
guishes water (seas, lakes and rivers) from land features. Good
penmanship adds much to the general appearance of a map but

63

not all of us possess the gift or the time to cultivate it. If need
be, an obliging printer will set up the names required and print
them off ; they can then be pasted on to the map before the block
is made.

Botanical cartography, like botanical illustration, must neces¬
sarily be educational and scientific, aiming as it does at the ac¬
curate presentation of verifiable data about natural phenomena,
but it can also be artistic and give pleasure to the eye as well as
material for thought. The Journal of the Royal Geographical
Society abounds in beautiful black and white maps, some very
simple, some very elaborate, but all of them pleasingly arranged
and lettered ; they thus provide models which botanists would do
well to study.

[The above paper on the principles and methods of botanical
cartography was illustrated by a series of maps taken from the
publications mentioned and shown by means of an epidiascope.
Fig. 10 is reproduced by courtesy of Mr. J. R. Sealy and the Cam¬
bridge University Press. Figs. 11 and 13 by courtesy of the Lin-
nean Society of London.]

THE STUDY OF PLANT DISTRIBUTION IN HOLLAND

A. W. Kloos.

(Readers who heard this paper read by Dr. Kloos will remem¬
ber with pleasure the charm with which it was enunciated in a
language which is not his own. It is with great reluctance that
I have amended the wording to make the meaning as clear in the
printed form as it was at the Conference. — Editor.)

I hope to succeed in giving you an idea of the work of I.V.O.N.
These initials are an abbreviation for Instituut voor het V egetatie-
Onderzoek in Nederland — the Institute for the Investigation of
the Vegetation of Holland. I hope to show you how the work of
I.V.O.N. leads to the production of maps illustrating the distri¬
bution of Dutch plants.

The method, which we owe to J. W. C. Goethart and W. J.
Jongmans, is based on the Military Geographical Map on the
scale 1 : 50,000. This is published in 58 sheets, all of the same
size, covering an area of 40 x 25 kilometres. These sheets are the
largest units of our system and each folds into 1 6 rectangles which
in turn are divided into 3 “squares”. These 48 “squares”, each
covering 5,000 x 4,133 metres are known as uurhok — “hour-
squares”, so called because their sides represent approximately
the distance which can be comfortably walked in an hour.

Each “hour-square” is in turn divided into four “half-an-hour
squares” and each of them once more into four kwartier hokjes —

64

“ quarter-squares ”, which are the principal units and measure
1250 x 1044 metres. Whenever more detailed studies are re¬
quired of a small area the divisions can be repeated and the
“quarter-squares” can be subdivided into 4 or 16 smaller squares
numbered in the same way : —

I 2

3 4

The basic fieldwork consists of making an inventory of the
species observed in a quarter-square. For this purpose Goethart

—

X*.

Hokfe: . , . , . . .

door : JcnC:.. .

datums /fra. .

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grostem. Agrostis,a,c/. Air J,d,f. Aj ,ch,g/. Alch.a/. Alis, n,P,r. Alliu, ca,
Sch,Sco,ur,vi. Ain, 3,1. Alop ,a,b,f,gp. Als.f. Akh,o. My, cal, camp. Amar, B,r,s.
mbr.o. Ammi.m. Ammo, a, b. Anac. Anag,a,e,<. Anch. Andr. Anem, n.P.r.
ng. Anthem, ar,c,r,ti. Antho, o,P. Anthr.C/v. Anthyl. Antir.O. Ape, i,S.
pi,?. Aq,v. Ara ,ar,0,h,s. Are, l,s. Ari3,Ci. Arm, e, to. Arni. Arno. Arrh.
rt, 46s, c,m,y. Aru.ijft. Asa. Aspara, o,p. Asperug. Asperul, o,c,o. Aspl,.4-n,
■m,T. Ast e,s,T. Astray. Athy ,f-f. Mn,d,ho,lac,lat,lip,r. Atro. A y,c,( aft, prat,
at,pu. Az.

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sta.m. Beto. Betu.p.v. Bid,c,A Ble. Bli,c,u. Bor. Bot. Brach.p/. Bias, e, I,
a ,ni,o,R. Bri. Bio, or, as, c,e,h,i,m,r, sc, st,t. B/r. Bup,A But.

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imo, d,m,$. Camp,?, pa, pc,ra-des,ra-- us, y6t.,T. Caps. Cai da, a, A.p.s. Cardu,
n. Care, ac ■■ a,ac--is, ar, br,Bu,can,dig,dio,dista,disti,div,ech,el,er,ex,fi.flav,
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hMric,strig,y,te,trin,ves,vulg,vulp. Carl. Carp. Cain, B,C,v. Cas. Cata.
uu. Centa ,Ca,Cy,J.j/(,Sc,So. Cento. Cepli,?. Ceras,ar,glo,glu,s,te,tr. Cerat,d,s.
iae,<. Chamag. Choir. Choi. Chen, a, b-h,f, g,h, to, o,p,r,u,v. Chl.p,s. Chon.
ii7sa,t',L,P,s. Chryso.a.o. Cicen. Cich,/. Cica. Cin,p. Circae,;. Cirsi,ac,an,
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mva ,maj. Convo, a, se, So. Coris. Corn/* 1. Coroni.u. Corr. Coryd ,ca,cl,l,s. Cory I/!
iryn.e. Cram. Crat/5,o. Crep,b,p,t,v. Cri. Cucub. Cus ,Epil,Epit,eu. Cynan, V.
/nod,D. Cynog ,0. Cynos.c. Cyp ,/1/m. Cys.

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)r,P. Dra.m.v. Dro, i,l,r.

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\tl,Par,Pep,pla,seg,atr,vir. Euphr ,Od,of. Efr.

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j pft,mc,o.

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Uat,sylves,t,u,v. Geni ,a,g,p,t. Gent, a, ca,cr,g,P. Ger,c,d,m.Phpr,pupy,Rob.
u ,i,rjf. Glauc.e,;. Glaux. (/e. Gly,d/,m,s. Gna,d,i-a,s,u. Good. Gra.
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rta. Herm. Hern,?. Hiera, aura, Auri,b,ca«, to, Pi,pr,r, ir, u.vu. Hiero. Hippo,
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stric,strig,sy,v. Myosu. Myric ,c,G. Myrio,a,s,».

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rr/ts,mil,)KO. Orig. Ornithog, n,u. Ornithop,p. Qroba,a,c,G,m,pa,Pi,ram,R
Osin. Ox,a,c,s. . — * * . . **

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Peu,C. Phalar,a,c. Ph e,Dp,R. Phl,a,p. Phr. Pliyt.,n,s. Pice,e. Piet
Pim,TO,S. Ping. Pmu.sy. Piro,m,r,s. Plan, a, C/,n/tj, mar ,rhe. Platant
Poa,/, b, co, n.pr,se,su,t. Polyc. Polygal,c,d,w. Polygon t,m,o. Polygonu,i

B, C,D,H,lap,min,mit,n,Pe,la. Polypod. Polys, a, c,F-m,0,s, T. Pop,a,n,i. I
co,cr,d,g,Ho,l,mu,n,obt,pec,per,po.pr.pu,r,t. Potent.ans.ai'.'^cy.i-t),?!^^)!^
r$>.T,ve. Pri ,//,o. Pry^ie. Prunu, Pa,/. Pt. Pule. Puli, d,v. Pulm.

Qu,R,s. X

Rad. Ran, ar, ar,a/ijf,Fl,L,n, Ph, po,r, see. Raphanu,r,s. Res,lutea,luteo. R!
Rhina, j4,ma, mi. Rhynch,a/. Rib, a, G,n/. Rob. Ros,ar,ca,cin,co,du.pi,po
Rubia. Ru/is,cae,/, sax, spp. Rum, Ac-- sa,Ac --lapong, cons, cr,div, Hip, f
U,mar,max/.p,sa,sc. Rup.m.r.

Sagln,a,c,n.p,s;r,3u. Sagit. Salic, h,r. Sa.]\x,ac,al,amh,amy,au,b,ca,ci,f,i,pc.pu,
se,sm,st,un,vim. Sals. Salvia, p, Sc, sy,ve. Salvin. Samb.P/.r. Samo. Sar
S/i. Sap,o. Syfr Sa x..g,t. Scab. Scan. Scheu. Schoe.n. Soil, 6. Scir, cae,
l,m.pa.pu,ru.se,sy,Ta,tr. Sclera, a.p. Sclero, Bp. Scot. Scor.ft. Scro,a,E,A
Scut.g.m. Sed, fi,al,B,C,d.y,r. Sel,c. Sem. Seneb,c,d. Senec,a,err,eru,
sa.sy,vi,vu. Sel,g,ve,vi. Sh. Silau. Sile,M.c,d,3,t,?!o,nw,0. Sily Sin.al,
Sis, /.C,I,L,o,p,S,T. Siu. Sola, O n. Soli,u. Son,ar,as/,p. Sor.a Sparg.a,/
Spart Spec.s. Spergula,a,Jf. Spergolaria,TOa,m«,r,sa,se Spira e,jf. Spiran
Stach.am, an, arp, s. Stat.L. Stel ,gl,gr,H,i/i,n,u. Stra. Stu. Suae/,m.
Sue. Sym.o.

T»o. T/r. Tax. Tee. Tetr. Teu.sc. Tha./la./Ze.mi. The. Thl,alp,ar,c. Thr.
Thys. Tili, g,i, pa. Till. Tor,A,.H,n. Trag,m,pj,pr. Trie. Trif ,ar,di,/i,fr,l
me,mi,pra,pro,r/p,sc,st,tu. Trigl, m,p. Trio, Trit,a,e,;',pu/. Tul. Turg.
T/s. Typha ,a,l.

tyfc. Cl m/.s. Ur/u. Dtr.B, i,m,n,e.

Vacca.s. Vacci ,ma,My,0,u,V . Valeriana, d,o. Valerianella.^.ca.rf.o Verba,
phl,Sch,th ■ ■ forme. Verbe. Vero .ag.An.ar.Bc. I3u,(/h,li,la,lo,m.of.o;>pe.j/
pro,sc,sc,t,u,v. Vib/,0. V ic, a, C,g, hi, la, sa,se,t,v. Vm,rjfi, Vio ,cal,canjl,f
s t,sy,t. \/,

Xanthium.s.

Zenpape. Zos.m.n.

Fig. 14. The Iloklijstje used by Dr. Kloos to score the plants he observed on the

Quendon Field Meeting.

Each species found in Holland is represented hy its scientific name in a very
abbreviated form which is crossed through if the plant is observed. For ex¬
ample, the first three species in the list are Acer campestris, Achillea Millefolium
and Achillea Ptarrnica— only the second was crossed through as observed.

65

and Jongmans’ prepared printed inventory lists, known as
Hoklijstjes. These include the names of all species, likely to be
found in any part of Holland, printed in a very abbreviated form.
As each plant is observed in the quarter-square, the name is
crossed off in the list. The work can be undertaken by a single
person but it is performed more efficiently by teams of three to
five botanists. One of these undertakes the reading of the map,
another marks off the plants on the list while the remainder
observe the plants and call out the names. The party “play leap¬
frog” — i.e. they go ahead in turns so that the ground is adequately
covered. It is evident that the value of such work depends on
the trustworthiness of those taking part and the need for accuracy
is impressed on all workers. The completed lists are sent to the
secretary of I.V.O.N.

The data are wrorked out by collaborators, appointed for each
sheet of the military map and chosen as knowing its flora well
and, for preference, as living in the region concerned. Each
species found within the territory of the sheet is plotted on a
separate distribution map. These are on the scale 1 : 200,000
and printed on more or less transparent paper. On one side there
is a reversed reproduction of the main contours of the area, on
the other a complete grid of the squares. The quarter-squares in
which the species has been observed are marked with a red spot.
By holding the map against the light the two are combined and
the distribution of the species in the territory can be seen against
the background of the contours.

These distribution maps are filed in loose-leaf binders and
form a complete florula for each sheet of the military map. For
most sheets there are three binders, for some of them four are
needed. From these sheets the indefatigable secretary of I.V.O.N.,
Mr. Jan G. Sloff at Bergen op Zoom, plots the observations on to
maps covering the whole of Holland on the scale of 1 : 1,500,000.
These maps are less detailed and show only the hour-squares in
which the species has been found. It will be appreciated that the
presence of a plant in an hour-square may represent its occurrence
in all of the 16 quarter-squares or, equally, it may occur in only
one of them or in several. Although the local frequency cannot
be shown on the general maps, they have nevertheless proved very
useful. They show at a glance whether the plant is common over
the whole country or rare, and the pattern of its distribution which
can be compared with maps for other species or with the geo¬
logical or meteorological maps, etc. Reference can be made back
to the separate sheets for more detailed information.

The published maps were at first on the scale 1 : 1,500,000
as used by Goethart and Jongmans, 1903-1908. The distribution
was shown in red overprinted on a black background. It was
proved by experience that this scale was hardly large enough to
indicate the quarter-squares by red dots, while failure of the over¬
printing to register exactly was a frequent cause of inaccuracy.
Moreover publication was too expensive. It was therefore

66

Eryngi um, catn/pestre L

Fig. 15. The distribution of Eryngium campestre L. in Holland (reduced to

1 : 3,000,000).

necessary to be content with showing only the hour-squares on
a scale of 1 : 3,000,000 (later 1 : 2,500,000) : see Fig. 15.

The plan was at first applied only to phanerogams and pteri-
dophytes but later extended to bryophytes, lichens and fungi. It
has also been used for other groups — e.g. mollusca.

This paper was discussed as follows : —

Dr. Valentine enquired whether a soil map was available on
the small scale of the published maps. Dr. Kloos replied that
only a geological map printed on the military maps was available,
but this was easily used in connection with the distribution maps
by employing the grid.

67

Prof. Tutin asked if difficulty was found in tracing the
boundaries of the squares in the field. Dr. Kloos replied that
in practice they found no difficulty. The scale of the military
maps was sufficiently large, and the detail sufficient, in a crowded
country like Holland, for lines on the map to be traced with ease
for this work.

Dr. Turrill suggested that it would be an advantage to print
the outline of the coast in heavier lines so that foreigners could
pick it out more easily in the printed maps. Dr. Kloos agreed
that this might be an advantage when the maps were consulted
abroad but the Dutch were so familiar with the outline of their
own coast that to them it hardly seemed necessary. Moreover,
in the later publications the land of Holland wTas shaded so that
it contrasted with the sea and land of neighbouring countries.

Mr. Lousley commented that he had been most impressed
with the rapidity with which his Dutch friends could supply de¬
tailed information about the distribution of their plants and
suggested that this was an extremely commendable feature of
the scheme. Dr. Kloos replied that the files of maps were always
available for consultation in Leiden.

Mr. Sandwith enquired whether microspecies were given on
each card used for listing purposes. Dr. Kloos said that they
were.

Mr. Brenan asked to what extent the records as plotted on
the squares were backed by herbarium specimens. Dr. Kloos
replied that critical species and the rarer plants were usually col¬
lected to authenticate the records but clearly this was impossible
in the case of common and well-known plants. He emphasised
that great care wTas taken to ensure that the lists used wTere reli¬
able as far as possible.

(At the Field Meeting to Quendon Wood on the following day,
Dr. Kloos demonstrated the use of the Hoklijstjes (Fig. 14).
Once the user became accustomed to the very abbreviated plant
names printed in the lists the vegetation could be scored quickly
and accurately and the record was available for filing without the
necessity for transcription.)

68

PROBLEMS OF DISTRIBUTION RAISED IN THE COMPILATION

OF A COUNTY FLORA

J. G. Dony.

The urge to write a Flora of his county has long been strong
in many a British botanist and is likely to continue. The county
can be the basis of local patriotism at its best and even if the
Watsonian vice-county system is ultimately discarded there is
little doubt that county floras will continue to be published. A
county Flora attempts to portray the individuality of the flora
of a county and to study the distribution of plants within its
boundary, especially in relationship to their distribution in neigh¬
bouring counties. This latter becomes a matter of increasing
importance with an inland county.

Bedfordshire is a small inland county. It is indeed one of the
smallest counties, the Watsonian vice-county 30, Bedford, coin¬
ciding very closely with the present administrative county (see
Dony (1947)). The county contains only one distributed species
which does not occur in any of the neighbouring counties. This
species, Omithogolum pyrenaicum, is relatively abundant in a
narrow strip of country about twelve miles long in the north-east
of the county, just as it is in a similar stretch of country near
Bath. Species which occur in one station only are not considered
to have a distribution.

Two main factors appear to determine plant distribution in
Bedfordshire: (a) surface geology, (b) the physical factors of
altitude, rainfall and temperature. Minor factors such as man’s
use, or in Bedfordshire more often misuse, of the land, are usually
related to these two main factors.

The Rock Geology of the county is simple as the various strata
are exposed in belts of land crossing the county from the south¬
west to the north-east. These geological formations could be
made the basis of a division of the county, as they divide it into
districts which conform to the botanist’s first impression of its
various plant communities. The species of the Chalk and the
Lower Greensand are each brought together and the large and
comparatively uninteresting Oxford Clay, occupying the northern
half of the county, is brought into sharp contrast with the rest.
This simple picture is, however, complicated by the Drift Geo¬
logy. The Ouse and Ivel, with their wide stretches of alluvium
and river gravels, cut into the Oxford Clay, and extensive caps
of Boulder Clay overlie large areas and have no respect for the
boundaries of the rock deposits beneath. Much of the Chalk is
overlain by Clay-with-Flints which has a flora peculiarly its own.

The physical factors are of less consequence in their effect on
plant distribution. The rainfall varies directly with altitude and
in the lower reaches of the Ouse, only 50 ft. above sea level, the
rainfall is less than 20 inches, while in the south-west, where the
highest part of the Chalk is above 800 ft., it increases to 30 inches.
There are too few temperature records from which one could

69

Fig. 16. Bedfordshire : Drift Geology, Rainfall, and division into Botanical
Districts based on (a) River Drainage and (b) Natural Regions.

70

draw reliable conclusions but there is little doubt that generally
speaking the eastern parts of the county have greater extremes
of temperature than the western parts. The contrast of the low
lying and drier eastern part of the county with the higher alti¬
tudes and more temperate and wetter copditions of the western
part determines the distribution of some of the more interesting
Bedfordshire species. Trifolium ochroleucon , Primula elatior,
Melampyrum cristatum, Ajuga Chamaepitys and Phleum phle-
oides appear only in the eastern part of the county and are ab¬
sent or exceedingly rare in counties to the west. Melandrium
dioicum is abundant in the west of the county but is rare or
absent in the east as it is also in Cambridgeshire. The fern flora
of the western parts is more varied than that of the eastern part
and Watson (1948) found the same to hold for the bramble flora.

A combination of the geological and physical features could
be the basis for the division of the county into natural regions.
In the earliest attempt to do this Batchelor (1808) made five
regions based on soils. Hillhouse (1877), no doubt influenced by
Babington, suggested seven regions, and to allow for all factors
sub-divided each into seven further divisions. This was no doubt
an ideal which could now be amended in the light of more exact
knowledge of the drift geology, but it is too complicated and
would be almost impossible to work satisfactorily. A more work¬
able division for the field botanist could be made on a basis of
twelve regions which could bring together all the more important
plant communities and give a reasonably accurate picture of the
flora of the county. But such a system would have serious dis¬
advantages, as the boundaries of the regions are difficult to
memorise and constant reference to maps would be necessary.
The Lower Greensand is divided into two parts and some regions,
especially the Gault Clay, being an awkward shape, would limit
serious work in the field. To divide the regions further would
bring one back to Hillhouse and his almost unworkable system.

A study of the methods adopted in neighbouring counties is
necessary, for a new county flora affords a useful comparison
with similar work already done in a wider field. In Hertfordshire,
Webb and Coleman (1839) used a river drainage basis, being the
first botanists to adopt this method. Pryor (1887) followed their
lead and produced a model county flora of its kind and period
and the method was retained by Hopkinson (1902). Druce used
the same basis for Buckinghamshire (1905 and 1926B) and North¬
amptonshire (1930). There is no map in the last-named work but
one may be found in an earlier account, Druce (1902). Hunt¬
ingdonshire is one of the few English counties without a pub¬
lished county flora and it is unlikely to have one for some time.
In an inadequate account of its flora Druce (1926A) considered
it as a whole. For Cambridgeshire, Babington (1860) used eight
natural regions and Godwin (1938) dealt with its types of flora.
Evans (1939). in a disappointing account, considered it as a
whole.

71

In the previous work done in Bedfordshire, Abbot (1798), and
Saunders (1911), considered the county as a whole. Hillhouse
(1877) suggested natural regions but no records had been related
to them. Druce (1904), who knew little of the county, made
seven districts based on river drainage. It is interesting to note
that for one district, the Nene, he listed only one species, picked
up from W. W. Newbould, and from another, the Cam, he re¬
corded nothing. On the other hand, Little (1936) subsequently
did some useful work on Druce’s Ivel district and his field notes
contained some records from the Cam district. Much of the use¬
ful work already done both in the county and in neighbouring
counties has been on a river drainage basis.

The boundaries adopted by Druce were, however, badly in
need of revision. His Lea district contained two catchment areas
and Pryor had two districts, the Lea and the Colne, based on
these. He had divided the large Ouse district somewhat artifi¬
cially into East and West Ouse for which there were no corre¬
sponding districts in his treatment of Northamptonshire. It ap¬
pears better to introduce a new district, the Kym, based on river
drainage. This is somewhat smaller than Druce’s East Ouse,
but its boundary is more easily seen in the field. It could, if need
be, be adopted in a division of Huntingdonshire. A study of the
watershed showed the Cam district to be larger than his map
indicated.

The river drainage basis has some practical virtues. The
boundaries can usually be seen in the field and in most cases a
road, footpath, or at least a field boundary is found to follow
the watershed closely. It conforms in a crude way with some
of the natural factors affecting plant distribution; the eastern
and western parts of the Lower Greensand with their differing
floras, for instance, are brought into separate districts. The
greater part of the Clay-with-Flints is brought into one district,
the Colne.

Its most serious defect is that the Chalk is brought into four
districts with few corresponding differences of flora. The dis¬
tricts differ greatly in size, but this has proved in some respects
an advantage. If a species is recorded from all districts it can
almost certainly be said to be well distributed in the county.
This is the case with some species comparatively rare in the
county, e.g. Ophioglossum vulgatum and Saxifraga tridactylites.
On the other hand some species, Primula vulgaris , Stellaria Holo-
stea and Knautia arvensis, wThich one would have considered from
their general abundance to be well distributed, are each, for no
accountable reason, apparently absent from one district. The
close search of some of the smaller districts has added some in¬
teresting species to the county flora and at least one, Cer ostium
brachypetalum , to the British flora.

There would appear to be, for Bedfordshire, no perfectly satis¬
factory basis for a division of the county. Natural regions are
being used for all descriptive matter relating to the flora of the

72

county as a whole and to individual species. Records, which
should be related to boundaries that can be readily checked in
the field, are linked to the river drainage system. Yet a third
alternative, a purely artificial one based on a grid system, has
been rejected. Bedfordshire is a relatively compact county yet
it contains only five complete ten kilometre grid-squares and
parts of seventeen others.

Each county will have its own difficulties and the divisions
adopted in Bedfordshire would probably be of little use in an¬
other county. A simpler method could have been adopted by
resorting to compromise, all too readily adopted by Druce. A
basis, once adopted, should be worked out to its logical conclusion.
If the final choice is between alternatives each with defects and
virtues the basis of useful work already done, not only in the
county under consideration but in neighbouring counties, may
well be considered.

References.

Abbot, C., 1798, Flora Bedfordiensis. Oxford.

Babington, C. C., 1860, Flora of Cambridgeshire (Map). London.
Batchelor, T., 1808, A General View of Agriculture in the County
of Bedford (Map). London.

Dony, J. G., 1947, What Bedfordshire Is, Journ. Beds. Nat. Hist.
Soc., 1, 8-12 (Map).

Druce, G. C., 1902, Botany, V.C.H. Northamptonshire, 1 (Map).

- , 1904, Botany, V.C.H. Bedfordshire, 1, 37-67 (Map).

- , 1905, Botany, V.C.H. Buckinghamshire, 1.

- , 1926a, Botany, V.C.H. Huntingdonshire, 1.

- , 1926b, Flora of Buckinghamshire (Map). Arbroath.

- , 1930, Flora of Northamptonshire. Arbroath.

Evans, A. H., 1939, Flora of Cambridgeshire (Map). London.
Godwin, H., 1938, Botany, V.C.H. Cambridgeshire, 1.

Hillhouse, W., 1877, On the Surface Geology and Physical Geo¬
graphy of Bedfordshire, Trans. Beds. Nat. Hist. Soc.,
1875-6 , 83-91 (Map).

Hopkinson, J., 1905, Botany, V.C.H. Hertfordshire, 1.

Little, J. E., 1936, The Ivel District of Bedfordshire, B.E.C.
1935 Rep., 50-67.

Pryor, A. R., 1887, A Flora of Hertfordshire, edited by B. Day-
don Jackson (Map). London.

Saunders, J., 1911, The Field Flowers of Bedfordshire. London.
Watson, W. C. R., 1948, The Brambles of Bedfordshire, Journ.
Beds. Nat. Hist. Soc., 2, 21-25

Webb, R. H., & Coleman, W. H., 1839, Flora Hertfordiensis
(Map). London.

This paper was discussed as follows : —

Mr. Rose suggested that in dividing counties up into drainage
areas it might be desirable to treat the chalk, which had no sur-

73

face drainage, separately. Dr. Dony replied that he agreed that
chalk areas with few streams did provide a problem but he found
that he could deal wTith it satisfactorily by using the Catchment
Board’s map as a check on his own.

Mr. Brenan remarked that if each author of a county flora
adopts his own system it becomes difficult to make comparisons
between neighbouring counties. Dr. Dony said that he had this
point very much in mind but as the authors of three out of the
four neighbouring counties of which floras had been published had
adopted drainage areas, it seemed clear that to base the divisions
of Bedfordshire on these would not create any difficulties in mak¬
ing comparisons.

Mr. Rose said that while he could agree that drainage areas
provided suitable divisions for Midland counties he felt that in
S.E. England physical features, which are there much more pro¬
minent, were more satisfactory.

Mr. Meyer asked whether it was not advisable to use main-
roads, railways, electric grid wires, and similar features easily
traced in the field as boundaries for the divisions. Dr. Dony
replied that these were not sufficiently permanent for the purpose.

Mr. Wade pointed out that the division of counties into drain¬
age areas produced divisions of very varied sizes. In Monmouth¬
shire, for example, it resulted in very unequal divisions.

THE DISTRIBUTION OF BUNIUM BULBOCASTANUM

(Exhibit)

J. G. Dony.

Bunium Bulbocastanum was first discovered in Britain by W.
H. Coleman, who found it at Cherry Hinton, Cambs., v.-c. 29, in
1839. In the two following years he studied its British distribu¬
tion and found it to be common on the chalk in v.-c. 30, Bedford,
and v.-c. 20, Herts. In 1877, Newbould and Pryor recorded it
from v.-c. 24, Bucks. Its distribution and frequency have appar¬
ently remained constant.

It is found most abundantly in arable fields and in previously
disturbed soils; it is rarely found in well-established turf. It is
apparently found in similar habitats on the Continent.

Maps were exhibited designed to show three alternative
methods of plotting this distribution : —

(1) On a comital basis.

(2) On a grid basis.

(3) By indicating each recorded locality by a dot. (See map).

74

Fig. 17. The Distribution of Bunium Bulbocastanum.

75

Comparison of the three maps clearly demonstrated the rela¬
tive advantages of the methods employed. In the case of the
one using the grid as a base it seems likely that closer search in
some of the grid squares would give the species a continuous
distribution.

DISTRIBUTION MAPS OF KENT PLANTS

(Exhibit)

F. Rose.

In connection with work on a new Flora of Kent, a number
of distribution maps of species occurring in the county have been
prepared and it is hoped eventually to map the majority of the
species.

The distributions are plotted upon an outline map of Kent,
which shows rivers, a few of the main geological boundaries, and
the larger built-up areas. Copies of this have been duplicated for
use as a base-map.

The records for each species are collected in the first place in
a card-index, which includes : —

(a) personal field-observations.

(b) records from other sources.

These latter include records confirmed by herbarium specimens
and also other records of reliable origin.

Kind of Records Accepted.

In plotting the present-day distribution of a species, the first
category of records is regarded as of most value as:

(I) One can be certain of the plant’s present existence.

(II) The exact locality is known.

With records from other than personal sources, discretion has
had to be exercised in their use, as when they are old the plant
may be extinct in the given locality, and in other cases, the
locality may not be defined exactly enough for accurate mapping.
Unreliable records are not used in the maps.

Method of Plotting.

For each species, each acceptable record is marked by means
of a solid black dot; reliable localities now apparently extinct
are marked by black circles. In some cases dots of different
colours are used to show the distribution of related species on
one map. To fix the position of the dots, it was decided that
minute exactitude was not necessary for the purpose for which
the maps were intended. They are therefore sketched as accur¬
ately as can be judged by eye from the one-inch Ordnance sur¬
vey map.

76

B.

Fig. 18. Maps to illustrate Distribution in the County of Kent (Y.-cc. 15 and 16).

A. Aster Tripolium L— restricted to the coast and tidal estuaries.

B. Ilippocrepis cornosa L.— confined to the chalk.

77

Field Methods.

In making field observations to determine the distribution of
species within a county, two methods may be used.

1. The stand ” method, by which complete lists are made
of all the plants seen at a very large number of different points
throughout a county. This is the method so excellently employed
by Prof. Good in his Geographical Handbook of the Dorset Flora
(1949).

2. The method of searching all suitable localities for one, or
a few, species at a time.

Both methods have been attempted by me, the first for deter¬
mining general distribution of the commoner plants, and the
second in special cases — for certain rather local plants it gives
profitable results.

The Results Revealed by Plotting.

The production of a large number of detailed distribution
maps reveals many points of often more than local interest. In
a county like Kent with well-marked natural geological and geo¬
graphical divisions, most species, apart from a few that are
ubiquitous, show a definite distribution-pattern. The simplest
kind of distribution-pattern is that which is determined by soil-
types; for example, some species are confined to chalk, but are
there widely distributed in old grassland (e.g. Hippocrepis comosa
— Fig. 18b). Others are fully distributed on both the chalk and
calcareous ragstone, but are rare or absent elsewhere (e.g. Clem¬
atis Vitalba , Viola hirta).

The species which are confined to certain types of habitat
(e.g. littoral species, salt-marsh species) reveal this clearly on
their maps (e.g. Glaucium flavum; Aster Tripolium — Fig. 18a).

There is a large group which are widespread on all soils in
woodland districts, but avoid the marshland areas where wood¬
land is absent (e.g. Mercurialis perennis). Besides these simple
examples, there are many more complex types of distributions,
where (a) historical and (b) climatic factors would appear to have
an influence.

(a) In the first of these categories come such plants as Cam¬
panula glomerata, Dentaria bulbifera, Sium latifolium, which,
though locally frequent in certain areas, are absent from other
areas which are apparently quite suitable and similar ecologically,
(b) In the second class some species such as Ophrys sphegodes
and Smyrnium Olusatnim , although not strictly maritime, are far
commoner near the coast than inland : and V accinium Myrtillus,
concentrated in the west of Kent on high ground where rainfall
is somewhat higher.

Then there are species with a very local distribution focus
with no obvious ecological explanation, e.g. Thesium humijusum,
only in a few spots on the chalk near Canterbury, or Vicia syl-
vatica ; and some with two or more such local foci, e.g. Lathyrus

78

sylvestris, Carex helodes. Chrysosplenium oppositi folium occurs
only in those areas where permanently moist but well-drained
stream banks or springs occur, and thus is widespread in the
dissected, well watered Hastings Beds country of the Weald. It
also occurs elsewhere along the springlines at the junction of
pervious and impervious strata. Its distribution map is very
complex as a result ; besides the dry chalk and sand, both the
low-lying Weald Clay and the alluvial marshlands of the coast
are avoided, for in both there is a lack of permanently damp,
well-drained, shaded habitats.

DISTRIBUTION MAPS OF LINCOLNSHIRE PLANTS

(Exhibit)

Miss E. J. Gibbons.

Maps were exhibited to illustrate the distribution of the fol¬
lowing species in South and North Lincolnshire (v.-cc. 53 & 54) : —

(1) Tilia cordata Mill. Although this is given only for v.-c. 53
in Comital Flora , it is not uncommon in v.-c. 54 where there
are old woods.

(2) Sorbus torminalis (L.) Crantz. Given for both vice-counties
in Comital Flora in brackets (i.e. with doubt as to nativity
or identification) but herbarium specimens exist for v.-c. 53
and it is no doubt indigenous in three or four woods in v.-c.
54 where it has been found recently.

(3) Geum rivale L. Fairly common in suitable habitats.

(4) Oenanthe crocata L. Very rare in both vice-counties.

(5) Petasites hybridus (L.) Gaertn., Mey. & Scherb. Map to show
distribution of male and female plants — the former known
only from near Grantham. All colonies checked were found
to be female.

(6) Digitalis purpurea L. Rare in both vice-counties.

Paintings of Lincolnshire flowers executed from 1895 to 1903
by Mrs Cheales (nee Miss E. M. Lane-Claypon) were also ex¬
hibited.

79

•: NORFOLK O farhj

80

Fig. 19. The distribution, of Primula elatior in Britain.

Plate I

To face page 81

Tlie distribution of Primula clatior within tbo Western (smaller) District

(si'C Fig. 19. P SO).

THE DISTRIBUTION OF PRIMULA ELATIOR (L.) HILL

(Exhibit)

Doris and Harry Meyer

This exhibit included distribution maps, dried specimens,
coloured drawings and photographs of plants in situ of P. elatior
(L.) Hill and also of P. vulgaris Huds. and P. veris L. and their
hybrids.

P. elatior in Britain is confined to East Anglia (Fig. 19)
and, apart from a few outlying colonies, it inhabits two boulder-
clay plateaux separated by a chalk escarpment. The smaller of
these plateaux lies to the west of Cambridge and has been studied
in detail by the writers with results as shown on a specially drawn
coloured map on the scale of one inch to the mile (Plate I).

This map show’s 21 areas of woodland, presumably ancient,
as well as a number of plantations, in a district of predominantly
arable land. It was found that not only in each individual wood,
but also in the area as a whole, P. elatior tends to occupy the
wetter central parts, and P. vulgaris the drier marginal parts,
and the hybrids are found in between where the two species
meet. There are six “ pure oxlip woods ” mostly in the centre
and north, i.e. the highest part of the boulder-clay plateau ; seven
“ pure primrose wroods ” around the area ; and eight woods,
mostly in the south, with a mixed population of P. elatior , P.
vulgaris and the hybrids between them. In the plantations, both
species are almost entirely absent ; and this is taken as an indica¬
tion that both are slow to spread to new ground, P. elatior hardly
ever doing this.

P. veris is frequent both outside and inside the wroods and
plantations and its hybrid with P. vulgaris occurs in open rides,
etc. The hybrid P. veris x elatior has not been seen.

Larger scale maps (6 inches to 1 mile) had also been prepared
of each individual wood to show the various populations in con¬
siderable detail.

A similar investigation of the larger eastern district has been
commenced and a map showing first results was exhibited.

81

GEOGRAPHICAL DISTRIBUTION AND ISOLATION IN SOME

BRITISH ECOSPECIES

D. H. Valentine.

The hybridization of species, leading to the exchange of genes,
is hindered or prevented by barriers of isolation, which are of
various kinds. The aim of this paper is to estimate the extent
and relative importance of geographical barriers of isolation in
certain groups of British species. The species selected here are
of a particular kind. Often, when allied species meet, hybrids
are not formed, or if formed are sterile, and we can say that the
species are genetically isolated from one another. This may oc¬
cur for example with species which are not closely related taxo-
nomically, or which stand at different levels in a polyploid series.
Such species will not be considered here; for although compara¬
tive studies of their geographical distribution may be informa¬
tive, they have little relevance from the point of view of
geographical isolation. If on the other hand we select allied
species which are capable of forming at least a moderately fertile
hybrid, we can weigh the importance of geographical against
genetical and other modes of isolation; and it is some species of
this kind that we propose to examine. The relationship between
them has been defined as ecospecific, and they may be classed as
gradual-ecospecies, i.e. rather widely distributed groups having
the same chromosome number which differ in morphology, eco¬
logy and geographical distribution and between which some gene-
exchange is possible (Valentine, 1949).

In drawing up a list, certain groups have been omitted, some
because we have not enough information about them and others
because one of the species concerned is probably an alien. In
these categories are Medicago falcata and M. sativa (n=16) (Gil-
mour, 1932), Crataegus monogyna and C. oxyacanthoides (n=17),
Centaurea nigra and C. jacea (n = 22) (Turrill, 1940) and Linaria
repens and L. vulgaris (n = 6).

The groups which will be considered are listed in Table 1.
The nomenclature in the Table and throughout the paper is that
of the Check-List (Clapham, 1946); the chromosome numbers
quoted are to be found in the lists issued by Maude (1939) and
Love & Love (1948); details of geographical distribution are
taken from Meusel (1943), Hegi (1931), Druce (1932) and from
British local floras. For each pair of species, we shall give, first
details of experimental crosses, then the distribution of the species
in Britain and elsewhere, then the frequency of natural hybrids
and finally the nature of the main isolating factors, viz. geogra¬
phical. genetical, ecological or of some other kind.

82

Table 1. Pairs of gradual-ecospecies in the British Flora.

Names. Haploid Chromosome Number.

1.

Nuphar lutea , N. pumila

17

2.

Viola odorata, V. hirta

10

3.

Melandrium dioicum, M. album

12

4.

Silene cucubalus, S. maritima

12

**

o.

Geum urbanum, G. rivale

21

6.

Epilobium hirsutum, E. parviflorum

18

7.

Saxijraga spathularis, S. lacti flora

14 (probably)

8.

Primula vulgaris, P. elatior

11

9.

Salix caprea, S. viminalis

19

10.

Quercus robur, Q. petraea

12

1. Nuphar. Focke (1881) reports the extensive hybridization
experiments of Caspary, who showed that artificial hybrids had
a pollen and seed fertility of 5-15% of that of the parents; he
succeeded in making backcrosses. In Britain N. lutea is wide¬
spread and fairly common in lowland wTaters while N. pumila is
a local northern species, occurring only in Merioneth, Shropshire
and ten Scottish vice-counties. Both species extend across
Europe into Asia, but N. pumila is more northerly, and is absent
from the lowlands of Europe (Meusel, 1943). Thus, over fairly
large areas the species are geographically isolated. The hybrid
is not recorded from Britain, but it occurs in some quantity in
Sweden and Russia. Both Caspary and Samuelsson (1934) re¬
cord hybrids growing with one or both of the parents, and Cas¬
pary states that whole populations may consist entirely of
hybrids, thus indicating that the isolating factors other than
geographical are not very effective

2. Viola. Snow and Chattaway (1930) made the cross V.
hirta 9 x V. odor at a cf and obtained vigorous hybrids which
could be matched with wild plants and whose seed fertility was
about one- tenth that of the parents; an F2 generation was also
raised. Both species occur fairly frequently in England but be¬
come rarer in Scotland and are absent from the far North. V.
hirta is found mainly on calcareous soils, often in exposed grass¬
land, and is rare and local in Ireland, while V. odorata is found
on a variety of soils (Walters, 1946), often in shady situations,
and is frequent in central Ireland. In Europe V . hirta is gener¬
ally distributed ; it occurs as far north as S. Sweden but becomes
rare in the Mediterranean. V. odorata on the other hand is re¬
garded by Meusel as a Mediterranean species, doubtfully indigen¬
ous in many of its northern stations. It may be noted that V.
odorata is most abundant in Britain in south-west England and
that many local floras, particularly of the north, record doubts
as to its status. It thus appears that both ecological and geo¬
graphical isolation are effective locally ; but the species frequently
meet and flower together, and hybrids are widespread and not
uncommon.

83

3. Melandrium. An account of these species, including dis¬
tribution maps, has been given by Baker (1948). The species
are highly intercompatible and interfertile, so that there is little
or no genetical isolation. Both are found over the whole of
Britain. M. dioicum is typically a woodland plant which in¬
creases in frequency towards the north and west, while M. album
is a weed associated with human activity, most frequent in the
south and east of England. Both have a general European dis¬
tribution, but M. dioicum extends further to the north and M.
album further to the south and east, occurring in N. Africa and
Asia Minor, where M. dioicum is absent. Thus, as in the species
of Viola, both geographical and ecological isolation are locally
effective, but the species often meet. Differences in flowering¬
time and pollination mechanism are contributory isolating fac¬
tors, but hybridization often occurs, and in Britain at least,
hybrid swarms are found.

4. Silene. Extensive hybridization experiments by Marsden-
Jones and Turrill (1928-1950) have shown that these species are
highly intercompatible and interfertile. Both occur throughout
Britain; S. cucubalus is generally a lowland weed, thinning out
in the far north, while S. maritima is found on beaches and cliffs
round the whole coast, occasionally occurring also in the moun¬
tains (to a height of over 3000 ft. in Scotland). Outside Britain,

S. cucubalus is found throughout Europe and Asia, but S. mari¬
tima is restricted to W. Europe, from Finland and Norway to
Italy, Spain and the Canary Is. Thus, both geographical and
ecological isolation are effective; in W. Europe the species occa¬
sionally meet, but in spite of the weakness of genetical barriers,
hybrids are rare.

5. Geum. An account of the many experiments made on
these species is given by Marsden- Jones (1930), who also obtained
hybrids and showed that they were moderately fertile. (From
published accounts and our preliminary experiments, it appears
that the cross is successful only when G. urbanum is the female
parent, and that even then it gives by no means a full yield of
seed, so that genetical isolation is at least partially effective). In
Britain, G. urbanum, a plant of woodland and waysides, is com¬
mon practically everywhere in the lowlands; G. rivale, rare in
S. England, is frequent in N. England and gradually thins out
northward (see map) ; it is a plant of damp woods and hedges, but
it also occurs in exposed places on hills and cliffs (to a height of
over 3000 ft. in Scotland). (It may be noted here that the de¬
tails of distribution of G. rivale in many parts of Wales, Scotland
and Ireland are lacking; similar gaps occur in our knowledge of
the distribution of many other species). G. urbanum is found
throughout Europe and Asia and G. rivale covers a similar area,
but goes a little further north and also extends to N. America.
Thus, geographical isolation is not effective over most of the
range of the two species, and ecological isolation only partly so,

84

n‘ it* io'

• ?• r r r

VVL0NO 9* 6“ 7“ 6* 5* 4* )* V 1* 0° 1 E LONG

Fig. 20. Distribution of Geum rivale in the British Isles.

With acknowledgment to “ The New Naturalist ” for use of base-map.

85

but there is a difference in time of flowering. Where the species
meet, as they often do, hybrids are generally found, and are in
fact recorded from 85 vice-counties in Britain.

6. Epilobium. Compton (1913) and Geith (1924) have
crossed these species and obtained hybrids. As in many other
crosses in this genus, reciprocal hybrids differ in degree of infer¬
tility both on the male and on the female side; Geith obtained
different results from Compton, but both obtained seeds from
some of their hybrids. Both species are common in lowland
Britain in marshy places, and it is difficult to distinguish their
types of habitat, but E. hirsutum becomes less common in the
north. Both too have a wide general range throughout Europe
and W. Asia, but E. hirsutum extends further east and south,
to China and S. Africa. The hybrid occurs rather rarely in
Britain and occasionally in Europe. It seems likely that the
scarcity of the hybrid is due to the high self-compatibility and
low cross-compatibility of the species, for neither geographical
nor ecological isolation appears to be effective. It may be noted
that practically all the British species of the section Lysimachion
are capable of forming partially fertile hybrids; the two closely
related species described here have been selected as typical.

7. Saxifraga. Hybridization experiments by Dixon are re¬
ported and discussed by Scully (1916); reciprocal hybrids were
obtained. S. lactiflora has a restricted distribution in Kerry and
Cork, while S. spathularis has a wider distribution in S. and W.
Ireland where it is the commoner plant. It is remarkable that
the general distribution of the two species is very restricted and
apparently almost identical; both are regarded as native only in
N. Spain and Portugal, the Pyrenees and Ireland. Wild hybrids
resembling those produced artificially occur in W. Ireland, and
it was shown by Dixon that they were fertile. It is not possible
to say at present what are the main isolating factors in this in¬
teresting case; more work on the taxonomy and the cytology
of the species is needed.

8. Primula. A summary of hybridization experiments is
given by Valentine (1947); reciprocal crosses give about a 20%
yield of viable seed, and the seed and pollen fertility of the hybrid
is about half that of the parents. P. vulgaris occurs throughout
lowland Britain in woods and hedgebanks on a variety of soils,
while P. elatior, as was shown by Christie (1897), is restricted to
a small area in E. Anglia, where however it is abundant in damp
woods on calcareous clay. P. vulgaris occurs along the western
borders of Europe and in the Mediterranean, and is absent from
Central Europe (Hegi, 1931), but P. elatior occurs throughout
Europe and W. Asia, ascending higher than P. vulgaris, and
overlapping its range only in the west and south. Geographical
isolation is thus effective, but in the region of overlap hybridiza¬
tion may occur to a considerable extent (Valentine, 1948).

86

P. vulgaris also often hybridizes with P. veris\ here, to geo¬
graphical isolation of the same type as with P. elatior is added
more marked ecological isolation; there is also a distinct differ¬
ence in time of flowering.

9. Salix. Artificial hybrids between these taxonomically very
distinct species have been made by Wichura (quoted in Focke,
1881) and Heribert-Nilsson (quoted in Turesson, 1929). Wichura
found that reciprocal hybrids were identical and fertile and he
made backcrosses; Nilsson obtained a segregating F2 generation.
Both species are fairly common in Britain, S. caprea in woods and
hedges, S. viminalis in marshes and by streams, where it is some¬
times planted; and both occur throughout Europe and Asia,
though S. viminalis is less frequent in S. Europe. The hybrid
is found occasionally in Britain, being recorded from 31 vice-
counties, and is scattered throughout Europe; male hybrids are
said to be rare. Geographical isolation plays little part here but
ecological isolation is probably fairly effective.

10. Quercus. Experiments on artificial hybridization are re¬
ported by Focke (1881); some of the hybrids produced had nor¬
mal pollen. Dr. E. W. Jones informs us that recent experiments
by Dengler and others have shown that the cross is difficult to
make and that, generally, only about 1 % of the pollinations give
viable seed. Both species are widespread in Britain and Tansley
(1939) gives a good account of their distribution and ecology.
Q. robur is generally dominant on the damper, heavier soils, Q.
pelraea on the lighter and more siliceous soils, especially in the
north and west. The general distribution of the two species is
similar in Europe, but Q. robur extends much further east, into
Asia (Meusel, 1943). Wild hybrids occur in a number of places;
thus Tansley states that in certain localities in S.E. England the
species hybridize freely and produce a number of intermediate
forms. It is clear that geographical isolation is important over
only a part of the range of Q. robur. Where, as in Europe, the
species meet, ecological isolation is probably effective; but the
experiments that have been mentioned indicate that genetic
isolation, due to low interspecific compatibility, may also play
an important part. It may be noted that, in some of the other
examples quoted, insufficient information about compatibility
makes it difficult to estimate the importance of genetical isolation.

Discussion. The information that has been presented can
obviously be treated in a variety of ways, but this brief discus¬
sion will be limited to matters most closely concerned with geo¬
graphical distribution. It is based on the useful hypothesis that
pairs of ecospecies, of the type considered here, have arisen from
a single ancestral form whose area of distribution has been
divided into two or more parts. This primary geographical isola¬
tion leads to speciation; morphological divergence sufficient to
merit taxonomic rank occurs, but for a time at least, the new
species are capable of interbreeding and forming a moderately

87

fertile hybrid. In some cases, geographical isolation persists,
but in others, for various reasons, the species meet again in the
same area, and we have a situation which is illustrated by our
examples. Two points arise.

First, during the primary geographical isolation, the species
have come to differ in many ways, morphologically, genetically,
ecologically and so on. When they are brought together, these
differences may either be sufficient to ensure that the species will
persist as distinct entities, or they may be insufficient. If the
latter is true, the species will not normally be able to exist to¬
gether in the same geographical area, and will tend to fuse into
a single polymorphic population. The Nuphar species show this
tendency to fusion, and their maintenance as distinct species
must depend largely on geographical isolation ; but in the remain¬
ing examples, other forms of isolation are sufficient, in most cir¬
cumstances, to allow the persistence of the species as distinct
units even where they meet in the same area.

The second point is concerned with the discovery of the causes
which have led to the coming together of pairs of ecospecies in
the same area, i.e. to the breakdown of the primary geographical
isolation. There appear to be two main reasons. The first is
concerned with the effects of human interference. The fact that
many plants are comparative newcomers to the British Flora is
common knowledge; there is a continual influx of alien plants
due to the activities of man, who not only causes them to be
introduced, but also provides them with appropriate habitats in
places where he has destroyed the natural vegetation. It is pos¬
sible that both Silene cucubalus and Melandrium album fall into
this class; thus, Baker (1948) believes that M. album has come
into our flora in this way from its original home in S.E. Europe.
In other words, the breakdown of geographical isolation between
this species and M. dioicum has been artificial. In addition, de¬
struction of woodland has driven M. dioicum to refuges in hedge-
banks where it comes into contact with M. album, so that break¬
down of ecological isolation is also due to man’s activities; the
result is the very extensive hybridization which occurs in S.E.
England. In the case of the species of Silene, ecological isolation
has remained effective in spite of the breakdown of geographical
isolation.

The other main reason for the breakdown of geographical
isolation is provided by climatic change. During the last million
years, the whole of N.W. Europe has been subjected to a series
of glaciations ; there have been repeated and considerable changes
in climate, and large areas have been cleared of vegetation for
a time and then exposed to re-colonisation from the south and
east. Thus conditions in Britain have been such as to suit first
one species, then another, and the distribution we see now has
to be interpreted in the light of this past history. For example,
Primula elatior may occupy its present area as a result of a
primary invasion when conditions suited it, to be followed by P.

88

vulgaris when conditions changed ; or both invasions may have been
simultaneous, one occurring from the south and west, the other
from the east. At the present time climatic and other conditions
are such that the species are roughly in an equilibrium, which,
however, may shift in the future as these conditions change.
Similarly, Nuphar pumila has probably retreated north and west
in post-glacial times, to be followed by N. lutea; and the same
may be true of Viola hirta and V. odorata, the latter reaching
Britain only when the climate became warm enough, and spread¬
ing northward, at least to some extent, with the help of man.
Similarly, Geum rivale may have preceded G. urbanum. Hybri¬
dization between these pairs of species is still frequent, though
genetical isolation is important in all of them as well as ecological.
Speculation as to the original homes of the species, at a time
when geographical isolation between them was complete, is also
possible; e.g. Primula vulgaris may have originated in S.W.
Europe, P. elatior in E. Europe or W. Asia. In a number of the
remaining cases, of which the Epilobium species provide the best
example, practically all trace of the original geographical pat¬
tern has been lost, and the species have identical distributions
over the greater part of their range; and it seems likely that this
is related to their comparatively ancient origin, and to the re¬
peated changes and migrations which have since occurred.

We can sum up our discussion by saying that, with closely
related but taxonomically distinct species of the type considered
here (gradual-ecospecies), isolating factors are of various kinds,
but that, when only a small area, such as Britain, is considered,
geographical isolation rarely plays the leading part; and that
the extent to which the originally distinct areas of the species
overlap or merge is a function sometimes of human activities,
more often of climatic changes, recent or remote. If it were
possible to extend this discussion to groups of gradual-ecospecies
in relation to an extensive area, such as the whole of Eurasia,
it is probable that we should have to assign a much more im¬
portant role to geographical isolation ; but such a treatment must
be postponed until more genetical information, concerning a
variety of genera, is available.

May I, in conclusion, make a practical suggestion which is
relevant to the theme of this paper? I think it would be of use
if the Society were to sponsor the compilation and publication
of a list of the interspecific hybrids which occur in Britain and
of their geographical distribution. The great value of Focke’s
work on Die Pflanzen-Mischlinge, which was published in 1881
and dealt with all the hybrids of the European flora, leads me to
believe that a similar up-to-date work, even if confined to the
flora of Britain, would both stimulate interest and promote in¬
tensive and critical observation.

I am indebted to the New Naturalist for the use of their
standard map of the British Isles, and to a number of correspon¬
dents for helpful information.

89

References.

Baker, H. G., 1948, Stages in invasion and replacement demon¬
strated by species of Melandrium, J. Ecol., 36, 96.

Christy, M., 1897, Primula elatior in Britain (Its distribution,
peculiarities, hybrids and allies), J. Linn. Soc., 33,
72.

Clapham, A. R., 1946, Check-list of British vascular plants,
J. Ecol, 33, 308.

Compton, R. H., 1913, Further notes on Epilobium hybrids,
J. Bot., 51, 79.

Druce, G. C., 1932, The Comital Flora of the British Isles.
Arbroath.

Focke, W. O., 1881, Die Pftanzen-Mischlinge. Berlin.

Geith, K., 1924, Experimentell-systematische Untersuchungen
an der Gattung Epilobium L., Bot. Archiv, 6, 123.

Gilmour, J. S. L., 1932, The taxonomy of plants intermediate
between Medicago sativa L. and M. falcata L. and
their history in East Anglia, B.E.C. Rep., 10, 393.

Hegi, G., 1931, Illustrierte Flora von Mittel-Europa. Munich.

Love, A. & D., 1948, Chromosome numbers of northern plant
species. Reykjavik.

Marsden- Jones, E. M., 1930, The Genetics of Geum intermedium
Willd. haud Ehrh. and its back-crosses, J. Gen., 23,
377.

Marsden- Jones, E. M., & Turrill, W. B., 1928-1950, Researches
on Silene maritima and S. vulgaris, Kew Bull.,

Maude, P. F., 1939, The Merton Catalogue, New Phytol., 38, 1.

Meusel, H., 1943, V ergleichende Arealkunde. Berlin.

Samuelsson, G., 1934, Die Verbreitung der hoheren Wasserpflan-
zen in Nordeuropa, Acta Phytogeogr. Suec., 6.

Scully, R. W., 1916, Flora of County Kerry. Dublin.

Snow, R., & Chattaway, M. M., 1930, An artificial cross between
Viola hirta and Viola odorata, J. Bot., 68, 115.

Tansley, A. G., 1939, The British Islands and their vegetation.
Cambridge.

Turesson, G., 1929, Zur Natur und Begrenzung der Arteinheiten,
Hereditas, 12, 323.

Turrill, W. B., 1940, Experimental and synthetic plant taxo¬
nomy, in Huxley, J., The New Systematics. Ox¬
ford.

Valentine, D. H., 1947, Studies in British Primulas I: Hybridiza¬
tion between Primrose and Oxlip (Primula vulgaris
Huds. and P. elatior Schreb.), New Phytol., 46, 229.

- , 1948, Studies in British Primulas II: Ecology and taxo¬
nomy of Primrose and Oxlip (Primula vulgaris
Huds. and P. elatior Schreb.), New Phytol., 47, 111.

- , 1949, The units of experimental taxonomy, Acta Biotheo-

retica, 9, 75.

Walters, S. M., 1946, Observations on varieties of Viola odorata
L., Rep. Bot. Soc. 6c E.C., 12 (6), 834.

90

THE GEOGRAPHICAL DISTRIBUTION OF THE BRITISH SPECIES
OF THYMUS, AND A BRIEF ILLUSTRATION OF THE APPLICATION
OF DISTRIBUTIONAL STUDIES IN ECOLOGY

C. D. PlGOTT.

Thymus.

As, with the exception of a summary of Jalas’ paper on
Fennoscandinavian Thymus which has appeared in Wat sonia,
no account has yet been published in English literature, I
must begin with a short survey of the taxonomy in order to ex¬
plain the names I have used. At this point I must stress that my
exhibit is rather precocious, and that a great deal remains to be
done to show that all I shall say is supported by conclusive evi¬
dence — however, I have put it out with the hope both of stimulat¬
ing interest and gaining assistance.

At the present stage of my investigations it appears that three
distinct units in the genus Thymus occur in the British Isles.
These, as my exhibit is planned to demonstrate, differ from each
other in their morphology, ecology and geographical distribution.
Furthermore, cytological examination has revealed that these
three units are distinct in chromosome number and, I suspect that
owing to this dissimilarity and to the apparent rarity of hybrids,
they are genetically isolated. From the modem concept of the
species I therefore agree wth Dr. Jalas in regarding these three
units as specifically distinct.

These species can be separated by the following morphological
characters : —

a. Plant with ascending shoots arising from a central, tufted,
rooted portion, and with short runners. *Internodes of the
flowering stems goniotrichous, that is with the hairs arranged
in four rows along the comers of the stem, and the interven¬
ing faces almost glabrous. Inflorescence elongated and gen¬
erally interrupted below, in well grown specimens. Leaves
often quite large (up to 12 x 6 mm.), of rather thin consis¬
tency, with distinct petiole, and generally glabrous, rarely
hairy . T. pulegioides Linn.

aa. Plant extensively creeping, and the runners rooting freely at
the nodes. *Internodes of the flowering stems not gonio¬
trichous, but holotrichous or with alternate faces glabrous
and hairy. Flowers of the hermaphrodite plants with long
corolla tubes, and “showy”. Inflorescence generally more or
less capitate. Leaves small (seldom larger than 8x4 mm.),
rather thick, often spathulate, glabrous or hairy, and with
the nerves prominent on the lower surface in dried material,
b. Plant forming a rather loose, straggling cushion. The
lateral shoots along the runners tending to grow upwards
and the intemodes long. *Intemodes of the flowering

91

stems more or less terete, holotrichous with short, down-

curved, white hairs, evenly distributed .

T. Serpyllum Linn. em. Miller.

bb. Plant forming a compact, flat carpet. The lateral shoots
along the runners growing out horizontally, and the in¬
ternodes short, so that the leaves tend to form a close
mosaic. Leaves coriaceous, glabrous or hairy, some¬
times quite woolly. *Internodes of the flowering stems

Fig. 21.

North and West European distribution of Thymus Serpyllum L. em. Mill, subsp.

rigidus (Wimm. et Grab.) Lyka em. Jalas. Inset : Distribution in the British

Isles of Thymus pulegioides L.

*The lower internodes of the flowering stem must be examined, and the inter¬
node immediately below the inflorescence neglected.

X.R.— The growth habit characters refer to ungrazed plants, growing in open,
unshaded habitats It is of interest to note, with reference to the growth
form, that the common T. “ serpyllum ” of rock gardens, both in the British
Isles and on the continent, is T. Drucei, which, with its close, matted
growth, is most suitable.

92

quadrangular, with numerous, evenly distributed hairs
on two faces, and with the alternate faces glabrous, or

sometimes with a few, scattered, short hairs .

T. Drucei Ronn. em. Jalas
( = T. Serpyllum L. em. Fr. ssp. arcticus

(Dur.) Hyl. em. Jalas).

The most widespread species in the British Isles is the oceanic
Thymus Drucei Ronn. em. Jalas, occurring in Greenland, Iceland,
the Trondelag region of Norway, the Faeroes, Scotland, Ireland,
Wales and England, the wTest of France and perhaps the Pyrenees.
This species has a somatic chromosome number of 54 and may
be supposed to be of polyploid origin, and to some extent this
explains the great variability it displays. The plant is a frequent
member of the Atlantic heath formation on the less acid and bet¬
ter drained soils, and it occurs abundantly in limestone grassland ;
it is plentiful in the north and west of Britain but becomes rarer
eastwards in England. This is the T. Serpyllum of most British

Fig. 22.

World distribution of Thymus Drucei Ronn. em. Jalas.

93

authors and includes most of the Ronniger segregates as distin¬
guished in British material.

Thymus Serpyllum L. em. Mill, with a somatic chromosome
number of 24, is ecologically a member of the continental “ grass-
steppe-sand-heath ” formation. At present my studies have only
revealed its occurrence in East Anglia and Clare in the British
isles, and this may well be a reflection of its continental nature
although I expect it will prove to be more widely spread when
more material has been examined. In Europe the species is wide¬
spread in the east, becoming rarer westwards and absent from the
north of Sweden and the whole of Norway as well as the Faeroes,
Iceland and Greenland.

The third species is Thymus pulegioides L. which has a soma¬
tic chromosome number of 28 and is plentiful in England but
rare or absent in Wales, Ireland and Scotland. The continental
distribution is very difficult to unravel and I have not attempted
to exhibit a map. In England the plant is found both on the
chalk downs and in limestone grassland generally, as well as on
podsolised sandy heaths.

In conclusion with regard to Thymus may I add that the
separation of the species in starved or incomplete specimens is
often difficult, and that cultivation m garden conditions often
results in the most remarkable phenotypic changes. To quote
a writer in the Phytologist for 1853: “Should botanists not be
able to do so [identify them], the sheep will, being the better
phytologists : they will readily eat the one, but will not touch the
other, on account of its pungency ”.

Studies of Plant Distribution in a Very Small Area.

In order to fill up at least one gap I will now pass on to a brief
discourse on the value of studies of plant distribution in a very
small area in relation to ecology. Much has already been con¬
tributed by previous speakers which has a direct bearing on this
subject, and I should like to draw attention to the ecological data
which can be drawn from such studies as Professor Good’s book
on the Dorset flora, from which I have taken one example. (A
map of the distribution of Filipendula vulgaris was exhibited.)

Precise maps of the distribution of a species in a very small
area form a valuable method of recording and assessing eco¬
logical data in general, and to demonstrate this I have taken a
few examples from the work of Dr. Hugo Sjors on a bog complex
in Bergslagen, Dalarna, Sweden. A special area (300 metres by
350 metres) was chosen and the distribution of important species
mapped. The area consisted of two small *ombrogenous raised
mosses, parted by a central soakway of *soligenous fen passing
down into the marginal *eutrophic belt of *topogenous fen (called
the lagg). In the lagg were situated two small springs, where
water rich in base nutrients rises into the lagg.

*For defiition see Index.

94

Thus such an area contains a great variety of habitats, and
the different regions in which species occur demonstrate the con¬
ditions that they require. It must be borne in mind, howrever,
that each habitat includes a number of different conditions and
that these interact in such a way that the influence of any one
factor must be considered in relation to the others and cannot be
singled out. (Examples taken — Polygonum viviparum , Scheuch-
zeria palustris, C oilier g on sarmentosum, etc.)

To conclude, I will summarise by saying that the present
distribution of a species is a direct reflection of its ecology in
relation to the habitat conditions, both at the present day, and
in the recent past. Therefore a close study of autecology is essen¬
tial for a full appreciation and interpretation of a species’ distri¬
bution, and the converse is equally true.

*Bccher, T. W., 1938, Biological Distributional Types in the
Flora of Greenland, Meddelelser om Gr&nland, 106.
Good, R., 1948, A Geographical Handbook of the Dorset Flora.
Dorchester.

*Gr,0NTVed, J., 1942, The Pteridophyta and Spermatophyta of
Iceland, Botany of Iceland, 4, Part I. Kobenhavn.
*Hegi, G., 1927, Illustrierte Flora von Mitteleuropa, 5 (4). Miin-
chen.

Jalas, J., 1947, Zur Systematik und Verbreitung der Fenno-
skandischen Formen der Kollektivart Thymus
Serpyllum L., em. Fr., Acta Botanica Fennica, 39.
(Abstract in Watsonia, 1, 173-4.)

- , 1948, Chromosome Studies in Thymus, Hereditas, 34.

Jorden, G., 1853, Thymus Serpyllum and T. Chamaedrys, The
Phytologist, 4, 1142-3.

*Mortensen, K. F., 1872, Nordostsjaellands Flora, Bot. Tidskr., 5.
*Rouy, G., 1927, Conspectus de la Flore de France. Paris.
Sjors, H., 1948, Myrvegetation i Bergslagen, Acta Phyt. Suec.,

21.

This paper was discussed by Dr. D. P. Young who suggested
that the observation reported in the Phytologist to the effect
that sheep will eat one species of thyme and not another should
not be lightly dismissed. He thought that taxonomists might
with advantage pay more attention to biochemistry. However,
terpenes may not be a reliable guide in this respect, as the same
species growing under different conditions may yield oils of sub¬
stantially different composition. Alkaloids seem to be much
more specific, and a difference in the type of alkaloids present in
a plant would be good support for taxonomic separation. Mr.
Pigott replied that he had quoted the report as a matter of in¬
terest but he thought there was considerable doubt about the
ability of sheep to discriminate between species of Thymus.

*Used for data employed in preparation of the maps reproduced.

95

A HISTORICAL APPROACH: SOME LATE-GLACIAL SPECIES
FROM THE LOWER TEES AREA AND THEIR PRESENT

DISTRIBUTION

Kathleen B. Blackburn.

I fear I must apologise to those members of my audience who
make a serious business of mapping plants for a somewhat mis¬
leading title. I am really going to try to show how modern
methods, particularly pollen statistics, have improved the possi¬
bilities of the historical approach to the subject of plant distribu¬
tion.

The peg on which I propose to hang my remarks is a brick-pit
at Neasham, near Darlington, in which, some time ago, an almost
complete skeleton of an Elk or Moose ( Alces alces or A. malchis)
was discovered embedded in peat. The deposit was examined
at the time but is now being re-investigated. Since the locality
is relatively close to the area in which the notable rare plants of
Teesdale occur to-day, the study of the plant remains at Neasham
has a considerable added importance beyond its intrinsic interest.

Attention was first drawn to the Neasham locality by the dis¬
covery of the elk bones. The elk is not an extinct animal like
the Irish giant deer: it occurs to-day, both in Europe and
America, so we can find out something of its habits. One thing
about this large, heavy, deer-like animal is its great fondness for
water : apparently its food largely consists of plants growing in
and near lakes and for this reason it often ends its days by drown¬
ing; as, apparently, did the elk at Neasham. The walls of the
pit in which it was found consist of a red clay from which bricks
are made and running through it is a peaty band. This band
widens out at one place to a depth of about three feet and at the
same time dips, once, no doubt, a deep place in a pool into
which the elk stumbled and fell. A great deal of the importance
of this find lies in the possibility of dating it, and it is the peat
that must date the elk, rather than the reverse, since there are
recorded occurrences of this animal in Scotland up to the 9tli
century (Ritchie, 1920).

A cleared face of the pit at this locality shows the red boulder
clay at the base gradually becoming slightly laminated, indicat¬
ing the beginning of water action, and then changing to a blue-
black colour. Throughout this black clay are rhizomes, leaves
and seeds of Potamogeton praelongus in extremely good preser¬
vation. Above is the peaty pond-bottom mud, here consisting of
three layers. The bottom one, which at the right stage of drying
will peel off in the thinnest layers like fine tissue paper, contains
large numbers of diatoms and green algae, chiefly desmids, and
small quantities of the seeds of Potamogeton praelongus and
other water plants. Immediately above this is a very elastic mud
with considerable mineral content. The third layer might be
considered a real peat for it consists chiefly of the stems and

96

leaves of Hypnum scorpioides. At various places in the quarry
this mossy peat was found to contain large quantities of seeds,
fruits and leaves from which the vegetation of the pond and
neighbourhood could be reconstructed. Water plants were com¬
monest and included Carex rostrata, species of Myriophyllum ,
species of Potamogeton , Ranunculus aquatilis agg., Menyanthes
trifoliata, Equisetum limosum, Chara spp. and a Nitella. Of land
plants the following were found: Salix herbacea and S. phylici-
folia, Betula pubescens and B. nana, Juniperus, Arctostaphylos
Uva-ursi , a Vaccinium and a fruit of some member of the Composi-
tae which has, so far, not been matched among British species :
one of the difficulties encountered in this technique is that of iden¬
tifying species with certainty from seeds or even leaves.

The clay immediately above this peat contains most ol
the water plants mentioned above in small quantity, also Selagin-
ella megaspores, an Armena fruit and Salix herbacea leaves. For
the first discovery of these I have to thank Mr G. F. Mitchell,
M.A., of Dublin, wTho recently visited Neasham. Salix phylicifolia
and Betula nana also occur there. It will be noticed that Salix
herbacea and B. nana are plants which do not grow in Upper
Teesdale now, though the other land plants mentioned do.
Above these deposits is clay, amorphous and barren below, but
laminated above and with layers of remains of Myriophyllum
verticillatum and Potamogeton. Still further up is a structure¬
less peat yielding results only to pollen analysis.

Let us for a few moments remind ourselves of the methods
and possibilities of pollen analysis or, as it is frequently called
nowadays, “ palynology ”. The technique has been most used for
studying the changing forest flora in post-glacial time and con¬
sists of counting the pollen which is preserved in peat at a series
of levels in the deposit, expressing the quantities of pollen of
different trees as percentages of total tree pollen and deducing
the forest succession of the area from these results. A diagram
from a peat near Ridsdale in the County of Northumberland, some
45 miles further north than Neasham, represents the whole period
from the end of the ice-age till the present time. Besides illus¬
trating the characteristic regional forest succession, conforming
well with the zonation worked out for England in general (God¬
win, 1940), this diagram includes the amounts of the most fre¬
quently occurring herbaceous plants as percentages of the tree
pollen. It is thus possible to discover when the county was com¬
pletely forest covered, and when it was more sparsely wooded, by
comparing the percentages of tree pollen and non-tree pollen at
the different levels.

Recognition of less frequent constituents of the pollen-rain
is frequently useful in indicating the local conditions, as well as
giving evidence of the distribution of individual plants in past
times. In the peat mentioned above the occurrence of Typha
pollen illustrates the former and of Polemonium in the earliest
post-glacial layers the latter.

97

We must now consider the results of examining the pollen
from the Neasham exposure which are illustrated in Fig. 23.

The junction of the upper clay and the upper peat seems to
correspond to the long recognized period at which alder per¬
centages rise suddenly from low values to high ones. This is
usually referred to as the Boreal- Atlantic transition of the Blytt-
Sernander terminology and is represented in Dr. Godwin’s (1940)
zonation as the VI- VII boundary. The upper peat thus belongs
to the forest period and is very rich in tree pollen, chiefly oak and
a]der, but elm, birch and lime are also present.

The lower peat, in which the elk was found, is comparatively
poor in quantity of pollen and the tree pollen is chiefly birch,
whereas the clays above and below it are very poor indeed and

EEPTH PERCENTAGES or TOTAL. TREE VOLLEN

'* ■ — i — i — i i i ittt i i i i i i i i — (“i n i — iiii n i i i i i i i i r~ n — tttt i — i — i — i — i — i — i
--Q JO »0 60 60 IOC 0 20 to 60 800 5 0 20 1.0 05 0 30 »0 60 30 10 60 600 400 IQO 0

cns. birch pine. elmoak lime mder

££TULA P/A/US ULAUS QU£PCUS J1LIA f\LNUS

y i i i i i i i i > ■ i i ■ ■ ' i i i i i u ■ ' ■ ■ ' u i i i i i j
' 0 SO 100 0 SO JSQOS 0 1,0 os 0 SO 7 0 0

WILLOW-®- HAZEL— HERBS
SALIX CORYLUS

llii i-±-

S0 600

MO

Fig. 23. Pollen Diagram of Late-Glacial Peat from Brick-Pit at Neasham, near

Darlington.

98

the tree pollen is mainly pine. In the clays, non-tree pollen,
chiefly grass and sedge, predominates, whereas in the peat birch
grains are in the majority. This poverty of pollen might suggest
that growing conditions were not good but the implication from
my title that the deposit belongs to the end of the ice-age, and
not to post-glacial times, needs further consideration.

We must remind ourselves that pollen analysis is a statistical
method which depends for its conclusions on the fact that it is a
regional study, and consider the results obtained by investigations
of the final stages of glaciation in N.W. Europe. There, in many
ways, the retreat stages of the last ice-age are clearer, and to them
we must look for our geographical evidence.

The last advance of the ice sheet which covered Scandinavia
is indicated by a series of terminal moraines, referred to as the
Fennoscandian line, passing over parts of S. Sweden and appear¬
ing again in Finland, as the name suggests. The rapid retreat
from this line is considered the beginning of post-glacial time.

De Geer, studying layers of clay deposited in the deltas of
glacial lakes, noticed laminations which he referred to as varves.
He believed these to be annual deposits and by skilful piecing
together of successive depositions came to the conclusion that
the time of the moraines was from 8300-7874 B.C.

The west of Denmark was not covered by the last advance of
the ice, but the evidence of frozen soils shows that arctic con¬
ditions returned to a land which was beginning to warm up
and change from tundra conditions to open birch forest. Strati-
graphically this temporary warm period is often shown by an
organic deposit, such as a lake mud, separating two layers of
varved clay. This succession was first observed at a place called
Allered and is referred to as the Allered oscillation. On the con¬
tinent the arctic nature of the top and bottom layers, which are
referred to as periods I and III, is shown by the presence of
Dryas (Dryas clays). A map illustrating the general distribu¬
tion of the known Allered deposits will show them chiefly in
Denmark and the southern shores of the Baltic Sea, but a con¬
siderable number are now recorded for Ireland, for which we are
indebted to Prof. Jessen and Mr. Mitchell. In Ireland there is
however a difference; the arctic clays seldom show Dryas ; their
characteristic plant is Salix herbacea. Now if you look at the
Neasham diagram you will see that we have, below, a similar
succession: clay, pond peat, clay; and, above, more peat. Such
oscillations have occurred through the whole Ice age and care is
necessary. Prof. Jessen realized this and, when describing the
deposits at Ballybetagh, is cautious about correlation, but after
studying many more deposits and noticing that the association
of plants in the two areas was astonishing similar, he now
considers the Irish oscillation to be equivalent to the Aller0d on
the continent (Jessen, 1949). Perhaps the case may be compared
to the post-glacial correspondence of forest succession through
the same areas. Just as in post-glacial time there are differences

99

between E. and W. and between N. and S., due to geographical
causes, so also in late glacial time differences are to be expected.
Firbas (1939) lias pointed out that at the time when N. Germany
and Denmark were in a tundra condition with no trees, the land
to the E. and W. of the ice-covered Alps carried birch and pine
forest of varying density whereas further south deeiduous forest
occurred. The tundra condition followed up the retreating ice and
the region of birch scrub also moved north in time of increased
warmth and both retreated when the ice readvanced. This oscilla¬
tion is just what is found in the deposits of the Alien: d type:
Periods or Zones I and III represent tundra conditions in our lati¬
tudes with the characteristic plant either Dry as or Salix herbacea
and no trees. Zone II, the Allered itself, is a warmer phase in which
there is evidence of considerable quantities of Betula pubescens.
There were also many more species of herbaceous plants at this
time. Considering the Neasham deposit, besides the plants
already mentioned as discovered from macroscopic remains, there
are two, of exceptional interest, found by means of their pollen
grains alone: Helianthemum canum and some species of Artc-
misia. The significant point of the total list from Neasham is
that almost all of the plants identified are characteristic of the
Allered oscillation elsewhere and this gives some further justifi¬
cation for the assumption of this dating for the peat. One puzzle
is provided by the occurrence of small quantities of the pollen of
hazel, which certainly would not be expected to grow there in
Allercd times. Its presence can only be explained by suggest¬
ing that it has blown very long distances from S. Europe, just as
jDine pollen found in Zones I and III is assumed to have done in
most of the profiles containing Altered deposits.

Now considering the present distribution of the plants re¬
corded from the Neasham brick-pit we find that only three do
not at present grow in Teesdale — Potamogeton praelongus ,
Betula nana and Salix herbacea, though all are found in the
British Isles to-day. On the other hand Dry as octopetala which
is characteristic of the Arctic beds Zones I and III on the con¬
tinent has not, so far, been found*, yet it grows on Cronkley Fell,
in Teesdale, to-day, in company with Helianthemum canum.

If we look at present world distribution for the plants in¬
volved there are notable differences between them.

Most of the species recorded for Neasham have an arctic area
of distribution and most occur in Iceland and Northern Scan¬
dinavia, but, on the other hand, all are now living somewhere in
the British Isles. The most extreme Arctic-alpines are Betula
nana and Salix herbacea. Salix phylicifolia and Selaginella
selaginoides are among the sub-arctic forms with alpine distribu¬
tion (Jessen, 1949).

There is a group of Arctic- Subarctic species widespread in
Europe and, as Jessen points out, reaching above the birch zone

*Two fruits of Dryas have since been found by Mr. G. F. Mitchell.

100

in the mountains of Norway: among these are Juniperus , Meny-
anthes, Armeria, Car ex rostrata and Myriophyllum spicatum.
Some reach the arctic circle though not the mountains of Nor¬
way; to these belong Potamogeton natans and P. praelongus.
Two remaining plants of the Neasham deposit do not come into
the category of arctic plants. The species of the Artemisia is
difficult to determine, but none of the likely species occurs in the
arctic, and it is much more probable that it is a species of the
steppes with its main distribution now in Central Asia.

The Helianthemum canum at first seems more definite, but
again, it is only an aggregate name for a group of species. The
pollen of H. canum has not so far been distinguished from that
of H. oelandicum, the endemic species of Oeland, and a map of
present localities must perforce include even the Mediterranean
subspecies, although the more northern forms are the likely ones
and the Neasham one, in particular, may well be the H. canum
var. vineale of Cronklev Fell.

What then can be deduced from the late-glacial fossil plant
and animal remains concerning the landscape of that day?

Iversen, describing conditions on the continent, sees a narrow
band of real tundra behind the advancing ice, though he thinks
that perhaps it was not as cold as the tundra we know. Behind
that, “ park-tundra ” was found with patches of birch trees at
more and more frequent intervals of gradually becoming real
birch forest. In the park- tundra the open land between the trees
carried a variety of plants and in many places probably not in
closed communities. The vegetation seems to have had some of
the characters of tundra, large amounts of grass suggestive of
steppe and some of the features of the alpine flora of central
Europe. Steppe animals, Bison, Elk and Irish Giant Deer,
roamed in this park-tundra and only disappeared with the ap¬
proach of closed forest.

Iversen’s picture for the continent can be applied to the Tees-
dale area to give a picture of its changing flora. The land exposed
after the retreat of the ice was covered with a tundra vegetation
between the numerous lakes in which Potamogeton praelongus
was a conspicuous feature. Later the climate improved and, in
addition to the surviving Salix herbacea, Betula nana and other
tundra plants, a scrub of Betula pubescens, Salix phylicifolia,
Sorbus aucuparia and Juniperus appeared with Arctostaphylos
TJva-ursi, Vaccinium, Armeria, and Helianthemum growing be¬
tween the trees. A return of cold conditions killed off the less
hardy plants, and in particular the Betula pubescens, giving
tundra conditions once more. The final warming up of the clim¬
ate finds the Neasham site covered with oak-alder forest in close
stand; the plants of open habitat and of arctic-alpine type have
disappeared and have only survived in the upper reaches of the
Tees where they remained undisturbed in a habitat favourable
to them.

101

References.

Firbas, F., 1939, Vegetationsentwicklung und Klimawandel in
der mitteleuropaischen Spat- und Nacheiszeit,
Naturwiss ., 27 , Heft 6.

Godwin, H., 1940, Pollen analysis and Forest History of England
and Wales, New Phyt., 39, No. 4.

Jessen, K., 1949, Studies in Late Quaternary Deposits and Flora
History of Ireland, Proc. Roy. Irish Acad., 52, B,
No. 6.

Jessen, K., & Farrington, A., 1938, The Bogs of Ballybetagh,
near Dublin, with remarks on Late-Glacial Condi¬
tions, Proc. Roy. Irish Acad., 44, B, No. 10.

Iversen, Johs., 1945, in The Bison in Denmark, Dan. Geol.
Unders., 2, Nr. 73.

Mitchell, G F., 1940, Studies in Irish Quaternary Deposits,
some lacustrine deposits near Dunshaughlin, County
Meath, Proc. Roy. Irish Acad., 46, B, Nr. 2.

Ritchie, J., 1920, Influence of Man on Animal Life in Scotland.
Camb. Univ. Press.

This paper was discussed by Miss Longfield. She said that
although the American Elk or Moose ( Alecs americanus) is ex¬
ceptionally fond in summer of aquatic vegetation for food, both
it and the European Elk (A. machlis ) spend the greater part of
their lives in forests, feeding on the buds, twigs, leaves and bark
of both coniferous and deciduous trees; the European Elk, at
least in Scandinavia, frequenting rather dry woods and browsing
often on young maples. She therefore considered that it would
not be peculiar if hazel pollen were found in the same deposits
as the Elk skeleton as presumably its feeding habits had been
much the same as those of the present-day species.

THE SEQUENCE OF THE PLIOCENE AND PLEISTOCENE BRAMBLE
FLORAS IN *PERIGLACIAL S.E. ENGLAND

(Exhibit)

W. C. R. Watson.

The line followed in this investigation was to find datable de¬
posits or geomorphological features of Pliocene and Pleistocene
age; to identify the bramble species now growing upon them; to
discover the distribution of those species in Britain and on the
Continent; and then, taking into account the observed means of

*Periglacial— lying beyond the limits reached by the ice-sheet at its maximum
extension.

102

migration and fecesis, to consider to what conclusions the evi¬
dence pointed.

At the Conference lists of the significant species were shown,
together with a few selected specimens and a geological section
from the Weald watershed to the Pliocene R. Thames running
into the North Sea at the R. Blackwater estuary in Essex.

Pliocene.

Relict floras were found : —

1. On the Forest Ridge around and to the south of Tunbridge
Wells, on Waterdown Forest and Ashdown Forest.

2. On the Lower Greensand Range of extreme E. Surrey and
W. Kent at 500-700'.

3. On the North Downs and Lower London Tertiaries above
the Lenham Sea coast-line; on the actual Lenham deposits
where they still remain; and on the Eocene beds from
which the Pliocene deposits have been denuded, down to
250'.

4. On isolated hilltop Lenham gravel deposits in N. Kent and

S. Essex, especially Shooter’s Hill (424 ).

A greater amount of Continental influence is evident in
E. Kent.

5. On and near the Lenham deposits on the Downs east of
the R. Stour at OOO'-SOO' ; and also, especially,

6. On a late Pliocene southern drift at 250' around Bigbury
and Chartham Hatch.

Pleistocene (Interglacial and Jinterstadial).

7. The species occurring on the four successive Lower Thames
Gravel terraces in Bucks, Surrey and Kent were listed at
nine localities.

Observation in nature and experimental culture, in shade and
in exposed situations, on clay and on sand, supplied information
as to the effects of frost and snow, heat, drought and excessive
moisture upon seeds, seedlings and mature plants. Brambles are
pre-eminently forest plants and there can be no doubt that from
several causes the Forest Ridge and the Greensand supply ideal
conditions for their growth. Continental and home ranges and
stations of the species concerned were considered.

The facts found are consistent with the preservation of many
Pliocene species on the geological levels given under 1 to 6 above.
Their antiquity is sometimes attested by their occurrence as out¬
liers separated from the main mass by barriers subsequently but

tEcesis — the germination of a seed after its arrival in a new area, its develop¬
ment tO’ a mature plant and its multiplication into a family of descendants.

jinterstadial— the temperate interval coming between the advance and re¬
advance of the ice-sheet within each of the series of Pleistocene glaciations.

103

anciently created; and by the absence of the distinctively Pleis¬
tocene species.

Some of the characteristic species have been looked for and
found at comparable geological horizons on the Chilterns, in
Savemake Forest, and on the Wiltshire Downs.

On the Forest Ridge and more particularly on the Greensand
and Pliocene hilltop gravels there are many links with the West
of England bramble flora, suggesting a former continuity of dis¬
tribution, now broken by the S. Hants. -Surrey flora which is in
sharp contrast with that of W. Kent.

THE DISTRIBUTION OF THE DIGITALIS PURPUREA COMPLEX

(Exhibit)

V. H. Heywood.

The genus Digitalis shows two main centres of development —
west Mediterranean (Iberian) and east Mediterranean (Balkan-
Anatolian). In the west the D. purpurea aggregate comprises the
major part of this development.

It is not often realised that the D. purpurea of this country
is only one segregate of a wide-ranging species. The following
table sets out the components of the purpurea complex and their
distribution :

Segregate

D. purpurea L., sensu lato
ssp. purpurea
var. purpurea

f . alpina Rivas Goday
var. gyspergerae (Rouy) Burnat
var. nevadensis (Kunze) Amo
var. albarracinensis Pau & Senn.
var. tomentosa (Hofm. & Lk.) Brot.
var. mauretanica Humb. & Maire
var. toletana Font-Quer
ssp. mariana (Boiss.) Rivas God.
ssp. thapsi (L.) Font-Quer
D. dubia Rodriguez
D. amandiana Sampaio
D. miniana Sampaio

Distribution.

W. & C. Europe, N. Africa

Throughout the species’
range

Spain, Portugal
Corsica, Sardinia
S. Spain (Sierra Nevada)
N.E. Spain
Portugal, Spain, Italy
N. Africa
C. Spain

S. Spain (Desperiaperros)
Portugal, Spain
Balearic Is.

Portugal

Portugal

Rivas Goday (1946) has suggested that this array of variants
has been derived from a Tertiary archetypal form by three series
of migrations: an Atlantic, a Tyrrhenic, and a Balearic. The
first of these engendered, inter alia, var. purpurea.

104

In the British Isles only var. purpurea, the typical form,
occurs ; it is essentially oceanic in climatic-type and is oxyphilous,
but the evolutionary development in the Iberian Peninsula has
been towards xeromorphy (var. tomentosa, ssp. thapsi, ssp. mari-
ana), and one form, D. dubia, is a calciphile.

The two varieties referring to stem indumentum of plants in
this country (var. nudicaulis, var. pubescens) should be noted ; a
summary of the other minor variants occurring in this country
is given by Turrill (1948). These are, however, forms of the typi¬
cal race of D. purpurea.

This type of distributional pattern — of a wide-ranging poly¬
morphic species represented by only one race in this country —
is not uncommon. Attention is drawn to it as it is thought that
it might help towards solving some of our distributional pro¬
blems if more consideration were given to the extra-British dis¬
tribution and variation of the species of our flora.

Specimens and figures of most of the above forms were ex¬
hibited together with a table showing the distribution of the
whole genus.

References.

Rivas Goday, S., 1946, Sobre la Habitacion de la Digitalis pur¬
purea L. (sensu lato), Anal. Inst. Mutis Farmacogn.,
5, 9, 123. Madrid.

Turrill, W. B., 1948, British Plant Life, 226. London.

THE TOPOCLINE IN ULMUS CORITAN A Melville

(Exhibit)

R. Melville.

The Coritanian Elm is an example of a plant in which con¬
tinuous variation occurs within the natural range of distribution
of the species. This variation does not occur haphazardly but
follows a regular topographical sequence, and is conveniently re¬
ferred to as a topocline. That is not to say that every individual
in any one locality will be of the same form, although on occasion
this may be so, but rather that the nature of the population
changes in a fairly regular manner as one proceeds across the
range of the species in a particular direction.

In Ulmus coritana slightly asymmetrical round-leaved forms
occur in the southern parts of the specific range in southern Essex
and to the north of London. Strongly asymmetrical narrow¬
leaved forms are found in the central and northern parts of Nor¬
folk. Forms with leaves of intermediate shapes occur in the inter¬
vening region and to some extent mingle with the narrow-leaved
forms in the north and the round-leaved forms in the south.

105

Fig:. 24. The end and middle terms of the topocline in Ulmus coritana are repre¬
sented by these short shoots from var. rotundifolia (left), var. angustifolia (right)

and var. media (centre).

var. media

Fig. 25. A series of leaf shapes calculated from the mean leaf shape of subdistal
leaves of Ulmus coritana var. media Melville (100) forming part of an arith¬
metical series differing only in breadth. The numerals indicate percentage

breadths.

Fig. 26. A series of leaf shapes calculated from the mean shape of subdistal
leaves of Ulmus coritana var. rotundifolia Melville (R), illustrating the nature
of the differences in leaf . shape between var. rotundifolia and var. media.

The Topocline in Ulmus coritana Melville.

Reproduced with permission from Journ. Linn. Soc., Botany, 53. 263-271, 1949

106

Narrow-leaved forms have not been found, so far, in the south,
nor broad-leaved forms in the north.

A series of herbarium sheets was exhibited to demonstrate
the changes in leaf-shape correlated with the distribution of the
species in East Anglia. This was supplemented by the distri¬
bution map and the drawings used in illustration of the original
description of U. coritana in J. Linn, Soc., Bot., 53, 263-271, 1949.
The existence of a wide range of intergrading forms within a
species may provide a difficult problem for the taxonomist. It is
obviously impracticable to describe every form. Where, as in U.
coritana, the sequence of variation is linked with distribution, it
can be described as a topocline, which may be sufficiently defined
by stating its limits and the mean. This plan was carried out
by describing a typical median form as var. media, while the
round-leaved and narrow-leaved ends of the sequence were de¬
fined as var. rotundifolia and var. angustifolia respectively.

The characteristic leaf shapes occurring on normal short shoots
of the three varieties are shown in Fig. 24. The leaves are
of a bright, rather yellowish-green and somewhat coriaceous
in texture. The serrature is rather blunt and axillary tufts of
hairs are usually well developed in the vein axils along the midrib
on the lower surface of the leaf. In habit, the tree is rather
spreading, with ascending to spreading branches well spaced and
giving a more or less open crown.

For the purpose of studying the variation, measurements were
made of the distal and subdistal leaves (i.e. the apparently ter¬
minal and the next below it) of normal short shoots of a number
of individuals by a method earlier described (Ann, Bot., Lond.,
n.s. 1, 673, 1937). The mean leaf shape of subdistal leaves of the
type tree of var. media is shown in Fig. 25, the outline being drawn
to pass through the tips of the serrations. The forms linking var.
media with var. angustifolia differ mainly in the breadth of the
leaf. Once the coordinates needed to define one of these leaf
shapes have been obtained, it is a simple matter of proportion to
alter the breadth without altering the other elements of the leaf
shape. The outlines in Fig. 25 form part of an arithmetical series
calculated from the mean shape of var. media as 100. The 60 per
cent, member of this series closely resembles the shape measured
from the type of var. angustifolia.

The transformation of the leaf shape of var. rotundifolia into
something resembling that of var. media is slightly more involved.
Here the most striking difference is a marked increase in the
asymmetry of the lower half of the leaf while the upper half and
the relative breadth remain almost unaltered. Supposing the
leaf were elastic and decreased regularly in elasticity from the
base to the apex, the effect is such as one would obtain by hold¬
ing the tip and pulling the petiole to increase the length of the
leaf. Such treatment would cause the base to elongate much
more than the apex. In treating the problem mathematically, it
was assumed that the extension decreased logarithmically from

107

base to apex. The effect of applying different logarithmic factors
without altering the breadth measurements is shown in Fig. 26.
When the factor J is used a close approximation to the shape of
var. media is obtained and by adjusting the breadth measure¬
ments in arithmetic proportion, as at M, the shape is a very close
fit to the measured shape of var. media in Fig. 25.

The control of leaf shape within the plant is, presumably,
governed by a balance of growth-promoting hormones. Evidently
different growth balances are reached in different individuals. In
U. coritana the balance of growth factors appears to change in a
comparatively regular manner as one passes across its territory
from north to south. One would suppose that environmental
factors must be in some way responsible for the changes. What
these factors are is an open question. Changes in temperature,
rainfall and other meteorological factors, across such a compara¬
tively small distance as the 100 miles or so of English countryside
in which the cline occurs, do not seem to provide an adequate ex¬
planation. Nor have I been able to link up any soil changes that
might be responsible.

THE ANTARTIC ORIGIN OF SOME BRITISH “ CARICES ”

(Exhibit)

E. Nelmes.

The word “ Carices ” in the above heading is in quotes, be¬
cause if my theory of their Antarctic origin be correct they are
not true Carices but derived from Uncinia or uncinioid ancestors.
The species under consideration are Carex microglochin Wahlenb.
and C. pauciflora Liglitf.

The genus Uncinia is a very natural one. There are about
thirty known species and they all have a terminal, unispicate,
androgynaeceous inflorescence, their utricles are usually nerve¬
less, often with a plumbagineous surface, often gradually tapering
above to a beakless or shortly beaked, truncate-hyaline apex.
There is invariably a vestigial axis or rhachilla arising from the
base of the ovary, adpressed to the mature achene, protruding,
usually considerably, from the mouth of the utricle, and strongly
hooked at the apex.

It is extremely likely that Uncinia has had an Antarctic
origin. Its present area of distribution comprises the western half
of South America, the eastern half of Australasia and
Malaysia, and most of Polynesia. In addition to this large south
Pacific area, the genus is linked up across the ocean south of
South Africa.

There is one species of Uncinia, U . Kingii Boott, restricted to
extreme South America, the hook of which is much less strongly
developed, and it is not difficult to accept this as a transition

108

stage on the way to Carex microglochin, to which it bears a strik¬
ing general resemblance.

Carex microglochin Wahlenb. ( Uncinia microglochin (Wah-
lenb.) Spreng.) can be described as an Uncinia which has lost its
hook but retains a protruding rhachilla. Its var. oligantha
(Boott) Kukenth. ( C . camptoglochin Krecz.), a more robust plant,
occurs over a similar *area to that of Uncinia Kingii , in extreme
South America, but the species itself covers a large area round
the arctic-alpine region of the northern hemisphere.

This brings to mind the subject of Antarctic glaciation, and
the controversial problems of polar wandering, transtropic migra¬
tion, and consequent bipolar distribution.

I believe that a plant similar to Carex microglochin was born
from Uncinia in the American Antarctic, and came, by way of
the Andes, up to the north, where it so successfully spread itself
over habitats similar to those of its youth.

After C. microglochin settled in its northern home it seems to
have given rise to C. pauciflora Lightf., which Kukenthal and
other caricologists agree is closely related to C. microglochin, and
whose present area of distribution almost coincides with that of
its progenitor.

Carex pauciflora has completely lost the ancestral rhachilla,
but strongly resembles C. microglochin in its few other morpho¬
logical characters. It also, of course, bears a close resemblance to
a number of other unispicate sedges which I believe to be true
Carices, and which have become reduced from multispicate an¬
cestors. There is, in fact, no conspicuous (macroscopic) character
by means of which uncinioid descendants which have lost the
rhachilla can be generically distinguished from similarly reduced
caricoid derivatives. By way of “ parallel ” evolution, owing to
similar environments, these two groups have converged so much
that they cannot easily be generically distinguished in words,
but I submit that, because of their having evolyed from widely
separate origins, it would be wrong to unite them into one genus.
This phylogenetic approach to the classification of existing species
of plants is, in my opinion, the truly scientific one, whereas the
classifying of them on the basis of gross morphological resemb¬
lances and differences, exhibited by them only at this moment
in their vastly long evolutionary history on this planet, is un¬
scientific and unsound, and it has led to unrelated groupings,
even by recognised authorities, in, for example, such ancient
families as the Cyperaceae and the Gramineae (in which there
are numerous greatly reduced species), especially when other aids
to classification, such as cytology and anatomy, are not taken
into account.

* Since writing the above I have found among some undetermined material at
Kew a specimen of Carex micro g I o chin var. oligantha having an important
bearing on the views here put forward. The specimen was collected by
F. W. Pennell and T. E. Hazen, on August 15-20, 1922, at Paramo del Quindio,
in Colombia, in the extreme north-west of South America.

109

Finally, it should be mentioned that two other British
“ Carices, C. capitata L. and C. pulicaris L., bear, the former con¬
stantly and the latter occasionally, a similar vestigial axis or
rliachilla within the utricle. Though these species are not closely
related to each other, nor to the two sedges discussed above,
they may well have evolved similarly from Uncinia or Uncinia-
like ancestors in the southern hemisphere.

I am unable to discuss this subject further at present, because
it forms only part of a new theory of phylogeny in the tribe
Cariceae of the Gyperaceae, on which I am now working.

DISTRIBUTIONAL STUDIES AND GENERIC SEPARATION IN

LEPTURUS sensu Bentham
(Exhibit)

C. E. Hubbard.

The studies on which this exhibit was based form part of a
revision of Lepturus, sensu lato, of which a brief abstract would
serve no useful purpose. Mr. Hubbard proposes that the group
should be divided into five smaller genera and has given a partial
accoimt of some of these, including Parapholis, in Blumea, Suppl.
3, 14, 1946. Each of these smaller genera has a well marked geo¬
graphical range which is obscured by lumping them together.
(J.E.L.)

A PROPOSAL FOR MAPPING THE DISTRIBUTION OF BRITISH

VASCULAR PLANTS

A. R. Clapham.

The contributions to this Conference have dealt with two
broad topics : the methods of ascertaining and recording plant
distributions, and the attempts to provide explanations for them.
Mr. Walters, in his admirable introductory talk, told us first
something of the history of distributional studies in this country
and then proceeded to point out a number of problems confront¬
ing those who seek explanations. Both he and Dr. Blackburn
stressed the importance of historical investigations and, in par¬
ticular, the significance of the recent findings by pollen-analysts
which point to the Late Glacial period as one when many com¬
ponents of our flora reached their present stations. I am sure
that this is a most fruitful field of study and I much look forward
to the further discoveries of Dr. Godwin, Dr. Blackburn and their
co-workers.

110

Dr. Valentine chose another topic, that of the cytogenetical
status of closely related pairs of species with the same number
of chromosomes, and he again considered the role of historical
factors. Mr. Pigott told us about the British species of Thymus
and showed that there were outstanding gaps in our distribu¬
tional information, gaps by no means easy to fill.

All these speakers appealed for more information or stressed
the difficulties in the way of securing the information they re¬
quired. The remaining speakers were more particularly con¬
cerned with problems of method. Dr. Dony considered problems
arising in the compilation of a county flora; Mr. Dandy and Mr.
Lousley dealt with aspects of the country-wide problem of re¬
cording and representing the collected information, and Mr.
Stearn gave us a most informative talk chiefly from the stand¬
point of a monographer. Dr. Kloos’ illuminating contribution
was also, of course, a discourse on method.

What we have heard makes it clear, I think, that an accurate,
up-to-date knowledge of the detailed distribution in this country
of our native and established species of vascular plants is of
great and growing importance. It would be of value, both for
ourselves and for our botanical colleagues in other countries, if
we were to summarise in a convenient form all the scattered in¬
formation we have about species-distribution ; and many of us
feel this to be a duty which we owe to our subject. I propose there¬
fore to treat the preparation of a collection of distribution-maps
of British vascular plants as an immediate desideratum, and to
devote the rest of my time to a consideration of some of the
difficulties and problems, inviting you to express your opinions
on the best ways of meeting and solving them.

First I suggest that such a work should be comprehen¬
sive, in the sense that it should include all British species of vas¬
cular plants. There will, of course, be some difficulty about what
is to be regarded as a species of Hieracium, Rubus, Orchis, etc. ;
but on the whole I think such difficulties can be overcome. It
is not essential that every species should have a whole map to
itself. It may often be possible and convenient to indicate the
distributions of two or more related species on the same map;
though the feasibility of this will obviously depend upon the
technique of representation employed.

Next the work must be accurate. Most obviously this
means that each map should show all the localities or unit-areas
in which a species is found and should not mislead by suggesting
that it occurs in localities where it has not been found in the
recent past and where it cannot be found now. This involves a
careful searching for records in the literature and in herbaria;
and an assessment of their reliability by reference to actual speci¬
mens, by consultation with local botanists or with others familiar
with the relevant districts, and by organising search parties. To
do this for the whole British flora is likely to take several years.

Ill

When all this has been done there will still remain the related
problem of how to treat old but authenticated records. What
criteria of extinction should be used, and how far should the
maps show the former as well as the present situation? I sug¬
gest first that a species ought not to be regarded as lost from a
locality if it has been found there during the past fifty years and
if the locality remains, as far as can be judged, a possible habitat
for it; but should be regarded as lost if it has not been seen for
more than fifty years or if the locality has clearly ceased to be a
possible one for it. But second I suggest that it will usually be
desirable to indicate such lost localities on the map, and as lost,
not as current localities. The treatment of sub-fossil records is
another matter to which we must turn later.

Besides being comprehensive and accurate the work must
be available. It should, in other words, be of convenient
fonnat and reasonable cost. To include two or three thousand
distribution-maps in one or two volumes which are no larger
than quarto and which are not unduly expensive entails severe
restrictions on the size and nature of the individual maps, and
we shall have to consider in due course whether enough informa¬
tion can be given to make the venture worth while. But if we
anticipate a favourable answer to that question I should like to
proceed to suggest as reasonable the printing of 4 maps at a scale
of 1 in 10 million (157.83 miles per inch) on each page of a single
Medium Quarto volume (9 x 11 J inches). The individual maps
would be about 3f x 4J inches, the size of those in the Biological
Flora (Fig. 28), and there would be 5-700 pages of maps in the
volume. Now these are smallish maps and that point must be
borne constantly in mind in considering what information the
maps are to give. This is the point we must now consider.
What ought the maps to show ?

(a) I suppose the first desideratum to be to show the range
of each species within the country. I suggest that it is not
enough merely to draw a continuous line round the area within
which the species is found, ignoring even the most striking dis¬
continuities of range. This may be all that is required by certain
plant-geographers who work on a world-scale, but much more
detailed information is wanted by other kinds of botanists, and
much more can be supplied despite the limitations imposed by
the small size of map. The most familiar alternatives are the in¬
dication of presence or absence of each species within unit-areas
of convenient type, and the marking of individual localities as
accurately as the scale permits. There is a very great deal to be
said in favour of marking, by means of dots, the individual
localities of species which are infrequent enough for this to be
feasible, and I should like to see this done. But for those species
which are more continuously distributed it becomes necessary
to find a suitable unit-area. It will, I think, be agreed that the
county is too coarse a unit.

112

The vice-county lias the advantages of being a somewhat
finer unit , of being familiar and of being established. The two
last points must be given a good deal of weight, despite the vari¬
ous objections which have been raised against the vice-county.
Our most accessible sources of information about the distribu¬
tion of British species use the vice-comital system, and these
sources would cease to be useful in their present form if a different
system were adopted. And the vice-comital pattern has become
very familiar, as Captain Diver pointed out at a recent meeting

Fig. 27. Distribution of Geranium sanguineum in Derbyshire. The diagonally
shaded area shows t lie Carboniferous Limestone, and the dotted area the

Magnesian Limestone.

113

where mapping methods were discussed. Also the vice-counties
are closely related to counties, and the county has for long been
the chief unit-area of the local flora.

But is the vice-county sufficiently small as a mapping unit?
It all depends on how much information about range is required
of the map. If all that is required is the approximate limits
to north, south, east and west, and the general shape of the dis¬
tribution-area, whether slanting from north-east to south-west
or from north-west to south-east, the vice-comital pattern will
give the broad picture. But it will obscure a great deal that a
finer unit would reveal, and may seriously mislead about the con¬
tinuity or otherwise of the distribution. Consider maps showing
vice-comital distribution of Dryas octopetala and Trifolium suffo-
catum. That of Dryas , especially in Ireland, gives a false im¬
pression of everything except the wide limits of range, while
the almost exclusively maritime distribution of the Trifolium is
obscured. In a similar way the restriction of Helianthemum
vulgare, Cirsium acaulon or Scabiosa columbaria to parts, and
often small parts, of most of their vice-counties, would be con¬
cealed. I feel it wrong to lose the opportunity of giving this in¬
formation if it can be done without confusing more important
issues.

What is the alternative? The obvious alternative is to make
use of the 10 km. squares of the National Grid. These are units
which are now shown on all Ordnance Survey maps. They are
all the same size and shape; in any limited area where work is
being carried out their designations and boundaries would soon
become familiar ; and, of course, their boundaries are always
straight lines which can be identified without difficulty by the
use of the new 2J" maps. Their great advantage is that they
are considerably smaller than vice-counties and so can give much
more precise information about distribution within the general
range. This point is well made in Fig. 27 showing the distri¬
bution of Geranium sanguineum in Derbyshire. You will see
how the species is restricted to the Carboniferous Limestone and
occurs in only five adjacent grid-squares out of 44. And this
information can be given clearly even at a scale of 1 in 10 mil¬
lion. when the 10 km. square becomes a 1 mm. square. It is, no
doubt, approaching the limit of its utility at this scale, but I am
sure you will agree that it has not passed the limit.

Let us see how it works out for a selected species. I have
chosen Himantoglossum hircinum because Professor Good’s
labours have made it a very convenient choice. It has the dis¬
advantage of being a rare species for much of whose range pre¬
cisely located dots constitute the most satisfactory mapping
technique. Nevertheless it will serve a useful purpose. Plate
II, a, is Professor Good’s own map from the New Phyto-
logist. It shows records up to the end of 1933. Note the con¬
centration on the chalk and the virtual absence from the Weald.
Plate II, b, is the vice-comital distribution. Note that the striking

114

c C

Distribution of II irnantoglossum liircinum (L.) Spreng.

■\. Map showing- t lie localities from which the species has been recorded from
the earliest dates to the end of 1933. The dotted lines indicate the approxi¬
mate boundaries of chalk soils. The large circle in the Hartford area in¬
cludes 11 localities. (From (food. R. d’O., New Phytol., 35 (1936).)

P>. Vire-comital distribution.

C. Distribution in squares of the 10 kilometre National Grid.

D. Same as C but with a single dot in the centre of each 10 km. grid-square.

ttu

pattern in the south-east has now been entirely lost. Plate II, c,
shows the same data using the 10 km. grid-squares. See how the
concentration on the Chalk and absence from the Weald re¬
appear as obvious features of the map. If arguments for retain¬
ing administrative counties for local workers and local floras are
regarded as strong, I see no reason why the two systems should
not exist side by side. All that would need to be asked of County
Floras is that they should record for each species the 10 km.
grid-squares in which it occurs.

You will note, incidentally, that it is not necessary to print
the grid over each map. Any marked square can readily be
identified from the margins by using a straight edge; or alter¬
natively a transparent gridded overlay could be supplied in the
cover of the book. If the grid is always printed the maps be¬
come congested and unpleasing. The maps in Plate II, c and d,
illustrate two different ways of indicating the presence of a species
within a grid-square : either by placing a single dot at the centre
of the square, or by blocking in the whole square. The former
method has the disadvantage of not being immediately intel¬
ligible, and the dots might be misinterpreted as exact locations.
The latter seems a good deal to be preferred, although in a map
of so thinly scattered a species as Himantoglossum isolated
squares have little to recommend them as against precisely
located dots.

(b) But we are now on the threshold of a different topic.
It is often illuminating to know not merely the range of a species
but also something about the variations in its abundance in
different parts of that range. Can our small maps give this in¬
formation without becoming confused and obscure? I think
they can, by the use of say three different modes of blocking in
the squares and by indicating individual localities by means of
dots where the localities are sparsely scattered.

This map from Miss Lambert’s contribution to the Biological
Flora (Fig. 28) shows the kind of technique I have in mind,
though here the unit-area is the vice-county. You will note the
range of tones and the individually marked outlying stations.
I cannot see why this should not be done equally well with 10 km.
squares. I think it most important not to ask too much of these
small maps, but I do not feel that four grades of abundance
(three tones plus individual dots) would be excessive. The re¬
placement of isolated squares by dots would add appreciably to
the precision of the information supplied, by showing whether
each square represents a single station or more; and by locating
the stations somewhat more precisely. It may be desirable or
even essential to add to each legend a note about the meaning
of the tones used, since their exact significance could hardly be
the same for all species.

(c) We must next consider whether it would be possible to
supply any additional ecological information — any information,
that is, about the habitat of each species. I do not think very

115

t

Fig. 28. Vice-comital distribution in tlie British Isles of Glyceria maxima
(Hartm.) Holmb. (From Lambert, J. M., J. Ecol.} 34 (1947).)

Locally common to abundant. Sparingly distributed.

Rare or very local. □ Absent.

'///, Recorded in Top. Bot. (or Supplements) and/or in Comit. FI. but no information
yyZ as to abundance.

• Isolated stations. ^ Very probably originally introduced.

Note.— The scale of this map. 1 in 10 million, is that suggested for an atlas of

distribution-maps

116

much can be done, unless by additional maps of larger scale, as,
for instance, was done for Juncus filiformis in Professor Richards’
account for the Biological Flora. But if the 10 km. grid-squares
were used it would be useful and feasible to have an overlay
showing perhaps (1) land over 1000 and 2000 ft. and (2) calcare¬
ous and basic igneous substrata. I do not know whether any
other features could be shown in this way : probably not, though
a set of gridded climatic, physiographical and geological maps
could be supplied for reference.

(d) Dr. Valentine’s paper raises a further point for consider¬
ation. Can our maps show the distribution of infra-specific units
having distinctive geographical ranges? I should like to have
views about the desirability and feasibility of this. I should have
thought it possible to show the separate ranges of geographical
subspecies, though I have not yet considered the available
methods very carefully. Mr. Walters has succeeded in conveying
this information for Eleocharis palustris in his map for the Bio¬
logical Flora, but has not attempted to show also any informa¬
tion about variations in abundance.

(e) There remains the problem of whether any historical in¬
formation can usefully be supplied in the maps. I have already
referred to the desirability of indicating lost marginal or outlying
localities. This I think important, since it may reveal progres¬
sive changes in range of great interest to the ecologist and phyto¬
geographer. But there are two other kinds of historical infor¬
mation which would be valuable: first, the history of spread of
aliens, which presents no serious difficulty if we are prepared in
these instances to sacrifice the information about relative abund¬
ance at the present time: and second, the location of sub-fossil
finds, the importance of which has been stressed by Dr. Black¬
burn and Mr. Walters. These localities should, I think, be shown
if they lie outside the present continuous range or portions of
range. They could be shown by crosses or open circles and
should present no practical difficulties.

This brings me to some final summarizing remarks. My sug¬
gestions, upon which I invite your comments, are that this Con¬
ference has made it clear that it is high time we had a set of dis¬
tribution-maps of British species, and that we ought to set about
the task; that the maps, when produced, should be comprehen¬
sive and accurate ; that they should be available, in the sense in
which I have used that term, by being of small scale (1 in 10 mil¬
lion) so that they can be printed four on each page of a single
Medium Quarto volume; that the unit-area should be the 10km.
grid-square, but that sparsely scattered localities should be shown
individually; that three tones should indicate three grades of
density of localities within the unit-squares ; that overlays should
show ground over 1000 and over 2000 ft. and also basic sub¬
strata; and that certain further information about infra- specific
units and certain historical data should also be supplied if pos¬
sible.

117

GENERAL DISCUSSION

Professor Clapham's paper was followed by a general discus¬
sion on the work of the Conference as follows : —

Prof. Faegri said that there was a fine tradition of mapping
plant distribution in Scandinavia where the task was made easier
by the exceptionally large amount of herbarium material avail¬
able. In fact to a great extent maps could be prepared from
herbarium specimens alone. Signs which had been employed
were : —

(1) A dot to mark a locality supported by a herbarium speci¬
men or a first-hand observation of the plant growing.

(2) A circle to indicate localities other than those in (1), and

(3) A cross to mark places where the plant was extinct —
either from recent loss, or known only from glacial
material.

The Uppsala school used a base map on which a mass of topo¬
graphical detail of the Baltic area was printed in blue so that it
was not reproduced in the published maps. In these only the
outlines and main features were required and these were printed
in black on the base maps. But he wished to stress that a single
base map could not serve all purposes; each map must be up to
the problem which is to be solved, and each map had its own
uses. The Swedes use old administrative boundaries but these
are of minor interest to botanists of other countries. They could
therefore be shown on a separate map with other details not
essential to the “ system ” of a plant distribution atlas.

He thought that all records should be shown on such maps;
either by dots or by shading. Making the dots larger had the
effect of making them confluent and showing a continuous distri¬
bution.

Dr. Warburg thought that any series of maps should not be
too rigid. Different information should be given for different
species and whereas 10-kilometre squares might be suitable for
some plants, it might be desirable to use dots for plotting the
distribution of others. He suggested that adequate information
about the distribution of some species is unlikely to be available
for several years and in the meanwhile distribution maps pre¬
pared from present data would in effect show the distribution of
the homes and haunts of botanists rather than of plants.

Mr. Lousley supported the remarks of the last speaker and
said that he felt that the first essential of any project for the
preparation of distribution maps was to collect reliable facts.
Once the facts were available and dependable they could be
plotted, but to attempt to prepare maps from a mass of data of
varied value could onlv mislead. To trace the source of an in-
accurate marking on a published map, and to disprove it, would
involve a great deal of work. He therefore suggested that the

118

work of marshalling and checking the facts should come first.
When this was done the maps could be prepared.

Prof. Tutin agreed that accuracy was extremely important
but there was a lot of available information which could be sifted.
On balance he was in favour of attempting a series of maps as
proposed by Prof. Clapham. He felt that a set of maps even if
not perfect was better than no maps at all.

Dr. Turrill said that in addition to the two stages of col¬
lecting the facts and plotting them on maps as stated by Mr.
Lousley, there was a third task — that of interpreting the maps
when they had been prepared. He suggested that this would be
facilitated if they were printed on transparent paper so that the
distribution maps of the various species could be compared with
one another and superimposed on maps showing geology, soils,
meteorological data, etc. As an example of what he had in mind
the Agricultural Atlas of Great Britain and Wales should be con¬
sulted.

Mr. Meyer stressed the desirability of using maps on different
scales for various species. For a local plant like Primula elatior
a lot of important detail would be lost if plotted on a map on the
same scale as a plant distributed over the whole of the British
Isles.

Mr. Collenette thought that it was desirable to indicate by
shading any areas where a species was known not to exist. He
felt that the negative method of plotting only areas where the
plant had been found and leaving the rest blank, failed to dis¬
tinguish between those in which a search had been made without
success and those which had not been searched.

Mr. Pigott said that common species should be collected
much more. If they were better represented in the larger her¬
baria it would be a great help in mapping their distribution.

Mr. Clark made a plea for adding small maps showing the
general distribution of each species in the Northern Hemisphere.

Mr. Meyer suggested that symbols might be used to indicate
vague information.

Dr. Valentine supported the suggestion that much more at¬
tention should be devoted to common species. He thought that
relatively too many records referred to the rarer plants, and the
best way of overcoming this was by some method of sampling.

Prof. Faegri then said that if our difficulty was lack of in¬
formation then it would not become more inaccurate by making
use of what we had. It was possible to show a considerable num¬
ber of different grades to distinguish various areas on printed
maps by means of a wide range of machine-hatchings, of which
he exhibited sample sheets from British makers.

The Chairman (Mr Gilmour) said that it was evident that
Prof. Clapham’s proposal had aroused considerable interest and
that it seemed that there wras general agreement that a series of

119

maps such as he proposed was needed, and that its preparation
was feasible. He suggested that the remaining time might be
devoted to considering how the plan could be implemented.

Dr. Warburg proposed that if the project was to be discussed
by the Council of the Botanical Society of the British Isles, Prof.
Clapham should be invited to the meeting.

Dr. Burges said that he thought it most desirable that all
Natural History Societies scattered over the British Isles should
be invited to collaborate in a scheme of this kind and the B.S.B.I.
would be an appropriate body to bring them together.

Dr, Young suggested that if it proved too expensive to pub¬
lish all the maps together in one book, or if this was likely to
involve very long delay until they were all ready, the Society
might consider publication in parts as was being done with the
Biological Flora.

Mr. Walters thought that the matter should be considered
in conjunction with the whole future of the Biological Flora.

The Chairman said that if the meeting was in favour of the
proposals for the 'preparation of a series of distribution maps and
passed a suitable resolution the matter would be considered by
the Council of the B.S.B.I. The initial approach to the problem
might come from this Society which could invite the co-operation
of other bodies.

Mr. Walters suggested that the B.S.B.I. should approach
other bodies such as the British Ecological Society with the pro¬
posal.

Dr. Valentine thought that the appropriate bodies in Wales,
Scotland and Ireland should also be approached.

Mr. Walters then proposed : —

That the Conference expresses its wish that the Council of
the B.S.B.I. should discuss the possibility of preparing and
producing a series of maps of the British flora and that if
they consider it practicable they should enlist the co¬
operation of such other bodies as may be desirable and
suggest that Prof. Clapham should be invited to attend
the meeting at which it is discussed.

The proposal was seconded by Dr. Burges and put to the
meeting. It was carried with acclamation.

120

BRAINS TRUST

Question Master — Mr. J. S. L. Gilmour.

Mr. J. P. M. Brenan. Dr. J. M. Lambert.

Dr. R. C. L. Burges. Dr. W. B. Turrill.

Mr. R. A. Graham. Prof. T. G. Tutin.

The following selection from the questions put to the Brains
Trust, with summaries of the replies, has been chosen from those
which had some reference to the subject of the Conference.

Can the Brains Trust give a definition of “ growing wild ” — as
distinct from “cultivated” — with particular reference to the
admission of a species as a wild plant in a Floral — “Yard¬
stick".

Dr. Turrill suggested that a “ wild ’’ plant might be defined
as one that had not been deliberately sown or planted and had ex¬
tended itself by natural means — this held good even if the plant
grew in a garden. Prof. Tutin agreed, but thought that for the
purpose of a Flora it was necessary to qualify the definition so
that only species which maintained themselves by seed or as
perennials for a number of years, or occurred repeatedly, were
included.

Dr, Lambert thought that the idea of competition was im¬
portant. She thought that plants growing on a waste space had
less claim to be considered “ wild ’’ than those in natural com¬
munities such as Impatiens capensis found in primary swamp.

Mr. Brenan thought that to insist on a species withstanding
competition before it could be regarded as “wild" raised difficul¬
ties. He instanced open communities on sand-dunes where aliens
frequently got established and were subject to little competition.

Dr. Burges also thought that insistence on withstanding
competition narrowed the field too much. Plants found on rub¬
bish dumps sometimes spread and grow freely in competition else¬
where. Perhaps the solution might be to include such plants in
a Flora in brackets. Prof. Tutin remarked that some undoubt¬
edly native species, such as Aira praecox, avoided competition.
Dr. Lambert said that by competition she intended competition
with external factors as much as competition with other species.
Larkspur could maintain itself from seed in gardens. Dr. Tur¬
rill said that if a gardener did not want such plants he said they
were ‘going wild’.

In summing up Mr. Gilmour remarked that the discussion
had brought out very clearly the distinction between “ growing
wild ’’ and “ being native ’’ — two concepts often confused.

Should future local floras follow the main lines of the “ Flora of
Gloucestershire ” or those of Good's “ Geographical Hand¬
book of the Dorset Flora” ‘l — “Ignotus”.

121

Mr. Graham thought that if a local flora was intended to
serve the purposes usually associated with such works it should
follow Gloucestershire. Prof. Tutin suggested that perhaps local
floras would be unnecessary when the projected series of maps
was published!

Dr. Burges thought that the answer must depend on whether
a comprehensive Flora on traditional lines had already been
issued for the area concerned. If so it might be desirable to
break new ground, but a volume of the Gloucestershire type was
most desirable for every county. Prof. Tutin remarked that
plants which catch the eye often do not get detailed localities in
local Floras. Botanists should record the common plants more.
For example, in Leicestershire Chenopodium Bonus-Henricus was
more local and less plentiful than Atriplex hastata but one would
not suspect this from the Flora where a long list of localities is
given for the former and no specific ones for the latter.

Mr. Brenan thought that the proper function of a county
Flora was twofold — it should show the distribution of plants in
relation to (1) the geography of the county and (2) soil and other
similar factors.

Mr. Gilmour summed up by saying that the discussion had
shown that there would still be a need for local Floras, even of
the modified kind, after the project for the publication of the
maps had got under way.

Some people are very fond of transplanting rare and beautiful
wild flowers to fresh localities either for experimental pur¬
poses cn', as they say, to increase a thing of beauty. Should
this be deplored or encouraged ? — “Country-lover”.

Prof. Tutin said that such actions were to be deplored and
especially if the person doing the transplanting had no serious
reason for it. When experiments were necessary they should be
recorded in a suitable journal — such as Watsonia. Mr. Graham
concurred but thought there was one justifiable exception — when
it was necessary to transplant a rare species otherwise doomed
to certain destruction. He instanced Schoenus ferrugineus which
would be “drowned” by the raising of the level of Loch Tummel.
Dr. Burges thought that even this exception should not be
made; he deplored the whole thought of moving plants.

Dr. Turrill suggested that the views of his colleagues on the
Brains Trust were too extreme. He thought that knowledge
would be advanced by establishing scheduled transplant areas for
experimental purposes. Such areas should be set up fairly widely
over the British Isles and kept under strict control. Dr. Lam¬
bert thought that in such an idea very careful consideration
should be given to what would happen when the experiments
came to an end ; surely there was a risk that transplanted species
might extend outside the areas.

122

As an example of a justified transplant into a natural habitat,
Dr. Turrill mentioned the male Ranunculus acris. Only one
plant was found — only one had ever been found. This was dug
up and multiplied vegetatively and then one part was sent back
for replanting in the place where it was found.

Mr. Gilmour in summing up suggested that the projected
National Nature Reserves might be able to supply limited areas
for transplant experiments under constant supervision.

Will the Brains Trust please explain the meaning of the word
“Cybele” in uCybele Britannica” l — Anon.

This led to some interesting observations and, with help from
the body of the hall, Cybele was explained as a term introduced by
H. C. Watson to describe a systematic treatise on the geography
of the plants of a specified area, being applied by analogy with
the term Flora which has long been used for a systematic descrip¬
tion of the families, genera and species of an area. In Greek
mythology, Cybele was the Phrygian goddess of nature and fer¬
tility and was chosen by Watson as a suitable parallel to Flora,
the Roman goddess of flowers.

(See H. C. Watson, 1847, Cybele Britannica , 1, 2.)

Does the Brains Trust view with alarm Dr. Valentine’s suggestion
that the Society might compile a sort of Comital Flora for
hybrids l — “Mongrel".

Prof. Tutin thought that it was worthwhile recording the
distribution of hybrids which reproduced vegetatively (e.g.
Mentha ), and also apomicts which showed a gradation to plants
known to be straight hybrids.

Dr. Turrill thought that it was first necessary to define the
term “hybrid" — did it mean in this case hybrids between species?
He thought that experimental evidence was essential before such
a list could be published and he was strongly opposed to guessing
hybrid origin from no more evidence than morphological charac¬
ters provided. He suggested that many recorded “ hybrids ” may
be merely mutations.

Dr. Lambert stressed the lack of permanence of many
hybrids which made them unsuitable for a work on the lines of
Comital Flora. Dr. Turrill then reminded the meeting that a
number of plants entered as “ species " in published lists of the
British flora are really hybrids — for example the hybrid swarms
of Centaurea which occur in Britain and Holland and perhaps
elsewhere.

Finally, Dr. Valentine was asked if after hearing the discus¬
sion, he still thought his suggestion could be carried out. He
replied that he still thought a list of interspecific hybrids with
British records could and should be prepared.

123

CONCLUDING REMARKS BY THE PRESIDENT

Mr Gilmour, in his concluding remarks, referred to the various
concrete proposals that had been put forward, and especially to
the plan outlined by Professor Clapham for the preparation and
publication of a series of distribution maps of the British Flora;
it had been agreed that this should be referred to the Council of
the Society for consideration and action.

He hoped that the proceedings of the Conference would be
published by the Society as were those of the last one in 1948.
Tn conclusion, Mr. Gilmour thanked all those who had contributed
to the success of the Conference, both as speakers, exhibitors,
organisers and helpers and he mentioned particularly Dr. J. G.
Dony, Hon. Secretary of the Field Work Committee, and Mr. W.
R. Price, Hon. Assistant Secretary of the Society

FIELD MEETING AT QUENDON WOOD, N. ESSEX,
SUNDAY, APRIL 2, 1950

On the day following the Conference a party of about 60
members and visitors travelled to Quendon Wood by coach to
study Primula elatior (L.) Hill, under the leadership of Dr. D. H.
Valentine and Mr. H. and Miss D. Meyer.

The species was chosen as offering an early flowering example
of a plant with a very interesting and restricted distribution in
Britain (see p. 81). At Quendon Wood, near Saffron Walden,
it grows in woodland of the oak-ash-hazel type on Boulder Clay.
Hybrids with P. vulgaris and back-crosses were plentiful. It was
demonstrated that P. elatior is a plant of the “high coppice”
phase of the woodland while P. vulgaris occurs around the borders
of the wood and along some of the rides.

The field meeting provided an excellent opportunity for the
continuation of informal discussions on the work of the Confer¬
ence and for English botanists to exchange views with the three
foreign visitors who were able to attend. A more detailed ac¬
count of the occasion will appear in the Society’s Year Book,
1951.

124

POSTSCRIPT

Readers will be interested to know that pursuant to the re¬
solution passed at the close of the general discussion, the Council
of the B.S.B.I. discussed Prof. Clapham’s suggestion for the pre¬
paration and production of a series of maps of the British flora
and at their meeting of May 11th, 1950, a Committee was ap¬
pointed to consider the part that the Society might play in the
project. Professors A. R. Clapham and T. G. Tutin, Dr. E. F.
Warburg, and Messrs. J. E. Lousley, E. Milne-Redhead and E. C.
Wallace were appointed to this Committee, which at its first meet¬
ing elected Prof. Clapham as Secretary. To carry out the task
successfully must inevitably entail several years’ work and the
Committee is at present engaged in investigation of the practical
difficulties with a view to formulating a definite plan.

Captain Diver’s suggestion that close co-operation should be
established between the Society and the Nature Conservancy has
also been implemented.

J. E. Lousley,

Hon. General Secretary, B.S.B.I.,
December 31, 1950.

125

INDEX

Figures in heavy type refer to pages on which maps or illustrations

appear.

Aims, 14

Aira praecox, 121
Ajnga Chamaepitys, 71
Alces alces, 96

— am eric anus, 102

— malcliis, 96, 102
Aller0d, 99

Anemone Palsatilla, 23, 38, 43
Antennaria dioica, 38, 43
Arbutus, 52

Archivum Kartografii Botanicznej, 46
Arctic-alpine element, 15, 18, 100
Arctostaphylos Uva-ursi, 101
Arenaria gothica, 21

— norvegica, 22
Armenia sp., 97, 101
Artemisia sp., 101
Aster Linosyris, 18

— Tripolium, 77, 78
Astragalus danicus, 18, 19, 20, 23

— goniatus, 20
Aut ecology, 22

Baker, J. G., 32
Bedfordshire, 69-, 70
Belgium, 37, 40, 45
Bennett, Arthur, 32
Betula nana, 97, 100

— pubescens, 97, 100, 101
Blackburn, K. B., 96-
Boreal-Atlantic, 98
Botanical Record Club, 24, 32
Boundary lines, 57

Brenan, J. P. M„ 29 , 68 , 74, 121-
Bunium Bulbocastanum, 74, 75
Burges, R. C. L., 120, 121-

Cain, S., 17

Calliergon sarmentosum, 95
Campanula glomerata, 78
Cardaria Draba, 36
Carex carnptoglochin, 109

— capitata, 110

— helodes, 78

— microglochin, 109

— pauciflora, 109

— pulicaris, 110

— rostrata, 97, 100
Centaurea Jacea, 82.

— nigra, 82, 123
Cerastium brachypetalum, 72
Chara spp., 97

Cheales, E. M., 79
Chrysosplenium oppositi folium, 78
Clapham, A. R., 110
Clark, W. A., H9

Clematis Vitalba, 35, 78
Collenette, C. L., 119
Cirsium acaulon, 114
Comital Flora, 24, 32, 37, 54
Competition factors, 17-
Continental, 18
Coritanian Elm, 105
Cornwall, 28
County boundaries, 25
County-divisions, 32
Crataegus monogyna, 82

— oxyacanthoides, 82
Cybele Britannica, 23, 24, 31, 123
Cyclamen, 49

Dandy, J. E., 23-, 30
Darwin, C., 13, 14
Denmark, 40, 45 -
Dentaria bulbifera , 78
Digitalis purpurea, 79, 104
— spp., 104
Diotis maritima, 35
Distribution, climatic factors, 15

— concept of, 12

— discontinuous, 12

— disjunct, 12

— historical factors, 15
Diver, C., 12, 113

Dony, .T. G., 69-, 74-
Dot Method, 38, 56
Dry as octopetala, 18, 114
— sp., 99, 100
Dunbarton, 27

Ecesis, 103
Ecospecies, 82
Elk, 96, 102
Enclaves, 27

Epilobium hirsutum, 83, 86

— parviflorum, 83, 86
Epimedium alpinum, 63
Eguisetum limosum, 97
Eryngium campestre, 67
Eutrophic, 94— applied to vegetation

which requires a high concentra¬
tion of mineral salts dissolved in
the ground water

Faegri, K., 118, 119
Fennoscandian line, 99
Filipendula hexapetala, 20, 94

— vulgaris, 94
Forbes, E., 13, 21

Galinsoga parviftora, 45
Gentiana vema, 18

126

Geographical isolation, 88
Geranium sanguineum, 113, 114
Germany, 46

Geum rivale, 79, 83, 84, 85, 89
— urban wm, S3, 84, 89
Gibbons, E. J., 23, 79
Gilmour, J. S. L., 12, 119, 120, 121-, 124
Glacial flora, 16, 18, 20, 96-
Gloucestershire, 23
Glyceria maxima, 116
Godwin, H., 18
Good, R., 16, 20, 37, 54, 78
Graham, R. A., 121-
Great Ormes Head, 28
Grids, 25, 36, 37, 54, 114-

Hall, P. M., 32

Helianthemum canurn, 100, 101
— vuigare, 114

Heneder, 40, 45
Hey wood, V. H., 104
Himanloglossum hircinum, 36, 45, 114,
Plate II

Hippocrepis comosa, 77, 78
Hoklijstje, 65
Holland, 37, 40, 45, 64
Hour-squares, 64
Hubbard, C. E., 110
Hulten, E., 48
Hybrids, 89, 123
Hgpnum scorpioides, 97

45

Iberis amara, 34
Ice Age, 15, 16
Impatiens capensis, 121
Institut pour la floristique de la Bel¬
gique, 45

Institut voor het Vegetatie-onderzoek
van Nederland, 45, 64
Interstadial, 103
Inula salicina, 18
Ireland, 32
Isolation, genetic, 82-

— geographical, 82, 87-
Isopores, 59
Isopsepheren, 59

I.V.O.N., 45, 64

Juncus alpinus, 18
Juniperus sp., 97, 101

Kent, 76-

Kloos, A. W., 12, 64-

Lambert, J. M., 121-
Lane-Claypon, E. M., 79
j T.arkspur, 121
Lathyrus sylvestris, 78
Lepturus, 110
Linaria repens, 82

— vulgaris, 82
Lincolnshire, 79
Liparis Loeselii, 20

Longfleld, C. E., 29, 102
Lousley, J. E., 30-, 43, 68, 118
Lusitanian element, 15

Matthews, J. R., 16, 32
Medicago falcata, 82

— saliva, 82
Melampyrum cristatum, 71
Melandrium album, 83, 84, 88

dioicum, 71, 83, 84, 88
Melville, R., 105
Menyanthes trifoliata, 97
Mercurialis perennis, 78
Methods, 14

Meyer, D. & H., 81, 124
— H., 74, 119

Mitchell, G. F., 97, 100
Moose, 96, 102
Myriophyllum sp., 97.

spicatum, 101
— verticillatum, 97

Narthecium ossifragum, 56
National Grid, 114
Neasham, 96-
Nelmes, E., 28, 108
Neotinea Intacta, 18
Newbould, W. W., 32
Nitella sp., 97

North American element, 22
Nunataks, 16
Nuphar lutea, 83, 89

— pumila, 83, 89

Oenanthe crocata, 79
Ophrys spliegodes, 78
Ombrogenous, 94 — applied to wet soils
when the water content is derived
entirely from direct precipitation
Omithogalum pyrenaicum, 69
Oxlip, go, 81

Palynology, 97
Parapholis, HO
periglacial, 102
Perthshire, 28
Petasites hybridus, 79
Pflanzen-Mischlinge, 89
Phleum phleoides, 71
Pigott, C. D., 91-, 119
Poland, 46
Polemonium sp., 97
Pollen-analysis, 97
Pollen diagram, 98
Polygonum viviparurn, 95
Potamogeton praelongus, 96, 100, 101
natans, 101
sp., 97

Potentilla fruticosa, 18
Praeger, R. L., 32, 33
Primula elatior, 71, 80, Plate I, 81,
86, 89, 124
— veris, si, 87

vulgaris, 72, 81, 86, 89

127

Quendon Wood, 68, 124
Quercus petraea, 83, 87
— Robur, 83, S7

Range (of a species), 12
Ranunculus acris, 123

aquatilis (aggr.), 97
Records (accuracy), 34, 35, 60, 111, 118
Reid, Clement, 16
Ridsdale, 97

Rose, F., 23 , 29 , 73 , 74 , 76-
Rubus, 102-

Rumex Hydrolapathum, 34
maritimus, 34, 35

— palustris, 34

Salisbury, E. J., 16, 18, 20
Salix caprea, S3, 87

— herbacea, 97, 99, 100, 101

— phylicifolia, 97, 100, 101

— viminalis, 83, 87
Sandwith, N. Y., 68
Saxifraga lactiflora, 83, 86

— spathularis, 83, 86
Scabiosa columbana, 114
Sclieuclizena palustris, 95
Schoenus ferrugineus, 122
Scirpus triqueter, 43, 44
Scutellaria bastifolia, 21
Selaginella, 97, 100
Senecio squalidus, 22, 36
Serratula tinctoria, 20
Silene Cucubalus, 83, 84

— mantima, 83, 84
Sium latifolium, 78
Smyrnium Olusatrum, 78
Soligenous, 94— applied to wet soils

when the water content is de¬
rived from mineral soil water,
the surface of which is sloping—
that is to say, when this water
is in motion
Sorb us aucuparia, 101

— torminalis, 79
Specific centres, 13
Stapf, O., 43
Steam. W. T., 48-
Sweden, 48, 118
Systematics Association, 24

Teesdale, 18, 100
Teucrium Scordium, 20
Thesium humifusum, 78

Tliymus, 91-, 92, 93
Tilia cordata, 79
Tolerance, Theory of, 17
Tofieldia, 55, 61
Topocline, 105

Topogenous, 94 — applied to wet soils
when the water content is de¬
rived from mineral soil water,
the surface of which is approxi¬
mately horizontal.

Topographical Botany, 24, 30, 32
Trifolium ochroleucon, 71

— suffocatum, 114
Turrill, H. B., 68, 119, 121-
Tutin, T. G., 68, 119, 121-
Typha sp., 97

Ulmus coritana, 105-, 106
Uncinia, 108

Vaccinium Myrtillus, 78

— sp.. 97, 101

Valentine, D. H., 67 , 82, 119, 120, 124
Vaives, 99

Veronica hybrida, 20, 21

— per sica, 36

— praecox, 21

— spicata, 20, 21

Vicia sylvatica, 78
Viola hirta, 78, 83, 89

— odorata, 83, 89

— rupestris, 18

— stagnina, 18, 20

Wade, A. E., 74
Wales, 32

Walters, S. M., 12-, 120
Warburg, E. F., US, 120
Watson, H. C., 13- , 23-, 30-
— W. C. R., 102

Watsonian Vice-county system, 3, 23-.
30-, 31

Webb, D. A., 32
Whitehead, F. N., 29
Wijk, R. van der, 12
■‘Wild”, 121

Wilmott, A. J., 12, 24, 27, 39
Willdenow, , 13
Worcestershire (Dudley), 27
Woodhead, T., 16

Young, D. P., 95, 120

128