In fact,
this lady may be regarded as the foundress of Kew, which, since
her time, has played the leading part in the dissemination of
botanical knowledge throughout the world.
this lady may be regarded as the foundress of Kew, which, since
her time, has played the leading part in the dissemination of
botanical knowledge throughout the world.
Cambridge History of English Literature - 1908 - v14
Black, Cavendish and Priestley
greatly advanced the science of chemistry.
So long as chemists formed vague generalisations founded on
introspective speculations, they made little progress. It was by
concentrating their attention on a few limited occurrences, and
accurately examining these by quantitative experiments, that
chemists gradually gained clear conceptions which could be
directly used in the investigation of more complicated chemical
changes. “True genius,' Coleridge said, 'begins by generalising
and condensing; it ends in realising and expanding. ' The vague
generalising of the alchemists was followed by the condensing
work of Black and Cavendish, and by the suggestive discoveries of
Priestley. The time was approaching for realising and expanding.
In 1808, a small book appeared, entitled A new system of
Chemical Philosophy, Part I, by John Dalton. The influence of
that book on the development of chemistry, and of physics also,
has been very great.
Dalton delivered a lecture in Manchester, in 1803, wherein he
said 'An enquiry into the relative weights of the ultimate particles
18-2
## p. 276 (#306) ############################################
276
The Literature of Science [CH.
of bodies is a subject, so far as I know, entirely new; I have lately
been prosecuting this enquiry with remarkable success. ' Many of
Dalton's predecessors, both chemists and physicists, had used, in a
vague and general manner, the Greek conception of the atomic
structure of matter. Dalton showed how the relative weights of
atoms can be determined. By doing that, he brought down the
atomic theory to the solid earth, and made it a bold, suggestive,
stimulating guide ready for the use of chemists and physicists.
Dalton was not a great experimenter; he generally used the
results of other chemists' experiments. He was a scientific thinker,
characterised by boldness and caution. Dalton assumed, as
Lucretius had done long before him, that matter has a grained
structure ; that all the ultimate particles of each particular
homogeneous substance are identical, and differ in properties,
one of which is their weight, from the particles of all other
definite substances; he also assumed that the mechanism of
chemical changes, that is, changes wherein homogeneous substances
are produced different from those present when the changes began,
is the coalescence of atoms of different kinds to form new sorts of
atoms.
In order to find the relative weights of atoms, Dalton argued
as follows: Analyses and syntheses of water show that eight
grains of oxygen unite with one grain of hydrogen to form water.
If this change is the union of atoms of oxygen with atoms of
hydrogen, to form atoms of water, and if all the atoms of each
one of these three homogeneous substances are identical in weight
and other properties, it follows that an atom of oxygen is eight
times heavier than an atom of hydrogen. If we take the atomic
weight of hydrogen as unity—because hydrogen is lighter than
any other known substance—then the atomic weight of oxygen is
eight, and the atomic weight of water is nine.
In arriving at the conclusion that the atomic weight of oxygen
is eight, if the atomic weight of hydrogen is one, Dalton made the
assumption that a single atom of oxygen unites with one atom of
hydrogen to form an atom of water. He made this assumption
because it was simpler than any other. Had he chosen to suppose
that two atoms of hydrogen unite with one atom of oxygen, he
must have assigned to oxygen the atomic weight sixteen, and to
water the atomic weight eighteen.
To make Dalton's method perfectly general, and quite conclusive
in its results, it was necessary to find means for fixing the relative
weights of the atoms formed by the union of other, simpler, atoms;
## p. 277 (#307) ############################################
VII] The Atomic Theory. Dalton and Others 277
it was also necessary to find means of determining the number of
atoms of each kind which unite to form a more complex atom.
A general method for solving these two problems was given to
chemistry in 1811–12 by an Italian physical chemist named
Avogadro, who brought into science the notion of a second order
of minute particles, supplementing the conception of atom by that
of molecule.
It is not possible in this brief sketch to indicate the many new
fields of investigation which were opened, and made fruitful, by
the Daltonian atomic theory. From the many workers who used
this theory as a means for pressing forward along new lines of
enquiry, two may be selected, since their work is typical of much
that was done in chemistry during the first half of the nineteenth
century.
Alexander Williamson strove to make chemists realise the need
of using the Avogadrean molecule as well as the Daltonian atom.
By his work on etherification, and by other experimental investiga-
tions, as well as by reasoning on his own results and those obtained
by other chemists, Williamson demonstrated the fruitfulness of
the notion of the molecule. He endeavoured to determine the
relative weights of molecules by purely chemical methods. These
methods proved to be less satisfactory, and much less general,
than the physical method which had been described by Avogadro.
The conception of equivalency, that is, equal value in exchange,
of determinate weights of different homogeneous substances, has
been very helpful in chemistry. In 1852, Edward Frankland
applied the notion of equivalency to the atoms of elements, that
is, homogeneous substances which have not been separated into
unlike parts. He arranged the elements in groups, the atoms of
those in any one group being of equal value in exchange, inasmuch
as each of these atoms combines with the same number of other
atoms to form molecules.
When Frankland's conception had been developed, and the
method of determining the equivalency of atoms made more
definite and more workable, a vast new field of enquiry was
opened, a eld which has proved remarkably fruitful both in
purely scientific work, and in applied chemistry. It is not an
exaggeration to say that the great industry of making aniline
colours is an outcome of the notion of atomic equivalency intro-
duced by Frankland into chemical science.
The words element and principle were used by the alchemist
as nearly synonymous; both words were used vaguely. The
## p. 278 (#308) ############################################
278
[ch.
The Literature of Science
meaning given to the term element, by Lavoisier, towards the
end of the eighteenth century—a definite kind of matter which
has not been decomposed, that is, separated into unlike parts-
was elucidated, and confirmed as the only fruitful connotation
of the term by the work of Sir Humphry Davy on potash and soda
in 1808.
Humphry Davy was the most brilliant of English chemists.
He was the friend of Wordsworth and Sir Walter Scott. Lockhart
says that the conversation of Davy and Scott was fascinating and
invigorating. Each drew out the powers of the other.
6
I remember William Laidlaw whispering to me, one night when their
‘rapt talk 'had kept the circle round the fire until long after the usual bedtime
of Abbotsford-Gude preserve us! this is a very superior occasion 1! '
Davy sent an electric current through pieces of potash and soda;
the solids melted, and 'small globules, having a high metallic
lustre, and being precisely similar in visible characters to quick-
silver, appeared. By burning the metal-like globules, Davy
'
obtained potash and soda. Making his experiments quantitative,
weighing the potash and the soda before passing the current, and
the potash and soda obtained by burning the metal-like products
of the first change, he proved that potash and soda, which, at that
time, were classed with the elements, are composed each of a metal
combined with oxygen. The new metals—potassium and sodium-
are soft and very light, and instantly combine with oxygen when
they are exposed to the air.
Everyone had been accustomed to think of a metal as a heavy,
hard solid, unchanged, or very slowly changed, by exposure to air.
Had chemists strictly defined the term metal, they could not have
allowed the bases of potash and soda (as Davy called the new sub-
stances) to be included among metals. Happily, the definitions of
natural science are not as the definitions of the logician; they are
descriptive summaries of what is known, and suggestive guides to
further enquiry.
As every attempt to separate potassium and sodium into unlike
parts failed, Davy put them into the class elements ; he said—Till
a body is decomposed, it should be considered as simple. '
In 1810, Davy investigated a substance concerning the
composition of which a fierce controversy raged. Oxymuriatic
acid was said by almost all chemists at that time to be a compound
of oxygen with an unknown base. No one had been able to get
1 Life of Sir Walter Scott (6 vols. , 1900), vol. III, p. 403.
## p. 279 (#309) ############################################
a
6
VII] Davy. Physical Chemistry
279
oxygen from it, or to isolate the base supposed to be a constituent
of it. By putting away, for the time, all hypotheses and specula-
tions, and by conducting his experiments quantitatively, Davy
showed that oxymuriatic acid is not an acid, but is a simple
substance, that is, a substance which is not decomposed in any
of the changes it undergoes. He proposed to name this simple
substance chlorine ; a name, Davy said, 'founded upon one of its
obvious and characteristic properties-its colour. ' Davy re-
marked— Names should express things not opinions. '
Davy thought much about the connections between chemical
affinity and electrical energy, and investigated these connections
by well planned experiments. In 1807, he said—May not the
electrical energy be identical with chemical affinity ? ' He used
the expressions—'different electrical states,' and 'degrees of
exaltation of the electrical states,' of the particles of bodies.
Recent researches into the subject of chemical affinity have
established the great importance of the conceptions adumbrated
by Davy in these expressions.
Chemistry, the study of the changes of composition and
properties which happen when homogeneous substances interact,
has always been closely connected with physics, the study of the
behaviour of substances apart from those interactions of them
in which composition is changed. Among the earlier physical
chemists, Graham occupies an important place.
Thomas Graham was a shy, retiring man, most of whose life
was spent in his laboratory. There is a tradition in the Glasgow
institution, where he taught chemistry, in his younger days, before
moving to London (in his later years he was master of the mint),
that, when he came into the lecture theatre, to deliver his first
lecture to a large audience, he looked around in dismay and fled.
Graham established the fundamental phenomena of the diffusion
of gases and of liquids; he distinguished, and applied the distinction,
between crystalloids, solutions of which pass through animal and
vegetable membranes, and colloids, which do not pass through
those membranes. The investigation of the behaviour of colloidal
substances has led, in recent years, to great advances in the
knowledge of phenomena common to chemistry, physics and
biology.
Electrochemistry, the study of the connections between chemical
and electrical actions, has been productive, in recent years, of more
far-reaching results than have been obtained in any other branch
of physical chemistry. Much of what has been done in the last
a
## p. 280 (#310) ############################################
280 The Literature of Science [CH.
half-century is based on the work of Faraday, and, indirectly, on the
suggestion of Davy. Both were men of genius, that is, men who
see the central position of the problem they are investigating, who
seize and hold that position until the problem is solved, letting the
surface phenomena, for the time, go to the dogs, what matters? '
Men of genius work from the centre outwards.
To Michael Faraday, we owe the fundamental terms of electro-
chemistry. The separation of a salt into two parts by the electric
current, he called electrolysis ; the surfaces from which the current
passes into, and out of, an electrolysable compound, he named
electrodes; the substances liberated at the electrodes, he called
ions. Faraday measured the chemical power of a current' by
the quantities of the ions set free during a determinate period
of electrolysis. Taking as his unit the quantity of electricity
which liberates one gram of hydrogen from an electrolysable
compound of that element, he showed that the weights of different
ions liberated from compounds by unit quantity of electricity are
in the proportion of their chemical equivalents. Using the language
of the atomic theory, Faraday declared that 'the atoms of bodies
which are equivalent to each other in their ordinary chemical action
have equal quantities of electricity mutually associated with them. '
In 1834, Faraday said— The forces called electricity and
chemical affinity are one and the same. ' Faraday distinguished
the intensity of electricity from the quantity of it, and indicated
the meaning of each of these factors. One would not greatly
exaggerate if one said that the notable advances made in the
last quarter of a century in the elucidation of chemical affinity
are but developments and applications of Faraday's pregnant
work on the two factors of electrical energy.
The results established by Faraday have led to the conception
of atoms of electricity, a conception which has been of great
service in advancing the study of radioactivity. Faraday's results
have also been the incentives and guides in researches which go
to the root of many problems of the physical sciences, and of not
a few of the biological sciences also.
At the time of the foundation of the Royal Society, chemistry
was a conglomeration of more or less useful recipes, and a dream
of the elixir. Today, chemistry is becoming an almost universal
science. Happily, chemists still dream.
## p. 281 (#311) ############################################
VIII]
Biology
281
C. BIOLOGY
6
Although science, during the eighteenth century, was, like
many other intellectual activities in our country, more or less
in abeyance, an attempt has been made, in the following pages,
to carry on the subject in the present chapter from that which
appeared in a previous volume (VIII) of this History.
'The Royal Society of London for Improving Natural Know-
ledge, one of the oldest scientific societies in the world and
certainly the oldest in the empire, was formally founded in 1660,
and received its royal charter of incorporation two years later.
At a preliminary meeting, a list had been prepared of some forty
names of such persons as were known to those present whom
they judged willing and fit to joyne. . . in the designe,' and among
these names we find those of 'Mr Robert Boyle, Sir Kenelme
Digby, Mr Evelyn, Dr Ward, Dr Wallis, Dr Glisson, Dr Ent,
Dr Cowley, Dr Willis, Dr Wren' names whose owners have been
dwelt upon in volume VIII.
Thus, for the first time in our country, the study of science was,
to a degree, organised and its advancement promoted, not only
by periodical meetings where experiments were conducted and
criticism freely offered, but by the collection of scientific books,
which still remain at Burlington house, and of 'natural objects,
which have for long formed part of the British Museum's
collections.
So Virtuous and so Noble a Design,
So Human for its Use, for Knowledge so Divine,
as Abraham Cowley, the laureate of the new movement, wrote,
was, in part, a protest against the credulity and superstitions of
a credulous and superstitious age, and the word ‘natural, as
used in the charter, was used in deliberate opposition to “super-
natural,' the aim of the society being, at any rate in part, to
discourage divination and witchcraft.
We have said something about the brilliant band of physio-
logists, headed by Harvey, who made the Stewart period remarkable
in the annals of English science; though there were then other
biologists less gifted than Harvey, but still leaders in their several
fields. The recent invention of the microscope had given a great
impetus to the study of the anatomical structure of plants and,
later, of animals; and, in relation to this, we must not overlook
## p. 282 (#312) ############################################
282 The Literature of Science [CH.
the work of Nehemiah Grew, who, with the Italian Malpighi, may
be considered a co-founder of the science of plant-anatomy.
Nehemiah Grew studied at Pembroke hall, Cambridge, and after-
wards took his doctor's degree at Leyden. He published numerous
treatises dealing with the anatomy of vegetables, and with the
comparative anatomy of trunks, roots, and so forth, illustrated
by admirable, if somewhat diagrammatic, plates. Although
essentially an anatomist, he made certain investigations into
plant physiology and suggested many more. Perhaps his most
interesting contribution to botany, however, was his discovery
that flowering plants, like animals, have male and female sexes.
It seems odd to reflect that this discovery is only about 250 years
old. When Grew began to work, the study of botany was in a
very neglected condition—the old herbal had ceased to interest,
and, with its contemporary, the bestiary, was disappearing from
current use, while the work of some of Grew's contemporaries,
notably Robert Morison and John Ray, hastened their dis-
appearance. Of these two systematists, Ray, on the whole, was the
more successful. His classification of plants obtained in England
until the latter half of the eighteenth century, when it was gradually
replaced by the Linnaean method of classification.
But Ray has other claims on our regard. He and Francis
Willughby, both of Trinity college, attacked a similar problem in
the animal kingdom. Willughby was the only son of wealthy and
titled parents, while Ray was the son of a village blacksmith.
But the older universities are great levellers, and Ray succeeded
in infusing into his fellow student at Cambridge his own genuine
love for natural history. With Willughby, he started forth on his
methodical investigations of animals and plants in all the accessible
parts of the world. Willughby died young and bequeathed a
small benefaction and his manuscripts to his older friend. After
his death, Ray undertook to revise and complete his Ornithology,
and therein paid great attention to the internal anatomy, to the
habits and to the eggs of most of the birds he described. He, further,
edited Willughby's History of Fishes, but perpetuated the mistake
of his predecessors in retaining whales among that group.
In
rather rationalistic mood, he argues that the fish which swallowed
Jonah must have been a shark. Perhaps the weakest of their
three great histories—the History of Insects—was such owing
to the fact that Ray edited it in his old age.
Ray was always a fine field naturalist, and his catalogues of
Cambridgeshire plants long remained a classic. We may, perhaps,
## p. 283 (#313) ############################################
VIII] Ray, Willughby and Hooke 283
sum up the contributions of this great naturalist in the words of
Miall :
During his long and strenuous life he introduced many lasting improve-
ments-fuller descriptions, better definitions, better associations, better
sequences. He strove to rest his distinctions upon knowledge of structure,
which he personally investigated at every opportunity. . . . His greatest
single improvement was the division of the herbs into Monocotyledons and
Dicotyledons 1
Robert Hooke, a Westminster boy and, later, a student at
Christ Church, was at once instructor and assistant to Boyle.
The year that the Royal Society received their charter, they
appointed Hooke curator, and his duty was 'to furnish the
Society' every day they met with three or four considerable
experiments. This amazing task he fulfilled in spite of the fact
that the fabrication of instruments for experiments was not
commonly known to workmen,' and that he never received above
£50 a year and that not certain. ' Hooke was a man of amazing
versatility, very self-confident, attacking problems in all branches
of science, greatly aiding their advance, but avid of fame.
In person but dispicable, being crooked and low in nature and as he grew
older more and more deformed. He was always very pale and lean and
latterly nothing but skin and bone 2.
His active, jealous mind conceived that almost every discovery of
his time had been there initiated; and this anxiety to claim ‘priority'
induced Newton to suppress his treatise Optics until after the date
of Hooke's death. His book Micrographia, 'a most excellent
piece, of which I am very proud,' as Pepys has it, is the record of
what a modern schoolboy newly introduced to the microscope would
write down. Yet he was undoubtedly, although not a lovable
character, the best 'mechanic of his age. '
British physiology, which had started magnificently with
Harvey, and had continued under Mayow, de Mayerne and others,
was carried forward by Stephen Hales, at one time fellow of
Corpus Christi college, Cambridge, and for years perpetual curate
at Teddington. He was a born experimenter, and, as a student,
worked in the 'elaboratory of Trinity College, which had been
established under the rule of Bentley, ever anxious to make his
college the leader in every kind of learning. Sachs has pointed
out that, during the eighteenth century, the study of the anatomy
of plants made but little progress ; but there was a very real
1 The Early Naturalists, L. C. Miall, London, 1912.
? Waller's Life of Hooke, 1705.
## p. 284 (#314) ############################################
284 The Literature of Science [CH.
advance in our knowledge of plant physiology. This, in the main,
was due to Hales; he investigated the rate of transpiration and
held views as to the force causing the ascent of sap which have
recently come to their own; he recognised that the air might
be a source of food for the plant and connected the assimilative
function of leaves with the action of light,' though he failed to
find the mode of the interaction. He worked much on gases, and
paved the way for Priestley and others by devising methods of
collecting them over water. Hales, this 'poor, good, primitive
creature,' as Horace Walpole called him, was not less remarkable
as an investigator of animal physiology, and was the first to
measure the blood-pressure, and the rate of flow in the capillaries.
Sir Francis Darwin states:
In first opening the way to a correct appreciation of blood-pressure Hales'
work may rank second in importance to Harvey's in founding the modern
science of physiology.
He was, further, a man of 'many inventions,' especially in the fields
of ventilation and hygiene.
The beginning of our period coincides with the formation of
public museums. Previous to the Stewart times, collections of
‘natural objects' were, for the most part, housed in churches, in the
houses of the great, in coffee-houses and in the shops of apothe-
caries; but now public libraries were being established, and, in many
of these, botanical, geological and especially zoological specimens
found a home. In more than one Cambridge college, the library
still gives shelter to a skeleton, a relic of the time when anatomy
was taught within the college walls; and, at this day, the curious,
and, at times, inconvenient, yoke joining the museum at South
Kensington with the museum in Bloomsbury testifies to this
primitive state of affairs.
In 1728, John Woodward bequeathed his 'Fossils, a vast quan-
tities of Ores, Minerals and Shells, with other curiosities well
worth viewing' to Cambridge university; it was housed in the
university library and formed the nucleus about which the present
magnificent museum has collected. For many years, the Royal
Society maintained a museum which, at one time, contained 'the
stones taken out of Lord Belcarre's heart in a silver box,'. . .
‘a petrified fish, the skin of an antelope which died in St James'
Park, a petrified foetus' and 'a bottle full of stag's tears. ' The
trustees of Gresham college assigned the long gallery as a home
for these and other 'rarities'; but, when the society, in 1781,
migrated to Somerset house, the entire collection was handed over
## p. 285 (#315) ############################################
VIII] Origin of Museums
285
to the British Museum. The charter of the last named is dated
1753, and its beginnings were the library of Sir Robert Cotton,
wbich the nation had purchased in 1700, and the collections of
Sir Hans Sloane, which were now purchased with the proceeds of
a lottery, set on foot for this purpose. The collections of this
General Repository,' as the act of 1753 called the museum, were
kept together until the middle of the nineteenth century, when,
after long delay, the natural history objects were transferred to
South Kensington and housed in a building which, in all respects,
was worthy of the Board of Works of the time.
John Tradescant and his son of the same name accumulated
and stored in south Lambeth a 'museum which was considered to
be the most extensive in Europe at that time. It was acquired in
1659 by Elias Ashmole, and, with his own collections, passed
by gift, twenty-three years later, to Oxford university, the whole
forming the nucleus of the present Ashmolean museum.
Want of space precludes the consideration of other museums;
but it may be remarked that the earlier collectors got together
their treasures much as schoolboys now collect, their taste was
universal and no rarity was too trivial for their notice. Such collec-
tions excited popular interest, and 'a museum of curiosities' was
often an added attraction to the London coffee-house. At the end of
the eighteenth century, the coffee-house part of the enterprise was
dropped, and the museum, with an entrance-fee and a priced cata-
logue, formed a source of revenue to many a collector, most
of whom were not too scrupulous in their identifications. The
dime museums in the Bowery, New York, are their modern
successors. These museums were of little scientific or educational
value ; at best, they stimulated the imagination of the uninformed,
or allowed a child to see with his own eyes something he had read
about in his books. The normal, as a rule, was passed by, the
abnormal treasured. Ethnographical objects were collected, not
so much to arouse in the spectator a desire to study seriously
‘y® beastlie devices of yo heathen' as to excite and startle him
with their rough unfinish, on the one hand, and their high finish
on the other. The collections of the museums were ill arranged,
inaccurately labelled and inaccessible to students; the staff
were wholly inadequate and mainly dependent for their living
on admission fees. It was not until the nineteenth century
was well advanced that a systematic and scientific attempt
was made to identify specimens accurately, to arrange them
logically, to label them fully and, further, to collect in the
6
## p. 286 (#316) ############################################
286 The Literature of Science [CH.
background, unseen by the fleeting visitor, vast accumulations
of material for the investigation of the genuine student and
researcher.
Museums as centres of real education, not as places of wonder
and vacant amazement, are almost affairs of our time, and it
was not until the twentieth century that official guides were
appointed to explain their treasures to the enquiring visitor.
Even today, the system of weekly lectures on the contents of a
museum which obtains largely on the other side of the Atlantic
is, with us, only beginning.
We must not omit to mention the magnificent museum of the
Royal college of Surgeons, in London, which incorporates the
Hunterian collection brought together by John Hunter, and which
has been growing ever since his time. Of its kind, it is without a
rival in the world.
During the seventeenth century, men of science still, to a
great extent, remained the gifted amateurs they were at the time
of the foundation of the Royal Society; and yet they were very
successful in establishing many institutions which had a greater
effect on the advance of biological sciences than their founders
foresaw.
Towards the beginning of the seventeenth century, the Oxford
botanic garden had been founded (1621), which was followed, in
1667, by the opening of the Edinburgh botanic garden, and, in 1673,
by the foundation of the Chelsea physic garden, by the Apothe-
caries' company.
At the beginning of the eighteenth century,
Glasgow followed suit. By this time, many of the universities had
chairs of botany, and botany and anatomy were the first biological
sciences represented by professorial chairs in this country. In
1724, a chair was established at Cambridge, with Bradley as
its first professor ; but he and his immediate followers had little
success and, for the most part, were non-resident. Oxford
followed, in 1734, and Dillenius was the first to occupy the chair,
which had been founded by William Sherrard. The botanic
garden at Oxford, however, had been in existence for many years.
At Cambridge, it was not till 1759 that Walker founded the
botanic garden, which, at that time, occupied the northern site
of the present museums of science. The fine specimen of the
Sophora tree, the tree which yields the Chinese imperial yellow
dye, is the last and only memorial of this old botanic garden.
In 1765, Kew gardens, originally in possession of the Capel family,
were combined with Richmond gardens, then occupied by the
## p. 287 (#317) ############################################
viii] Botanic Gardens and Learned Societies 287
princess Augusta, widow of Frederick, prince of Wales.
In fact,
this lady may be regarded as the foundress of Kew, which, since
her time, has played the leading part in the dissemination of
botanical knowledge throughout the world.
In the latter half of the eighteenth century, the Linnaean
system of classification had been generally adopted in Great
Britain, and, in the year 1783, Sir James Edward Smith secured,
from the mother of Linnaeus, for £1050, the entire Linnaean
collections. These did not, however, reach these islands without
an effort on the part of the Swedish government to retrieve
them. Indeed, it sent a man-of-war after the ship which
transported them.
Following on this acquisition, Smith, in 1788, founded the
Linnaean society, the immediate effect of which, perhaps, was
to bring about a revolution in the mode of publishing scien-
tific literature From the first, the Linnaean society issued
journals and transactions instead of books or treatises; their
publications took the form of memoirs read before the society.
In this respect, the Linnaean society set a fashion which has been
consistently followed by the numerous societies which since have
sprung up.
The Royal Society had taken all science as its province, and
nothing in natural history was alien to the activities of the
Linnaean society ; but, with the beginning of the nineteenth
century, societies began to spring up in the metropolis which
devoted their energies to the advancement of one science alone.
The earliest effort was that of the Royal Horticultural society,
founded in 1803. Its first secretary was Joseph Sabine, to whom
much of its earlier success was due. For a time, it undertook
the training of gardeners and also sent collectors to foreign
countries in search of horticultural rarities. It still does much
for horticulture, especially by its very successful flower-shows.
The Geological society of London was founded in 1807. It was
partly the outcome of a previous club known as the Askesian
society, and among the more prominent founders were William
Babington, Humphry Davy, George Greenough and others. The
meetings were at first held at the Freemasons' tavern. The
society, like many other learned societies, now has rooms at
Burlington house.
The Zoological society of London for the advancement of
zoology and animal physiology, and for the introduction of new
and curious subjects of the animal kingdom was founded in
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288
[ch.
The Literature of Science
1826 by Sir Stamford Raffles, the wellknown traveller and governor
in the east and the godfather of Rafflesia, J. Sabine, N. A. Vigors
and other eminent naturalists. It was incorporated by royal
charter in 1829.
The Royal Botanic society was founded in 1839, and was
granted an area of eighteen acres within the inner circle of
Regent's park, and here Marnock laid out the gardens very much
as they still are. Shortly after its establishment, annual exhi-
bitions or flower-shows were begun, and such exhibitions, not
entirely confined to flowers, are still one of the features of the
society.
Another society which has played a most useful part in the
promotion of science is the Cambridge Philosophical society,
founded in the year 1819, the only society outside the capital
towns which possesses a royal charter. About the same time,
the Dublin society (founded in 1731) assumed the title royal
The Edinburgh Royal society was founded in 1783; the date of its
revised charter is 1811. Many other societies in our chief towns
did much to advance the cause of science; but they are too
numerous to record here.
Another institution which embraced all branches of science was
the British Association for the Advancement of Science, which was
due largely to the enterprise of Brewster, Babbage and Herschel
It held its first meeting in York in the year 1831. The objects of
its founders were
to give a stronger impulse and a more systematic direction to scientifie
enquiry, to promote the intercourse of those who cultivate science in different
parts of the British Empire with one another, and with foreign philosophers,
to obtain a more general attention the objects of science, and the removal
of any disadvantages of a public kind, which impede its progress.
With certain exceptions, the books on biology during the last
half of the eighteenth century and the beginning of the nineteenth,
were largely treatises on classification, or on the practical applica-
tion of the knowledge of plants, such as medical and agricultural
works. It was during this period, too, that certain magazines
were started. Curtis founded The Botanical Magazine in the
year 1787. But the great increase of scientific journals only
began some fifty years later; many of those dealing with different
branches of biological science were first published about the
middle of the nineteenth century. Among them may be men-
tioned the following, with the date of their first appearance:
The Annals and Magazine of Natural History, 1841 ; The
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VIII] Scientific Journals and Exploration 289
Zoologist, 1843 ; Quarterly Journal of Microscopical Science,
1853; The Journal of Horticulture, 1862; The Geological
Magazine, 1864; The Journal of Anatomy and Physiology,
1866.
Great advance was also being made in our knowledge of the
flora and fauna of the British dominions beyond the seas. Pro-
minent among explorers was Sir Joseph Banks, who studied the
flora of Newfoundland in 1766 and, later, accompanied by Solander
and others, started with Cook on his memorable voyage round
the world in the 'Endeavour. ' He returned to England in
1771 and, during the following year, visited Iceland. Banks's
very extensive explorations helped to make Kew the centre of
botanical activity, an activity which soon became world-wide.
It is worth recalling that his private secretary was the dis-
tinguished botanist Robert Brown, to whom he bequeathed his
herbarium and library. Brown took part in the celebrated expe-
dition of Flinders to Australia, which started in 1801, and added
greatly to our knowledge of the fauna and flora of Australasia.
Nor must it be forgotten that Brown was the first to observe the
cell-nucleus. This, as one of his biographers remarks, was a
triumph of genius,' for Brown worked only with the simple
microscope, and the technique of staining cells and tissues was
then unknown. It is interesting to note that the nucleus was
described and figured eight years before the surrounding proto-
plasm attracted attention. In fact, in the early part of the
nineteenth century, repeated improvements in the microscope
and in histological technique were demonstrating very clearly that
all living organisms, whether plant or animal, consist either of
a single cell or a complex of cells, and that they all began life
as a single cellular unit.
At the beginning of the nineteenth century, men of science
specialised less than now. Each branch of science was smaller,
and more than one branch could be grasped and studied by
the same observer. Among such men were J. S. Henslow and
Adam Sedgwick, the prime movers in the founding of the Cam-
bridge Philosophical society. Henslow, at first, devoted especial
attention to conchology, entomology and geology. He was a
professor of mineralogy at twenty-six, and with that power of
quick change of chair, once more prevalent than now, he became
professor of botany the following year. He was succeeded
in the chair of mineralogy by Whewell, which recalls the fact
that Whewell's History of the Inductive Sciences, one of the
19
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[Ch.
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wellknown Bridgewater treatises, played a large part in the
thought of our great-grandparents. Henslow was among the
first to insist upon practical work in his botanical classes. His
class dissected living plants, and investigated and recorded such
structure as they could make out. He provided them with
proper apparatus for dissections, and he saw that they studied
the physiology and the minute anatomy of plants as well as
external features.
Another striking feature of the British botanists of a hundred
years ago was their determined and steady effort to replace the
artificial Linnaean system by a more natural one. Prominent
among the men who gradually evolved a sounder view of the
interrelationship of plants were the elder Hooker, Robert Brown,
Sir Joseph Banks (“the greatest Englishman of his time'), Bentham
and, especially, John Lindley. Lindley was professor at the newly-
founded university college in Gower street; and this institution
took a very prominent part in the science of the century, being
untrammelled by restrictions which sorely retarded the advance-
ment of science at the older universities.
Plant pathology was, also, coming to the fore, and Miles
Joseph Berkeley was establishing a permanent reputation as a
systematic mycologist. He has, indeed, been called the origi-
nator and founder of plant pathology, and was the first to
recognise the economic importance of many fungoid plant
diseases. His work on Phytophthora infestans—the potato fungus
-(1846) is still a classic.
Another branch of science, of less economic but of more
academic interest, was plant palaeontology, which, under Witham,
Binney and Williamson—the last named was elected, in 1851,
professor of natural history, anatomy and physiology at the
newly-founded Owens college, Manchester—was rapidly forging
ahead, at any rate in the north of England. Here, chiefly, the
foundations were being laid for the very remarkable advances
which have been made in this branch of the subject since the
last quarter of the nineteenth century.
Modern geology, in Great Britain, might be said to begin with
James Hutton, who, after taking the degree of doctor of medicine
at Leyden, devoted himself to the cultivation of a small estate,
inherited from his father, and to practical chemistry. The lucrative
results of the latter employment enabled him to give himself up
wholly to scientific pursuits. His agricultural studies, especially
during his residence with a farmer in Norfolk, interested him in
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Geology
291
the various sediments deposited either by rivers or seas, and he
recognised that much of the present land had once been below
the sea. But he also investigated the movements of strata and the
origin of igneous rocks, and especially the nature and relations
of granite. The great and distinctive feature of Hutton's work
in geology is the strictly inductive method applied throughout.
He maintained that the great masses of the earth are the same
everywhere. He saw no occasion to have recourse to the
agency of any preternatural cause in explaining what actually
occurs,' and he remarks that, the result therefore of our present
enquiry is, that we find no vestige of a beginning—no prospect
of an end. '
John Playfair, a pupil and friend of Hutton, issued, in 1802,
a volume entitled Iustrations of the Huttonian Theory of the
Earth. Playfair, to quote Sir A. Geikie's words, was 'gifted with
a clear penetrating mind, a rare faculty of orderly logical arrange-
ment, and an English style of altogether remarkable precision and
elegance. ' He was an able exponent of his master's views and
capable of adding many observations and contributions of his own
to his convincing sketch of the Huttonian theory.
William Smith, whom Sedgwick called the 'father of English
Geology,' became interested in the structure of the earth's crust,
at first, from a land-surveyor's and engineer's point of view. He
was one of the earliest to recognise that each of the strata he
studied carefully contains animal and plant fossils peculiar to
itself, by which it can be identified. In 1815, he published his
geological map of England and Wales; and, between 1794 and
1821, he issued separate geological maps of many English counties.
Further he is responsible for introducing many terms—'arbitrary
and somewhat uncouth,' as Sedgwick remarked-which have
become the verbal currency of British geology.
Adam Sedgwick, whose personality made a deep impression
on his university, was appointed Woodwardian professor of
geology in 1818, and threw himself, with surprising vigour, into a
subject which, to him, at that time, was almost new.
He was
great as a teacher and as an exponent of his science, being gifted
with eloquence, and, as founder of the Sedgwick museum, he
greatly enlarged the collection got together by John Woodward,
who established the professorship. From 1819 to 1823, he worked
chiefly in the south and east of England ; then, he turned his
attention to Lake-land and, afterwards, in 1827, to Scotland (with
Murchison). In 1829, he went abroad with Murchison, visiting
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292 The Literature of Science [CH.
parts of Germany and the eastern Alps, the result being an
important joint paper on the latter (1829-30). In the long vaca-
tion of 1831, he attacked the problem of the ancient rocks in the
northern part of Wales, which, owing to the absence of good
maps or easy communication, the complicated structure of the
country and the frequent rarity or imperfect preservation of its
fossils, presented exceptional difficulties. In that and the follow-
ing summer (as well as in some later visits), he ascertained the
general succession of the rocks from the base of the Cambrian to
the top of the Bala, or of the whole series afterwards called Cam-
brian and lower Silurian (more recently Ordovician). Laborious
fieldwork became more difficult after an illness in 1839; but he
continued to extend and publish the results of his investigations
in Wales, in the Lake district and in the Permo-Triassic strata
of north-eastern England. Though he was a liberal in politics,
his inclinations as a geologist were conservative.
George Julius Poulett Scrope, by his studies of volcanic dis-
tricts in Italy, Sicily and Germany, and especially by his memoir
on the volcanoes of central France, and by his observations on the
erosion of valleys by rivers, did much to extend and confirm the
views of Hutton and Playfair. His remarks, also, on the lamination
and cleavage of rocks were highly suggestive; in fact, but for the
interruptions of politics, he would have hardly fallen behind his
friend Charles Lyell.
During the first half of the nineteenth century, the belief in a
universal deluge was widely held by geologists. William Buckland,
in his Reliquiae Diluvianae (1823), supported his belief by his
'Observations on the Organic Remains contained in Caves, Fissures
and Diluvial Gravel. ' But, both he and Sedgwick, without giving
up the view of a universal flood, abandoned, to some extent, the
evidence on which, at one time, they had based their belief.
Another geologist of great eminence was H. T. de la Beche,
whose ancestors really did come over with the Normang. His
Geological Manual was spoken of, at the time, as the best work of
its kind which had appeared in our country; and his Report on the
Geology of Cornwall, Devon and West Somerset (1839) is a
masterly production. He occupied himself for a long time in
a
making a geological survey of parts of Devon and Dorset on
one-inch ordnance maps, and was appointed, in 1832, by govern-
ment to conduct the geological survey of England, in which posi-
tion he superintended the erection of the Jermyn street museum.
The interest of (Sir) Charles Lyell in geology was aroused by
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Geology
293
a
the fascinating lectures of Buckland. He was trained, at first, for
the law; but his legal studies were arrested by a weakness in his
eyes, which, for a considerable time, prevented any continuous
reading, and troubled him more or less throughout life. But this
enforced rest enabled him to devote himself to geology, and, in
1824, he began systematic travel for that purpose. About 1827,
his future book—The Principles of Geology-began to take a
definite shape in his mind. In the spring of that year, with the
Murchisons, he visited Auvergne, passing to the south of France and
to the north of Italy as far as the Vicentine and the Euganean hills.
Thence he went to Naples and Sicily, studying not only their
volcanic districts, but, also, the tertiary fossils of other parts of
Italy, returning to London after an absence of more than three-
quarters of a year. The first volume of The Principles appeared
in 1831, while he was travelling in France and studying the extinct
volcanoes of Olot in Spain, the second volume early in 1832 and
the third in 1833. At a later date, the book was divided, the first
two volumes retaining the title Principles, and the third appearing,
in 1838, as The Elements of Geology. During these years, he con-
tinued his studies of European geology, extending his journeys to
Denmark and Scandinavia. In 1841, he began a twelvemonth's
journey in Canada and North America, an account of which is
given in Travels in North America, published early in 1845. The
same year he revisited that continent, making a much more
extended journey in the United States, which is recounted in his
Second Visit etc. , published in 1849. He returned, for shorter visits,
in 1852 and 1853, and, in 1854, went to Madeira and the Canary
islands. During the years between 1842 and 1859, he continued
his work in various parts of Europe, and, in the latter year,
appeared Darwin's Origin of Species. The study of this book
completed Lyell's conversion to the views expressed by Darwin',
and he also investigated the evidence in favour of the early
existence of man.
The results of these studies, with an account of the glacial
epoch, form the 'trilogy' entitled The Antiquity of Man, which
appeared early in 1863. After this time, his journeys, necessarily,
,
became shorter, though his interest in geology continued to be
as keen as ever, till, after a period of increasing weakness, he
died in February 1873.
Henry Clifton Sorby made his mark in more than one depart-
ment of science, to which a sufficiency of income enabled him to
| Prior to that he had been sceptical. See Darwin, Life and Letters, vol. 11, p. 229.
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devote his life ; but he will always be remembered as the father
of microscopic petrology. Thin slices of hard bodies had already
been made for examination under the microscope; but Sorby was
the first to perceive the value of this method for the examination
of rocks in general. In 1849, he made the first transparent section
of one with his own hands, publishing his first petrographical
study in 1851. In a few years, his example had been followed
both in England and in other countries, and the result has been
a vast increase in our knowledge of the mineral composition
and structures of rocks, and of many difficult problems in their
history.
Sir Roderick Impey Murchison was descended from a well-
known Scottish clan living in Ross-shire. He was brought up in
the army and took part in several of the engagements under
Wellesley in Portugal and Moore in Galicia. He was a man of means,
and having, at an early date, retired from the army, he occupied
himself at first with the active sports of a country gentleman. But,
his attention having been turned to science by Sir Humphry Davy,
he very soon became an eager and enthusiastic geologist. At first,
he especially devoted himself to the rocks of Sussex, Hants and
Surrey. Later, he explored the volcanic regions of Auvergne
and other parts of France, and of Italy, the Tyrol and Switzerland,
and, together with Sedgwick, published much on the geology of
the Alps. But it was not till 1831 that Murchison began his real
life's work, which was a definite enquiry into the stratification of
the rocks on the border of Wales. The result of his labours,
published in 1839, was the establishment of the Silurian system
and the record of strata older than and different from any that had
hitherto been described in these islands. In 1837, he and Sedgwick,
by their work in the south-west of England and the Rhineland,
established the Devonian system; and, in 1840, he extended his
investigations from Germany to Russia. In the following year, at
the desire of the Tsar, he travelled over a considerable part of
that country as far as the Ural mountains on the east and the sea
of Azov on the south. In 1855, he was appointed director general
of the geological survey and director of the museum in Jermyn
street, in both of which posts he succeeded Sir Henry de la Beche.
Towards the end of his life, he founded a chair of geology and
mineralogy at Edinburgh.
William Buckland was, perhaps, better known as a teacher
and as an exponent of his science than for any very outstanding
original investigation carried on by him in geology. Unlike
i
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VIII] Geology. Zoology
295
Sedgwick, however, he had made a systematic study of his subject
before he was appointed, in 1813, reader of mineralogy at Oxford.
In this post, he so aroused the interest of his students that a
readership in geology was specially endowed by the Treasury six
years later, of which he was the first holder. He was a man of
many accomplishments, and he by no means confined his attention
to geology. He entered with great zest into many practical
questions of the day, especially such as affected agriculture and
sanitary science. In 1845, he was appointed dean of Westminster,
and, shortly after this, his health began to decline.
We have mentioned above that men of science were less
specialised at the earlier part of our period than they have now
become. It is a peculiar feature of British science that many of
its most successful researchers were amateurs-gifted not only
with brains but with wealth. Many of those whose names we
mention held no kind of professional or academic posts. Even
the holding of professorial chairs in the earlier part of the nine-
teenth century usually involved teaching in more than one science.
To the year 1866, the professor of anatomy at Cambridge was
responsible for the teaching of zoology as well as for that of
anatomy. In many other places, the professorship of zoology was
responsible for what teaching there was in animal physiology, and,
in the London hospitals, strictly scientific subjects were then
taught by doctors in practice who were on the staff of the hospital.
It was not till the year 1883 that Michael Foster was appointed to
the professorship of physiology at Cambridge, though, as praelector
in that subject at Trinity college, he had been building up a great
physiological school for several years.
On the zoological side, one of the most productive morpho-
logical anatomists of the nineteenth century was Richard Owen,
Hunterian professor and, later, conservator of the museum of the
Royal college of Surgeons. In 1856, he became superintendent
of the natural history branch of the British Museum, and this post
he held until 1884. He added greatly to our knowledge of animal
structure by his successful dissection of many rare forms, such as
the pearly nautilus, limulus, lingula, apteryx and others, and,
following on the lines of Cuvier, he was particularly successful in
reconstructing extinct vertebrates. Another considerable advance
he made in science was the introduction of the terms 'homologous'
and 'analogous. ' His successor in both his posts, Sir William
Flower, an authority on cetacea and on mammals in general, took
an active part in arranging the contents of the museums under his
6
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296 The Literature of Science
[CH.
charge in such a way as to teach the intelligent public a lesson in
morphology and classification.
Throughout the century, repeated attempts had been made to
classify the members of the animal kingdom on a natural basis,
but, until their anatomy and, indeed, their embryology had been
sufficiently explored, these attempts proved somewhat vain. As
late as 1869, Huxley classified sponges with Protozoa, Echino-
derms with Scolecida and Tunicates with Polyzoa and Brachio-
poda. By the middle of the century, much work had been
done in sorting out the animal kingdom on a natural basis, and
Vaughan Thompson had already shown that Flustra was not
a hydroid, but a member of a new group which he named
Polyzoa. Although hardly remembered now, he demonstrated,
by tracing their development, that Cirripedia are not molluscs ;
he established the fact that they began life as free-swimming
Crustacea; he, again, it was who showed that Pentacrinus is
the larval form of the feather-star, Antedon.
Among marine biologists of eminence was Edward Forbes,
who was the first to investigate the distribution of marine
organisms at various depths in the sea; and he it was who de-
fined the areas associated with the bathymetrical distribution of
marine life, and pointed out that, as we descend into depths below
fifty fathoms, vegetable life tends to fade away and that aquatic
organisms become more and more modified.
The custom of naturalists to go on long voyages was still main-
tained. The younger Hooker accompanied Sir James Ross in the
'Erebus' on his voyage in search of the south magnetic pole; Huxley
sailed on the Rattlesnake' with Owen Stanley, and, on this voyage,
laid the foundation of his remarkable knowledge of the structure
of marine animals; Darwin sailed on the ‘Beagle' (1831—6) and,
among the many results of this memorable voyage, was his theory
of the structure and origin of coral-reefs. The invention of
telegraphy indirectly brought about a great advance in our know-
ledge of deep-sea fauna. It was necessary to survey the routes
upon which the large oceanic cables were to be laid, and, by the
inventions of new sounding and dredging instruments, it was
becoming possible to secure samples of the bottom fauna as well
as of the sub-stratum upon which it existed.
Other names
that occur in connection with deep-sea dredging are those of
Sir Wyville Thomson, of W. B. Carpenter and of J. Gwyn Jeffreys.
But by far the most important and, up to the present time,
unrivalled attempt to solve the mysteries of the seas was that of
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VIII] Zoological Exploration 297
H. M. S. 'Challenger,' which was despatched by the admiralty at
the close of the year 1872, the results of whose voyage have
appeared in some eighty quarto volumes. The results of the
exploration of the sea by the Challenger' have never been
equalled. In one respect, however, they were disappointing. It
had been hoped that, in the deeper abysms of the sea, creatures
whom we only know as geological, fossilised, bony specimens,
might be found in the flesh; but, with one or two exceptions-
and these of no great importance—such were not found. Neither
did any new type of organism appear. Nothing, in fact, was
dredged from the depths or found in the tow-net that did not fit
into the larger groups which already had been established before
the 'Challenger' was thought of. On the other hand, many new
methods of research were developed during this voyage, and
with it will ever be associated the names of Wyville Thomson,
mentioned above, Moseley, John Murray and others who, happily,
are still with us.
During the nineteenth century, many other expeditions left
Great Britain to explore the natural history of the world, some
the result of public, some of private, enterprise. They are too
numerous to mention. But a word must be said about the
wonderful exploration of central America which has just been com-
pleted, under the auspices of F. D. Goodman and 0. Salvin. The
results are incorporated in a series of magnificently illustrated
quarto volumes which have been issued during the last thirty-six
years. Fifty-two of these relate to zoology, five to botany and
six to archaeology. Nearly forty thousand species of animals
have been described, of which about twenty thousand are new,
and nearly twelve thousand species of plants. There are few
remote and partially civilised areas of the world whose zoology
and botany are on so secure a basis, and this is entirely owing
to the munificence and enterprise of the above mentioned men of
science.
greatly advanced the science of chemistry.
So long as chemists formed vague generalisations founded on
introspective speculations, they made little progress. It was by
concentrating their attention on a few limited occurrences, and
accurately examining these by quantitative experiments, that
chemists gradually gained clear conceptions which could be
directly used in the investigation of more complicated chemical
changes. “True genius,' Coleridge said, 'begins by generalising
and condensing; it ends in realising and expanding. ' The vague
generalising of the alchemists was followed by the condensing
work of Black and Cavendish, and by the suggestive discoveries of
Priestley. The time was approaching for realising and expanding.
In 1808, a small book appeared, entitled A new system of
Chemical Philosophy, Part I, by John Dalton. The influence of
that book on the development of chemistry, and of physics also,
has been very great.
Dalton delivered a lecture in Manchester, in 1803, wherein he
said 'An enquiry into the relative weights of the ultimate particles
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of bodies is a subject, so far as I know, entirely new; I have lately
been prosecuting this enquiry with remarkable success. ' Many of
Dalton's predecessors, both chemists and physicists, had used, in a
vague and general manner, the Greek conception of the atomic
structure of matter. Dalton showed how the relative weights of
atoms can be determined. By doing that, he brought down the
atomic theory to the solid earth, and made it a bold, suggestive,
stimulating guide ready for the use of chemists and physicists.
Dalton was not a great experimenter; he generally used the
results of other chemists' experiments. He was a scientific thinker,
characterised by boldness and caution. Dalton assumed, as
Lucretius had done long before him, that matter has a grained
structure ; that all the ultimate particles of each particular
homogeneous substance are identical, and differ in properties,
one of which is their weight, from the particles of all other
definite substances; he also assumed that the mechanism of
chemical changes, that is, changes wherein homogeneous substances
are produced different from those present when the changes began,
is the coalescence of atoms of different kinds to form new sorts of
atoms.
In order to find the relative weights of atoms, Dalton argued
as follows: Analyses and syntheses of water show that eight
grains of oxygen unite with one grain of hydrogen to form water.
If this change is the union of atoms of oxygen with atoms of
hydrogen, to form atoms of water, and if all the atoms of each
one of these three homogeneous substances are identical in weight
and other properties, it follows that an atom of oxygen is eight
times heavier than an atom of hydrogen. If we take the atomic
weight of hydrogen as unity—because hydrogen is lighter than
any other known substance—then the atomic weight of oxygen is
eight, and the atomic weight of water is nine.
In arriving at the conclusion that the atomic weight of oxygen
is eight, if the atomic weight of hydrogen is one, Dalton made the
assumption that a single atom of oxygen unites with one atom of
hydrogen to form an atom of water. He made this assumption
because it was simpler than any other. Had he chosen to suppose
that two atoms of hydrogen unite with one atom of oxygen, he
must have assigned to oxygen the atomic weight sixteen, and to
water the atomic weight eighteen.
To make Dalton's method perfectly general, and quite conclusive
in its results, it was necessary to find means for fixing the relative
weights of the atoms formed by the union of other, simpler, atoms;
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VII] The Atomic Theory. Dalton and Others 277
it was also necessary to find means of determining the number of
atoms of each kind which unite to form a more complex atom.
A general method for solving these two problems was given to
chemistry in 1811–12 by an Italian physical chemist named
Avogadro, who brought into science the notion of a second order
of minute particles, supplementing the conception of atom by that
of molecule.
It is not possible in this brief sketch to indicate the many new
fields of investigation which were opened, and made fruitful, by
the Daltonian atomic theory. From the many workers who used
this theory as a means for pressing forward along new lines of
enquiry, two may be selected, since their work is typical of much
that was done in chemistry during the first half of the nineteenth
century.
Alexander Williamson strove to make chemists realise the need
of using the Avogadrean molecule as well as the Daltonian atom.
By his work on etherification, and by other experimental investiga-
tions, as well as by reasoning on his own results and those obtained
by other chemists, Williamson demonstrated the fruitfulness of
the notion of the molecule. He endeavoured to determine the
relative weights of molecules by purely chemical methods. These
methods proved to be less satisfactory, and much less general,
than the physical method which had been described by Avogadro.
The conception of equivalency, that is, equal value in exchange,
of determinate weights of different homogeneous substances, has
been very helpful in chemistry. In 1852, Edward Frankland
applied the notion of equivalency to the atoms of elements, that
is, homogeneous substances which have not been separated into
unlike parts. He arranged the elements in groups, the atoms of
those in any one group being of equal value in exchange, inasmuch
as each of these atoms combines with the same number of other
atoms to form molecules.
When Frankland's conception had been developed, and the
method of determining the equivalency of atoms made more
definite and more workable, a vast new field of enquiry was
opened, a eld which has proved remarkably fruitful both in
purely scientific work, and in applied chemistry. It is not an
exaggeration to say that the great industry of making aniline
colours is an outcome of the notion of atomic equivalency intro-
duced by Frankland into chemical science.
The words element and principle were used by the alchemist
as nearly synonymous; both words were used vaguely. The
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meaning given to the term element, by Lavoisier, towards the
end of the eighteenth century—a definite kind of matter which
has not been decomposed, that is, separated into unlike parts-
was elucidated, and confirmed as the only fruitful connotation
of the term by the work of Sir Humphry Davy on potash and soda
in 1808.
Humphry Davy was the most brilliant of English chemists.
He was the friend of Wordsworth and Sir Walter Scott. Lockhart
says that the conversation of Davy and Scott was fascinating and
invigorating. Each drew out the powers of the other.
6
I remember William Laidlaw whispering to me, one night when their
‘rapt talk 'had kept the circle round the fire until long after the usual bedtime
of Abbotsford-Gude preserve us! this is a very superior occasion 1! '
Davy sent an electric current through pieces of potash and soda;
the solids melted, and 'small globules, having a high metallic
lustre, and being precisely similar in visible characters to quick-
silver, appeared. By burning the metal-like globules, Davy
'
obtained potash and soda. Making his experiments quantitative,
weighing the potash and the soda before passing the current, and
the potash and soda obtained by burning the metal-like products
of the first change, he proved that potash and soda, which, at that
time, were classed with the elements, are composed each of a metal
combined with oxygen. The new metals—potassium and sodium-
are soft and very light, and instantly combine with oxygen when
they are exposed to the air.
Everyone had been accustomed to think of a metal as a heavy,
hard solid, unchanged, or very slowly changed, by exposure to air.
Had chemists strictly defined the term metal, they could not have
allowed the bases of potash and soda (as Davy called the new sub-
stances) to be included among metals. Happily, the definitions of
natural science are not as the definitions of the logician; they are
descriptive summaries of what is known, and suggestive guides to
further enquiry.
As every attempt to separate potassium and sodium into unlike
parts failed, Davy put them into the class elements ; he said—Till
a body is decomposed, it should be considered as simple. '
In 1810, Davy investigated a substance concerning the
composition of which a fierce controversy raged. Oxymuriatic
acid was said by almost all chemists at that time to be a compound
of oxygen with an unknown base. No one had been able to get
1 Life of Sir Walter Scott (6 vols. , 1900), vol. III, p. 403.
## p. 279 (#309) ############################################
a
6
VII] Davy. Physical Chemistry
279
oxygen from it, or to isolate the base supposed to be a constituent
of it. By putting away, for the time, all hypotheses and specula-
tions, and by conducting his experiments quantitatively, Davy
showed that oxymuriatic acid is not an acid, but is a simple
substance, that is, a substance which is not decomposed in any
of the changes it undergoes. He proposed to name this simple
substance chlorine ; a name, Davy said, 'founded upon one of its
obvious and characteristic properties-its colour. ' Davy re-
marked— Names should express things not opinions. '
Davy thought much about the connections between chemical
affinity and electrical energy, and investigated these connections
by well planned experiments. In 1807, he said—May not the
electrical energy be identical with chemical affinity ? ' He used
the expressions—'different electrical states,' and 'degrees of
exaltation of the electrical states,' of the particles of bodies.
Recent researches into the subject of chemical affinity have
established the great importance of the conceptions adumbrated
by Davy in these expressions.
Chemistry, the study of the changes of composition and
properties which happen when homogeneous substances interact,
has always been closely connected with physics, the study of the
behaviour of substances apart from those interactions of them
in which composition is changed. Among the earlier physical
chemists, Graham occupies an important place.
Thomas Graham was a shy, retiring man, most of whose life
was spent in his laboratory. There is a tradition in the Glasgow
institution, where he taught chemistry, in his younger days, before
moving to London (in his later years he was master of the mint),
that, when he came into the lecture theatre, to deliver his first
lecture to a large audience, he looked around in dismay and fled.
Graham established the fundamental phenomena of the diffusion
of gases and of liquids; he distinguished, and applied the distinction,
between crystalloids, solutions of which pass through animal and
vegetable membranes, and colloids, which do not pass through
those membranes. The investigation of the behaviour of colloidal
substances has led, in recent years, to great advances in the
knowledge of phenomena common to chemistry, physics and
biology.
Electrochemistry, the study of the connections between chemical
and electrical actions, has been productive, in recent years, of more
far-reaching results than have been obtained in any other branch
of physical chemistry. Much of what has been done in the last
a
## p. 280 (#310) ############################################
280 The Literature of Science [CH.
half-century is based on the work of Faraday, and, indirectly, on the
suggestion of Davy. Both were men of genius, that is, men who
see the central position of the problem they are investigating, who
seize and hold that position until the problem is solved, letting the
surface phenomena, for the time, go to the dogs, what matters? '
Men of genius work from the centre outwards.
To Michael Faraday, we owe the fundamental terms of electro-
chemistry. The separation of a salt into two parts by the electric
current, he called electrolysis ; the surfaces from which the current
passes into, and out of, an electrolysable compound, he named
electrodes; the substances liberated at the electrodes, he called
ions. Faraday measured the chemical power of a current' by
the quantities of the ions set free during a determinate period
of electrolysis. Taking as his unit the quantity of electricity
which liberates one gram of hydrogen from an electrolysable
compound of that element, he showed that the weights of different
ions liberated from compounds by unit quantity of electricity are
in the proportion of their chemical equivalents. Using the language
of the atomic theory, Faraday declared that 'the atoms of bodies
which are equivalent to each other in their ordinary chemical action
have equal quantities of electricity mutually associated with them. '
In 1834, Faraday said— The forces called electricity and
chemical affinity are one and the same. ' Faraday distinguished
the intensity of electricity from the quantity of it, and indicated
the meaning of each of these factors. One would not greatly
exaggerate if one said that the notable advances made in the
last quarter of a century in the elucidation of chemical affinity
are but developments and applications of Faraday's pregnant
work on the two factors of electrical energy.
The results established by Faraday have led to the conception
of atoms of electricity, a conception which has been of great
service in advancing the study of radioactivity. Faraday's results
have also been the incentives and guides in researches which go
to the root of many problems of the physical sciences, and of not
a few of the biological sciences also.
At the time of the foundation of the Royal Society, chemistry
was a conglomeration of more or less useful recipes, and a dream
of the elixir. Today, chemistry is becoming an almost universal
science. Happily, chemists still dream.
## p. 281 (#311) ############################################
VIII]
Biology
281
C. BIOLOGY
6
Although science, during the eighteenth century, was, like
many other intellectual activities in our country, more or less
in abeyance, an attempt has been made, in the following pages,
to carry on the subject in the present chapter from that which
appeared in a previous volume (VIII) of this History.
'The Royal Society of London for Improving Natural Know-
ledge, one of the oldest scientific societies in the world and
certainly the oldest in the empire, was formally founded in 1660,
and received its royal charter of incorporation two years later.
At a preliminary meeting, a list had been prepared of some forty
names of such persons as were known to those present whom
they judged willing and fit to joyne. . . in the designe,' and among
these names we find those of 'Mr Robert Boyle, Sir Kenelme
Digby, Mr Evelyn, Dr Ward, Dr Wallis, Dr Glisson, Dr Ent,
Dr Cowley, Dr Willis, Dr Wren' names whose owners have been
dwelt upon in volume VIII.
Thus, for the first time in our country, the study of science was,
to a degree, organised and its advancement promoted, not only
by periodical meetings where experiments were conducted and
criticism freely offered, but by the collection of scientific books,
which still remain at Burlington house, and of 'natural objects,
which have for long formed part of the British Museum's
collections.
So Virtuous and so Noble a Design,
So Human for its Use, for Knowledge so Divine,
as Abraham Cowley, the laureate of the new movement, wrote,
was, in part, a protest against the credulity and superstitions of
a credulous and superstitious age, and the word ‘natural, as
used in the charter, was used in deliberate opposition to “super-
natural,' the aim of the society being, at any rate in part, to
discourage divination and witchcraft.
We have said something about the brilliant band of physio-
logists, headed by Harvey, who made the Stewart period remarkable
in the annals of English science; though there were then other
biologists less gifted than Harvey, but still leaders in their several
fields. The recent invention of the microscope had given a great
impetus to the study of the anatomical structure of plants and,
later, of animals; and, in relation to this, we must not overlook
## p. 282 (#312) ############################################
282 The Literature of Science [CH.
the work of Nehemiah Grew, who, with the Italian Malpighi, may
be considered a co-founder of the science of plant-anatomy.
Nehemiah Grew studied at Pembroke hall, Cambridge, and after-
wards took his doctor's degree at Leyden. He published numerous
treatises dealing with the anatomy of vegetables, and with the
comparative anatomy of trunks, roots, and so forth, illustrated
by admirable, if somewhat diagrammatic, plates. Although
essentially an anatomist, he made certain investigations into
plant physiology and suggested many more. Perhaps his most
interesting contribution to botany, however, was his discovery
that flowering plants, like animals, have male and female sexes.
It seems odd to reflect that this discovery is only about 250 years
old. When Grew began to work, the study of botany was in a
very neglected condition—the old herbal had ceased to interest,
and, with its contemporary, the bestiary, was disappearing from
current use, while the work of some of Grew's contemporaries,
notably Robert Morison and John Ray, hastened their dis-
appearance. Of these two systematists, Ray, on the whole, was the
more successful. His classification of plants obtained in England
until the latter half of the eighteenth century, when it was gradually
replaced by the Linnaean method of classification.
But Ray has other claims on our regard. He and Francis
Willughby, both of Trinity college, attacked a similar problem in
the animal kingdom. Willughby was the only son of wealthy and
titled parents, while Ray was the son of a village blacksmith.
But the older universities are great levellers, and Ray succeeded
in infusing into his fellow student at Cambridge his own genuine
love for natural history. With Willughby, he started forth on his
methodical investigations of animals and plants in all the accessible
parts of the world. Willughby died young and bequeathed a
small benefaction and his manuscripts to his older friend. After
his death, Ray undertook to revise and complete his Ornithology,
and therein paid great attention to the internal anatomy, to the
habits and to the eggs of most of the birds he described. He, further,
edited Willughby's History of Fishes, but perpetuated the mistake
of his predecessors in retaining whales among that group.
In
rather rationalistic mood, he argues that the fish which swallowed
Jonah must have been a shark. Perhaps the weakest of their
three great histories—the History of Insects—was such owing
to the fact that Ray edited it in his old age.
Ray was always a fine field naturalist, and his catalogues of
Cambridgeshire plants long remained a classic. We may, perhaps,
## p. 283 (#313) ############################################
VIII] Ray, Willughby and Hooke 283
sum up the contributions of this great naturalist in the words of
Miall :
During his long and strenuous life he introduced many lasting improve-
ments-fuller descriptions, better definitions, better associations, better
sequences. He strove to rest his distinctions upon knowledge of structure,
which he personally investigated at every opportunity. . . . His greatest
single improvement was the division of the herbs into Monocotyledons and
Dicotyledons 1
Robert Hooke, a Westminster boy and, later, a student at
Christ Church, was at once instructor and assistant to Boyle.
The year that the Royal Society received their charter, they
appointed Hooke curator, and his duty was 'to furnish the
Society' every day they met with three or four considerable
experiments. This amazing task he fulfilled in spite of the fact
that the fabrication of instruments for experiments was not
commonly known to workmen,' and that he never received above
£50 a year and that not certain. ' Hooke was a man of amazing
versatility, very self-confident, attacking problems in all branches
of science, greatly aiding their advance, but avid of fame.
In person but dispicable, being crooked and low in nature and as he grew
older more and more deformed. He was always very pale and lean and
latterly nothing but skin and bone 2.
His active, jealous mind conceived that almost every discovery of
his time had been there initiated; and this anxiety to claim ‘priority'
induced Newton to suppress his treatise Optics until after the date
of Hooke's death. His book Micrographia, 'a most excellent
piece, of which I am very proud,' as Pepys has it, is the record of
what a modern schoolboy newly introduced to the microscope would
write down. Yet he was undoubtedly, although not a lovable
character, the best 'mechanic of his age. '
British physiology, which had started magnificently with
Harvey, and had continued under Mayow, de Mayerne and others,
was carried forward by Stephen Hales, at one time fellow of
Corpus Christi college, Cambridge, and for years perpetual curate
at Teddington. He was a born experimenter, and, as a student,
worked in the 'elaboratory of Trinity College, which had been
established under the rule of Bentley, ever anxious to make his
college the leader in every kind of learning. Sachs has pointed
out that, during the eighteenth century, the study of the anatomy
of plants made but little progress ; but there was a very real
1 The Early Naturalists, L. C. Miall, London, 1912.
? Waller's Life of Hooke, 1705.
## p. 284 (#314) ############################################
284 The Literature of Science [CH.
advance in our knowledge of plant physiology. This, in the main,
was due to Hales; he investigated the rate of transpiration and
held views as to the force causing the ascent of sap which have
recently come to their own; he recognised that the air might
be a source of food for the plant and connected the assimilative
function of leaves with the action of light,' though he failed to
find the mode of the interaction. He worked much on gases, and
paved the way for Priestley and others by devising methods of
collecting them over water. Hales, this 'poor, good, primitive
creature,' as Horace Walpole called him, was not less remarkable
as an investigator of animal physiology, and was the first to
measure the blood-pressure, and the rate of flow in the capillaries.
Sir Francis Darwin states:
In first opening the way to a correct appreciation of blood-pressure Hales'
work may rank second in importance to Harvey's in founding the modern
science of physiology.
He was, further, a man of 'many inventions,' especially in the fields
of ventilation and hygiene.
The beginning of our period coincides with the formation of
public museums. Previous to the Stewart times, collections of
‘natural objects' were, for the most part, housed in churches, in the
houses of the great, in coffee-houses and in the shops of apothe-
caries; but now public libraries were being established, and, in many
of these, botanical, geological and especially zoological specimens
found a home. In more than one Cambridge college, the library
still gives shelter to a skeleton, a relic of the time when anatomy
was taught within the college walls; and, at this day, the curious,
and, at times, inconvenient, yoke joining the museum at South
Kensington with the museum in Bloomsbury testifies to this
primitive state of affairs.
In 1728, John Woodward bequeathed his 'Fossils, a vast quan-
tities of Ores, Minerals and Shells, with other curiosities well
worth viewing' to Cambridge university; it was housed in the
university library and formed the nucleus about which the present
magnificent museum has collected. For many years, the Royal
Society maintained a museum which, at one time, contained 'the
stones taken out of Lord Belcarre's heart in a silver box,'. . .
‘a petrified fish, the skin of an antelope which died in St James'
Park, a petrified foetus' and 'a bottle full of stag's tears. ' The
trustees of Gresham college assigned the long gallery as a home
for these and other 'rarities'; but, when the society, in 1781,
migrated to Somerset house, the entire collection was handed over
## p. 285 (#315) ############################################
VIII] Origin of Museums
285
to the British Museum. The charter of the last named is dated
1753, and its beginnings were the library of Sir Robert Cotton,
wbich the nation had purchased in 1700, and the collections of
Sir Hans Sloane, which were now purchased with the proceeds of
a lottery, set on foot for this purpose. The collections of this
General Repository,' as the act of 1753 called the museum, were
kept together until the middle of the nineteenth century, when,
after long delay, the natural history objects were transferred to
South Kensington and housed in a building which, in all respects,
was worthy of the Board of Works of the time.
John Tradescant and his son of the same name accumulated
and stored in south Lambeth a 'museum which was considered to
be the most extensive in Europe at that time. It was acquired in
1659 by Elias Ashmole, and, with his own collections, passed
by gift, twenty-three years later, to Oxford university, the whole
forming the nucleus of the present Ashmolean museum.
Want of space precludes the consideration of other museums;
but it may be remarked that the earlier collectors got together
their treasures much as schoolboys now collect, their taste was
universal and no rarity was too trivial for their notice. Such collec-
tions excited popular interest, and 'a museum of curiosities' was
often an added attraction to the London coffee-house. At the end of
the eighteenth century, the coffee-house part of the enterprise was
dropped, and the museum, with an entrance-fee and a priced cata-
logue, formed a source of revenue to many a collector, most
of whom were not too scrupulous in their identifications. The
dime museums in the Bowery, New York, are their modern
successors. These museums were of little scientific or educational
value ; at best, they stimulated the imagination of the uninformed,
or allowed a child to see with his own eyes something he had read
about in his books. The normal, as a rule, was passed by, the
abnormal treasured. Ethnographical objects were collected, not
so much to arouse in the spectator a desire to study seriously
‘y® beastlie devices of yo heathen' as to excite and startle him
with their rough unfinish, on the one hand, and their high finish
on the other. The collections of the museums were ill arranged,
inaccurately labelled and inaccessible to students; the staff
were wholly inadequate and mainly dependent for their living
on admission fees. It was not until the nineteenth century
was well advanced that a systematic and scientific attempt
was made to identify specimens accurately, to arrange them
logically, to label them fully and, further, to collect in the
6
## p. 286 (#316) ############################################
286 The Literature of Science [CH.
background, unseen by the fleeting visitor, vast accumulations
of material for the investigation of the genuine student and
researcher.
Museums as centres of real education, not as places of wonder
and vacant amazement, are almost affairs of our time, and it
was not until the twentieth century that official guides were
appointed to explain their treasures to the enquiring visitor.
Even today, the system of weekly lectures on the contents of a
museum which obtains largely on the other side of the Atlantic
is, with us, only beginning.
We must not omit to mention the magnificent museum of the
Royal college of Surgeons, in London, which incorporates the
Hunterian collection brought together by John Hunter, and which
has been growing ever since his time. Of its kind, it is without a
rival in the world.
During the seventeenth century, men of science still, to a
great extent, remained the gifted amateurs they were at the time
of the foundation of the Royal Society; and yet they were very
successful in establishing many institutions which had a greater
effect on the advance of biological sciences than their founders
foresaw.
Towards the beginning of the seventeenth century, the Oxford
botanic garden had been founded (1621), which was followed, in
1667, by the opening of the Edinburgh botanic garden, and, in 1673,
by the foundation of the Chelsea physic garden, by the Apothe-
caries' company.
At the beginning of the eighteenth century,
Glasgow followed suit. By this time, many of the universities had
chairs of botany, and botany and anatomy were the first biological
sciences represented by professorial chairs in this country. In
1724, a chair was established at Cambridge, with Bradley as
its first professor ; but he and his immediate followers had little
success and, for the most part, were non-resident. Oxford
followed, in 1734, and Dillenius was the first to occupy the chair,
which had been founded by William Sherrard. The botanic
garden at Oxford, however, had been in existence for many years.
At Cambridge, it was not till 1759 that Walker founded the
botanic garden, which, at that time, occupied the northern site
of the present museums of science. The fine specimen of the
Sophora tree, the tree which yields the Chinese imperial yellow
dye, is the last and only memorial of this old botanic garden.
In 1765, Kew gardens, originally in possession of the Capel family,
were combined with Richmond gardens, then occupied by the
## p. 287 (#317) ############################################
viii] Botanic Gardens and Learned Societies 287
princess Augusta, widow of Frederick, prince of Wales.
In fact,
this lady may be regarded as the foundress of Kew, which, since
her time, has played the leading part in the dissemination of
botanical knowledge throughout the world.
In the latter half of the eighteenth century, the Linnaean
system of classification had been generally adopted in Great
Britain, and, in the year 1783, Sir James Edward Smith secured,
from the mother of Linnaeus, for £1050, the entire Linnaean
collections. These did not, however, reach these islands without
an effort on the part of the Swedish government to retrieve
them. Indeed, it sent a man-of-war after the ship which
transported them.
Following on this acquisition, Smith, in 1788, founded the
Linnaean society, the immediate effect of which, perhaps, was
to bring about a revolution in the mode of publishing scien-
tific literature From the first, the Linnaean society issued
journals and transactions instead of books or treatises; their
publications took the form of memoirs read before the society.
In this respect, the Linnaean society set a fashion which has been
consistently followed by the numerous societies which since have
sprung up.
The Royal Society had taken all science as its province, and
nothing in natural history was alien to the activities of the
Linnaean society ; but, with the beginning of the nineteenth
century, societies began to spring up in the metropolis which
devoted their energies to the advancement of one science alone.
The earliest effort was that of the Royal Horticultural society,
founded in 1803. Its first secretary was Joseph Sabine, to whom
much of its earlier success was due. For a time, it undertook
the training of gardeners and also sent collectors to foreign
countries in search of horticultural rarities. It still does much
for horticulture, especially by its very successful flower-shows.
The Geological society of London was founded in 1807. It was
partly the outcome of a previous club known as the Askesian
society, and among the more prominent founders were William
Babington, Humphry Davy, George Greenough and others. The
meetings were at first held at the Freemasons' tavern. The
society, like many other learned societies, now has rooms at
Burlington house.
The Zoological society of London for the advancement of
zoology and animal physiology, and for the introduction of new
and curious subjects of the animal kingdom was founded in
## p. 288 (#318) ############################################
288
[ch.
The Literature of Science
1826 by Sir Stamford Raffles, the wellknown traveller and governor
in the east and the godfather of Rafflesia, J. Sabine, N. A. Vigors
and other eminent naturalists. It was incorporated by royal
charter in 1829.
The Royal Botanic society was founded in 1839, and was
granted an area of eighteen acres within the inner circle of
Regent's park, and here Marnock laid out the gardens very much
as they still are. Shortly after its establishment, annual exhi-
bitions or flower-shows were begun, and such exhibitions, not
entirely confined to flowers, are still one of the features of the
society.
Another society which has played a most useful part in the
promotion of science is the Cambridge Philosophical society,
founded in the year 1819, the only society outside the capital
towns which possesses a royal charter. About the same time,
the Dublin society (founded in 1731) assumed the title royal
The Edinburgh Royal society was founded in 1783; the date of its
revised charter is 1811. Many other societies in our chief towns
did much to advance the cause of science; but they are too
numerous to record here.
Another institution which embraced all branches of science was
the British Association for the Advancement of Science, which was
due largely to the enterprise of Brewster, Babbage and Herschel
It held its first meeting in York in the year 1831. The objects of
its founders were
to give a stronger impulse and a more systematic direction to scientifie
enquiry, to promote the intercourse of those who cultivate science in different
parts of the British Empire with one another, and with foreign philosophers,
to obtain a more general attention the objects of science, and the removal
of any disadvantages of a public kind, which impede its progress.
With certain exceptions, the books on biology during the last
half of the eighteenth century and the beginning of the nineteenth,
were largely treatises on classification, or on the practical applica-
tion of the knowledge of plants, such as medical and agricultural
works. It was during this period, too, that certain magazines
were started. Curtis founded The Botanical Magazine in the
year 1787. But the great increase of scientific journals only
began some fifty years later; many of those dealing with different
branches of biological science were first published about the
middle of the nineteenth century. Among them may be men-
tioned the following, with the date of their first appearance:
The Annals and Magazine of Natural History, 1841 ; The
## p. 289 (#319) ############################################
VIII] Scientific Journals and Exploration 289
Zoologist, 1843 ; Quarterly Journal of Microscopical Science,
1853; The Journal of Horticulture, 1862; The Geological
Magazine, 1864; The Journal of Anatomy and Physiology,
1866.
Great advance was also being made in our knowledge of the
flora and fauna of the British dominions beyond the seas. Pro-
minent among explorers was Sir Joseph Banks, who studied the
flora of Newfoundland in 1766 and, later, accompanied by Solander
and others, started with Cook on his memorable voyage round
the world in the 'Endeavour. ' He returned to England in
1771 and, during the following year, visited Iceland. Banks's
very extensive explorations helped to make Kew the centre of
botanical activity, an activity which soon became world-wide.
It is worth recalling that his private secretary was the dis-
tinguished botanist Robert Brown, to whom he bequeathed his
herbarium and library. Brown took part in the celebrated expe-
dition of Flinders to Australia, which started in 1801, and added
greatly to our knowledge of the fauna and flora of Australasia.
Nor must it be forgotten that Brown was the first to observe the
cell-nucleus. This, as one of his biographers remarks, was a
triumph of genius,' for Brown worked only with the simple
microscope, and the technique of staining cells and tissues was
then unknown. It is interesting to note that the nucleus was
described and figured eight years before the surrounding proto-
plasm attracted attention. In fact, in the early part of the
nineteenth century, repeated improvements in the microscope
and in histological technique were demonstrating very clearly that
all living organisms, whether plant or animal, consist either of
a single cell or a complex of cells, and that they all began life
as a single cellular unit.
At the beginning of the nineteenth century, men of science
specialised less than now. Each branch of science was smaller,
and more than one branch could be grasped and studied by
the same observer. Among such men were J. S. Henslow and
Adam Sedgwick, the prime movers in the founding of the Cam-
bridge Philosophical society. Henslow, at first, devoted especial
attention to conchology, entomology and geology. He was a
professor of mineralogy at twenty-six, and with that power of
quick change of chair, once more prevalent than now, he became
professor of botany the following year. He was succeeded
in the chair of mineralogy by Whewell, which recalls the fact
that Whewell's History of the Inductive Sciences, one of the
19
E, L, XIV.
CH. VIII.
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wellknown Bridgewater treatises, played a large part in the
thought of our great-grandparents. Henslow was among the
first to insist upon practical work in his botanical classes. His
class dissected living plants, and investigated and recorded such
structure as they could make out. He provided them with
proper apparatus for dissections, and he saw that they studied
the physiology and the minute anatomy of plants as well as
external features.
Another striking feature of the British botanists of a hundred
years ago was their determined and steady effort to replace the
artificial Linnaean system by a more natural one. Prominent
among the men who gradually evolved a sounder view of the
interrelationship of plants were the elder Hooker, Robert Brown,
Sir Joseph Banks (“the greatest Englishman of his time'), Bentham
and, especially, John Lindley. Lindley was professor at the newly-
founded university college in Gower street; and this institution
took a very prominent part in the science of the century, being
untrammelled by restrictions which sorely retarded the advance-
ment of science at the older universities.
Plant pathology was, also, coming to the fore, and Miles
Joseph Berkeley was establishing a permanent reputation as a
systematic mycologist. He has, indeed, been called the origi-
nator and founder of plant pathology, and was the first to
recognise the economic importance of many fungoid plant
diseases. His work on Phytophthora infestans—the potato fungus
-(1846) is still a classic.
Another branch of science, of less economic but of more
academic interest, was plant palaeontology, which, under Witham,
Binney and Williamson—the last named was elected, in 1851,
professor of natural history, anatomy and physiology at the
newly-founded Owens college, Manchester—was rapidly forging
ahead, at any rate in the north of England. Here, chiefly, the
foundations were being laid for the very remarkable advances
which have been made in this branch of the subject since the
last quarter of the nineteenth century.
Modern geology, in Great Britain, might be said to begin with
James Hutton, who, after taking the degree of doctor of medicine
at Leyden, devoted himself to the cultivation of a small estate,
inherited from his father, and to practical chemistry. The lucrative
results of the latter employment enabled him to give himself up
wholly to scientific pursuits. His agricultural studies, especially
during his residence with a farmer in Norfolk, interested him in
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Geology
291
the various sediments deposited either by rivers or seas, and he
recognised that much of the present land had once been below
the sea. But he also investigated the movements of strata and the
origin of igneous rocks, and especially the nature and relations
of granite. The great and distinctive feature of Hutton's work
in geology is the strictly inductive method applied throughout.
He maintained that the great masses of the earth are the same
everywhere. He saw no occasion to have recourse to the
agency of any preternatural cause in explaining what actually
occurs,' and he remarks that, the result therefore of our present
enquiry is, that we find no vestige of a beginning—no prospect
of an end. '
John Playfair, a pupil and friend of Hutton, issued, in 1802,
a volume entitled Iustrations of the Huttonian Theory of the
Earth. Playfair, to quote Sir A. Geikie's words, was 'gifted with
a clear penetrating mind, a rare faculty of orderly logical arrange-
ment, and an English style of altogether remarkable precision and
elegance. ' He was an able exponent of his master's views and
capable of adding many observations and contributions of his own
to his convincing sketch of the Huttonian theory.
William Smith, whom Sedgwick called the 'father of English
Geology,' became interested in the structure of the earth's crust,
at first, from a land-surveyor's and engineer's point of view. He
was one of the earliest to recognise that each of the strata he
studied carefully contains animal and plant fossils peculiar to
itself, by which it can be identified. In 1815, he published his
geological map of England and Wales; and, between 1794 and
1821, he issued separate geological maps of many English counties.
Further he is responsible for introducing many terms—'arbitrary
and somewhat uncouth,' as Sedgwick remarked-which have
become the verbal currency of British geology.
Adam Sedgwick, whose personality made a deep impression
on his university, was appointed Woodwardian professor of
geology in 1818, and threw himself, with surprising vigour, into a
subject which, to him, at that time, was almost new.
He was
great as a teacher and as an exponent of his science, being gifted
with eloquence, and, as founder of the Sedgwick museum, he
greatly enlarged the collection got together by John Woodward,
who established the professorship. From 1819 to 1823, he worked
chiefly in the south and east of England ; then, he turned his
attention to Lake-land and, afterwards, in 1827, to Scotland (with
Murchison). In 1829, he went abroad with Murchison, visiting
19-2
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292 The Literature of Science [CH.
parts of Germany and the eastern Alps, the result being an
important joint paper on the latter (1829-30). In the long vaca-
tion of 1831, he attacked the problem of the ancient rocks in the
northern part of Wales, which, owing to the absence of good
maps or easy communication, the complicated structure of the
country and the frequent rarity or imperfect preservation of its
fossils, presented exceptional difficulties. In that and the follow-
ing summer (as well as in some later visits), he ascertained the
general succession of the rocks from the base of the Cambrian to
the top of the Bala, or of the whole series afterwards called Cam-
brian and lower Silurian (more recently Ordovician). Laborious
fieldwork became more difficult after an illness in 1839; but he
continued to extend and publish the results of his investigations
in Wales, in the Lake district and in the Permo-Triassic strata
of north-eastern England. Though he was a liberal in politics,
his inclinations as a geologist were conservative.
George Julius Poulett Scrope, by his studies of volcanic dis-
tricts in Italy, Sicily and Germany, and especially by his memoir
on the volcanoes of central France, and by his observations on the
erosion of valleys by rivers, did much to extend and confirm the
views of Hutton and Playfair. His remarks, also, on the lamination
and cleavage of rocks were highly suggestive; in fact, but for the
interruptions of politics, he would have hardly fallen behind his
friend Charles Lyell.
During the first half of the nineteenth century, the belief in a
universal deluge was widely held by geologists. William Buckland,
in his Reliquiae Diluvianae (1823), supported his belief by his
'Observations on the Organic Remains contained in Caves, Fissures
and Diluvial Gravel. ' But, both he and Sedgwick, without giving
up the view of a universal flood, abandoned, to some extent, the
evidence on which, at one time, they had based their belief.
Another geologist of great eminence was H. T. de la Beche,
whose ancestors really did come over with the Normang. His
Geological Manual was spoken of, at the time, as the best work of
its kind which had appeared in our country; and his Report on the
Geology of Cornwall, Devon and West Somerset (1839) is a
masterly production. He occupied himself for a long time in
a
making a geological survey of parts of Devon and Dorset on
one-inch ordnance maps, and was appointed, in 1832, by govern-
ment to conduct the geological survey of England, in which posi-
tion he superintended the erection of the Jermyn street museum.
The interest of (Sir) Charles Lyell in geology was aroused by
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VII]
Geology
293
a
the fascinating lectures of Buckland. He was trained, at first, for
the law; but his legal studies were arrested by a weakness in his
eyes, which, for a considerable time, prevented any continuous
reading, and troubled him more or less throughout life. But this
enforced rest enabled him to devote himself to geology, and, in
1824, he began systematic travel for that purpose. About 1827,
his future book—The Principles of Geology-began to take a
definite shape in his mind. In the spring of that year, with the
Murchisons, he visited Auvergne, passing to the south of France and
to the north of Italy as far as the Vicentine and the Euganean hills.
Thence he went to Naples and Sicily, studying not only their
volcanic districts, but, also, the tertiary fossils of other parts of
Italy, returning to London after an absence of more than three-
quarters of a year. The first volume of The Principles appeared
in 1831, while he was travelling in France and studying the extinct
volcanoes of Olot in Spain, the second volume early in 1832 and
the third in 1833. At a later date, the book was divided, the first
two volumes retaining the title Principles, and the third appearing,
in 1838, as The Elements of Geology. During these years, he con-
tinued his studies of European geology, extending his journeys to
Denmark and Scandinavia. In 1841, he began a twelvemonth's
journey in Canada and North America, an account of which is
given in Travels in North America, published early in 1845. The
same year he revisited that continent, making a much more
extended journey in the United States, which is recounted in his
Second Visit etc. , published in 1849. He returned, for shorter visits,
in 1852 and 1853, and, in 1854, went to Madeira and the Canary
islands. During the years between 1842 and 1859, he continued
his work in various parts of Europe, and, in the latter year,
appeared Darwin's Origin of Species. The study of this book
completed Lyell's conversion to the views expressed by Darwin',
and he also investigated the evidence in favour of the early
existence of man.
The results of these studies, with an account of the glacial
epoch, form the 'trilogy' entitled The Antiquity of Man, which
appeared early in 1863. After this time, his journeys, necessarily,
,
became shorter, though his interest in geology continued to be
as keen as ever, till, after a period of increasing weakness, he
died in February 1873.
Henry Clifton Sorby made his mark in more than one depart-
ment of science, to which a sufficiency of income enabled him to
| Prior to that he had been sceptical. See Darwin, Life and Letters, vol. 11, p. 229.
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294
[CH.
The Literature of Science
devote his life ; but he will always be remembered as the father
of microscopic petrology. Thin slices of hard bodies had already
been made for examination under the microscope; but Sorby was
the first to perceive the value of this method for the examination
of rocks in general. In 1849, he made the first transparent section
of one with his own hands, publishing his first petrographical
study in 1851. In a few years, his example had been followed
both in England and in other countries, and the result has been
a vast increase in our knowledge of the mineral composition
and structures of rocks, and of many difficult problems in their
history.
Sir Roderick Impey Murchison was descended from a well-
known Scottish clan living in Ross-shire. He was brought up in
the army and took part in several of the engagements under
Wellesley in Portugal and Moore in Galicia. He was a man of means,
and having, at an early date, retired from the army, he occupied
himself at first with the active sports of a country gentleman. But,
his attention having been turned to science by Sir Humphry Davy,
he very soon became an eager and enthusiastic geologist. At first,
he especially devoted himself to the rocks of Sussex, Hants and
Surrey. Later, he explored the volcanic regions of Auvergne
and other parts of France, and of Italy, the Tyrol and Switzerland,
and, together with Sedgwick, published much on the geology of
the Alps. But it was not till 1831 that Murchison began his real
life's work, which was a definite enquiry into the stratification of
the rocks on the border of Wales. The result of his labours,
published in 1839, was the establishment of the Silurian system
and the record of strata older than and different from any that had
hitherto been described in these islands. In 1837, he and Sedgwick,
by their work in the south-west of England and the Rhineland,
established the Devonian system; and, in 1840, he extended his
investigations from Germany to Russia. In the following year, at
the desire of the Tsar, he travelled over a considerable part of
that country as far as the Ural mountains on the east and the sea
of Azov on the south. In 1855, he was appointed director general
of the geological survey and director of the museum in Jermyn
street, in both of which posts he succeeded Sir Henry de la Beche.
Towards the end of his life, he founded a chair of geology and
mineralogy at Edinburgh.
William Buckland was, perhaps, better known as a teacher
and as an exponent of his science than for any very outstanding
original investigation carried on by him in geology. Unlike
i
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VIII] Geology. Zoology
295
Sedgwick, however, he had made a systematic study of his subject
before he was appointed, in 1813, reader of mineralogy at Oxford.
In this post, he so aroused the interest of his students that a
readership in geology was specially endowed by the Treasury six
years later, of which he was the first holder. He was a man of
many accomplishments, and he by no means confined his attention
to geology. He entered with great zest into many practical
questions of the day, especially such as affected agriculture and
sanitary science. In 1845, he was appointed dean of Westminster,
and, shortly after this, his health began to decline.
We have mentioned above that men of science were less
specialised at the earlier part of our period than they have now
become. It is a peculiar feature of British science that many of
its most successful researchers were amateurs-gifted not only
with brains but with wealth. Many of those whose names we
mention held no kind of professional or academic posts. Even
the holding of professorial chairs in the earlier part of the nine-
teenth century usually involved teaching in more than one science.
To the year 1866, the professor of anatomy at Cambridge was
responsible for the teaching of zoology as well as for that of
anatomy. In many other places, the professorship of zoology was
responsible for what teaching there was in animal physiology, and,
in the London hospitals, strictly scientific subjects were then
taught by doctors in practice who were on the staff of the hospital.
It was not till the year 1883 that Michael Foster was appointed to
the professorship of physiology at Cambridge, though, as praelector
in that subject at Trinity college, he had been building up a great
physiological school for several years.
On the zoological side, one of the most productive morpho-
logical anatomists of the nineteenth century was Richard Owen,
Hunterian professor and, later, conservator of the museum of the
Royal college of Surgeons. In 1856, he became superintendent
of the natural history branch of the British Museum, and this post
he held until 1884. He added greatly to our knowledge of animal
structure by his successful dissection of many rare forms, such as
the pearly nautilus, limulus, lingula, apteryx and others, and,
following on the lines of Cuvier, he was particularly successful in
reconstructing extinct vertebrates. Another considerable advance
he made in science was the introduction of the terms 'homologous'
and 'analogous. ' His successor in both his posts, Sir William
Flower, an authority on cetacea and on mammals in general, took
an active part in arranging the contents of the museums under his
6
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296 The Literature of Science
[CH.
charge in such a way as to teach the intelligent public a lesson in
morphology and classification.
Throughout the century, repeated attempts had been made to
classify the members of the animal kingdom on a natural basis,
but, until their anatomy and, indeed, their embryology had been
sufficiently explored, these attempts proved somewhat vain. As
late as 1869, Huxley classified sponges with Protozoa, Echino-
derms with Scolecida and Tunicates with Polyzoa and Brachio-
poda. By the middle of the century, much work had been
done in sorting out the animal kingdom on a natural basis, and
Vaughan Thompson had already shown that Flustra was not
a hydroid, but a member of a new group which he named
Polyzoa. Although hardly remembered now, he demonstrated,
by tracing their development, that Cirripedia are not molluscs ;
he established the fact that they began life as free-swimming
Crustacea; he, again, it was who showed that Pentacrinus is
the larval form of the feather-star, Antedon.
Among marine biologists of eminence was Edward Forbes,
who was the first to investigate the distribution of marine
organisms at various depths in the sea; and he it was who de-
fined the areas associated with the bathymetrical distribution of
marine life, and pointed out that, as we descend into depths below
fifty fathoms, vegetable life tends to fade away and that aquatic
organisms become more and more modified.
The custom of naturalists to go on long voyages was still main-
tained. The younger Hooker accompanied Sir James Ross in the
'Erebus' on his voyage in search of the south magnetic pole; Huxley
sailed on the Rattlesnake' with Owen Stanley, and, on this voyage,
laid the foundation of his remarkable knowledge of the structure
of marine animals; Darwin sailed on the ‘Beagle' (1831—6) and,
among the many results of this memorable voyage, was his theory
of the structure and origin of coral-reefs. The invention of
telegraphy indirectly brought about a great advance in our know-
ledge of deep-sea fauna. It was necessary to survey the routes
upon which the large oceanic cables were to be laid, and, by the
inventions of new sounding and dredging instruments, it was
becoming possible to secure samples of the bottom fauna as well
as of the sub-stratum upon which it existed.
Other names
that occur in connection with deep-sea dredging are those of
Sir Wyville Thomson, of W. B. Carpenter and of J. Gwyn Jeffreys.
But by far the most important and, up to the present time,
unrivalled attempt to solve the mysteries of the seas was that of
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6
VIII] Zoological Exploration 297
H. M. S. 'Challenger,' which was despatched by the admiralty at
the close of the year 1872, the results of whose voyage have
appeared in some eighty quarto volumes. The results of the
exploration of the sea by the Challenger' have never been
equalled. In one respect, however, they were disappointing. It
had been hoped that, in the deeper abysms of the sea, creatures
whom we only know as geological, fossilised, bony specimens,
might be found in the flesh; but, with one or two exceptions-
and these of no great importance—such were not found. Neither
did any new type of organism appear. Nothing, in fact, was
dredged from the depths or found in the tow-net that did not fit
into the larger groups which already had been established before
the 'Challenger' was thought of. On the other hand, many new
methods of research were developed during this voyage, and
with it will ever be associated the names of Wyville Thomson,
mentioned above, Moseley, John Murray and others who, happily,
are still with us.
During the nineteenth century, many other expeditions left
Great Britain to explore the natural history of the world, some
the result of public, some of private, enterprise. They are too
numerous to mention. But a word must be said about the
wonderful exploration of central America which has just been com-
pleted, under the auspices of F. D. Goodman and 0. Salvin. The
results are incorporated in a series of magnificently illustrated
quarto volumes which have been issued during the last thirty-six
years. Fifty-two of these relate to zoology, five to botany and
six to archaeology. Nearly forty thousand species of animals
have been described, of which about twenty thousand are new,
and nearly twelve thousand species of plants. There are few
remote and partially civilised areas of the world whose zoology
and botany are on so secure a basis, and this is entirely owing
to the munificence and enterprise of the above mentioned men of
science.
