This book was originally delivered as a lecture by the biochemist
J. B. S. Haldane in 1923, was published as a book in 1924, and has been out-of-
print virtually ever since. I have transcribed it and ventured to add notes
explaining some of Haldane's allusions, referring to works on subsequent
developments and correcting what I, as a physicist, believe to be a number of
mis-statements. Reports of errata will be greatly appreciated.
Cosma Rohilla Shalizi
lizi@ocf.berkeley.edu
Berkeley, 10 April 1993
DAEDALUS
or
Science and the Future
A paper read to the Heretics, Cambridge, on February 4th, 1923
by
J. B. S. Haldane
INTRODUCTION
I have slightly expanded certain parts of this paper since reading it. It has
therefore probably lost any unity which it may once have possessed. It will be
criticized for its undue emphasis on certain unpleasant topics. This is
necessary if people are to be induced to think about them, and it is the
whole business of a university teacher to induce people to think.
DAEDALUS, or, SCIENCE AND THE FUTURE
As I sit down to write these pages I can see before me two scenes from my
experience of the late war. The first is a glimpse of a forgotten battle of
1915. It has a curious suggestion of a rather bad cinema film. Through a blur
of dust and fumes there appear, quite sudddenly, great black and yellow masses
of smoke which seem to be tearing up the surface of the earth and
disintegrating the works of man with an almost visible hatred. These form the
chief part of the picture, but some where in the middle distance one can see
a few irrelevant looking human figures, and soon there are fewer. It is hard
to believe that these are the protagonists in the battle. One would rather
choose those huge substantive oily black masses which are so much more
conspicuous, and suppose that the men are in reality their servants, and
playing an inglorious, subordinate, and fatal part in the combat. It is
possible, after all, that this view is correct.
Had I been privileged to watch a battle three years later, the
general aspect would have been very similar, but there would have been
fewer men and more shell-bursts. There would probably, however, have been
one very significant addition. Then men would have been running, with mad
terror in their eyes, from gigantic steel slugs, which were deliberately,
relentlessly and successfully pursuing them.
The other picture is of three Europeans in India looking at a great
new star in the milky way. These were appearantly all of the guests at a
large dance who were interested in such matters. Amongst those who were at
all competent to form views as to the origin of this cosmoclastic explosion,
the most popular theory attributed it to a collisin between two stars, or a
star and a nebula. There seem, however, to be at least two possible
alternatives to this hypothesis. Perhaps it was the last judgement of some
inhabited world, perhaps a too successful experiment in induced radioactivity
the part of some of the dwellers there. And perhaps also these two hypotheses
are identical, and what we were watching that evening was the detonation of a
world on which too many men came out to look at the stars when they should have
been dancing.
These two scenes suggest, very briefly, a part of the case against
science. Has mankind released from the womb of matter a Demogorgon which is
already beginning to turn against him, and may at any moment hurl him into
the bottomless void? Or is Samuel Butler's even more horrible vision correct,
in which man becomes a mere parasite of machinery, an appendage of the
reproductive system of huge and complicated engines which will successively
usurp his activities, and end by ousting him from the mastery of this planet?
Is the machine-minder engaged on repetition-work the goal and ideal to which
humanity is tending? Perhaps a survey of the present trend of science may
throw some light on these questions.
But first we may consider for a moment, the question of whether there
is any hope of stopping the progress of scientific research. It is after all a
very recent form of human activity, and a sufficiently universal protest of
mankind would be able to arrest it even now. In the middle ages public opinion
made it so dangerous as to be practically impossible, and I am inclined to
suspect that Mr. Chesterton, for example, would not be averse to a repetition
of this state of things. The late M. Joseph Reinach, an able and not wholy
illiberal thinker, publicaly advocated it.
I think, however, that so long as our present economic and national
systems continue, scientific research has little to fear. Capitalism, though
it may not always give the scientific worker a living wage, will always
protect him, as being one of the geese which produce golden eggs for its
table. And competitive nationalism, even if war is wholly or largely prevented,
will hardly forego the national advantages accruing from scientific research.
If we look at the other most probable alternative the prospect is
little more hopeful. In this country the labour party alone among political
organizations includes the fostering of research in its official programme.
Indeed as far as biological research is concerned labour may prove a better
master than capitalism, and there can be little doubt that it would be equally
friendly to physical and chemical research if these came to lead immediately
to shortened hours rather than to unemployment. In particular there is
perhaps reason to think that that form of sentimentalism which hampers
medical research in this country by legislation would be less likely to
flourish in a robust and selfish labour party of the Australian type than in
parties whose members enjoy the leisure which seems necessary to the
development of such emotional luxuries.
It is of course possible that civilisation may collapse throughout
the world as it has done in parts of Russia, and science with it, but such an
event would, in all probability, only postpone the problem for a few
thousand years. And even in Russia we must not forget that first-rate
scientific research is still being carried on.
The possibility has been suggested -- I do not know how seriously --
that the progress of science may cease through lack of new problems for
investigation. Mr. Chesterton in _The Napoleon of Notting Hill_, a book written
fifteen years or so ago, prophesied that hansom-cabs would still be in
existence a hundred years hence owing to a cessation of invention. Within six
years there was a hansom-cab in a museum, and now that romantic but tardy
vehicle is a memory like the trireme, the velocipede, and the 1907 Voisin
biplane. I do not suggest that Mr. Chesterton be dragged -- a heavier Hector --
behind the last hansom cab, but I do contend that, in so far as he claims to
be a prophet rather than the voice of one crying in the wilderness, he may be
regarded as negligible for the purposes of our discussion. I shal try shortly
to show how far from complete are any branches of science at the present time.
But first a word on Mr. H. G. Wells might not be out of place. The
very mention of the future suggests him. There are two points I wish to make
about Mr. Wells. In the first place, considered as a serious prophet, as
opposed to a fantastic romancer, he is singularly modest. In 1902, for example,
in a book called "Anticipations," he gave it as his personal opion that by
1950 there would be heavier than air flying machines cpable of practical use
in war. That, he said, was his own view, though he was well aware that it
would excite considerable ridicule. _I_propose_in_this_paper_to_make_no_
prophecies_rasher_than_the_above_.
The second and more important point is that he is a generation
behind the time. When his scientific ideas were formed, flying and
radio-telegraphy, for example, were scientific problems, and the centre of
scientific interest still lay in physics and chemistry. Now these are
commercial problems, and I believe that the centre of scientific interest
lies in biology. A generation hence it may be elsehwere, and the views
expressed in this paper will appear as modest, conservative, and unimaginative
as do many of those of Mr. Wells to-day.
I will only touch very briefly on the future of physics, as the
subject is inevitably technical. At present physical theory is in a state
of profound suspense. This is primarily due to Einstein -- the greatest Jew
since Jesus. I have no doubt that Einstein's name will still be remembered
and revered when Lloyd George, Foch, and William Hohenzollern share with
Charlie Chaplin that ineluctable oblivion which awaits the uncreative mind.
I trust that I may be excused if I trespass from the strict subject of my theme
to add my quota to the rather numerous mistatements of Einstein's views which
have appeared during the last few years.
Ever since the time of Berkeley it has been customary for the majority
of metaphysicians to proclaim the ideality of Time, of Space, or of both. But
they soon made it clear that in spite of this, time would continue to wait for
no man, and space to separate lovers. The only practical consequences that they
generally drew was that their own ethical and political views were somehow
inherent in the structure of the universe. The experimental proof or disproof
of such deductions is difficult, and -- if the late war may be regraded as an
experimental disproof of certain of Hegel's political tenets -- costly and
unsatisfactory.
Einstein, so far from deducing an new decalogue, has contented himself
with deducing the consequences to space and time themselves of their ideality.
{1} These are mostly too small to be measurable, but some, such as the
deflection of light but the sun's gravitational field, are susceptible of
verification, and have been verified. The majority of scientific men are now
being constrained by the evidence of these experiments to adopt a very
extreme form of Kantian idealism. The Kantian _Ding-an-sich_ is an eternal
four-dimensional manifold, which we perceive as space and time, but what we
regard as space and what as time is more or less fortuitous.
It is perhaps interesting to speculate on the practical consequences
of Einstein's discovery. I do not doubt that he will be believed. A prophet
who can give signs in the heavens is always believed. No one ever seriously
questioned Newton's theory after the return of Halley's comet. Einstein has
told us that space, time and matter are shadows of the fifth dimension, and
the heavens have declared his glory. In consequence Kantian idealism will
become the basal working hypothesis of the physicist and finally of all
educated men, just as materialism did after Newton's day. We may not call
ourselves materialists, but we do interpret the activities of the moon, the
Thames, influenza, and aeroplanes in terms of matter. Our ancestors did not,
nor, in all probability, will our descendants. The materialism (whether
conscious or sub-conscious does not matter very much) of the last few
generations has led to various results of practical importance, such as
sanitation, Marxian socialism, and the right of an accused person to give
evidence on his or her own behalf. The reign of Kantian idealism as the basal
working hypothesis, first of physics, and then of every-day life, will in all
probability last for some centuries. At the end of that time a similar step in
advance will be taken. Einstein showed that experience cannot be interpreted
in terms of space and time. This was a well-known fact, but so long as space
and time down not break down in their own special sphere, that of explaining
the facts of motion, physicists continued to believe in them, or at any rate,
what was much more important, to think in terms of them for practical
pruposes.
A time will however come (as I believe) when physiology will invade
and destroy mathematical physics, as the latter have destroyed geometry. The
basic metaphysical working hypothesis of science and practical life will then,
I think, be something like Bergsonian activism. I do not for one moment
suggest that this or any other metaphysical system has any claims whatever to
finality.
Meanwhile we are in for a few centuries during which many practical
activities will probably be conducted on a basis, not of materialism, but of
Kantian idealism. How will this affect our manners, morals and politics?
Frankly I do not know, though I think the effect will be as great as that of
Newton's work, which created most of the intellectual forces of the 18th
century. The Condorcets, Benthams, and Marxs of the future will I think be
as ruthlessly critical of the metaphysics and ethics of their times as were
their predecessors, but not quite so sure of their own; they will lack a
certain heaviness of touch which we may note in Utilitarianism and Socialism.
They will recognise that perhaps in ethics as in physics, there are so to speak
fourth and fifth dimensions that show themselves by effects which, like the
perturbations of the planet Mercury, are hard to detect even in one generation,
but yet perhaps in the course of ages are quite as important as the three-
dimensional phenomena.
If the quantum hypothesis is generally adopted even more radical
alterations in our thinking will be necessary. But I feel it premature even to
suggest their direction in the present unsatisfactory state of quantum
mechanics. It may be that as Poincare (the other Poincare) suggested we shall
be forced to conceive of all changer as occuring in a series of clicks, and
all space as consisting of discrete points. However this may be it is safe
to say that a better knowledge of radiation will permit us to produce it in a
more satisfactory manner than is at present possible. Almost all our present
sources of light are hot bodies, 95% of whose radiation is invisible. To
light a lamp as a source of light is about as wasteful of energy as to burn
down one's house to roast one's pork. It is a fairly safe prophecy that in 50
years light will cost about a fitieth of its present price, and there will be
no more night in our cities. The alternation of day and night is a check on
the freedom of human activity which must go the way of other spatial and
temporal checks. In the long run I think that all that applied physics can do
for us is abolish these checks. It enables us to possess more, travel more, and
communicate more. I shall not attempt to predict in detail the future
developments of transport and communication. They are only limited by the
velocity of light. We are working towards a condition when any two persons on
earth will be able to be completely present to one another in not more than
1/24 of a second. We shall never reach it, but that is the limit which we shall
approach indefinitely. {2}
Developments in this direction are tending to bring mankind more and
more together, to render life more and more complex, artificial, and rich in
possibilities -- to increase indefinitely man's powers for good and evil.
But there are two prerequisites for all progress of this kind, namely
continuous supplies of human and mechanical power. As industries become more
and more closely interwoven, so that a dislocation of any one will paralyse a
dozen others (and that is the position towards which we are rapidly moving),
the ideal of the leaders of industry, under no matter what economic system,
will be directed less and less to the indefinite increase of production in the
intervals between such dislocations, and more and more to stable and regular
production, even at the cost of reduction of profits and output while the
industry is proceeding normally. {3} It is quite possible that capitalism
itself may demand that the control of certain key industries be handed over
completely to the workers in those industries, simply in order to reduce the
number of sporadic strikes in them. And as industrial progress continues an
ever larger number -- perhaps the majority -- of industries will become key
industries. The solution may be entirely different -- we may well see a return
to feudalism. But the probability is that the problem will be solved. This view
may seem optimistic, but it is more likely than the alternative thesis which
may be briefly stated as follows: "No human society will ever succeed in
producing a stable organization in which the majority of the population is
employed otherwise than in agriculture, animal-rearing, hunting or fishing." It
took some thousands of years to produce the stable agricultural society which
forms the basis of European life and whose morals we are too apt to regards as
eternal truths. It should take a shorter time to evolve a stable industrial
society. The people that do so will inherit the earth. In sum, I believe that
the progress of science will ultimately make industrial injustice as self-
destructive as it is now making international injustice.
As for the supplies of mechanical power, it is axiomatic that the
exhaustion of our coal and oil-fields is a matter of centuries only. As it has
often been assumed that their exhaustion would lead to the collapse of
industrial civilization, I may perhaps be pardoned if I give some of the
reasons which lead me to doubt this proposition.
Water-power is not, I think, a probable substitute, on account of its
small quantity, seasonal fluctuation, and sporadic distribution. It may
perhaps, however, shift the centre of industrial gravity to well-watered
mountainous tracts such as the Himalayan foothills, British Columbia, and
Armenia. Ultimately we shall have to tap those intermittent but inexhaustable
sources of power, the wind and the sunlight. The problem is simply one of
storing their energy in a form as convenient as coal or petrol. If a windmill
in opne's back garden could produce a hundredweight of coal daily (and it can
produce its equivalent in energy), our coalmines would be shut down to-morrow.
Even to-morrow a cheap, foolproof, and durable storage battery may be invented,
which will enable us to transform the intermittent energy of the wind into
continuous electric power.
Personally, I think that four hundred years hence the power question
in England may be solved somewhat as follows: The country will be covered with
rows of metallic windmills working electric motors which in their turn supply
current at a very high voltage to great electric mains. At suitable distances,
there will be great power stations where during windy weather the surplus power
will be used for the electrolytic decomposition of water into oxygen and
hydrogen. Thes gases will be liquefied, and stored in vast vaccuum jacketed
reservoirs, probably sunk in the ground. If these reservoirs are sufficiently
large, the loss of liquid due to leakage inwards of heat will not be great;
thus the proportion evaporating daily from a reservoir 100 yards square by
60 feet deep would not be 1/1000 of that lost from a tank measuring two feet
each way. In times of calm, the gases will be recombined in explosion motors
working gynamos which produce electrical energy once more, or more probably
in oxidation cells. Liquid hydrogen is weight for weight the most efficient
known method of storing energy, as it gives about three times as much heat per
pound as petrol. On the other hand it is very light, and bulk for bulk has only
one third of the efficiency of petrol. This will not, however, detract from its
use in aeroplanes, where weight is more important than bulk. These huge
reservoirs of liquiefied gases will enable wind energy to be stored, so that
it can be expended for industry, transportation, heating and lighting, as
desired. The initial costs will be very considerable, but the running expenses
less than those of our present system. Among its more obvious advantages will
be the fact that energy will be as cheap in one part of the country as another,
so that industry will be greatly decentralized; and that no smoke or ash will
be produced.
It is on some such lines as these, I think, that the problem will be
solved. It is essentially a practical problem, and the exhaustion of our coal-
fields will furnish the necessary stimulus for its solution. Even now perhaps
Italy might achieve economic independence by the expenditure of a few million
pounds upon research on the lines indicated. I may add in parenthesis that,
on thermodynamical grounds which I can hardly summarize shortly, I do not
much believe in the commerical possibility of induced radio-activity.
Before I turn to the principal part of my subject I should like to
consider very briefly the influence on art and literature of our gradual
conquest of space and time. I think that the blame for the decay of certain
arts rests primarily on the defective education of the artists. An artist must
understand his subject matter. At present not a single competent poet and very
few painters and etchers outside the Glasgow School understand industrial life,
and I believe that there is only one architect of any real originality who
understands the possibilities of ferro-concrete. I do not know his name, but he
produced in Soissons before the war a market-place with the dignity and daring
of an ancient Egyptian temple. If I knew that he had been entrusted with the
rebuilding of Soissons, I could not regret its destruction.
Now if we want poets to interpret physical science as Milton and
Shelley did (Shelley and Keats were the last English poets who were at all up-
to-date in their chemical knowledge), we must see that our possible poets are
indstructed, as their masters were, in science and economics. I am absolutely
convinced that science is vastly more stimulating to the imagination than are
the classics {4}, but the products of this stimulus do not normally see the
light because scientific men as a class are devoid of any perception of
literary form. When they can express themselves we get a Butler or a Norman
Douglas. Not until our poets are once more drawn from the educated classes
(I speak as a scientist), will they appeal to the average man by showing him
the beauty in his own life as Homer and Virgil appealed to the street urchins
who scrawled their verses on the walls of Pompeii.
And if we must educate our poets and artists in science, we must
educate our masters, labour and capital, in art. Personally I believe that we
may have good hopes of both. The capitalist's idea of art in industry at
present tends to limit itself to painting green and white stripes on the front
of his factories in certain cases. This is a primitive type of decoration, but
it has, I think, the root of the matter in it. Before long someone may discover
that frescoes inside a factory increase the average efficiency of the worker
1.03% and art will become a commerical proposition once more. Even now it is
being discovered that artistic advertising often pays. Similarly I do not doubt
that labour will come to find that it cannot live by bread (or shall we say
bread and beer) alone. But it can hardly be expected to make this discovery
until it is assured of its supply of bread and beer.
Applied chemistry has introduced into human life no radical novelty of
the importance of the heat-engine or the telegraph. It has vastly increased the
production of various types of substance the most important being metals. But
there were explosives, dyes and drugs before chemistry was a science, and its
progress along present lines will mainly alter life in a quantitative manner.
Perhaps the biggest problems before it in metallurgy are the utilization of
low-grade iron ores, and the production of aluminium from clay, which contains
up to 24% of that metal. I do not think that even when this is accomplished
aluminium will oust iron and steel as they ousted bronze and flint, but it and
its alloys will certainly take the second, and possibly the first place as
industrial metals. There is just a hope, though I fear little more, that a
large-scale production of perfume may form the basis of a re-education of our
rather rudimentary sense of smell, but the most interesting possibilities of
chemical invention are very clearly in biological chemistry, and for the
following reasons.
Desirable substances fall on the whole into two classes. The first are
desirable on account of their physical or chemical properties, for example
iron, wood or glass, which we use as a part of systems such as fires, houses
or razors, which procure us certain benefits. The second are desirable on
account of their physiological properties. Such substances include foods,
drinks, tobacco and drugs. Colours and scents occupy an intermediate position.
The value of this second class of substances rests on a quite special
relationship to the human organism which depends in the most intimate way on
the constitution of the latter, and has not in general been at all fully
explained in terms of physics and chemistry. For example fires can be made of
coal or peat instead of wood, but no other chemical substance has the same
effect as water or alcohol. So unless a chemical substance has new physio-
logical properties its production will merely serve to improve or make possible
some appliance whose use lies within the sphere of applied physics. Within
historical time two and only two substances of the second class have come into
universal use in Europe, namely caffeine and nicotine, which were introduced
into this country in the sixteenth and seventeenth centuries. There are others
of immense importance, such as chloroform and quinine, but their use is not
universal. But coffee, tea, and tobacco, with alcohol, are as much a part of
normal life as food and water. There is no reason to suppose that the list
of such substances is exhausted. During the war Embden {5} the professor of
physiology in Frankfurt University discovered that a dose of about 7 grams of
acid sodium phosphate increasesd a man's capacity for prolonged muscular work
by about 20% and probably aids in prolonged mental work. It can be taken over
very lengthy periods. A group of coal-miners took it for nine months on end
with very great effects on their output. It has no after-effects like those of
alcohol, and one cannot take a serious overdose as it merely acts as a
purgative. (they gave certain Stosstruppen too much!) Thousands of people in
Germany take it habitually. It is possible that it may become as normal a
beverage as coffee or tea. It costs 1/9 per pound, or 1/3d. per dose.
The vast majority of chemical substances with physiological properties
are unsuited for daily use like castor oil, or dangerous like morphine;
probably none are without bad effects in certain cases. Those which are
susceptible of daily use are of the utmost social importance. Tobacco has
slight but definite effects on the character. Coffee-houses in London in the
seventeenth and eighteenth centuries and cafes in modern Europe were and are
civilizing influences of incalculable value. But these substances are
profoundly obnoxious to a certain type of mind. It would perhaps be fantastic
to suggest that Sir Walter Raleigh owed his death in part to his sovereign's
objection to tobacco. But is he is not its proto-martyr it is at least
probable that more have died for tobacco smoking at the hands of Sikhs,
Senussis, and Wahabis, whose religions forbid this practice, than died under
the Roman empire for professing Christianity. Should it ever be generally
realised that temperance is a mean we may expect that mankind will ultimately
have at its disposal a vast array of substances like wine, coffee and tobacco,
whose intelligent use can add to the amenity of life and promote the expression
of man's higher faculties.
But before that day comes chemistry will be applied to the production
of a still more important group of physiologically active substances,
namely foods. The facts about food are rather curious. Everyone knows that
food is ultimately produced by plants, though we may get it at second or third
hand if we eat animals or their products. But the average plant turns most of
its sugar not into starch which is digestible, but into cellulose which is not,
but forms its woody skeleton. The hoofed animals have dealt with this problem
in their own way, by turning their bellies into vast hives of bacteria that
attack cellulose, and on whose by-products they live. We have got to do the
same, but outside our bodies. It may be done on chemical lines. Irvine has
obtained a 95% yield of sugar from cellulose, but at a prohibitive cost. Or
we may use micro-organisms, but in any case within the next century sugar and
starch will be about as cheap as sawdust. Many of our foodstuffs, including the
proteins, we shall probably build up from simpler sources such as coal and
atmospheric nitrogen. I should be inclined to allow 120 years, but not much
more, before a completely satisfactory diet can be produced in this way on a
commercial scale.
This will mean that agriculture will become a luxury, and that mankind
will be completely urbanized. Personally I do not regret the probable
disappearance of the agricultural labourer in favour of the factory worker,
who seems to me a higher type of person from most points of view. Human
progess in historical time has been the progress of cities dragging a
reluctant countryside in their wake. Synthetic food will substitute the flower
garden and the factory for the dunghill and the slaughterhouse, and make the
city at last self-sufficient.
There's many a strong farmer whose heart would break in two
If he could see the townland that we are riding to.
Boughs have their fruit and blossom at all times of the year,
Rivers are running over with red beer and brown beer,
An old man plays the bagpipes in a golden and silver wood,
Queens, their eyes blue like the ice, are dancing in a crowd.
I should have like had time allowed to have added my quota to the
speculations which have been made with regard to inter-planetary communication.
Whether this is possible I can form no conjecture; that it will be attempted
I have no doubt whatever.
With regard to the application of biology to human life, the average
prophet appears to content himself with considerable if rather rudimentary
progress in medicine and surgery, some improvements in domestic plants and
animals, and possibly the introduction of a little eugenics. The eugenic
official, a compound, it would appear, of the policeman, the priest and the
procurer, is to hale us off at suitable intervals to the local temple of Venus
Genetrix with a partner chosen, one gathers, by something of a glorified
medical board. To this prophecy I should reply that it proceeds from a type of
mind as lacking in originality as in knowledge of human nature. Marriage "by
numbers", so to speak, was a comparatively novel idea when proposed by Plato
2,300 years ago, but it has already actually been practised in various places,
notably among the subject of the Jesuits in Paraguay. It is moreover likely,
as we shall see, that the ends proposed by the eugenist will be attained in a
very different manner,
But before we proceed to prophecy I should like to turn back to the
past and examine very briefly the half dozen or so important biological
inventions which have already been made. By a biological invention I mean the
establishment of a new relationship between man and other animals or plants,
or between different human beings, provided that such relationship is one
which comes primarily under the domain of biology rather than physics,
psychology or ethics. Of the biological invetions of the past, four were made
before the dawn of history. I refer to the domestication of animals, the
domestication of plants, the domestication of fungi for the production of
alcohol, and to a fourth invetion, which I believe was of more ultimate and
far-reaching importance than any of these, since it altered the path of sexual
selection, focussed the attention of man as a lover upon woman's face and
breasts, and changed our idea of beauty from the steatapygous Hottentot to the
modern European, from the Venus of Brassempouy to the Venus of Milo. There are
certain races which have not yet made this last invention. And in our own day
two more have been made, namely bactericide and the artificial control of
conception.
The first point that we may notice about these inventions is that they
have all had a profound emotional and ethical effect. Of the four earlier there
is not one which has not formed the basis of a religion. I do not know what
strange god will have the hardihood to adopt Charles Bradlaugh and Annie
Besant in the place of Triptolemus and Noah, but one may remark that it is
impossible to keep religion out of any discussion of the practices which they
popularized.
The second point is perhaps harder to express. The chemical or physical
inventor is always a Prometheus. There is no great invention, from fire to
flying, which has not been hailed as an insult to some god. But if every
physical and chemical invention is a blasphemy, every biological invention is
a perversion. There is hardly one which, on first being brought to the notice
of an observer from any nation which has not previously heard of their
existence, would not appear to him as indecent and unnatural.
Consider so simple and time-honored a process as the milking of a cow.
The milk which should have been an intimate and almost sacramental bond
between mother and child is elicited by the deft fingers of a milk-maid, and
drunk, cooked, or even allowed to rot into cheese. We have only to imagine
ourselves as drinking any of its other secretions, in order to realise the
radical indecency of our relation to the cow. {6}
No less disgusting a priori is the process of corruption which yields
our wine and beer. But in actual fact the process of milking and of the making
and drinking of beer appear to us profoundly natural; they have even tended to
develop a ritual of their own whose infraction nowadays has a certain air of
impropriety. There is something slightly disgusting in the idea of milking a
cow electrically or drinking beer out of tea-cups. And all this of course
applies much more strongly to the sexual act.
I fancy that the sentimental interest attaching to Prometheus has
unduly distracted our attention from the far more interesting figure of
Daedalus. It is with infinite relief that amidst a welter of heroes armed
with gorgon's heads or protected by Stygian baptisms the student of Greek
mythology comes across the first modern man. Beginning as a realistic sculptor
(he was the first to produce statues whose feet were separated) it was natural
that he should proceed to the consturction of an image of Aphrodite whose
limbs were activated by quicksilver. After this his interest inevitably turned
to biological problems, and it is safe to say that posterity has never equalled
is only recorded success in experimental genetics. Had the housing and feeding
of the Minotaur been less expensive it is probable that Daedalus would have
anticipated Mendel. But Minos held that a labyrinth and an annual provision of
50 youths and 50 virgins were excessive as an endowmenent for research, and
in order to escape from his ruthless economies Daedalus was forced to invent
the art of flying. Minos pursued him to Sicily and was slain there. Save for
his valuable invention of glue, little else is known of Daedalus. But it is
most significant that, although he was responsible for the death of Zeus'
son Minos he was neither smitten by a thunderbolt, chained to a rock, nor
pursued by furies. Still less did any of the rather numerous visitors to
Hades discover him either in Elysium or Tartarus. We can hardly imagine him
as a member of the throng of shades who besieged Charon's ferry like sheep at
a gap. He was the first to demonstrate that the scientific worker is not
concerned with gods.
The unconscious mind of the early Greeks, who focussed in this amazing
figure the dim traditions of Minoan science, was presumably aware of this fact.
The most monstrous and unnatural action in all human legend was unpunished in
this world or the next. Even the death of Icarus must have weighed lightly with
a man who had already been banished from Athens for the murder of his nephew.
But if he escaped the vengence of the gods he has been exposed to the universal
and agelong reprobation of a humanity to whom biological inventions are
abhorrent, with one very significant exception. Socrates was proud to claim
him as an ancestor.
The biological invetion then tends to begin as a perversion and end as
a ritual supported by unquestioned beliefs and prejudices. Even now surgical
cleanliness is developing its rites and its dogmas, which, it may be remarked,
are accepted most religiously by women. With the above facts in your minds I
would ask you to excuse what at first sight might appear improbable or indecent
in any speculations which appear below, and to dismiss from your minds the
belief that biology will consist merely and physical and chemical discoveries
as applied to men, animals and plants.
I say advisedly "will consist", for we are at present almost
completely ignorant of biology, a fact which often escapes the notice of
biologists, and renders them to presumptuous in their estimates of the present
position of their science, too modest in their claims for its future. If for
example we take a typical case of applied biology such as the detection and
destruction of the cholera bacillis, we find a great deal of science involved,
but the only purely biological principle s the very important but not very
profound one that some bacteria kill some men. The really scientific parts of
the process are the optical and chemical methods involved in the magnification,
staining and killing of the bacilli. When on the other hand we come to
immunization to typhoid we find certain purely biological principles involved
which are neither simple nor at all completely understood.
Actually biological theory consists of some ancient but not very
easily stated truths about organisms in general, due largely to Aristotle,
Hippocrates and Harvey, a few great principles such as those formulated by
Darwin, Mayer, Claude Bernard, and Mendel, and a vast mass of facts about
individual organisms and their parts which are still awaiting adequate
generalization.
Darwin's results are beginning to be appreciated, with alarming effects
on certain types of religion, those of Weismann and Mendel will be digested
in the course of the present century, and are going to affect political and
philosophical theories almost equally profoundly. I need hardly say that these
latter results deal with the question of reproduction and heredity. We may
expect, moreover, as time goes on, that a series of shocks of the type of
Darwinism will be given to established opinions on all sorts of subjects. One
cannot suggest in detail what these shocks will be, but since the opinions
on which they will impinge are deep-seated and irrational, they will come upon
us and our descendants with the same air of presumption and indecency with
which the view that we are descended from monkeys came to our grandfathers.
But owing to man's fortunate capacity for thinking in watertight (or rather
idea-tight) compartments, they will probably not have immediate and disruptive
effects upon society any more than Darwinism had.
Far more profound will be the effect of the practical applications of
biology. I believe that the progress of medicine has had almost, if not quite,
as deep an effect on society in Western Europe as the industrial revolution.
Apart from the important social consequences which have flowed from the partial
substitution of the doctor for the priest, its net result has been that whereas
four hundred years ago most people died in childhood, they now live on an
average, (apart from the late war), until forty-five. Bad as our urban
conditions are, there is not a slum in the country which has a third of the
infantile death-rates of the royal family in the middle ages. Largely as a
result of this religion has come to lay less and less stress on a good death,
and more and more on a good life, and its whole outlook has gradually
changed in consequence. Death has receded so far into the background of our
normal thoughts that when we came into somewhat close contact with it during
the war most of us failed to take it seriously.
Similarly institutions which were based on short lives have almost
wholly collapsed. For example the English land system postulated that the land-
owner should die aged about forty, and be succeeded by his eldest son, aged
about twenty. The son had spent most of his life on the estate, and had few
interests outside it. He managed it at least as well as anyone else could
have done. Nowadays the father dodders on till about eighty, and is generally
incompetent for ten years before his death. His son succeeds him at the age of
fifty or so, by which time he may be a fairly competent colonel or stockbroker,
but cannot hope to learn the art of managing an estate. In consequence he
either hands it over to an agent who is often corrupt, or runs it
unscientifically, gets a low return, and ascribes to Bolshevism what he should
really lay at the door of vaccination.
But to return, if I may use the expression, to the future, I am going
to suggest a few obvious developments which seem probable in the present
state of biological science, without assuming any great new generalizations
of the type of Darwinism. I have the very best precedents for introducing a
myth at this point, so perhaps I may be excused if I reproduce some extracts
from an essay on the influence of biology on history during the 20th
century which will (it is hoped) be read by a rather stupid undergraduate
member of this university to his supervisor during his first term 150 years
hence.
"As early as the first decade of the twentieth century we find a
conscious attempt at the application of biology to politics in the so-called
eugenic movement. A number of earnest pesons, having discovered the
existence of biology, attempted to apply it in its then very crude condition to
the production of a reace of super-men, and in certain countries managed to
carry a good deal of legislation. They appear to have managed to prevent the
transmission of a good deal of syphilis, insanity, and the like, and they
certainly succeeded in producing the most violent opposition and hatred amongst
the classes whom they somewhat gratuitously regarded as undesirable parents.
(There was even a rebellion in Nebraska). However, they undoubtably prepared
public opinion for what was to come, and so far served a useful purpose. Far
more important was the progress in medicine which practically abolished
infectious diseases in those countries which were prepared to tolerate the
requisite amount of state interference in private life, and finally, after
the league's {7} ordinance of 1958, all over the world; though owing to
Hindu opposition, parts of India were still quite unhealthy up to 1980 or
so.
But from a wider point of view the most important biological work in
the first third of the century was in experimental zoology and botany. When
we consider that in 1912 Morgan had located several Mendelian factors in the
nucleous of Drosophilia, and modified its sex-ratio, while Marmorek had
taught a harmless bacillus to kill guinea-pigs, and finally in 1913 Brachet
had grown rabbit embryos in serum for some days, it is remarkable how little
the scientific workers of that time, and a fortiori the general public, seem
to have foreseen the practical bearing of such results.
As a matter of fact it was not until 1940 that Selkovski invented the
purple alga _Porphyrococcus fixator_ which was to have so great an effect on
the world's history. In the 50 years before this date the world's average
wheat yield per hectar had been approximately doubled, partly by the
application of various chemical manures, but most of all by the results of
systematic crossing work with different races; there was however little
prospect of further advance on any of these lines. _Porphyrococcus_ is an
enormously efficient nitrogen-fixer and will grow in almost any climate
where there are water and traces of potash and phosphates in the soil,
obtaining its nitrogen from the air. It has about the effect in four days
that a crop of vetches would have had in a year. It could not, of course,
have been produced in the course of nature, as its immediate ancestors would
only grow in artificial media and could not have survived outside a
laboratory. Wherever nitrogen was the princiapl limiting factor to plant
growth it doubled the yield of wheat, and quadrupled the value of grass land
for grazing purposes. The enormous fall in food prices and the ruin of purely
agricultural states was of course one of the chief causes of the disastrous
events of 1943 and 1944. The food glut was also greatly accentuated when in
1942 the Q strain of _Porphyrococcus_ escaped into the sea and multiplied
with enormous rapidity. Indeed for two months the surface of the tropical
Atlantic set to a jelly, with disastrous results to the weather of Europe.
When Certain of the plankton organisms developed ferments capable of digesting
it the increase of the fish population of the seas was so great as to make
fish the universal good that it is now, and to render even England self-
supporting in respect of food. So great was the prosperity in England that
in that year the coal-miner's union enteed its first horse for the Derby
(a horse-race which still took place annually at that time).
It was of course as a result of its invasion by _Porphyrococcus_
that the sea assumed the intense purple colour which seems so natural to us,
but which so distressed the more aesthetically minded of our great grand-
parents who witnessed the change. It is certainly curious to us to read of
the sea as having been green or blue. I need not detail the work of Ferguson
and Rahmatullah who in 1957 produced the lichen which has bound the drifting
sand of the world's deserts (for it was merely a continuation of that of
Selkovski), nor yet the story of how the agricultural countries dealt with
their unemployment by huge socialistic windpower schemes.
It was in 1951 that Dupont and Schwarz produced the first ecto-
genetic child. As early as 1901 Heape had transferred embryo rabbits from
one female to another, in 1925 Haldane had grown embryonic rats in serum for
ten days, but had failed to carry the process to its conclusion, and it was not
till 194 that Clark succeeded with the pig, using Kehlmann's solution as
medium. Dupont and Schwarz obtained a fresh ovary from a woman who was the
victim of an aeroplane accident, and kept it living in their medium for five
years. They obtained several eggs from it and fertilized them successfully,
but the problem of nutrition and support of the embryo was more difficult,
and was only solved in the fourth year. Now that the technique is fully
developed, we can take an ovary from a woman, and keep it growing in a
suitable fluid for as long as twenty years, producing a fresh ovum each month,
of which 90 per cent can be fertilized, and the embryos grown successfully
for nine months, and then brough out into the air. Schwarz never got such
good results, but the news of his first success caused an unprecedented
sensation throughout the entire world, for the birthrate was already less than
the deathrate in most civilised countries. France was the first country to
adopt ectogenesis officially, and by 1968 was producing 60,000 children
annually by this method. In most countries the opposition was far stronger,
and was intensified by the Papal Bull "Nunquam prius audito", and by the
similar fetwa of the Khalif, both of which appeared in 1960.
As we know ectogenesis is now universal, and in this country less
than 30 per cent of children are now born of woman. The effect on human
psychology and social life of the separation of sexual love and reproduction
which was begun in the 19th century and completed in the 20th is by no means
wholly satisfactory. The old family life had certainly a good deal to
commend it, and although nowadys we bring on lactation in women by injection
of placentin as a routine, and thus conserve much of what was best in the
former instinctive cycle, we must admit that in certain respects our great
grandparents had the advantage of us. On the other hand it is generally
admitted that the effects of selection have more than counterbalanced these
evils. The small proportion of men and women who are selected as ancestors
for the next generation are so undoubtedly superior to the average that the
advance in each generation in any single respect, from the increased output
of first-class music to the decreased convictions for theft, is very startling.
{8} Had it not been for ectogenesis there can be little doubt that
civilistion would have collapsed within a measurable time owing to the greater
fertility of the less desirable members of the population in almost all
countries.
It is perhaps fortunate that the process of becoming an ectogenetic
mother of the next generation involves an operation which is somewhat
unpleasant, though now no longer disfiguring or dangerous, and never
physiologically injurious, and is therefore an honour but by no means a
pleasure. Had this not been the case, it is perfectly possible that popular
opposition would have proved too strong for the selectionist movement. As
it was the opposition was very fierce, and characteristically enough this
country only adopted its present rather stringent standard of selection a
generation late than Germany, though it is now perhaps more advanced than any
other country in this respect. The advantages of thorough-going selection,
have, however, proved to be enormous. The question of the ideal sex ratio is
still a matter of violent discussion, but the modern reaction towards
equality is certainly strong."
Our essayist would then perhaps go on to discuss some far more
radical advances made about 1990, but I have only quoted his account of the
earlier applications of biology. The second appears to me to be neither
impossible nor improbable, but it has those features which we saw above to
be characteristic of biological inventions. If reproduction is once completely
separated from sexual love mankind will be free in an altogether new sense.
At present the national character is changing slowly according to quite un-
known laws. The problem of politics is to find institutions suitable to it.
In the future perhaps it may be possible by selective breeding to change
character as quickly as institutions. I can foresee the election placards of
300 years hence, if such quaint political methods survive, which is perhaps
improbable, "Vote for Smith and more musicians", "Vote for O'Leary and more
girls", or perhaps finally "Vote for Macpherson and a perhensile tail for
your great-grandchildren". We can already alter animal species to an enormous
extent, and it seems only a question of time before we shall be able to apply
the same principles to our own.
I suggest then that biology will probably be applied on lines roughly
resembling the above. There are perhaps equally great possibilities in the way
of direct improvemtn of the individual, as we come to know more of the
physiological obstalces ot the development of different faculties. But at
present we can only guess at the nature of these obstacles, and the line of
attack suggested in the myth is the one which seems most obvious to a
Darwinian. We already know however that many of our spiritual faculties can
only be manifested if certain glands, notably the thyroid and sex-glands, are
functioning properly, and that very minute changes in such glands affect the
character greatly. As our knowledge of this subject increases we may be able,
for example, to control our passions by some more direct method than fasting
and flagellation, to stimulate our imagintion by some reagent with less after-
effects than alcohol, to deal with perverted instincts by physiology rather
than prison. Conversely there will inevitably arise possibilities of new vices
similar to but even more profound than those opened up by the pharmacological
discoveries of the 19th century.
The recent history of medicine is as follows. Until about 1870 medicine
was largely founded on physiology, or, as the Scotch called it "Institutes of
medicine". Disease was looked at from the point of view of the patient, as
injuries still are. Pateur's discovery of the nature of infecctious disease
transformed the whole outlook, and made it possible to abolish one group of
diseases. But it also diverted scientific medicine from its former path, and
it is probable that, were bacteria unknown, though many more people would die
of sepsis and typhoid, we should be better able to cope with kidney diease and
cancer. Certain diseases such as cancer are probably not due to specific
organisms, whilst others such as phthisis are due to forms which are fairly
harmless to the average person, but attack others for unknown reasons. We are
not likely to deal with them effectually on Pasteur's lines, we must divert
our view from the micro-organism to the patient. Where the doctor cannot deal
with the former he can often keep the patient alive long enough to be able to
do so himself. And here he has to rely largely on a knowledge of physiology.
I do not say that a physiologist will discover how to prevent cancer. Pasteur
started life as a crystallographer. But whoever does so is likely at least to
make use of physiological data on a large scale.
The abolition of disease will make death a physiological event like
sleep. A generation that has lived together will die together. I suspect that
man's desire for a future life is largely due to two causes, a feeling that
most lives are incomplete, and a desire to meet friends from whom we have
parted prematurely. A gentle decline into the grave at the end of a completed
life's work will largely do away with the first, and our contemporaries will
rarely leave us sorrowing for long.
Old age is perhaps harder on women than on men. They live longer, but
their life is too often marred by the sudden change which generally overtakes
them between forty and fifty, and sometimes leaves them a prey to disease,
though it may improve their health. This change seems to be due to a sudden
failure of a definite chemical substance produced by the ovary. When we can
isolate and synthesize this body we shall be able to prolong a woman's youth,
and allow her to age as agradually as the average man.
Psychology is hardly a science yet. Like biology it has arrived at
certain generalizations of a rather abstract and philosophic character, but
these are still to some extent matters of controversy. And though a vast number
of most important empirical facts are known, only a few great generalizations
from them -- such as the existence of the subconscious mind -- have yet been
made. But anyone who has seen even a single example of the power of hypnotism
and suggestion must realise that the face of the world and the possibilities
of existence will be totally altered when we can control their effects and
standardize their application, as has been possible, for example, with drugs
which were once regarded as equally magical. Infinitely greater, of course,
would be the results of the opening up of systematic communication with
spiritual beings in another world, which is claimed as a scientific
possibility. Spiritualism is already Christianity's most formidable enemy, and
we have no data which allow us to estimate the probable effect on man of a
religion whose dogmas are matters of experiment, whose mysteries are prosaic
as electric lighting, whose ethics are based on the observed results in the
next world of a good or bad life in this. Yet that is the prospect before us if
spiritualism obtains the scientific verification which it is now demanding, not
perhaps with great success.
I have only been able, in the time at my disposal, to traverse a very
few of the possible fields of scientific advance. If I have convinced anyone
present that science has still a good deal up her sleeve, and that of
sufficiently startling character, I shall be amply repaid. If anything I have
said appears to be of a gratuitously disgusting nature, I would reply that
certain phenomena of normal life do seem to many to be of that nature, and that
these phenomena are of the utmost scientific and practical importance.
I have tried to show why I believe that the biologist is the most
romantic figure on earth at the present day. At first sight he seems to be just
a poor little scrubby underpaid man, groping blindly amid the mazes of the
ultra-microscopic, engaging in bitter and lifelong quarrels over the nephridia
of flatworms, waking perhaps one morning to find that someone whose name he has
never heard has demolished by a few crucial experiments thw ork which he had
hoped would render him immortal. There is real tragedy in his life, but he
knows that he has a responsibility which he dare not disclaim, and he is urged
on, apart from all utilitarian considerations, by something or someone which he
feels to be higher than himself.
The conservative has but little to fear from the man whose reason is
the servant of his passions, but let him beware of him in whom reason has
become the greatest and most terrible of the passions. These are the wreckers
of outworn empires and civilisations, doubters, disintegrators, deicides {9}.
In the past they have been, in general, men like Voltaire, Bentham, Thales,
Marx, and very possibly the divine Julius {10}, but I think that Darwin
furnishes an example of the same relentlessness of reason in the field of
science. I suspect that as it becomes clear that at present reason not only has
a freer play in science than elsehwere, but can produce as great effects on the
world through science as through politics, philosophy, or literature, there
will be more Darwins. Such men are interested primarily in truth as such, but
they can hardly be quite uninterested in what will happen when they throw down
the their dragon's teeth into the world.
I do not say that biologists as a general rule try to imagine in any
detail the future applications of their science. The central problems of life
for them may be the relationship between the echinoderms and the brachiopods,
and the attempt to live on their salaries. They do not see themselves as
sinister and revolutionary figures. They have no time to dream. But I suspect
that more of them dream than would care to confess it.
I have given above a very small selection from my dreams. Perhaps they
are bad dreams. It is of course almost hopeless to attempt any very exact
prophecies as to how in detail scientific knowledge is going to revolutionize
human life, but I believe that it will continue to do so, and even more
profoundly than I have suggested. And though personally I am Victorian enough
in my sympathies to hope that after all family life, for example, may be
spared, I can only reiterate that not one of the practical advances which I
have predicted is not already foreshadowed by recent scientific work. If a
chemist or physicist living at the end of the seventeenth century had been
asked to predict the future application of his science he would doubtless have
made many laughable errors in the best Laputan style, but he would have been
certain that it would somehow be applied, and his faith would have been
justified.
We must regard science then from three points of view. First it is the
free activity of man's divine faculties of reason and imagination. Secondly it
is the answer of the few to the demands of the amny for wealth, comfort and
vicotry, for {Here Haldane quots a Greek phrase I cannot reproduce in ASCII},
gifts which it will grant only in exchange for peace, security and stagnation.
Finally it is man's gradual conquest, first of space and time, then of matter
as such, then of his own body and those of other living beings, and finally the
subjugation of the dark and evil elements in his own soul.
None of these conquests will ever be complete but all, I believe will
be progressive. The question of what he will do with these powers is
essentially a question for religion and aesthetic. It may be urged that they
are only fit to be placed in the hands of a being who has learned to control
himself, and that man armed with science is like a baby armed with a box of
matches.
The answer to this contention may, I think, be found in the daily
papers. For scores of centuries idealists had urged that wars must cease and
all the earth be united under one rule. As long as any other alternative was
possible it was persisted in. The events of the last nine years constituted
a reductio ad absurdum of war, but when we ask who responsible for this we
shall find that it was not the visionaries but men like Black, Kekule, and
Langley, who enlarged man's power over natureuntil he was forced by the
inexorable logic of facts to form the nucleus of an international government.
We have already reacted against the frame of mind that engendered the
league of nations, but we have not reacted at all completely. The league exists
and is working, and in every country on earth there are many people, and
ordinary normal people, who favor the idea in one form or another of a world
state. I do not suggest that a world-state will arise from the present league
-- or for the matter of that from the third international. I merely observe
that there is a widespread and organized desire for such an institution, and
several possible nuclei for it. It may take another world-war or two to convert
the majority. The prospect of the next world-war has at least this satisfactory
element. In the late war the most rabid nationalists were to be found well
behind the front line. In the next war no one will be behind the front line.
It will be brought home to all whom it may concern that war is a very dirty
business.
No doubt there is a fair chance that the possibility of human
organization on a planetary scale may be rendered impossible by such a war. If
so mankind will probably have to wait for a couple of thousand years for
another opportunity. But to the student of geology such a period is negligible.
It took man 250,00 years to transcend the hunting pack. It will not take him so
long to transcend the nation.
I think then that the tendency of applied sicne is to magnify
injustices until they become too intolerable to be borne, and the average man
whom all the prophets and poets could not move, turns at least and extinguishes
the evil at its source. Marx' theory of industrial evolution is a particular
example of this tendency, though it does not in the least follow that his
somewhat artificial solution of the problem will be adopted.
It is probable that biological progress will prove to be as
incompatible with certain of our social evils as industrial progress has proved
to be with war or certain systems of private ownership. To take a concrete
example it is clear that the second biological invention considered by my
future essayist would be intolerable in conjunction with our present system of
relations between classes and sexes. Moral progress is so difficult that I
think any developmens are to be welcomed which present it as the naked
alternative to destruction, no matter how horrible may be the stimulus which is
necessary before man will take the moral step in question.
To sum up, then, science is as yet in its infancy, and we can fortell
little of the future save that the thing that has not been is the thing that
shall be; that no beliefs, no values, no institutions are safe. So far from
being an isolated phenomenon the late war is only an example of the disruptive
result that we may constantly expect from the progress of science. The future
will be no primrose path. It will have its own problems. Some will be the
secular problems of the past, giant flowers of evil blossoming at last to their
own destruction. Others will be wholly new. Whether in the end man will survive
his accenssions of power we cannot tell. But the problem is no new one. It is
the old paradox of freedom re-enacted with mankind for actor and the earth for
stage. To those who believe in the divinity of that part of man which aspires
after knowledge for its own sake, who are, in the words of Boethius:
te cernere finis
Principoum, vector, dux, semita, terminus idem
the prospect will appear most hopeful. But it is only hopeful if mankind can
adjust its morality to its powers. If we can succeed in this, then science
holds in her hands one at least of the keys to the thorny and arduous path of
moral progress, then:
Per cruciamina leti
Via panditur ardua justis,
Et ad astra doloribus itur.
That is possibly a correct large-scale view, but it is only for short
periods that one can take views of history sufficiently broad to render the
fate of one's own generation irrelevant. The scientific worker is brought up
with the moral values of his neighbors. He is perhaps fortunate if he does not
realize that it is his destiny to turn good into evil. The moral and physical
(though not the intellecutal) virtues are means between two extremes. They are
essentially quantitative. It followsd that an alteration in the scale of human
power will render actions bad which were formerly good. Our increased knowledge
of hygiene has transformed resignation and inaction in face of epidemic disease
from a religious virtue to a justly punishable offence. We have improved our
armaments, and patriotism, which was once a flame upon the altar, has become a
world-devouring conflagration.
The time has gone by when a Huxley could believe that while science
might indeed remould traditional mythology, traditional morals were impregnable
and sancrosanct to it. We must learn not to take traditional morals too
seriously. And it is just because even the least dogmatic of religions tends to
associate itself with some kind of unalterable moral tradition, that there can
be no truce between science and religion.
There does not seem to be any particular reason why a religion should
not arise with an ethic as fluid as Hindu mythology, but it has not yet arisen.
Christianity has probably the most flexible morals of any religion, because
Jesus left no code of law behind him like Moses or Muhammad, and his moral
precepts are so different from those of ordinary life that no society has ever
made any serious attempt to carry them out, such as was possible in the case of
Israel and Islam. But every Christian church has tried to impose a code of
morals of some kind for which it has claimed divine sanction. As these codes
have always been opposed to those of the gospels a loophole has been left for
moral progress such as hardly exists in other religions. This is no doubt an
argument for Christianity as against other religions, but not as against none
at all, or as against a religion which will frankly admit that its mythology
and morals are provisional. That is the only sort of religion that would
satisfy the scientific mind, and it is very doubtful whether it could properly
be called a religion at all.
No doubt many people hope that such a religion may develop from
Christianity. The human intellect is feeble, and there are times when it does
not assert the infinity of its claims. But even then:
Though in black jest it bows and nods
* * * *
I know it is roaring at the gods
Waiting for the last eclipse.
The scientific worker of the future will more and more resmble the
lonely figure of Daedalus as he becomes conscious of his ghastly mission, and
proud of it.
Black is his robe from top to toe,
His flesh is white and warm below,
All through his silent veins flow free
Hunger and thirst and venery,
But in his eyes a still small flame
Like the first cell from which he came
Burns round and luminous, as he rides
Singing my song of deicides.
EDITOR'S NOTES
1: Speaking as a physicist, and with all due respect for Haldane, Einstein's
theories do not depend on any "ideality" of space or time, or even imply
their ideality. See Russell's _The ABC of Relativity_, or Wheeler's
_Spacetime Physics_.
2: Cf. Arthur C. Clarke's _The City and the Stars_ and Stewart Brand's _The
Media Lab: Inventing the Future at MIT_.
3: Cf. John Kenneth Galbraith's _The Affluent Society_ and _The New Industrial
State_.
4: Haldane was a classics student as an undergraduate.
5: Embden, Grafe and Schmitz. Zeitschrift fur physiologische Chemie, Vol.
113, p. 67, 1921. [Haldane's note.]
6: The Hindus have recognized the special and physiological relation of man to
the cow by making the latter animal holy. A good Hindu would no more kill a
cow than his foster-mother. But the holiness of the cow has unfortunately
extend to all its products, and the extensive use of cowdung in Indian
religious ceremnoies is disgusting to the average European. The latter,
however, is insensitive to the equally loathsome injunctions of the
Catholic Church with regard to human marriage. It would perhaps be better
if both marriage and milking could be secularized. [Haldane's note.]
7: All referneces to "the league" are to the League of Nations.
8: Whether Haldane meant to imply that there were fewer theives, or merely
fewer dumb enough to let themselves be convicted, is unclear.
9: That is, god-killers.
10: That is, Julius Caeser.