THE ELECTRIC ORRERY.
“Half-moon Junction! Change
here for Venus, Mercury, the Earth, Mars, Jupiter,
Saturn, Uranus, Neptune!”
So I called in the style of a Clapham
railway porter, as I entered the observatory of Professor
Gazen on the following night.
“What is the matter?”
said he with a smile. “Are you imitating
the officials of the Universal Navigation Company
in the distant future?”
“Not so distant as you may imagine,”
I responded significantly; and then I told him all
that I had seen and heard of the new flying machine.
The professor listened with serious
attention, but manifested neither astonishment nor
scepticism.
“What do you think about it?”
I asked. “What should I do in the case?”
“Well, I hardly know,”
he replied doubtfully. “It is rather out
of my line, and after my experience with Mars the
other night, I am not inclined to dogmatise.
At all events, I should like to see and try the machine
before giving an opinion.”
“I will arrange for that with the inventor.”
“Possibly I can find out something
about him from my American friends if he
is genuine. What’s his name again?”
“Carmichael Nasmyth Carmichael.”
“Nasmyth Carmichael,”
repeated Gazen, musingly. “It seems to me
I’ve heard the name somewhere. Yes, now
I recollect. When I was a student at Cambridge,
I remember reading a textbook on physics by Professor
Nasmyth Carmichael, an American, and a capital book
it was beautifully simple, clear, and profound
like Nature herself. Professors, as a rule, and
especially professors of science, are not the best
writers in the world. Pity they can’t teach
the economy of energy without wasting that of their
readers. Carmichael’s book was not a dead
system of mathematics and figures, but rather a living
tale, with illustrations drawn from every part of
the world. I got far more help from it than the
prescribed treatises, and the best of that was a liking
for the subject. I believe I should have been
plucked without it.”
“The very man, no doubt.”
“He was remarkably sane when
he wrote that book, whatever he is now. As to
his character, that is another question. Given
a work of science, to find the character of the author.
Problem.”
“I shall proceed cautiously
in the affair. Before I commit myself, I must
be satisfied by inspection and trial that there is
neither trickery nor self-delusion on his part.
We can make some trial trips, and gain experience
before we attempt to leave the world.”
“If you take my advice you will
keep to the earth altogether.”
“Surely, if we can ascend into
the higher regions of the atmosphere, we can traverse
empty space. You would have me stop within sight
of the goal. The end of travel is to reach the
other planets.”
“Why not say the fixed stars when you are about
it?”
“That’s impossible.”
“On the contrary, with a vessel
large enough to contain the necessaries of life, a
select party of ladies and gentlemen might start for
the Milky Way, and if all went right, their descendants
would arrive there in the course of a few million
years.”
“Rather a long journey, I’m afraid.”
“What would you have? A
million years quotha! nay, not so much. It depends
on the speed and the direction taken. If they
were able to cover, say, the distance from Liverpool
to New York in a tenth of a second, they would get
to Alpha in the constellation Centaur, perhaps the
nearest of the fixed stars, in twenty or thirty years a
mere bagatelle. But why should we stop there?”
went on Gazen. “Why should we not build
large vessels for the navigation of the ether artificial
planets in fact and go cruising about in
space, from universe to universe, on a celestial Cook’s
excursion
“We are doing that now, I believe.”
“Yes, but in tow of the Sun.
Not at our own sweet will, like gipsies in a caravan.
Independent, free of rent and taxes, these hollow planetoids
would serve for schools, hotels, dwelling-houses
“And lunatic asylums.”
“They would relieve the surplus
population of the globe,” continued Gazen, warming
to his theme. “It is an idea of the first
political importance especially to British
statesmen. The Empire is only in its infancy.
With a fleet of ethereal gunboats we might colonise
the solar system, and annex the stars. What a
stroke of business!”
“Another illusion gone,”
I observed “Think of Manchester cotton in the
Pleiades! Of Scotch whiskey in Orion! However,
I am afraid your policy would lead to international
complications. The French would set up a claim
for ‘Ancient Lights.’ The Germans
would discover a nebulous Hinterland under their protection.
The Americans would protest in the name of the Monroe
Doctrine. It is necessary to be modest. Let
us return to our muttons.”
“Everybody will be able to pick
a world that suits him,” pursued Gazen, still
on the trail of his thought. “If he grows
tired of one he can look round for a better.
Criminals will be weeded out and sent to Coventry,
I mean transplanted into a worse. When a planet
is dying of old age, the inhabitants will flit to
another.”
“Seriously, if Carmichael’s
machine turns out all right, will you join me in a
trip?”
“Thanks, no. I believe
I shall wait and see how you get on first.”
“And where would you advise me to go, Mars or
Venus?”
The professor smiled, but I was quite in earnest.
“Well,” he replied, “Mars
is evidently inhabited; but so is Venus, probably,
and of the two I think you will find her the more hospitable
and the nearest. When do you propose to start?”
“Perhaps within six months.”
“We must consider their relative
distances from the earth. By the way, I don’t
think you have seen my new electrical orrery.”
“An electrical orrery,” I exclaimed.
“Surely that is something new!”
“So far as I am aware; but you
never know in these days. There is nothing new
under the sun, or even above it.”
So saying, he opened a small door
in the side of the observatory, and, ushering me into
a very dark apartment, closed it behind us.
“Follow me, there is no danger,”
said he, taking me by the arm, and guiding me for
several paces into the darkness.
At length we halted, and I looked
all around me, but was unable to perceive a single
object.
“Where are we?” I enquired;
“in the realms of Chaos and Old Night?”
“You are now in the centre of
the Universe,” replied Gazen; “or, to
speak more correctly, at a point in space overlooking
the solar system.”
“Well, I can’t see it,”
said I. “Have you got such a thing as a
match about you?”
“Let there be light!”
responded Gazen in a reverent manner, and instantly
a soft, weird radiance was over all. The contrast
of that sudden illumination with the preceding darkness
was electrical in more senses than one, and I could
not repress a cry of genuine admiration.
A kind of twilight still reigned,
and after the first moment of surprise, I perceived
that we were standing on a light metal gangway in
the middle of a great hollow cell of a luminous black
or dark blue colour, relieved by innumerable bright
points, and resembling the night sky in miniature.
“I need hardly say that is a
model of the celestial sphere,” whispered Gazen,
indicating the starry vault.
“It is a wonderful imitation,”
I responded, my awestruck eyes wandering over the
mysterious tracts of the Milky Way and the familiar
constellations of the mimic heavens. “May
I ask how it is done how you produce that
impression of infinite distance?”
“By means of translucent shells
illuminated from behind. The stars, of course,
are electric lamps, and some of them, as you see, have
a tinge of red or blue.”
Most of the light, however, came from
a brilliant globe of a bluish lustre, which appeared
to occupy the centre of the crystal sphere, and was
surrounded by a number of smaller and fainter orbs
that shone by its reflected rays.
“This, again, is a model of
the solar system,” said Gazen. “The
central luminary is, of course, the sun, and the others
are the planets with their satellites.”
“They seem to float in air.”
“That is because their supports
are invisible, or nearly so. Both their lights
and periodic motions are produced by the electric current.”
“Surely they are not moving now?”
“Oh, yes, and with velocities
proportionate to those of the real bodies; but you
know that whilst the actual movements of the sun and
planets are so rapid, the dimensions of the system
are so vast that if you could survey the whole from
a standpoint in space, as we are supposed to do, it
would appear at rest. Let us look at them a little
closer.”
I followed Gazen along the gangway
which encircled the orrery, and allowed us to survey
each of the planets closer at hand.
“This kind of place would make
a good theatre for a class in astronomy,” said
I, “or for the meetings of the Interplanetary
Congress of Astronomers, in the year 2000. You
can turn on the stars and planets when you please.
I wish you would give me a lecture on the subject now.
My knowledge is a little the worse for wear, and a
man ought to know something of the worlds around him especially
if he intends to visit them.”
“I should only bore you with an old story.”
“Not at all. You cannot
be too simple and elementary. Regard me as a
small boy in the stage of
“’Twinkle, twinkle,
little star,
How I wonder what
you are!’”
“Very well, my little man, have
you any idea how many stars you can see on a clear
night?”
“Billions.”
“No, Tommy. You are wrong,
my dear boy. Go to the foot of your class.
With the naked eye we can only distinguish three or
four thousand, but with the telescope we are able
to count at least fifty millions. They are thickest
in the Milky Way, which, as you can see, runs all round
the heavens, over your head, and under your feet,
like an irregular tract of hazy light, a girdle of
stars in short. Of course we cannot tell how
many more there are beyond the range of vision, or
what other galaxies may be scattered in the depths
of space. The stars are suns, larger or smaller
than our own, and of various colours white,
blue, yellow, green, and red. Some are single,
but others are held together in pairs or groups by
the force of gravitation. From their immense distance
they appear fixed to us, but in reality they are flying
in all directions at enormous velocities. Alpha,
of the constellation Cygnus, for example, is coming
towards us at a speed of 500 million leagues per annum,
and some move a great deal faster. Most of them
probably have planets circling round them in different
stages of growth, but these are invisible to us.
Here and there amongst them we find luminous patches
or ‘nebulae,’ which prove to be either
clusters of stars or stupendous clouds of glowing
gases. Our sun is a solitary blue star on the
verge of the Milky Way, 20 billion miles from Alpha
Centauri his next-door neighbour. He is
travelling in a straight line towards the constellation
Hercules at the rate of 20,000 miles an hour, much
quicker than a rifle bullet; and, nevertheless, he
will take more than a million years to cover the distance.
Eight large or major planets, with their satellites,
and a flock of minor planets or planetoids, are revolving
round him as their common centre and luminary at various
distances, but all in the same direction. The
orbits, or paths, about the sun are ovals or ellipses,
almost circular, of which the sun occupies one focus,
and they are so nearly in one plane, or at one level,
that if seen from the sun, they would appear to wander
along a narrow belt of the heavens, called the zodiac,
which extends a few degrees on each side of the Elliptic
or apparent course of the sun against the stars.
The planets are all globes, more or less flat at the
poles, like an orange, and each is turning and swaying
on its axis, thus exposing every part to the light
and warmth of the sun. They are divided by the
planetoids into an inner and an outer band. The
inner four are Mercury, Venus, the Earth, and Mars;
the outer four are Jupiter, Saturn, Uranus, and Neptune.
Moreover, a number of comets and swarms of meteoric
stones or meteorites are circulating round the sun
in eccentric paths, which cross those of the planets.
Such is the solar system a lonely archipelago
in the ethereal ocean a little family of
worlds.”
“Not without its jars, I’m afraid.”
“The sun is chief of the clan,”
continued Gazen, “and keeps it together by the
mysterious tie of gravitation. While flying through
space, he turns round his own axis like a rifle bullet
in 25 or 26 days. His diameter is 860,000 miles,
and although he is not much denser than sea-water,
his mass is over 700 times greater than the combined
mass of all his retinue. Gravity on his surface
being 28 times stronger than on the earth, a piece
of timber would be as heavy as gold there, and a stone
let fall would drop 460 feet the first second instead
of 16 feet as here. He is built of the same kind
of matter as the earth and other planets, but is hotter
than the hottest electric arc or reverberatory furnace.
Apparently his glowing bulk is made up of several concentric
shells like an onion. First there is a kernel
or liquid nucleus, probably as dense as pitch.
Above it is the photosphere, the part we usually see,
a jacket of incandescent clouds, or vapours, which
in the telescope is seen to resemble ‘willow
leaves,’ or ’rice grains in a plate of
soup,’ and in the spectroscope to reveal the
rays of iron, manganese, or other heavy elements.
What we call ‘faculae’ (or little torches),
are brighter streaks, not unlike some kinds of coral.
The ‘Sunspots’ are immense gaps or holes
in the photosphere, some of them 150,000 miles in
diameter, which afford us a peep at the glowing interior.
There are different theories as to their nature, hence
they provide rival astronomers with an excellent opportunity
of spotting each other’s reputations. For
instance, I look upon them as eruptions, and Professor
Sylvanus Pettifer Possil (my pet aversion) regards
them as cyclonic storms; consequently we never lose
an opportunity of erupting and storming at each other.
Above the photosphere comes a stratum of cooler vapours
and gases, namely, hydrogen and helium, a very light
element recently found on the earth, along with argon,
in the rare mineral cleveite. Tremendous jets
of blazing hydrogen are seen to burst through the
clouds of the photosphere, and play about in this higher
region like the flames of a coal fire. These are
the famous ‘red flames’ or ‘prominences,’
which are seen during a total eclipse as a ragged
fringe of rosy fire about the black disc of the moon.
Some of them rush through the chromosphere to a height
of 80,000 miles in 15 minutes.
“Higher still is the ‘corona,’
an aureole of silvery beams visible in a total eclipse,
and resembling the star of a decoration. The streamers
have been traced for hundreds of thousands of miles
beyond the solar disc. It appears to consist
of meteoric stones, illuminated by the sunlight as
well as of incandescent vapours of ‘coronium,’
a very light element unknown on the earth, and probably,
too, of electrical discharges. The ‘zodiacal
light,’ that silvery glow often seen in the
west after sunset, or in the east before sunrise, may
be a prolongation of it.”
“I daresay these meteorites
are swarming about the sun like midges about a lamp,”
said I.
“And just as eager to get burnt
up,” replied Gazen, with a smile. “Let
us pass now to the planets. The little one next
the sun is Mercury, who can be seen as a rosy-white
star soon after sunset or before sunrise. He
is about 36 million miles, more or less, from the sun;
travels round his orbit in 88 days, the length of
his year; and spins about his axis in 24 hours, making
a day and night. His diameter is 3,000 miles,
and his mass is nearly seven times that of an equal
volume of water. The attraction of gravity on
his surface is barely half that on the earth, and
a man would feel very light there. Mercury seems
to have a dense atmosphere, and probably high mountains,
if not active volcanoes. The sunshine is from
four to nine times stronger there than on the earth,
and as summer and winter follow each other in six weeks,
he is doubtless rather warm.
“Venus, the ‘Shepherd’s
Star,’ and the brightest object in the heavens
after the moon, can sometimes be seen by day, and casts
a distinct shadow at night. She is about 67 million
miles from the sun, revolves round him in 225 days,
and rotates on her axis in 23 to 24 hours, or as Schiaparelli
believes, in 224 days. Her diameter is 7,600 miles,
and her mass nearly five times that of an equal volume
of water. Gravity is rather less there than it
is here. Like Mercury, she appears to have a
cloudy atmosphere, and very high mountains. On
the whole she resembles the earth, but is, perhaps,
a younger as well as a warmer planet.
“The green ball, next to Venus,
is, I need hardly say, our own dear little world.
Terra, or the earth, is 93 million miles from the sun,
goes round him in 365 days, and turns on her axis in
24 hours less four minutes. Her diameter is 7,918
miles, and her density is 5.66 times that of water.
She is attended by a single satellite, the moon, which
revolves round her in 27.3 days, at a distance of 238,000
miles. The moon rotates on her axis in about
the same time, and hence we can only see one side
of her. She is 2,160 miles in diameter, but her
mass is only one-eightieth that of the earth.
A pound weight on the moon would scale six pounds
on the earth. Having little or no atmosphere or
water, she is apparently a dead world.
“The red planet beyond the earth
is Mars, who appears in the sky as a ruddy gold or
coppery star. He is 141 million miles from the
sun, travels his orbit in 687 days, and wheels round
his axis in 24 hours 37 minutes. His diameter
is 4,200 miles, and his mass about one-ninth that
of the earth. A body weighing two pounds on the
earth would only make half a pound on Mars. As
you know, his atmosphere is clear and thin, his surface
flat, and subject to floods from the melting of the
polar snows. Mars is evidently a colder and more
aged planet than the earth.
“He is accompanied by two little
moons, Phobos (Fear), which is from ten to forty miles
in diameter, and revolves round him in 7 hours 39
minutes, at a distance of 6,000 miles, a fact unparalleled
in astronomy; and Deimos (Rout), who completes a revolution
in 30 hours 18 minutes, at a distance of 14,500 miles.
“About 400 planetoids have been
discovered up to now, but we are always catching more
of them. Medusa, the nearest, is 198 million miles,
and Thule, the farthest, is 396 million miles from
the sun. Vesta, the brightest and probably the
largest, a pale yellow, or, as some say, bluish white
orb, visible with the naked eye, is from 200 to 400
miles in diameter. It is impossible to say which
is the smallest. Probably the mass of the whole
is not greater than one quarter that of the earth.
“Jupiter, surnamed the ‘giant
planet,’ who almost rivals Venus in her splendour,
is 480 million miles from the sun; travels round his
orbit in 12 years less 50 days; and is believed to
whirl round his axis in 10 hours. His diameter
is 85,000 miles, and his bulk is not only 1,200 times
that of the earth, but exceeds that of all the other
planets put together. Nevertheless, his mass
is only 200 to 300 times that of the earth, for his
density is not much greater than that of water.
What we see is evidently his vaporous atmosphere,
which is marked by coloured spots and bands or belts,
probably caused by storms and currents, especially
in the equatorial regions. Jupiter is thought
to be self luminous, at least in parts, and is, perchance,
a cooling star, not yet entirely crusted over.
“Four or five numbered satellites,
about the size of our moon and upwards, are circulating
round him in orbits from 2,000 to 1,000,000 miles
distant in periods ranging from 11 hours to 16 days
18 hours.
“Saturn, the ‘ringed planet,’
who appears as a dull red star of the first magnitude,
is the most interesting of all the planets. He
is 884 million miles from the sun; his period of revolution
is 291/2 years, and he turns on his axis in 10 hours
14 minutes. His diameter is 75,000 miles, but
his mass is only 94 times that of the earth, for he
is lighter than pinewood. His atmosphere is marked
with spots and belts, and on the whole his condition
is like that of Jupiter.
“Two flat rings or hoops, divided
by a dark space, encircle his ball in the plane of
his equator. The inner ring is over 18,000 miles
from the ball, and nearly 17,000 miles broad.
The gap between is 1,750 miles wide, and the outer
ring is over 10,000 miles broad. The rings are
banded, bright or dark, and vary in thickness from
40 to 250 miles. They consist of innumerable
small satellites and meteoric stones, travelling round
the ball in rather more than ten hours, and are brightest
in their densest parts. Of course they form a
magnificent object in the night sky of the planet,
and it may be that our own zodiacal light is the last
vestige of a similar ring, and not an extension of
the solar corona.
“Saturn has eight moons outside
his rings, the nearest, Mimas, being 115,000, and
the farthest, Japetus, 220,400 miles from his ball.
With the exception of Japetus, they revolve round
him in the plane of his rings, and when these are
seen edgewise, appear to run along it like beads on
a string.
“Uranus, the next planet visible,
is a pale star of the sixth magnitude, 1,770 million
miles from the sun, and completes his round in 84 years.
His axis, differing from those of the foregoing planets,
lies almost in the plane of his orbit, but we cannot
speak as to his axial rotation. He is 31,000
miles in diameter, and somewhat heavier, bulk for bulk,
than water. Four satellites revolve round him,
the nearest, Ariel, being 103,500, and the farthest,
Oberon, 347,500 miles distant. Unlike the orbits
of the foregoing satellites, which are nearly in the
same plane as the orbits of their primaries, those
of the satellites of Uranus are almost perpendicular
to his own. They are travelled in periods of two
and a half to thirteen and a half days.
“Neptune, invisible to the naked
eye, but seen as a pale blue star in the telescope,
is 2,780 million miles from the sun, and makes a revolution
in 165 years. His diameter is about 35,000 miles,
and his density rather less than that of water.
“Neptune has one satellite,
at a distance of 202,000 miles, which, like those
of Uranus, revolves about its primary in an orbit at
a considerable angle to his own in five days twenty-one
hours. Both Neptune and Uranus are probably dying
suns.
“Comets of unknown number travel
in long elliptical or parabolic orbits round the sun
at great velocities. They seem to consist partly
of glowing vapours, especially hydrogen, and partly
of meteoric stones. ‘Shooting stars,’
that is to say, stones which fall to the earth, are
known to swarm in their wake, and are believed to be
as plentiful in space as fishes in the sea.”
“The trash or leavings of creation,” said
I reflectively.
“And the raw material, for nothing
is lost,” rejoined Gazen. “Now, in
spite of all its diversity, there is a remarkable symmetry
in the solar system. The planets are all moving
round the sun in one direction along circular paths.
As a rule each is nearly as far again from the sun
as the next within it. Thus, if we take Mercury
as 3/4 inch from the sun, Venus is about 11/4 inches,
the Earth 21/4, Mars 2, the planetoids 51/4, Jupiter
93/4, Saturn 14, Uranus 36, and Neptune 60 inches.
On the same scale, by the way, Enckes’ comet
at Aphelion, its farthest distance from the sun, would
be about 12 feet; Donatis almost a mile; and Alpha
Centauri, a near star in the Milky Way, some ten
miles.
“The stately march of the planets
in their orbits becomes slower the farther they are
from the sun. The velocity of Mercury in its orbit
is thirty, that of Jupiter is eight, and that of Neptune
is only three miles a second. On the other hand,
the inner planets, as a rule, take some twenty-four
hours, and the outer only ten hours to spin round their
axis. The inner planets are small in comparison
with the outer. If we represent the sun by a
gourd, 20 inches in diameter, Mercury will seem a
bilberry ({~FRACTION NUMERATOR ONE~}{~SUBSCRIPT ONE~}{~SUBSCRIPT
SIX~} inch) Venus, a white currant, the Earth a black
currant (1/4 inch), Mars a red currant ({~VULGAR FRACTION
ONE EIGHTH~} inch), the planetoids as fine seed, Jupiter
an orange or peach (2 inches), Saturn a nectarine or
greengage (1 inch), Uranus a red cherry (3/4 inch),
and Neptune a white cherry (barely 1 inch in diameter).
By putting the sun and planets in a row, and drawing
a contour of the whole, we obtain the figure of a dirk,
a bodkin, or an Indian club, in which the sun stands
for the knob (disproportionately big), the inner planets
for the handle, and the outer for the blade or body.
Again, the average density of the inner planets exceeds
that of the outer by nearly five to one, but the mass
of any planet is greater than the combined masses
of all which are smaller than it. The inner planets
derive all their light and heat from the sun, and
have few or no satellites; whereas the outer, to all
appearance, are secondary suns, and have their own
retinue of worlds. On the similitude of a clan
or house we may regard the inner planets as the immediate
retainers of the chief, and the outer as the chieftains
of their own septs or families.”
“How do you account for the
symmetrical arrangement?” I enquired.
“The origin of the solar system
is, you know, a mystery,” replied the astronomer.
“According to the nebular hypothesis we may imagine
that two or more dark suns, perhaps encircled with
planets, have come into collision. Burst into
atoms by the stupendous shock they would fill the
surrounding region with a vast nebula of incandescent
gases in a state of violent agitation. Its luminous
fringes would fly immeasurably beyond the present
orbit of Neptune, and then rush inwards to the centre,
only to be driven outwards again. Surging out
and in, the fluid mass would expand and contract alternately,
until in course of ages the fiery tides would cease
to ebb and flow. If the impact had been somewhat
indirect it would rotate slowly on its axis, and under
the influence of gravity and centrifugal force acquire
a globular shape which would gradually flatten to
a lenticular disc. As it cooled and shrank in
volume it would whirl the faster round its axis, and
grow the denser towards its heart. By and by,
as the centrifugal force overcame gravity, the nebula
would part, and the lighter outskirts would be shed
one after another in concentric rings to mould the
planets. The inner rings, being relatively small
and heavy, would probably condense much sooner than
the large, light, outer rings. The planetoids
are apparently the rubbish of a ring which has failed
to condense into one body, perhaps through its uniformity
or thinness. The separation of so big a mass as
Jupiter might well attenuate the border.”
“If the planetoids were born
of a single small ring, might not several planets
be condensed from a large one?”
“I see nothing to hinder it.
A large ring might split into smaller rings, or condense
in several centres.”
“Because it seems to me that
might explain the distinction between the inner and
the outer planets. Perhaps the outer were first
thrown off in one immense ring, and then the inner
in a smaller ring. Before separation the nebula
viewed edgewise might resemble your Indian club.”
“A ‘dumb-bell nebula,’
like those we find in the heavens,” observed
Gazen. “Be that as it may, the rings would
collect into balls, and some of these, especially
the outer, would cast off rings which would condense
into moons, always excepting the rings of Saturn, which,
like the planetoids, are evidently a failure.
The solar system would then appear as a group of suns,
a cluster of stars, in short, a constellation.
Each would be what we call a ‘nebulous star,’
not unlike the sun at present; that is to say, it
would be surrounded by a glowing atmosphere of vapours,
and perhaps meteoric matter. Under the action
of gravity, centrifugal force, and tidal retardation,
their orbits would become more circular, they would
gradually move further apart, rotate more slowly on
their axes, and assume the shapes they have now.
In cooling down, new chemical compounds, and probably
elements would be formed, since the so-called elements
are perhaps mere combinations of a primordial substance
which have been produced at various temperatures.
The heavier elements, such as platinum, gold, and iron,
would sink towards the core; and the lighter, such
as carbon, silicon, oxygen, nitrogen, and hydrogen,
would rise towards the surface. A crust would
form, and portions of it breaking in or bursting out
together with eruptions and floods of molten lava,
would disturb the poise of the planet, and give rise
to inequalities of surface, to continents, and mountains.
When the crust was sufficiently stable, sound, and
cool, the mists and clouds would condense into rivers,
lakes, or seas, and the atmosphere would become clear.
In due course life would make its appearance.”
“Can you account for that mystery?”
“No. Science is bound in
honour, no doubt, to explain all it can without calling
in a special act of creation; but the origin of life
and intelligence seems to go beyond it, so far.
Spontaneous generation from dead matter is ruled out
of court at present. We believe that life only
proceeds from life. As for the hypothesis that
meteoric stones, the ‘moss-grown fragments of
another world’ may have brought life to the
earth, I hardly know what to think of it.”
“Has life ever been found on a meteoric stone?”
“Not that I know. Carbon,
at all events in the state of graphite and diamond,
has been got from them. They arc generally a kind
of slag, containing nodules or crystals of iron, nickle,
and other metals, and look to me as if they had solidified
from a liquid or vapour. Are they ruins of an
earlier cosmos the crumbs of an exploded
world matter ejected from the sun the
snow of a nebulous ring frozen spray from
the fiery surge of a nebula? we cannot tell; but,
according to the meteoric as distinguished from the
nebular hypothesis of the solar system, the sun, planets,
and comets, as well as the stars and nebula were all
generated by the clash of meteorites; and not as I
have supposed, of dead globes.”
“Which hypothesis do you believe?”
“There may be some truth in
both,” replied Gazen. “The two processes
might even go on together. What if meteorites
are simply frozen nebula? It is certain that
the earth is still growing a little from the fall of
meteoric stones, and that part of the sun’s heat
comes from meteoric fuel. Most of it, however,
arises from the shrinkage of his bulk. Five or
ten million years ago the sun was double the size he
is now. Twenty or thirty million years ago he
was rather a nebula than a sun. In five or ten
million more he will probably be as Jupiter is now a
smoking cinder.”
“And the earth how
long is it since she was crusted over?”
“Anything from ten to several
hundred million years. In that time the stratified
rocks have been deposited under water, the land and
sea have taken their present configurations; the atmosphere
has been purified; plants and animals have spread
all over the surface. Man has probably been from
twenty to a hundred thousand years or more on the earth,
but his civilization is a thing of yesterday.”
“How long will the earth continue fit for life?”
“Perhaps five or ten million
years. The entire solar system is gradually losing
its internal heat, and must inevitably die of sheer
inanition. The time is coming when the sun will
drift through space, a black star in the midst of
dead worlds. Perhaps the system will fall together,
perhaps it will run against a star. In either
case there would probably be a ‘new heaven and
a new earth.’”
“Born like a phoenix from the
ashes of the old,” said I, feeling the justice
of the well-worn simile.
“I daresay the process goes on to all eternity.”
“Like enough.”
The sublime idea, with its prospect
of the infinite, held us for a time in silence.
At length my thoughts reverted to the original question
which had been forgotten.
“Now, whether should I go to
Mars or Venus?” I enquired, fixing my eyes on
these planets and trying to estimate their relative
distances from the earth.
Gazen made a mental computation, and
replied with decision,
“Venus.”
“All right,” I responded. “Venus
let it be.”