QC
UC-NRLF
B M 553 7714
1819
ID
ON
RADIANT MATTER
A LECTURE DELIVERED
TO THE
BRITISH ASSOCIATION FOR THE ADVANCEMENT
OF SCIENCE,
AT SHEFFIELD,
FRIDAY, AUGUST 22, 1879.
BY
WILLIAM CROOKES, F.R.S.
Qc ill
ON
RADIANT MATTER.
throw light on the title of this lecture I must go back
more than sixty years — to 1816. Faraday, then a
mere student and ardent experimentalist, was 24 years
old, and at this early period of his career he delivered a
series of lectures on the General Properties of Matter,
and one of them bore the remarkable title, On Radiant
Matter. The great philosopher's notes of this lecture are to
be found in Dr. Bence Jones's Life and Letters of Faraday,
and I will here quote a passage in which he first employs
the expression Radiant Matter : —
" If we conceive a change as far beyond vaporisation as that is above
fluidity, and then take into account also the proportional increased
extent of alteration as the changes rise, we shall perhaps, if we can
form any conception at all, not fall far short of Radiant Matter ; and
as in the last conversion many qualities were lost, so here also many
more would disappear."
Faraday was evidently engrossed with this far-reaching
speculation, for three years later — in 1819 — we find him
bringing fresh evidence and argument to strengthen his
startling hypothesis. His notes are now more extended, and
they show that in the intervening three years he had thought
much and deeply on this higher form of matter. He first
points out that matter may be classed into four states — solid,
liquid, gaseous, and radiant — these modifications depending
upon differences in their several essential properties. He
admits that the existence of Radiant Matter is as yet un-
proved, and then proceeds, in a series of ingenious analogical
arguments, to show the probability of its existence.*
* " I may now notice a curious progression in physical properties ac-
companying changes of form, and which is perhaps sufficient to induce,
in the inventive and sanguine philosopher, a considerable degree of
216 B*
4 On Radiant Matter.
If, in the beginning of this century, we had asked, What is
a Gas ? the answer then would have been that it is matter,
expanded and rarefied to such an extent as to be impalpable,
save when set in violent motion ; invisible, incapable of as-
suming or of being reduced into any definite form like solids,
or of forming drops like liquids ; always ready to expand
where no resistance is offered, and to contract on being sub-
jected to pressure. Sixty years ago such were the chief
attributes assigned to gases. Modern research, however, has
greatly enlarged and modified our views on the constitution
of these elastic fluids. Gases are now considered to be com-
posed of an almost infinite number of small particles or
molecules, which are constantly moving in every direc-
tion with velocities of all conceivable magnitudes. As
these molecules are exceedingly numerous, it follows that
no molecule can move far in any direction without coming
in contact with some other molecule. But if we exhaust the
airorgas contained in a closed vessel, the number of molecules
becomes diminished, and the distance through which any
one of them can move without coming in contact with
another is increased, the length of the mean free path being
inversely proportional to the number of molecules present.
The further this process is carried the longer becomes the
average distance a molecule can travel before entering
belief in the association of the radiant form with the others in the set
of changes I have mentioned.
" As we ascend from the solid to the fluid and gaseous states, phy-
sical properties diminish in number and variety, each state losing some
of those which belonged to the preceding state. When solids are con-
verted into fluids, all the varieties of hardness and softness are neces-
sarily lost. Crystalline and other shapes are destroyed. Opacity and
colour frequently give way to a colourless transparency, and a general
mobility of particles is conferred.
" Passing onward to the gaseous state, still more of the evident cha-
racters of bodies are annihilated. The immense differences in their
weight almost disappear ; the remains of difference in colour that were
left, are lost. Transparency becomes universal, and they are all elastic.
They now form but one set of substances, and the varieties of density,
hardness, opacity, colour, elasticity and form, which render the num-
ber of solids and fluids almost infinite, are now supplied by a few slight
variations in weight, and some unimportant shades of colour.
"To those, therefore, who admit the radiant form of matter, no dif-
ficulty exists in the simplicity of the properties it possesses, but rather
an argument in their favour. These persons show you a gradual
resignation of properties in the matter we can appreciate as the matter
ascends in the scale of forms, and they would be surprised if that effect
were to cease at the gaseous state. They point out the greater exer-
tions which Nature makes at each step of the change, and think that,
consistently, it ought to be greatest in the passage from the gaseous to
the radiant form." — Life and Letters of Faraday, vol. i., p. 308.
On Radiant Matter. 5
into collision ; or, in other words, the longer its mean free
path, the more the physical properties of the gas or air are
modified. Thus, at a certain point, the phenomena of the
radiometer become possible, and on pushing the rarefaction
still further, i.e., decreasing the number of molecules in a
given space and lengthening their mean free path, the expe-
rimental results are obtainable to which I am now about to
call your attention. So distinct are these phenomena from
anything which occurs in air or gas at the ordinary tension,
that we are led to assume that we are here brought face to
face with Matter in a Fourth state or condition, a condition
as far removed from the state of gas as a gas is from a liquid.
Mean Free Path. Radiant Matter.
I have long believed that a well-known appearance ob-
served in vacuum tubes is closely related to the phenomena
of the mean free path of the molecules. When the negative
pole is examined while the discharge from an induction-coil
is passing through an exhausted tube, a dark space is seen
to surround it. This dark space is found to increase
and diminish as the vacuum is varied, in the same way that
the mean free path of the molecules lengthens and contracts.
As the one is perceived by the mind's eye to get greater, so
the other is seen by the bodily eye to increase in size ; and if
the vacuum is insufficient to permit much play of the mole-
cules before they enter into collision, the passage of electri-
city shows that the "dark space" has shrunk to small
dimensions. We naturally infer that the dark space is
the mean free path of the molecules of the residual gas,
an inference confirmed by experiment.
I will endeavour to render this " dark space " visible to
all present. Here is a tube, (Fig. i), having a pole in the
FIG.
6 On Radiant Matter.
centre in the form of a metal disk, and other poles at each
end. The centre pole is made negative, and the two end
poles connected together are made the positive terminal.
The dark space will he in the centre. When the exhaustion
is not very great the dark space extends only a little
on each side of the negative pole in the centre. When the
exhaustion is good, as in the tube before yon, and I turn
on the coil, the dark space is seen to extend for about an
inch on each side of the pole.
Here, then, we see the induction spark actually illumin-
ating the lines of molecular pressure caused by the excite-
ment of the negative pole. The thickness *of this dark
space is the measure of the mean free path between suc-
cessive collisions of the molecules of the residual gas.
The extra velocity with which the negatively electrified
molecules rebound from the excited pole keeps back the
more slowly moving molecules which are advancing to-
wards that pole. A conflict occurs at the boundary of the
dark space, where the luminous margin bears witness to the
energy of the discharge.
Therefore the residual gas — or, as I prefer to call it, the
gaseous residue — within the dark space is in an entirely
different state to that of the residual gas in vessels at a
lower degree of exhaustion. To quote the words of our last
year's President, in his Address at Dublin :—
" In the exhausted column we have a vehicle for electricity not
constant like an ordinary conductor, but itself modified by the passage
of the discharge, and perhaps subject to laws differing materially from
those which it obeys at atmospheric pressure."
In the vessels with the lower degree of exhaustion,
the length of the mean free path of the molecules is
exceedingly small as compared with the dimensions of
the bulb, and the properties belonging to the ordinary
gaseous state of matter, depending upon constant col-
lisions, can be observed. But in the phenomena now
about to be examined, so high is the exhaustion carried
that the dark space around the negative pole has widened
out till it entirely fills the tube. By great rarefaction
the mean free path has become so long that the hits in
a given time in comparison to the misses may be disre-
garded, and the average molecule is now allowed to obey
its own motions or laws without interference. The mean
free path, in fact, is comparable to the dimensions of the
vessel, and we have no longer to deal with a continuous portion
of matter, as would be the case were the tubes less highly
On Radiant Matter. 7
exhausted, but we must here contemplate the molecules
individually. In these highly exhausted vessels the mole-
cules of the gaseous residue are able to dart across the tube
with comparatively few collisions, and radiating from the pole
with enormous velocity, they assume properties so novel and
so characteristic as to entirely justify the application of the
term borrowed from Faraday, that of Radiant Matter.
Radiant Matter exerts powerful phosphor o genie action where
it strikes.
I have mentioned that the Radiant Matter within the
dark space excites luminosity where its velocity is arrested
by residual gas outside the dark space. But if no residual
gas is left, the molecules will have their velocity ar-
rested by the sides of the glass ; and here we come to
the first and one of the most noteworthy properties of
Radiant Matter discharged from the negative pole — its
power of exciting phosphorescence when it strikes against
solid matter. The number of bodies which respond
luminously to this molecular bombardment is very great,
and the resulting colours are of every variety. Glass,
for instance, is highly phosphorescent when exposed to a
stream of Radiant Matter. Here (Fig. 2) are three bulbs
FIG. 2.
composed of different glass: one is uranium glass (a),
which phosphorescesof adark green colour; anotherisEnglish
glass (b), which phosphoresces of a blue colour ; and the third
(c) is soft German glass, — of which most of the apparatus
before you is made, — which phosphoresces of a bright apple-
green.
My earlier experiments were almost entirely carried on by
the aid of the phosphorescence which glass takes up when it
8 On Radiant Matter.
is under the influence of the radiant discharge ; but many
other substances possess this phosphorescent power in a
still higher degree than glass. For instance, here is some
of the luminous sulphide of calcium prepared according to
M. Ed. Becquerel's description. When the sulphide is
exposed to light — even candlelight — it phosphoresces for
hours with a bluish white colour. It is, however, much more
strongly phosphorescent to the molecular discharge in a
good vacuum, as you will see when I pass the discharge
through this tube.
Other substances besides English, German, and uranium
glass, and Becquerel's luminous sulphides, are also phos-
phorescent. The rare mineral Phenakite (aluminate of
glucinum) phosphoresces blue ; the mineral Spodumene (a
silicate of aluminium and lithium) phosphoresces a rich
golden yellow ; the emerald' gives out a crimson light.
But without exception, the diamond is the most sensitive
substance I have yet met for ready and brilliant phos-
phorescence. Here is a very curious fluorescent diamond,
green by daylight, colourless by candlelight. It is
mounted in the centre of an exhausted bulb (Fig. 3),
FIG. i.
and the molecular discharge will be directed on it from
below upwards. On darkening the room you see the
On Radiant Matter. g
diamond shines with as much light as a candle, phosphor-
escing of a bright green.
Next to the diamond the ruby is one of the most remarkable
stones for phosphorescing. In this tube (Fig. 4) is a fine col-
lection of ruby pebbles. As soon as the induction spark is
FIG 4.
turned on you will see these rubies shining with a brilliant
rich red tone, as if they were glowing hot. It scarcely
matters what colour the ruby is, to begin with. In this tube
of natural rubies there are stones of all colours — the deep
red and also the pale pink ruby. There are some so pale
as to be almost colourless, and some of the highly-prized
tint of pigeon's blood ; but under the impact of Radiant
Matter they all phosphoresce with about the same colour.
Now the ruby is nothing but crystallised alumina with a
little colouring-matter. In a paper by Ed. Becquerel,*
published twenty years ago, he describes the appearance
of alumina as glowing with a rich red colour in the
phosphoroscope. Here is some precipitated alumina pre-
pared in the most careful manner. It has been heated
to whiteness, and you see it also glows under the molecular
discharge with the same rich red colour.
The spectrum of the red light emitted by these varie-
ties of alumina is the same as described by Becquerel
twenty years ago. There is one intense red line, a little
below the fixed line B in the spectrum, having a wave-
length of about 6895. There is a continuous spectrum be-
ginning at about B, and a few fainter lines beyond it, but
they are so faint in comparison with this red line that they
* Annales de Chimie ct de Physique, 3rd series, vol. Ivii., p. 50, 1859.
io On- Radiant Matter.
may be neglected. This line is easily seen by examining
with a small pocket spectroscope the light reflected from a
good ruby.
There is one particular degree of exhaustion more
favourable than any other for the development of the pro-
perties of Radiant Matter which are now under examina-
tion. Roughly speaking it may be put at the millionth of
an atmosphere.* At this degree of exhaustion the phos-
phorescence is very strong, and after that it begins to
diminish until the spark refuses to pass.t
i-o millionth of an atmosphere = 0*00076 millim.
1315-789 millionths of an atmosphere= fo millim.
1,000,000- ,, ,, ,, = 760*0 millims.
„ ,, „ „ =i atmosphere.
t Nearly 100 years ago Mr. Wm. Morgan communicated to the Royal
Society a Paper entitled " Electrical Experiments made to ascertain the Non-
conducting Power of a Perfect Vacuum, &c." The following extracts from
this Paper, which was published in the Phil. Trans, for 1785 (vol. Ixxv., p. 272),
will be read with interest : —
" A mercurial gage about 15 inches long, carefully and accurately boiled till
every particle of air was expelled from the inside, was coated with tin-foil
5 inches down from its sealed end, and being inverted into mercury through a
perforation in the brass cap which covered the mouth of the cistern ; the
whole was cemented together, and the air was exhausted from the inside of
the cistern through a valve in the brass cap, which producing a perfect vacuum
in the gage formed an instrument peculiarly well adapted for experiments of
this kind. Things being thus adjusted (a small wire having been previously
fixed on the inside of the cistern to form a communication between the brass
cap and the mercury, into which the gage was inverted) the coated end was
applied to the conductor of an electrical machine, and notwithstanding every
effort, neither the smallest ray of light, nor the slightest charge, could ever be
procured in this exhausted gage."
" If the mercury in the gage be imperfectly boiled, the experiment will not
succeed; but the colour of the electric light, which in air rarefied by an
exhauster is always violet or purple, appears in this case of a beautiful green,
and, what is very curious, the degree of the air's rarefaction may be nearly
determined by this means ; for I have known instances, during the course of
these experiments, where a small particle of air having found its way into the
tube, the electric light became visible, and as usual of a green colour; but the
charge being often repeated, the gage has at length cracked at its sealed end,
and in consequence the external air, by being admitted into the inside, has
gradually produced a change in the electric light from green to blue, from blue
to indigo, and so on to violet and purple, till the medium has at length become
so dense as no longer to he a conductor of electricity. I think there can be
little doubt, from the above experiments, of the non-conducting power of a
perfect vacuum."
" This seems to prove that there is a limit even in the rarefaction of air,
which sets bounds to its conducting power ; or, in other words, that the parti-
cles of air may be so far separated from each other as no longer to be able to
transmit the electric fluid ; that if they are brought within a certain distance
of each other, their conducting power begins, and continually increases till
their approach also arrives at its limit."
On Radiant Matter. n
I have here a tube (Fig. 5) which will serve to illus-
trate the dependence of the phosphorescence of the glass
on the degree of exhaustion. The two poles are at a
and b, and at the end (c) is a small supplementary tube
connected with the other by a narrow aperture, and
containing solid caustic potash. The tube has been
exhausted to a very high point, and the potash heated
so as to drive off moisture and injure the vacuum.
Exhaustion has then been re-commenced, and the alternate
heating and exhaustion repeated until the tube has been
brought to the state in which it now appears before
you. When the induction spark is first turned on nothing
is visible — the vacuum is so high that the tube is non-con-
ducting. I now warm the potash slightly and liberate a
trace of aqueous vapour. Instantly conduction commences,
and the green phosphorescence flashes out along the length
of the tube. I continue the heat, so as to drive off more
gas from the potash. The green gets fainter, and now a
wave of cloudy luminosity sweeps over the tube, and strati-
fications appear, which rapidly get narrower, until the
spark passes along the tube in the form of a narrow purple
line. I take the lamp away, and allow the potash to cool ;
as it cools, the aqueous vapour, which the heat had driven
off, is re-absorbed. The purple line broadens out, and breaks
up into fine stratifications ; these get wider, and travel to-
wards the potash tube. Now a wave of gresn light appears
on the glass at the other end, sweeping on and driving the
last pale stratification into the potash ; and now the tube
glows over its whole length with the green phosphorescence.
I might keep it before you, and show the green growing
fainter and the vacuum becoming non-conducting; but I
should detain you too long, as time is required for the ab-
sorption of the last traces of vapour by the potash, and 1
must pass on to the next subject.
12
On Radiant Matter.
Radiant Matter proceeds in straight lines.
The Radiant Matter whose impact on the glass causes an
evolution of light, absolutely refuses to turn a corner.
Here is a V-shaped tube (Fig. 6), a pole being at each ex-
tremity. The pole at the right side (a) being negative, you
FIG. 6.
see that the whole of the right arm is flooded with green
light, but at the bottom it stops sharply and will not turn
the corner to get into the left side. When I reverse the
current and make the left pole negative, the green changes
to the left side, always following the negative pole and
leaving the positive side with scarcely any luminosity.
In the ordinary phenomena exhibited by vacuum
tubes — phenomena with which we are all familiar — it is
customary, in order to bring out the striking contrasts
of colour, to bend the tubes into very elaborate designs.
The luminosity caused by the phosphorescence of the
residual gas follows all the convolutions into which
skilful glass-blowers can manage to twist the glass.
The negative pole being at one end and the positive pole
On Radiant Matter. 13
at the other, the luminous phenomena seem to depend
more on the positive than on the negative at the
ordinary exhaustion hitherto used to get the best
phenomena of vacuum tubes. But at a very high
exhaustion the phenomena noticed in ordinary vacuum
tubes when the induction spark passes through them — an
appearance of cloudy luminosity and of stratifications —
disappear entirely. No cloud or fog whatever is seen in
the body of the tube, and with such a vacuum as I am
working with in these experiments, the only light observed
is that from the phosphorescent surface of the glass. I
have here two bulbs (Fig. 7), alike in shape and position
Fie, 7.
of pules, the only difference being that one is at an
exhaustion equal to a few millimetres of mercury — such
a moderate exhaustion as will give the ordinary luminous
phenomena — whilst the other is exhausted to about the
millionth of an atmosphere. I will first conned* the mode-
14 On Radiant Matter.
rately exhausted bulb (A) with the induction-coil, and re-
taining the pole at one side (a) always negative, I will put
the positive wire successively to the other poles with which
the bulb is furnished. You see that as I change the
position of the positive pole, the line of violet light joining
the two poles changes, the electric current always choosing
the shortest path between the two poles, and moving about
the bulb as I alter the position of the wires.
This, then, is the kind of phenomenon we get in ordinary
exhaustions. I will now try the same experiment with a bulb
(B) that is very highly exhausted, and as before, will make
the side pole (a') the negative, the top pole (6) being positive.
Notice how widely different is the appearance from that
shown by the last bulb. The negative pole is in the
form of a shallow cup. The molecular rays from the cup
cross in the centre of the bulb, and thence diverging fall on
the opposite side and produce a circular patch of green
phosphorescent light. As I turn the bulb round you will
all be able to see the green patch on the glass. Now observe,
I remove the positive wire from the top, and connect it with
the side pole (c). The green patch from the divergent negative
focus is there still . I now make the lowest pole (d) posi-
tive, and the green patch remains where it was at first,
unchanged in position or intensity.
We have here another property of Radiant Matter. In the
low vacuum the position of the positive pole is of every
importance, whilst in a high vacuum the position of the posi-
tive pole scarcely matters at all ; the phenomena seem to
depend entirely on the negative pole. If the negative pole
points in the direction of the positive, all very well, but
if the negative pole is entirely in the opposite direction it
is of little consequence : the Radiant Matter darts all the
same in a straight line from the negative.
If, instead of a flat disk, a hemi-cylinder is used for the
negative pole, the Matter still radiates normal to its surface.
The tube before you (Fig. 8) illustrates this property. It
contains, as a negative pole, a hemi-cylinder (a) of polished
aluminium. This is connected with a fine copper wire, 6,
ending at the platinum terminal, c. At the upper end of
the tube is another terminal, d. The induction-coil is con-
nected so that the hemi-cylinder is negative and the upper
pole positive, and when exhausted to a sufficient extent
the projection of the molecular rays to a focus is very
beautifully shown. The rays of Matter being driven from
the hemi-cylinder in a direction normal to its surface, come
On Radiant Matter. 15
to a focus and then diverge, tracing their path in brilliant
green phosphorescence on the surface of the glass.
FIG.
Instead of receiving the molecular rays on the glass, I
\vill show you another tube in which the focus falls on a
phosphorescent screen. See how brilliantly the lines of
discharge shine out, and how intensely the focal point is
illuminated, lighting up the table.
Radiant Matter when intercepted by solid matter casts a
shadow.
Radiant Matter comes from the pole in straight lines, and
does not merely permeate all parts of the tube and fill it with
light, as would be the case were the exhaustion less good.
Where there is nothing in the way the rays strike the screen
and produce phosphorescence, and where solid matter inter-
venes they are obstructed by it, and a shadow is thrown on
16 On Radiant Matter.
the screen. In this pear-shaped bulb (Fig. 9) the nega-
tive pole (a) is at the pointed end. In the middle is a
FIG. g
cross (6) cut out of sheet aluminium, so that the rays
from the negative pole projected along the tube will be
partly intercepted by the aluminium cross, and will project
an image of it on the hemispherical end of the tube which
is phosphorescent. I turn on the coil, and you will all
see the black shadow of the cross on the luminous end of
the bulb (c, d). Now, the Radiant Matter from the nega-
tive pole has been passing by the side cf the aluminium
cross to produce the shadow; the glass has been ham-
mered and bombarded till it is appreciably warm, and at
the same time anothei effect has been produced on the
glass — its sensibility has been deadened. The glass has
got tired, if I may use the expression, by the enforced
phosphorescence. A change has been produced by this
molecular bombardment which will prevent the glass
from responding easily to additional excitement ; but the
part that the shadow has fallen on is not tired — it has not
been phosphorescing at all and is perfectly fresh ; therefore
if I throw down this cross, — I can easily do so by giving
the apparatus a slight jerk, for it has been most ingeniously
constructed with a hinge by Mr. Gimingham, — and so allow
the rays from the negative pole to fall uninterruptedly on to
the end of the bulb, you will suddenly see the black cross (c, d,
Fig. 10) change to a luminous one (e, /), because the back-
ground is now only capable of faintly phosphorescing, whilst
the part which had the black shadow on it retains its full
phosphorescent power. The stencilled image of the lu-
minous cross unfortunately soon dies out. After a period
On Radiant Matter. • 17
of rest the glass partly recovers its power of phosphor-
escing, but it is never so good as it was at first.
FIG. 10.
Here, therefore, is another important property of Radiant
Matter. It is projected with great velocity from the nega-
tive pole, and not only strikes the glass in such a way as to
cause it to vibrate and become temporarily luminous while
the discharge is going on, but the molecules hammer away
with sufficient energy to produce a permanent impression
upon the glass.
Radiant Matter exerts strong mechanical action where it
strikes.
We have seen, from the sharpness of the molecular sha-
dows, that Radiant Matter is arrested by solid matter placed
in its path. If this solid body is easily moved the impact of
the molecules will reveal itself in strong mechanical action.
Mr. Gimingham has constructed for me an ingenious piece
of apparatus which when placed in the electric lantern
will render this mechanical action visible to all present. It
consists of a highly-exhausted glass tube (Fig. n), having
FIG, IT.
a little glass railway running along it from one end to the
other. The axle of a small wheel revolves on the rails, the
c
i8 On Radiant Matter.
spokes of the wheel carrying wide mica paddles. At each
end of the tube, and rather above the centre, is an aluminium
pole, so that whichever pole is made negative the stream of
Radiant Matter darts from it along the tube, and striking
the upper vanes of the little paddle-wheel causes it to turn
round and travel along the railway. By reversing the poles
I can arrest the wheel and send it the reverse way, and if I
gently incline the tube the force of impact is observed to be
sufficient even to drive the wheel up-hill.
This experiment therefore shows that the molecular
stream from the negative pole is able to move any light
object in front of it.
The molecules being driven violently from the pole there
should be a recoil of the pole from the molecules, and by
arranging an apparatus so as to have the negative pole
movable and the body receiving the impact of the Radiant
Matter fixed, this recoil can be rendered sensible. In
appearance the apparatus (Fig. 12) is not unlike an ordinary
FIG. 12.
radiometer with aluminium disks for vanes, each disk coated
on one side with a film of mica. The fly is supported by
a hard steel instead of glass cup, and the needle point on
which it works is connected bv means of a wire with a
On Radiant Matter. 19
platinum terminal sealed into the glass. At the top of the
radiometer bulb a second terminal is sealed in. The radio-
meter therefore can be connected with an induction-coil, the
movable fly being made the negative pole.
For these mechanical effects the exhaustion need not be
so high as when phosphorescence is produced. The best
pressure for this electrical radiometer is a little beyond
that at which the dark space round the negative pole ex-
tends to the sides of the glass bulb. When the pressure
is only a few millims. of mercury, on passing the induc-
tion current a halo of velvety violet light forms on the
metallic side of the vanes, the mica side remaining dark.
As the pressure diminishes, a dark space is seen to
separate the violet halo from the metal. At a pressure
of half a millim. this dark space extends to the glass, and
rotation commences. On continuing the exhaustion
the dark space further widens out and appears to flatten
itself against the glass, when the rotation becomes very
rapid.
FIG. 1-5.
Here is another piece of apparatus (Fig. 13) which illusr
trates the mechanical force of the Radiant Matter from the
negative pole. A stem (a) carries a needle-point in which
c 2
2O On Radiant Matter.
revolves a light mica fly (6 b). The fly consists of four
square vanes of thin clear mica, supported on light
aluminium arms, and in the centre is a small glass
cap which rests on the needle-point. The vanes are in-
clined at an angle of 45° to the horizontal plane. Below
the fly is a ring of fine platinum wire (c c), the ends of which
pass through the glass at d d. An aluminium terminal (e) is
sealed in at the top of the tube, and the whole is exhausted
to a very high point.
By means of the electric lantern I project an image of
the vanes on the screen. Wires from the induction-coil are
attached, so that the platinum ring is made the negative
pole, the aluminium wire (e) being positive. Instantly,
owing to the projection of Radiant Matter from the plati-
num ring, the vanes rotate with extreme velocity. Thus
far the apparatus has shown nothing more than the pre-
vious experiments have prepared us to expect ; but observe
what now happens. I disconnect the induction-coil alto-
gether, and connect the two ends of the platinum wire with
a small galvanic battery ; this makes the ring c c red-hot, and
under this influence you see that the vanes spin as fast as
they did when the induction-coil was at work.
Here, then, is another most important fact. Radiant
Matter in these high vacua is not only excited by the nega-
tive pole of an induction-coil, but a hot wire will set it in
motion with force sufficient to drive round the sloping vanes.
Radiant Matter is deflected by a Magnet.
I now pass to another property of Radiant Matter.
This long glass tube (Fig. 14), is very highly exhausted ;
FIG. 14.
it has a negative pole at one end (a) and a long phosphor-
escent screen (b, c) down the centre of the tube. In
front of the negative pole is a plate of mica (b, d) with
On Radiant Matter. 21
a hole (e) in it, and the result is, when I turn on the cur-
rent, a line of phosphorescent light (e,f) is projected along the
whole length of the tube. I now place beneath the tube a
powerful horseshoe magnet : observe how the line of light
(2, g) becomes curved under the magnetic influence waving
about like a flexible wand as I move the magnet to and fro.
This action of the magnet is very curious, and if carefully
followed up will elucidate other properties of Radiant Matter.
Here (Fig. 15) is an exactly similar tube, but having at
FIG. 15.
one end a small potash tube, which if heated will slightly
injure the vacuum. I turn on the induction current, and
you see the ray of Radiant Matter tracing its trajectory in a
curved line along the screen, under the influence of the
horse-shoe magnet beneath. Observe the shape of the
curve. The molecules shot from the negative pole may be
likened to a discharge of iron bullets from a mitrailleuse,
and the magnet beneath will represent the earth curving
the trajectory of the shot by gravitation. Here on this
luminous screen you see the curved trajectory of the shot
accurately traced. Now suppose the deflecting force to
remain constant, the curve traced by the projectile varies
with the velocity. If I put more powder in the gun the
velocity will be greater and the trajectory flatter, and if I
interpose a denser resisting medium between the gun and
the target, I diminish the velocity of the shot, and thereby
cause it to move in a greater curve and come to the ground
sooner. I cannot well increase before you the velocity of
my stream of radiant molecules by putting more powder in
my battery, but I will try and make them suffer greater
resistance in their flight from one end of the tube to the
other. I heat the caustic potash with a spirit-lamp and so
22 On Radiant Matter.
throw in a trace more gas. Instantly the stream of Radiant
Matter responds. Its velocity is impeded, the magnetism
has longer time on which to act on the individual molecules,
the trajectory gets more and more curved, until, instead of
shooting nearly to the end of the tube, my molecular bullets
fall to the bottom before they have got more than half-way.
It is of great interest to ascertain whether the law
governing the magnetic deflection of the trajectory of
Radiant Matter is the same as has been found to
hold good at a lower vacuum. The experiments I have
just shown you were with a very high vacuum. Here
is a tube with a low vacuum (Fig. 16). When I turn on
FIG. 16.
the induction spark, it passes as a narrow line ot
violet light joining the two poles. Underneath I have
a powerful electro-magnet. I make contact with the
magnet, and the line of light dips in the centre towards
the magnet. I reverse the poles, and the line is driven
up to the top of the tube. Notice the difference be-
tween the two phenomena. Here the action is temporary.
The dip takes place under the magnetic influence ; the
line of discharge then rises and pursues its path to the
positive pole. In the high exhaustion, however, after the
stream of Radiant Matter had dipped to the magnet it
did not recover itself, but continued its path in the altered
direction.
By means of this little wheel, skilfully constructed by
Mr. Gimingham, I am able to show the magnetic deflection
in the electric lantern. The apparatus is shown in this dia-
gram (Fig. 17). The negative pole (a, b) is in the form of a
very shallow cup. In front of the cup is a mica screen (c, d),
wide enough to intercept the Radiant Matter coming from
the negative pole. Behind this screen is a mica wheel
(e, f) with a series of vanes, making a sort of paddle-wheel.
So arranged, the molecular rays from the pole a b will be
cut off from the wheel, and will not produce any movement.
On Radiant Matter. 23
I now put a magnet, #, over the tube, so as to deflect the
stream over or under the obstacle cd, and the result will be
FIG. 17.
rapid motion in one or the other direction, according to
the way the magnet is turned. I throw the image of
the apparatus on the screen. The spiral lines painted on
the wheel show which way it turns. I arrange the
magnet to draw the molecular stream so as to beat
against the upper vanes, and the wheel revolves rapidly
as if it were an over-shot water-wheel. I turn the
magnet so as to drive the Radiant Matter underneath ; the
wheel slackens speed, stops, and then begins to rotate the
other way, like an under-shot water-wheel. This can be
repeated as often as I reverse the position of the magnet.
I have mentioned that the molecules of the Radiant
Matter discharged from the negative pole are negatively
electrified. It is probable that their velocity is owing to
the mutual repulsion between the similarly electrified pole
and the molecules. In less high vacua, such as you saw a
few minutes ago (Fig. 16), the discharge passes from one
pole to another, carrying an electric current, as if it were
a flexible wire. Now it is of great interest to ascertain if
the stream of Radiant Matter from the negative pole also
carries a current. Here (Fig. 18) is an apparatus which will
decide the question at once. The tube contains two negative
terminals (a, b) close together at one end, and one positive
terminal (c) at the other. This enables me to send two
streams of Radiant Matter side by side along the phos-
24 On Radiant Matter.
phorescent screen, — or by disconnecting one negative pole,
only one stream.
FIG. 18.
If the streams of Radiant Matter carry an electric current
they will act like two parallel conducting wires and attract
one another ; but if they are simply built up of negatively
electrified molecules they will repel each other.
I will first connect the upper negative pole (a) with the
coil, and you see the ray shooting along the line d, f. I
now bring the lower negative pole (b) into play, and another
line (e, h) darts along the screen. But notice the way the
first line behaves; it jumps up from its first position, d f,
to dg, showing that it is repelled, and if time permitted I
could show you that the lower ray is also deflected from its
normal direction : therefore the two parallel streams of
Radiant Matter exert mutual repulsion, acting not like cur-
rent carriers, but merely as similarly electrified bodies.
Radiant Matter produces heat when its motion is arrested.
During these experiments another property of Radiant
Matter has made itself evident, although I have not
yet drawn attention to it The glass gets very warm
where the green phosphorescence is strongest. The
molecular focus on the tube, which we saw earlier in the
evening (Fig. 8) is intensely hot, and I have prepared an
apparatus by which this heat at the focus can be rendered
apparent to all present.
I have here a small tube (Fig. 19, a) with a cup-
shaped negative pole. This cup projects the rays to a
focus in the middle of the tube. At the side of the
tube is a small electro-magnet, which I can set in action
by touching a key, and the focus is then drawn to the
On Radiant Matter. 25
side of the glass tube (Fig. 19, b). To show the first
action of the heat I have coated the tube with wax.
FIG. 19.
I will put the apparatus in front of the electric lantern
(Fig. 20, d), and throw a magnified image of the tube on
the screen. The coil is now at work, and the focus of
molecular rays is projected along the tube. I turn the
magnetism on, and draw the focus to the side of the glass.
The first thing you see is a small circular patch melted in
the coating of wax. The glass soon begins to disintegrate,
and cracks are shooting starwise from the centre of heat.
The glass is softening. Now the atmospheric pressure forces
it in, and now it melts. A hole (e) is perforated in the
middle, the air rushes in, and the experiment is at an end.
I can render this focal heat more evident if I allow
it to play on a piece of metal. This bulb (Fig. 21) is
furnished with a negative pole in the form of a cup (a).
The rays will therefore be projected to a focus on a piece
of iridio-platinum (b) supported in the centre of the bulb.
I first turn on the induction-coil slightly, so as not to bring
out its full power. The focus is now playing on the metal,
raising it to a white-heat. I bring a small magnet near,
and you see I can deflect the focus of heat just as I
did the luminous focus in the other tube. By shifting
the magnet I can drive the focus up and down, or draw it
On Radiant Matter. 27
completely away from the metal, and leave it non-luminous.
I withdraw the magnet, and let the molecules have full
FIG 21.
play again ; the metal is now white-hot. I increase the
intensity of the spark. The iridio-platinum glows withal-
most insupportable brilliancy, and at last melts.
The Chemistry of Radiant Matter.
As might be expected, the chemical distinctions between
one kind of Radiant Matter and another at these high ex-
haustions are difficult to recognise. The physical pro-
perties I have been elucidating seem to be common to all
matter at this low density. Whether the gas originally
under experiment be hydrogen, carbonic acid, or atmospheric
air, the phenomena of phosphorescence, shadows, magnetic
deflection, &c., are identical, only they commence at
different pressures. Other facts however, show that at this
low density the molecules retain their chemical character-
istics. Thus by introducing into the tubes appropriate ab-
sorbents of residual gas, I can see that chemical attraction
goes on long after the attenuation has reached the best stage
28 On Radiant Matter.
for showing the phenomena now under illustration, and I am
able by this means to carry the exhaustion to much higher
degrees than I can get by mere pumping. Working with
aqueous vapour I can use phosphoric anhydride as an ab-
sorbent ; with carbonic acid, potash ; with hydrogen, palla-
dium ; and with oxygen, carbon, and then potash. The
highest vacuum I have yet succeeded in obtaining has been
the 1-20,000, oooth of an atmosphere, a degree which may
be better understood if I say that it corresponds to about
the hundredth of an inch in a barometric column three miles
high.
It may be objected that it is hardly consistent to attach
primary importance to the presence of Matter, when I
have taken extraordinary pains to remove as much Matter
as possible from these bulbs and these tubes, and have suc-
ceeded so far as to leave only about the one-millionth of an
atmosphere in them. At its ordinary pressure the atmo-
sphere is not very dense, and its recognition as a constituent
of the world of Matter is quite a modern notion. It would
seem that when divided by a million, so little Matter will
necessarily be left that we may justifiably neglect the trifling
residue and apply the term vacuum to space from which the
air has been so nearly removed. To do so, however, would be
a great error, attributable to our limited faculties being unable
to grasp high numbers. It is generally taken for granted
that when a number is divided by a million the quotient
must necessarily be small, whereas it may happen that
the original number is so large that its division by a
million seems to make little impression on it. According to
the best authorities, a bulb of the size of the one before
you (13*5 centimetres in diameter) contains more than
1,000000,000000,000000,000000 (a quadrillion) molecules.
Now, when exhausted to a millionth of an atmosphere we
shall still have a trillion molecules left in the bulb — a
number quite sufficient to justify me in speaking of the
residue as Matter.
To suggest some idea of this vast number I take the
exhausted bulb, and perforate it by a spark from the induc-
tion coil. The spark produces a hole of microscopical
fineness, yet sufficient to allow molecules to penetrate and
to destroy the vacuum. The inrush of air impinges against
the vanes and sets them rotating after the manner of a
windmill. Let us suppose the molecules to be of such a size
that at every second of time a hundred millions could enter,
On Radiant Matter. 29
How long, think you, would it take for this small vessel to
get full of air ? An hour ? A day ? A year ? A century ?
Nay, almost an eternity ! A time so enormous that ima-
gination itself cannot grasp the reality. Supposing this
exhausted glass bulb, indued with indestructibility, had
been pierced at the birth of the solar system ; supposing
it to have been present when the earth was without form
and void ; supposing it to have borne witness to all the
stupendous changes evolved during the full cycles of
geologic time, to have seen the first living creature appear,
and the last man disappear ; supposing it to survive until
the fulfilment of the mathematicians' prediction that the
Sun, the source of energy, four million centuries from
its formation will ultimately become a burnt-out cinder ;*
supposing all this, — at the rate of filling I have just
described, 100 million molecules a second — this little bulb
even then would scarcely have admitted its full quadrillion
of molecules.!
But what will you say if I tell you that all these molecules,
this quadrillion of molecules, will enter through the micro-
scopic hole before you leave this room ? The hole being
unaltered in size, the number of molecules undiminished,
this apparent paradox can only be explained by again sup-
posing the size of the molecules to be diminished almost
infinitely — so that instead of entering at the rate of
100 millions every second, they troop in at a rate of some-
thing like 300 trillions a second. I have done the sum,
but figures when they mount so high cease to have any
meaning, and such calculations are as futile as trying to
count the drops in the ocean.
In studying this Fourth state of Matter we seem at
length to have within our grasp and obedient to our control
* The possible duration of the Sun from formation to extinction has been
variously estimated by different authorities, at from 18 million years to
400 million years. For the purpose of this illustration I have taken the high-
est estimate.
f According to Mr. Johnstone Stoney (Phil. Mag., vol. 36. p. 141), i c.c. of
air contains about 1000,000000,000000,000000 molecules. Therefore a bulb
13-5 centims. diameter contains J-3'53 x 0^5236 x 1000,000000,000000,000000 or
1,288252 350000,000000,000000 molecules of air at the ordinary pressure.
Therefore the bulb when exhausted to the millionth of an atmosphere contains
1,288252,350000,000000 molecules, leaving 1,288251,061747,650000,000000
molecules to enter through the perforation. At the rate of 100,000000 mole-
cules a second, the time required for them all to enter will be
12882,510617,476500 seconds, or
214,708510,291275 minutes, or
3-578475»I7I521 hours, or
149103,132147 days, or
408 501731 years.
30 On Radiant Matter.
the little indivisible particles which with good warrant are
supposed to constitute the physical basis of the universe.
We have seen that in some of its properties Radiant Matter
is as material as this table, whilst in other properties it
almost assumes the character of Radiant Energy. We
have actually touched the border land where Matter and
Force seem to merge into one another, the shadowy realm
between Known and Unknown which for me has always had
peculiar temptations. I venture to think that the greatest
scientific problems of the future will find their solution in
this Border Land, and even beyond ; here, it seems to me,
lie Ultimate Realities, subtle, far-reaching, wonderful.
" Yet all these were, when no Man did them know,
Yet have from wisest Ages hidden beene ;
And later Times thinges more unknowne shall show.
Why then should witlesse Man so much misweene,
That nothing is, but that which he hath seene ?"
London: Printed by H. J. DAVty.Boy Court, Ludgat: Hill, E.G.
14 DAY USE
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^ 2 1967 55
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