<h2>CHAPTER XXIV.</h2>
<h3>WHY DOES ICE FLOAT?</h3>
<p>Nature is full of surprises. By a long series of experimental
investigations you think you have established a law that is as
unalterable as those of the Medes and Persians. But once in a while you
stumble upon phenomena that seem to contradict all that has gone before.</p>
<p>These, however, may be only the exceptions that prove the rule. It is
recognized as a fundamental law that heat expands and cold contracts;
that the atom when in a state of intense motion (which is the condition
producing the effect that we call "heat") requires more room than when
its motions are of a less amplitude. In other words, an increase in the
amplitude of atomic motion is heating, while a decrease is cooling. It
follows from the above statement that the colder a body becomes the
smaller will be its dimensions. There are two or three, and perhaps
more, exceptions to this rule, and the most notable one is that of
water. Water follows the same law that all other substances do under the
action<span class="pagenum"><SPAN name="Page_193" id="Page_193"></SPAN></span> of heat and cold, within certain limits only. If we take water,
say, at 50 degrees Fahrenheit and subject it to cold it will gradually
contract in bulk until it reaches 39 degrees Fahrenheit. At this point,
very curiously, contraction ceases, and here we find the maximum density
of water. If the temperature is still lowered we find the bulk is
gradually increasing instead of diminishing (as is the rule with other
fluids), and when it reaches the freezing point there is a sudden and
marked expansion, so much so that a cubic foot of ice, which is
solidified water, will not weigh as much as a cubic foot of water before
it freezes—hence it floats.</p>
<p>Let us try an experiment. Take a small glass flask, terminating in a
long neck, say of four to six inches, and of small diameter. Suppose the
water in the glass to be at 50 degrees Fahrenheit. Fill the flask with
water until it stands halfway up the neck at 50 degrees temperature. Now
immerse the flask gradually in hot water, and observe the effect. For a
moment the water will lower in the neck of the tube, but this is due to
the fact that the glass expands before the heat is communicated to the
water and enlarges its capacity. But immediately the water will begin to
rise as the heat is communicated to it, and will continue to expand up
to the boiling point. Now take the flask out of the hot<span class="pagenum"><SPAN name="Page_194" id="Page_194"></SPAN></span> water and
gradually introduce it into a freezing mixture made of broken ice and
salt. Immediately the water will begin to fall in the tube, showing that
it is contracting under the cold, and it will continue to contract until
it reaches a temperature of 39 degrees Fahrenheit, when it will come to
a standstill and then proceed to expand as the temperature of the water
lowers. When it reaches the freezing point the fluid can no longer rise
in the neck of the flask, which is broken by the sudden expansion that
takes place at this point.</p>
<p>To show what an irresistible power resides in the atoms of which the
body is made, let us take an iron flask with walls one-half inch or more
in thickness; fill it with water and seal it up by screwing on the neck
an iron cap; now plunge it into the freezing mixture, and the first
effect will be to contract the water unless it is already below 39
degrees Fahrenheit, but when it reaches that point expansion sets in,
which continues to the freezing point, when a greatly increased
expansion takes place suddenly. The walls of the iron flask, although a
half-inch in thickness, are no longer able to resist the combined
efforts of the billions upon billions of the atoms of which the water is
made up, in their individual clamor for more room, hence the flask is
shivered into pieces.</p>
<p>There are one or two other substances which are exceptions to the
general rule, but we will<span class="pagenum"><SPAN name="Page_195" id="Page_195"></SPAN></span> mention only one, which is the metal bismuth.
If we should melt a sufficient amount to fill an iron flask, such as we
have described, and subject it to the same freezing process, the flask
will be broken the same as in the experiment made with the water.</p>
<p>A query arises, Why this phenomenon? Why does water follow a different
law in cooling from that of nearly all other substances?</p>
<p>This is a case where it is much easier to ask a question than to answer
it. When water solidifies at the moment of freezing, crystallization
sets in. But what is crystallization? Crystallization is a peculiar
arrangement of the molecules of matter, which takes place in some
substances when they pass from the liquid to the solid form. The
molecules assume definite forms and shapes, according to the nature of
the substance. When water assumes the solid form under the action of
cold the molecules arrange themselves according to certain definite and
fixed laws, the result of which is to increase the bulk to a
considerable extent over that which the same number of molecules would
occupy at a temperature of 39 degrees Fahrenheit. Hence, as has been
heretofore stated, a given block of solidified water is lighter than the
same bulk would be in the fluid state, and this is the reason why ice
floats.<span class="pagenum"><SPAN name="Page_196" id="Page_196"></SPAN></span></p>
<p>What would happen in case nature did not make this exception to the laws
of expansion and contraction by heat and cold, in the case of water?
First, our lakes would freeze from the bottom upward; as soon as the
surface became frozen, or even colder than the water underneath, it
would drop to the bottom, the warmer water below coming up by a
well-known law—that the warmer fluid rises and the colder falls. This
circulation would continue until ice began to form, which would
immediately drop to the bottom, and this process would go on until the
whole mass were frozen solid. In the same way our rivers in the northern
climates would freeze from the bottom, and in time our valleys would
fill up with ice to a thickness that the summer's sun would never melt,
and gradually all north of a certain zone would become a great glacier,
rendering not only the lakes and rivers but also the surface of the
earth unfitted for animal life.</p>
<p>Those who believe that the laws of nature are the creations of a
beneficent and all-wise Intelligence will see in this exception to the
general law in the case of freezing water a striking evidence of design.
But those who have no such belief will say it is a most fortunate though
fortuitous circumstance (a saying they will have to make, regarding
thousands of other things in nature), and go on<span class="pagenum"><SPAN name="Page_197" id="Page_197"></SPAN></span> floundering in the
interminable sea of "I don't know."</p>
<p>The atom when it is acting under the direction of a fixed law is a giant
in strength. And when its individual strength is multiplied by billions
upon billions the combined energy exerted produces a power that is
irresistible. Not only has nature endowed these atoms with this
wonderful power, but she has also willed that they arrange themselves in
lines of beauty. In confirmation of this we need only to study the work
of the frost upon our window panes. As we lie in our beds on a cold
night and exhale moisture from our lungs it settles upon the window
panes of our bedrooms, where Nature—that wonderful artist—forms it
into beautiful pictures that gladden our eyes when we awake:</p>
<div class="poem"><div class="stanza">
<span class="i0">Most beautiful things; there are flowers and trees,<br/></span>
<span class="i0">And bevies of birds, and swarms of bees,<br/></span>
<span class="i0">And cities, and temples, and towers, and these<br/></span>
<span class="i0">All pictured in silver sheen.<br/></span>
<span class="pagenum"><SPAN name="Page_198" id="Page_198"></SPAN></span></div>
</div>
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