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better than that to propose.”

      “What?” asked the major.

      “Aluminium,” answered Barbicane.

      “Aluminium!” cried all the three colleagues of the president.

      “Certainly, my friends. You know that an illustrious French chemist, Henry St. Claire Deville, succeeded in 1854 in obtaining aluminium in a compact mass. This precious metal possesses the whiteness of silver, the indestructibility of gold, the tenacity of iron, the fusibility of copper, the lightness of glass; it is easily wrought, and is very widely distributed in nature, as aluminium forms the basis of most rocks; it is three times lighter than iron, and seems to have been created expressly to furnish us with the material for our projectile!”

      “Hurrah for aluminium!” cried the secretary, always very noisy in his moments of enthusiasm.

      “But, my dear president,” said the major, “is not aluminium quoted exceedingly high?”

      “It was so,” answered Barbicane; “when first discovered a pound of aluminium cost 260 to 280 dollars; then it fell to twenty-seven dollars, and now it is worth nine dollars.”

      “But nine dollars a pound,” replied the major, who did not easily give in; “that is still an enormous price.”

      “Doubtless, my dear major; but not out of reach.”

      “What will the projectile weigh, then?” asked Morgan.

      “Here is the result of my calculations,” answered Barbicane. “A projectile of 108 inches in diameter and 12 inches thick would weigh, if it were made of cast-iron, 67,440 lbs.; cast in aluminium it would be reduced to 19,250 lbs.”

      “Perfect!” cried Maston; “that suits our programme capitally.”

      “Yes,” replied the major; “but do you not know that at nine dollars a pound the projectile would cost—”

      “One hundred seventy-three thousand and fifty dollars. Yes, I know that; but fear nothing, my friends; money for our enterprise will not be wanting, I answer for that.”

      “It will be showered upon us,” replied J.T. Maston.

      “Well, what do you say to aluminium?” asked the president.

      “Adopted,” answered the three members of the committee.

      “As to the form of the projectile,” resumed Barbicane, “it is of little consequence, since, once the atmosphere cleared, it will find itself in empty space; I therefore propose a round ball, which will turn on itself, if it so pleases.”

      Thus ended the first committee meeting. The question of the projectile was definitely resolved upon, and J.T. Maston was delighted with the idea of sending an aluminium bullet to the Selenites, “as it will give them no end of an idea of the inhabitants of the earth!”

      HISTORY OF THE CANNON.

      Table of Contents

      The resolutions passed at this meeting produced a great effect outside. Some timid people grew alarmed at the idea of a projectile weighing 20,000 lbs. hurled into space. People asked what cannon could ever transmit an initial speed sufficient for such a mass. The report of the second meeting was destined to answer these questions victoriously.

      The next evening the four members of the Gun Club sat down before fresh mountains of sandwiches and a veritable ocean of tea. The debate then began.

      “My dear colleagues,” said Barbicane, “we are going to occupy ourselves with the construction of the engine, its length, form, composition, and weight. It is probable that we shall have to give it gigantic dimensions, but, however great our difficulties might be, our industrial genius will easily overcome them. Will you please listen to me and spare objections for the present? I do not fear them.”

      An approving murmur greeted this declaration.

      “We must not forget,” resumed Barbicane, “to what point our yesterday’s debate brought us; the problem is now the following: how to give an initial speed of 12,000 yards a second to a shot 108 inches in diameter weighing 20,000 lbs.

      “That is the problem indeed,” answered Major Elphinstone.

      “When a projectile is hurled into space,” resumed Barbicane, “what happens? It is acted upon by three independent forces, the resistance of the medium, the attraction of the earth, and the force of impulsion with which it is animated. Let us examine these three forces. The resistance of the medium—that is to say, the resistance of the air—is of little importance. In fact, the terrestrial atmosphere is only forty miles deep. With a rapidity of 12,000 yards the projectile will cross that in five seconds, and this time will be short enough to make the resistance of the medium insignificant. Let us now pass to the attraction of the earth—that is to say, to the weight of the projectile. We know that that weight diminishes in an inverse ratio to the square of distances—in fact, this is what physics teach us: when a body left to itself falls on the surface of the earth, it falls 15 feet in the first second, and if the same body had to fall 257,542 miles—that is to say, the distance between the earth and the moon—its fall would be reduced to half a line in the first second. That is almost equivalent to immobility. The question is, therefore, how progressively to overcome this law of gravitation. How shall we do it? By the force of impulsion?”

      “That is the difficulty,” answered the major.

      “That is it indeed,” replied the president. “But we shall triumph over it, for this force of impulsion we want depends on the length of the engine and the quantity of powder employed, the one only being limited by the resistance of the other. Let us occupy ourselves, therefore, to-day with the dimensions to be given to the cannon. It is quite understood that we can make it, as large as we like, seeing it will not have to be moved.”

      “All that is evident,” replied the general.

      “Until now,” said Barbicane, “the longest cannon, our enormous Columbiads, have not been more than twenty-five feet long; we shall therefore astonish many people by the dimensions we shall have to adopt.”

      “Certainly,” exclaimed J.T. Maston. “For my part, I ask for a cannon half a mile long at least!”

      “Half a mile!” cried the major and the general.

      “Yes, half a mile, and that will be half too short.”

      “Come, Maston,” answered Morgan, “you exaggerate.”

      “No, I do not,” said the irate secretary; “and I really do not know why you tax me with exaggeration.”

      “Because you go too far.”

      “You must know, sir,” answered J.T. Maston, looking dignified, “that an artilleryman is like a cannonball, he can never go too far.”

      The debate was getting personal, but the president interfered.

      “Be calm, my friends, and let us reason it out. We evidently want a gun of great range, as the length of the engine will increase the detention of gas accumulated behind the projectile, but it is useless to overstep certain limits.”

      “Perfectly,” said the major.

      “What are the usual rules in such a case? Ordinarily the length of a cannon is twenty or twenty-five times the diameter of the projectile, and it weighs 235 to 240 times its weight.”

      “It is not enough,” cried J.T. Maston with impetuosity.

      “I agree to that, my worthy friend, and in fact by keeping that proportion for a projectile nine feet wide, weighing 30,000 lbs., the engine would only have a length of 225 feet and a weight of 7,200,000 lbs.”

      “That

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