Wings of Madness: Alberto Santos-Dumont and the Invention of Flight. Paul Hoffman

Читать онлайн книгу.

Wings of Madness: Alberto Santos-Dumont and the Invention of Flight - Paul  Hoffman


Скачать книгу
equivalent volume of water. But the analogy between ship and balloon worked only if one accepted the idea that the atmosphere weighed something, and that was not known until Galileo’s time, when Evangelista Torricelli, the inventor of the barometer, demonstrated that the atmosphere had a measurable weight that decreased with elevation. Another seventeenth-century investigator, Otto von Guericke in Magdeburg, Germany, invented a vacuum pump for creating the “rarefied air” found at very high elevations. In 1670, Francesco de Lana-Terzi, an Italian Jesuit priest, conceived of a man-carrying vessel supported by four huge hollow-copper spheres devoid of air. Because the evacuated spheres would be lighter than the air they displaced, he expected the vessel to rise through the atmosphere like an air bubble ascending through water. The mathematically sophisticated priest calculated that the spheres had to be twenty-five feet in diameter and 1/225 of an inch in thickness. When his physicist friends warned him that spheres this thin would collapse when the air was withdrawn from them, he responded—according to engineering historian L. T. C. Rolt—“that his was only a theoretical exercise, arguing that since God had not intended man to fly, any serious practical attempt to flout His designs must be impious and fraught with peril for the human race. One suspects that the Jesuit fathers may have had a serious talk with their scientifically minded son and that he made this disclaimer because he could smell faggots burning.”

      But other clerics continued the armchair exercise. In 1755, Joseph Galien, a Dominican friar and theologian at the papal university in Avignon, proposed collecting rarefied air from the upper reaches of the atmosphere and enclosing it in a mile-long vessel that would be capable of lifting fifty-four times the weight carried by Noah’s ark. Galien never explained how he planned to reach the upper atmosphere in the first place, and his supervisor at the divinity school implored him to take a long respite from clerical duties and, on his return, to restrict his speculation to theology not technology.

      Such chimerical schemes for ballooning were abandoned once the Montgolfiers showed how little there really was to it. On June 5, 1783, the two brothers demonstrated a thirty-foot-diameter unmanned balloon in the public square in Annonay. It required eight men to hold down the twenty-thousand-cubic-foot balloon, whose envelope consisted of pieces of silk lined with paper fastened together by buttons and buttonholes. When the Montgolfiers gave the signal, the men released the giant gasbag and it climbed six thousand feet. After ten minutes, it came down in a field a mile and a half away.

      News of the accomplishment reached the Paris Academy of Sciences, whose members had been actively experimenting with the construction of a lighter-than-air balloon but had so far failed to get anything off the ground. The Parisian scientists, not wanting to be upstaged by unschooled papermakers, accelerated their efforts. The physicist-engineer Jacques Alexandre César Charles, assisted by two craftsmen, the brothers Ainé and Cadet Robert, substituted hydrogen gas for the burning-straw fumes, and on August 23, 1783, in the place des Victoires began inflating a twelve-foot-diameter silk balloon. The hydrogen was obtained by pouring five hundred pounds of sulfuric acid over one thousand pounds of iron filings. Charles had not counted on the chemical reaction to produce as much heat as it did, and the balloon fabric had to be repeatedly doused with cold water to keep it from singeing. The water vapor trapped in the balloon condensed and weighed it down.

      The inflation took three days, and, as word spread of the spectacle, a crowd gathered, choking the neighboring streets. To ease the congestion, Charles ordered the balloon moved in the stealth of night, escorted by armed guards, to the more expansive Champ de Mars, at the foot of what is now the Eiffel Tower. Barthélemy Faujas de Saint-Fond witnessed the move:

      No more wonderful scene could be imagined than the Balloon being thus conveyed, preceded by lighted torches, surrounded by a “cortege” and escorted by a detachment of foot and horse guards; the nocturnal march, the form and capacity of the body, carried with so much precaution; the silence that reigned, the unseasonable hour, all tended to give a singularity and mystery truly imposing to all those who were acquainted with the cause. The cab-drivers on the road were so astonished that they were impelled to stop their carriages, and to kneel humbly, hat in hand, whilst the procession was passing.

      At 5:00 P.M. on August 27, Charles’s assistants triumphantly released the balloon and it rose rapidly to a height of three thousand feet. After forty-five minutes, it descended in a field in the village of Gonesse, fifteen miles from Paris.

      Unlike the hot-air balloon, which could have been made at any time in recorded history, the hydrogen balloon could not have been invented much earlier than it was because the gas, initially called phlogiston, or “inflammable air,” was discovered only in 1766, by the English scientist Henry Cavendish. On learning that “inflammable air” was nine times lighter than ordinary air, Joseph Black in Edinburgh filled a small, thin bag with the new gas and watched it rise to the ceiling of his laboratory. He had difficulty, though, in scaling up the experiment. The problem was that the materials he tried for bags were either too heavy or too porous. At a large public lecture, he used the allantois of a calf as the gasbag, but was humiliated by its failure to ascend and gave up ballooning entirely. In 1782, Tiberius Cavallo, a fellow of London’s Royal Society, “found that bladders, even when carefully scraped, are too heavy, and that China paper is permeable to the gas.” Charles succeeded because he had the idea of making the silk impermeable but still lightweight by varnishing it with a solution of elastic gum.

      The Montgolfiers made the next move in the race to advance aerostation. On September 19, 1783, they repeated the Annonay experiment at Versailles for the benefit of Louis XVI, Marie Antoinette, and their court. According to one observer, the papermakers “had caused all the old shoes that could be collected to be brought here, and threw them into the damp straw that was burning, together with pieces of decomposed meat; for these are the substances which supply their gas. The King and the Queen came up to examine the machine, but the noxious smell thus produced obliged them to retreat at once.” French scientists found the demonstration particularly insulting because the two brothers had beaten them to the balloon’s invention while harboring incorrect notions about the cause of the ascension. The Montgolfiers attributed the “lifting power” to the lighter-than-air smoke generated from their patented combination of fetid meat and dirty shoes. In fact, the smoke particles were heavier than air and actually worked to counteract the balloon’s rise. The lift came not from the imprisoned smoke but the captured hot air, which was lighter than the cooler ambient air. Most of the observers did not care why the spectacular blue-and-gold balloon was aloft—they just marveled at the fact that it was. And the world’s first aerial travelers, a sheep, a rooster, and a duck, were suspended in a cage below the balloon. The animals emerged unscathed from their two-mile trip to the forest of Vaucresson, except for the rooster, whose right wing had suffered a nasty kick from the sheep.

      Charles and the Montgolfiers independently told the king that on the next ascension they themselves would be the passengers, but his majesty forbade such valuable subjects from risking their lives. Instead he offered prisoners as the first pilots, proposing to set them free if they survived. But Charles ultimately convinced him that the first person aloft should be a man of science who could describe the voyage if he were fortunate enough to make it back. The honor went to Francis Pilâtre de Rozier, a distinguished member of the Academy of Sciences who was the superintendent of the king’s natural-history collection. On October 15, 1783, he ascended in a captive balloon (one tethered to the ground), the hot air replenished by the burning of straw and wood in an iron basket hung below the balloon. Having found it easy to stoke the fire when he was in the air, Pilâtre de Rozier and a companion, the Marquis d’Arlandes, went up in a free balloon for the first time on November 21. Ascending from the Bois de Boulogne at 1:54 P.M., they reached an elevation of five hundred to one thousand feet and, after twenty-five minutes, descended beyond the Paris city limits, some nine thousand yards from where they had started. Ten days later, Charles and Ainé Robert had the honor of being the first people to ascend in a hydrogen balloon, in a two-hour journey that began in the Tuileries and ended twenty-seven miles away in the town of Nesle.

      Within a few months of Charles’s trip, the skies of Paris were


Скачать книгу