Chasing the Moon Read online

  In 1903 Tsiolkovsky published a scientific paper that contained the first appearance of what came to be known as the “rocket equation,” a mathematical formula comparing a rocket’s mass ratio to its velocity, the essential calculation necessary to determine how to escape a planet’s gravity. Unfortunately, the importance of his publication went unnoticed; the Russian scientific community ignored his work, dismissing it as the musings of an amateur. His paper would remain unread for another twenty years. Undaunted, Tsiolkovsky continued his studies, going on to publish nearly four hundred scientific papers on such matters as space-vehicle weightlessness, the operation of multi-staged launch vehicles, the orbital dynamics of differing rocket burns, and the scientific advantages of polar orbits.

  A full decade after Tsiolkovsky’s groundbreaking paper, in 1913, a French aircraft designer named Robert Esnault-Pelterie independently published his own version of the rocket equation. But once again few took notice. In the United States, Robert Goddard, the second of the three pioneers of rocketry and a part-time instructor and research fellow at Clark University in Worcester, Massachusetts, was quietly conducting his own rocket research. Entirely unaware of Tsiolkovsky or Esnault-Pelterie, he submitted patent applications for both a liquid-fueled rocket and a multi-stage vehicle.

  Clark University professor Robert Goddard, who in 1926 launched the world’s first liquid-fueled rocket from a farm in Auburn, Massachusetts. Throughout most of his career he revealed few details about the progress of his research. However, spies in the United States working at the behest of the Soviet Union and Hitler’s Germany attempted to breach Goddard’s wall of secrecy.

  Like Tsiolkovsky, Goddard had also experienced social isolation during his formative years. A frail only child, he was kept out of school for extended periods due to ill health. As a result, he didn’t graduate from high school until age twenty-one. During his solitary time at home he read stacks of books from the local library, particularly volumes from the science and technology shelves. He also read H. G. Wells’s science-fiction classic The War of the Worlds, which made a lasting impression. At age seventeen in 1899, while aloft in the branches of a cherry tree on his family’s New England farm, Goddard experienced an epiphany that moved him so deeply that he noted the date on which it occurred. “As I looked towards the fields at the east, I imagined how wonderful it would be to make some device which had even the possibility of ascending to Mars. I was a different boy when I descended the tree from when I ascended for existence at last seemed very purposive.”

  During World War I, while teaching at Clark University, Goddard obtained research funding from the War Department for an experimental tube-launched solid-fuel rocket rifle, an early version of what would become the bazooka. He also proposed a rocket that could ascend seventy miles into the atmosphere and carry high explosives or poison gas at least two hundred miles. But after the Armistice, no American military officials thought long-range missiles a subject worthy of further research, so Goddard sought to find support elsewhere.

  It was a technical paper funded and published by the Smithsonian Institution in 1920 that suddenly placed Goddard’s name on newspaper front pages around the world. “A Method of Reaching Extreme Altitudes” proposed that a rocket could be used for the scientific exploration of the atmosphere, placing artificial satellites into orbit, aiding weather forecasting, and physically hitting the Moon. His paper made no mention of human space travel to the Moon; however, many newspaper reports heralded his study with dramatic headlines implying Goddard was working on a moon rocket that would transport human passengers.

  Within weeks, The New York Times announced that a twenty-four-year-old pilot of the New York City Air Police had willingly volunteered to be the first person to fly to Mars. Concerned that the United States must maintain its position with other nations in the air, Captain Claude Collins said he would ride the world’s first interplanetary rocket, provided a ten-thousand-dollar life-insurance policy was part of the arrangement. The Times treated Goddard somewhat less admiringly than it did Captain Collins when it published a scathing editorial taking the college professor to task for believing that a rocket would function in the vacuum of space. The Times slammed Goddard, claiming he was unfamiliar with basic Newtonian physics and showed a “lack of knowledge ladled out daily in high schools.” His pride wounded, Goddard soon grew wary of the popular press. Sensational stories about the American professor’s forthcoming moon-rocket flight continued to appear in publications around the globe throughout the early 1920s. And occasionally Goddard was complicit, supplying dramatic quotations apparently intended to entice potential investors, such as his plan for a giant passenger rocket capable of crossing the Atlantic Ocean in a few minutes.

  However, when Goddard actually made history with the world’s first successful launch of a liquid-fueled rocket on March 16, 1926, in Auburn, Massachusetts, no journalists were present, and no account appeared in contemporary newspapers. The date is now celebrated as the dawn of the space age, but for most of his career Goddard carefully guarded information about his research, afraid that others might steal his secrets and profit from his work.

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  Hermann Oberth photographed in his workshop while assisting on the production of the German science-fiction feature film Woman in the Moon. When he was ten years old, the telephone and the automobile first appeared in his rural hometown. In his later years he witnessed the launches of Apollo 11 and the space shuttle Challenger.

  THE SENSATIONAL ATTENTION accorded Goddard’s Smithsonian paper appeared in the European press just as the third of the trio of rocketry pioneers, a former medical student from Austro-Hungaria named Hermann Oberth, was readying his work for academic review. Born in 1894, Oberth was a brilliant student of mathematics and had been fascinated by the idea of spaceflight since age twelve, when he committed to memory passages from Jules Verne’s From the Earth to the Moon. Oberth had tried to interest military strategists in a proposal for long-range missiles during the First World War, but his paper went unread. After the war he revised his work, this time focusing on the basic mathematics underlying space travel. However, when he submitted the paper as his doctoral dissertation, it was rejected as “too fantastic.”

  Undeterred, Oberth obstinately continued to pursue his studies independently, dismissing his instructors as unworthy to judge his work. For this gifted mathematician, formulating the necessary calculations for space travel was a diverting intellectual exercise that gave him a sense of ownership and agency. “This was nothing but a hobby for me,” he said, “like catching butterflies or collecting stamps for other people, with the only difference that I was engaged in rocket development.”

  He asked himself a series of questions that would need to be answered if humans were to enter outer space: Which propellant should be used—liquid or solid? Is interplanetary travel possible? Can humans adapt to weightlessness? How might humans nourish themselves in space? Can humans wearing space suits venture outside vehicles? In contrast to Goddard’s more cautious approach, Oberth embraced the unknown by posing imaginative questions prompted by his reading of science fiction. He then devised practical solutions founded on his mathematical and engineering expertise.

  In 1923 he published a short technical version of his dissertation, Die Rakete zu den Planetenräumen (The Rocket into Interplanetary Space), personally paying the expense of the book’s entire printing. Fortunately, his vanity-publishing project was a wise decision. By issuing the book in German, which in the early twentieth century was the dominant language of the scientific community, Oberth established himself as the world’s leading theorist of human spaceflight, overshadowing the more reclusive Goddard. When he read the German monograph, Goddard believed Oberth had borrowed his ideas without proper attribution, though there is little evidence to support his suspicions.

  The Rocket into Interplanetary Space appeared at a mo
ment when many Germans were hungry for something bold, dynamic, and modern to restore the nation’s pride, following the defeat in World War I. The 1920s were a time of experimentation in art, film, and architecture and the arrival of new consumer technologies like radio, air travel, and neon lighting. The speed, power, and streamlined design of rockets became associated with a future of exciting possibilites. Less than four years after the publication of Oberth’s book, the Verein für Raumschiffahrt—or Society for Space Travel—was formed in Germany, and it soon became the world’s leading rocketry organization. It published a journal, held conferences, and conducted research experiments. But the stunts of Max Valier, one of the society’s founders, were what drew the greatest media attention: He strapped himself into a rocket-powered car and hurtled down a racetrack, trailing a cloud of smoke and flame. Such daredevil exploits proved to be an effective way of generating publicity but did little to boost the society’s scientific reputation.

  Not long after the society’s founding, the noted Austrian-German filmmaker Fritz Lang approached it for technical assistance in connection with his forthcoming science-fiction space epic, Frau im Mond (Woman in the Moon), a follow-up to his international hit Metropolis. Lang hired Oberth, the society’s figurehead president, to be the film’s technical adviser. The film’s studio also engaged Oberth to build a functioning liquid-fuel rocket to promote the movie’s premiere, a project that, despite providing the society needed research-and-development money, was unsuccessful.

  Albert Einstein and other scientists were among the celebrities who attended the film’s opening, but the only rocket to be seen that night was the one that appeared on the screen, created by the studio’s special-effects department. Although Frau im Mond wasn’t a critical hit, it was historically important for introducing the world’s first rocket countdown. Fritz Lang created it as a dramatic device to instill suspense in the final moments before the blastoff. It was such an effective way to focus attention and convey the sequence of procedures prior to liftoff that rocket engineers around the world immediately adopted it.

  Meanwhile, in the Soviet Union, reports of Goddard’s moon rocket and Oberth’s scientific monograph prompted Russian space enthusiasts to stake their country’s claim by recognizing that Konstantin Tsiolkovsky had been the first to mathematically publish the rocket equation. Tsiolkovsky was in his mid-sixties when he received his vindication, and it coincided with a brief and bizarre moment of space-travel mania. After the First World War, revolution, and a civil war, Russia was in the throes of change, as audacious and provocative new ideas permeated the culture; among them was a renewed interest in utopian Russian cosmism, and a desire to explore new worlds. One of Tsiolkovsky’s leading Soviet advocates rallied followers with the slogan “Forward to Mars!”

  In 1924, Russian magazines and newspapers reported that Goddard was about to shoot his rocket to the Moon or, in fact, may have already done so. Many Russian readers assumed that colonizing the planets was imminent. At space-advocacy lectures and public programs—including one with a crowd so keyed up that a riot nearly took place—curious attendees demanded to know when flights to the Moon and planets would commence and where to volunteer to be among the first settlers. But after learning that trips to the planets were at least a few decades away, the crowd dispersed in disappointment. In Moscow, an international space exhibition attracted twelve thousand visitors, and a Russian Society for Studies of Interplanetary Travel was founded. But Stalin’s rise to power and the beginning of the Five-Year Plan brought an end to Russia’s short experimental post-revolutionary sojourn. Despite his new fame at home, Tsiolkovsky received little recognition abroad.

  Goddard’s reticence for publicity may partly account for the reason that, unlike in Germany and the Soviet Union, no comparable rocketry fad occurred in 1920s America. Instead, a different and more long-lasting phenomenon, which proved influential for the emergence of the space age, arose in the United States: the publication of the first popular science-fiction magazines. In 1926, Hugo Gernsback, an immigrant who had built a business issuing cheaply printed magazines about electronics and radio, introduced Amazing Stories, a specialty-fiction publication for which he coined the term “scientifiction.” Not long after, Gernsback hired a young technical writer named David Lasser to serve as the editor of a new publication, Science Wonder Stories. Lasser, the son of Russian immigrant parents, had enlisted in the Army and experienced combat during the First World War by the age of sixteen. Following months of hospitalization due to the injuries he sustained in a poison-gas attack, Lasser used a disabled-veterans scholarship to attend and graduate from the Massachusetts Institute of Technology. Avid readers noticed that, shortly after Lasser’s name appeared on the masthead of the Gernsback magazines, their literary quality improved significantly.

  Lasser had become intrigued by press accounts about Goddard, Oberth, and Germany’s Verein für Raumschiffahrt, and in April 1930 he and fellow New York science-fiction writers and editors formed the American Interplanetary Society. Much like the Verein für Raumschiffahrt, its American counterpart aimed to stimulate awareness, enthusiasm, and advocate for private funding of rocket research—while also expanding the readership for Gernsback’s magazines. Goddard informed Lasser that he approved of the American Interplanetary Society’s mission but abstained from becoming a member. The Clark University professor apparently feared that if it were known he associated with science-fiction enthusiasts, research grant donors might question his judgment and reluctantly withdraw their support.

  In one of his first roles as the president of the American Interplanetary Society, Lasser presided over a special event held at New York’s American Museum of Natural History: a lecture about space travel, featuring one of the first American screenings of Fritz Lang’s Frau im Mond. Though a modest-sized audience had been expected, nearly two thousand curious New Yorkers converged on the museum. The only way to accommodate the sizable audience was to add a second screening later that evening.

  David Lasser had concluded that there was a need for a book written for curious readers that explained in realistic, accurate, but understandable scientific terms the fundamentals of rocket science, why constructing an operational vehicle should be attempted, and what piloted space travel would mean to humanity. Lasser believed that once humans departed their home planet, a philosophical and political shift would occur throughout the world as people began to perceive the Earth as a small, fragile, isolated sphere in the emptiness of space. This change in thought, he concluded, would lead to the erosion of the dangerous nationalistic and tribal divisions that had brought about the recent carnage of the First World War. He wanted his book to provide the fundamental scientific concepts while forgoing the higher mathematics that might intimidate some readers.

  Researching the book, Lasser gathered recently published technical papers from leading scientific journals and corresponded with rocketry activists around the world. He wrote it during the immediate aftermath of the Wall Street Crash, a time when he and many other Americans hoped for a better future. Lasser’s optimism colors his imaginary account of the moment when news from the first lunar space travelers is received on Earth: “We learn that wild excitement prevails all over the globe….We cannot but feel now that this journey has served its purpose in the breaking down of racial jealousies.” Elsewhere he writes that space travel will result in a new planetary outlook, the realization that “the whole Earth is our home.”

  Unfortunately, the early years of the Great Depression were not a good time to publish such a book. Lasser and members of the American Interplanetary Society financed the publication of The Conquest of Space, but sales were modest. The British rights were sold to a small but venerable publisher, which issued a few thousand copies. Serendipitously, one crucial copy found its way into the hands of teenage Arthur C. Clarke after being displayed in the bookshop window in southwest England.

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  WHEN HE READ Lasser’s book, Archie Clarke was already familiar with the world of American science-fiction magazines. Unsold copies returned from newsstands and drugstores were used as ballast in the holds of the great transatlantic liners sailing between New York and Great Britain. Once they arrived in England, the magazines were sold in shops for a few pence each, including the Woolworth’s store across the street from Archie’s grammar school, where he often searched through piles of American detective, Western, and romance pulps for the newest science-fiction issues. He soon amassed a substantial collection and compiled a catalog of his reading, scoring stories with a grade ranging from F (fair) to VVG (very, very good).

  But when he read The Conquest of Space he realized for the first time that “space travel was not merely fiction. One day it could really happen.” Shortly before reading Lasser’s book, Archie had been fascinated by Olaf Stapledon’s Last and First Men, an ambitious philosophical novel contemplating the evolutionary fate of the human race hundreds of thousands of years hence. Lasser’s suggestion that space exploration would signal the transformation of the human species was a provocative idea, and Clarke yearned to see it happen in his lifetime. He wanted to meet and exchange ideas with others who also shared these dreams of space and adventure.

  A small, unelectrified, three-hundred-year-old stone farmhouse in a southwestern English village was the unlikely home where one of the twentieth century’s most visionary minds began dreaming about humanity’s destiny in the stars. Archie Clarke’s parents had both been telegraph operators at different branches of the General Post Office, where, prior to the First World War, they had conducted a covert courtship via Morse code when not under the gaze of their supervisors. Archie had been born while his father, a lieutenant in the Royal Engineers, was stationed in France, later to return badly disabled.