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Monday, June 28, 2021

Robert H. Goddard

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Robert H. Goddard
Dr. Robert H. Goddard - GPN-2002-000131.jpg
Robert Hutchings Goddard (1882–1945)
BornOctober 5, 1882
DiedAugust 10, 1945 (aged 62)
NationalityAmerican
Education
OccupationProfessor, aerospace engineer, physicist, inventor
Known forFirst liquid-fueled rocket
Spouse(s)
Esther Christine Kisk
(m. 1924⁠–⁠1945)
Awards

Robert Hutchings Goddard (October 5, 1882 – August 10, 1945) was an American engineer, professor, physicist, and inventor who is credited with creating and building the world's first liquid-fueled rocket. Goddard successfully launched his rocket on March 16, 1926, which ushered in an era of space flight and innovation. He and his team launched 34 rockets between 1926 and 1941, achieving altitudes as high as 2.6 km (1.6 mi) and speeds as fast as 885 km/h (550 mph).

Goddard's work as both theorist and engineer anticipated many of the developments that would make spaceflight possible. He has been called the man who ushered in the Space Age. Two of Goddard's 214 patented inventions, a multi-stage rocket (1914), and a liquid-fuel rocket (1914), were important milestones toward spaceflight. His 1919 monograph A Method of Reaching Extreme Altitudes is considered one of the classic texts of 20th-century rocket science. Goddard successfully pioneered modern methods such as two-axis control (gyroscopes and steerable thrust) to rockets to control their flight effectively.

Although his work in the field was revolutionary, Goddard received little public support, moral or monetary, for his research and development work. He was a shy person, and rocket research was not considered a suitable pursuit for a physics professor. The press and other scientists ridiculed his theories of spaceflight. As a result, he became protective of his privacy and his work. He preferred to work alone also because of the after effects of a bout with tuberculosis.

Years after his death, at the dawn of the Space Age, Goddard came to be recognized as one of the founding fathers of modern rocketry, along with Robert Esnault-Pelterie, Konstantin Tsiolkovsky, and Hermann Oberth. He not only recognized early on the potential of rockets for atmospheric research, ballistic missiles and space travel but also was the first to scientifically study, design, construct and fly the precursory rockets needed to eventually implement those ideas.

NASA's Goddard Space Flight Center was named in Goddard's honor in 1959. He was also inducted into the International Aerospace Hall of Fame in 1966, and the International Space Hall of Fame in 1976.

Early life and inspiration

Goddard was born in Worcester, Massachusetts, to Nahum Danford Goddard (1859–1928) and Fannie Louise Hoyt (1864–1920). Robert was their only child to survive; a younger son, Richard Henry, was born with a spinal deformity and died before his first birthday. Nahum was employed by manufacturers, and he invented several useful tools. Goddard had English paternal family roots in New England with William Goddard (1628–91) a London grocer who settled in Watertown, Massachusetts in 1666. On his maternal side he was descended from John Hoyt and other settlers of Massachusetts in the late 1600s. Shortly after his birth, the family moved to Boston. With a curiosity about nature, he studied the heavens using a telescope from his father and observed the birds flying. Essentially a country boy, he loved the outdoors and hiking with his father on trips to Worcester and became an excellent marksman with a rifle. In 1898, his mother contracted tuberculosis and they moved back to Worcester for the clear air. On Sundays, the family attended the Episcopal church, and Robert sang in the choir.

Childhood experiment

With the electrification of American cities in the 1880s, the young Goddard became interested in science—specifically, engineering and technology. When his father showed him how to generate static electricity on the family's carpet, the five-year-old's imagination was sparked. Robert experimented, believing he could jump higher if the zinc from a battery could be charged by scuffing his feet on the gravel walk. But, holding the zinc, he could jump no higher than usual. Goddard halted the experiments after a warning from his mother that if he succeeded, he could "go sailing away and might not be able to come back." He experimented with chemicals and created a cloud of smoke and an explosion in the house. Goddard's father further encouraged Robert's scientific interest by providing him with a telescope, a microscope, and a subscription to Scientific American. Robert developed a fascination with flight, first with kites and then with balloons. He became a thorough diarist and documenter of his work—a skill that would greatly benefit his later career. These interests merged at age 16, when Goddard attempted to construct a balloon out of aluminum, shaping the raw metal in his home workshop, and filling it with hydrogen. After nearly five weeks of methodical, documented efforts, he finally abandoned the project, remarking, "... balloon will not go up. ... Aluminum is too heavy. Failior [sic] crowns enterprise." However, the lesson of this failure did not restrain Goddard's growing determination and confidence in his work. He wrote in 1927, "I imagine an innate interest in mechanical things was inherited from a number of ancestors who were machinists."

Cherry tree dream

He became interested in space when he read H. G. Wells' science fiction classic The War of the Worlds at 16 years old. His dedication to pursuing space flight became fixed on October 19, 1899. The 17-year-old Goddard climbed a cherry tree to cut off dead limbs. He was transfixed by the sky, and his imagination grew. He later wrote:

On this day I climbed a tall cherry tree at the back of the barn ... and as I looked toward 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, and how it would look on a small scale, if sent up from the meadow at my feet. I have several photographs of the tree, taken since, with the little ladder I made to climb it, leaning against it.

It seemed to me then that a weight whirling around a horizontal shaft, moving more rapidly above than below, could furnish lift by virtue of the greater centrifugal force at the top of the path.

I was a different boy when I descended the tree from when I ascended. Existence at last seemed very purposive.

For the rest of his life, he observed October 19 as "Anniversary Day", a private commemoration of the day of his greatest inspiration.

Education and early studies

The young Goddard was a thin and frail boy, almost always in fragile health. He suffered from stomach problems, pleurisy, colds, and bronchitis, and he fell two years behind his classmates. He became a voracious reader, regularly visiting the local public library to borrow books on the physical sciences.

Aerodynamics and motion

Goddard's interest in aerodynamics led him to study some of Samuel Langley's scientific papers in the periodical Smithsonian. In these papers, Langley wrote that birds flap their wings with different force on each side to turn in the air. Inspired by these articles, the teenage Goddard watched swallows and chimney swifts from the porch of his home, noting how subtly the birds moved their wings to control their flight. He noted how remarkably the birds controlled their flight with their tail feathers, which he called the birds' equivalent of ailerons. He took exception to some of Langley's conclusions and in 1901 wrote a letter to St. Nicholas magazine with his own ideas. The editor of St. Nicholas declined to publish Goddard's letter, remarking that birds fly with a certain amount of intelligence and that "machines will not act with such intelligence." Goddard disagreed, believing that a man could control a flying machine with his own intelligence.

Around this time, Goddard read Newton's Principia Mathematica, and found that Newton's Third Law of Motion applied to motion in space. He wrote later about his own tests of the Law:

I began to realize that there might be something after all to Newton's Laws. The Third Law was accordingly tested, both with devices suspended by rubber bands and by devices on floats, in the little brook back of the barn, and the said law was verified conclusively. It made me realize that if a way to navigate space were to be discovered, or invented, it would be the result of a knowledge of physics and mathematics.

Academics

As his health improved, Goddard continued his formal schooling as a 19-year-old sophomore at South High Community School in Worcester in 1901. He excelled in his coursework, and his peers twice elected him class president. Making up for lost time, he studied books on mathematics, astronomy, mechanics and composition from the school library. At his graduation ceremony in 1904, he gave his class oration as valedictorian. In his speech, entitled "On Taking Things for Granted", Goddard included a section that would become emblematic of his life:

[J]ust as in the sciences we have learned that we are too ignorant to safely pronounce anything impossible, so for the individual, since we cannot know just what are his limitations, we can hardly say with certainty that anything is necessarily within or beyond his grasp. Each must remember that no one can predict to what heights of wealth, fame, or usefulness he may rise until he has honestly endeavored, and he should derive courage from the fact that all sciences have been, at some time, in the same condition as he, and that it has often proved true that the dream of yesterday is the hope of today and the reality of tomorrow.

Goddard enrolled at Worcester Polytechnic Institute in 1904. He quickly impressed the head of the physics department, A. Wilmer Duff, with his thirst for knowledge, and Duff took him on as a laboratory assistant and tutor. At WPI, Goddard joined the Sigma Alpha Epsilon fraternity and began a long courtship with high school classmate Miriam Olmstead, an honor student who had graduated with him as salutatorian. Eventually, she and Goddard were engaged, but they drifted apart and ended the engagement around 1909.

Goddard at Clark University

Goddard received his B.S. degree in physics from Worcester Polytechnic in 1908, and after serving there for a year as an instructor in physics, he began his graduate studies at Clark University in Worcester in the fall of 1909. Goddard received his M.A. degree in physics from Clark University in 1910, and then stayed at Clark to complete his Ph.D. in physics in 1911. He spent another year at Clark as an honorary fellow in physics, and in 1912 he accepted a research fellowship at Princeton University's Palmer Physical Laboratory.

First scientific writings

The high school student summed up his ideas on space travel in a proposed article, "The Navigation of Space," which he submitted to the Popular Science News. The journal's editor returned it, saying that they could not use it "in the near future."

While still an undergraduate, Goddard wrote a paper proposing a method for balancing airplanes using gyro-stabilization. He submitted the idea to Scientific American, which published the paper in 1907. Goddard later wrote in his diaries that he believed his paper was the first proposal of a way to automatically stabilize aircraft in flight. His proposal came around the same time as other scientists were making breakthroughs in developing functional gyroscopes.

While studying physics at WPI, ideas came to Goddard's mind that sometimes seemed impossible, but he was compelled to record them for future investigation. He wrote that "there was something inside which simply would not stop working." He purchased some cloth-covered notebooks and began filling them with a variety of thoughts, mostly concerning his dream of space travel. He considered centrifugal force, radio waves, magnetic reaction, solar energy, atomic energy, ion or electrostatic propulsion and other methods to reach space. After experimenting with solid fuel rockets he was convinced by 1909 that chemical-propellant engines were the answer. A particularly complex concept was set down in June 1908: Sending a camera around distant planets, guided by measurements of gravity along the trajectory, and returning to earth.

His first writing on the possibility of a liquid-fueled rocket came on February 2, 1909. Goddard had begun to study ways of increasing a rocket's efficiency using methods differing from conventional solid-fuel rockets. He wrote in his notebook about using liquid hydrogen as a fuel with liquid oxygen as the oxidizer. He believed that 50 percent efficiency could be achieved with these liquid propellants (i.e., half of the heat energy of combustion converted to the kinetic energy of the exhaust gases).

First patents

In the decades around 1910, radio was a new technology, fertile for innovation. In 1912, while working at Princeton University, Goddard investigated the effects of radio waves on insulators. In order to generate radio-frequency power, he invented a vacuum tube with a beam deflection that operated like a cathode-ray oscillator tube. His patent on this tube, which predated that of Lee De Forest, became central in the suit between Arthur A. Collins, whose small company made radio transmitter tubes, and AT&T and RCA over his use of vacuum tube technology. Goddard accepted only a consultant's fee from Collins when the suit was dropped. Eventually the two big companies allowed the country's growing electronics industry to use the De Forest patents freely.

Rocket math

By 1912 he had in his spare time, using calculus, developed the mathematics which allowed him to calculate the position and velocity of a rocket in vertical flight, given the weight of the rocket and weight of the propellant and the velocity (with respect to the rocket frame) of the exhaust gases. In effect he had independently developed the Tsiolkovsky rocket equation published a decade earlier in Russia. Tsiolkovsky, however, did not account for gravity nor drag. For vertical flight from the surface of Earth Goddard included in his differential equation the effects of gravity and aerodynamic drag. He wrote: "An approximate method was found necessary ... in order to avoid an unsolved problem in the calculus of variations. The solution that was obtained revealed the fact that surprisingly small initial masses would be necessary ... provided the gases were ejected from the rocket at a high velocity, and also provided that most of the rocket consisted of propellant material."

His first goal was to build a sounding rocket with which to study the atmosphere. Not only would such investigation aid meteorology, but it was necessary to determine temperature, density and wind speed as functions of altitude in order to design efficient space launch vehicles. He was very reluctant to admit that his ultimate goal was in fact to develop a vehicle for flights into space, since most scientists, especially in the United States, did not consider such a goal to be a realistic or practical scientific pursuit, nor was the public yet ready to seriously consider such ideas. Later, in 1933, Goddard said that "[I]n no case must we allow ourselves to be deterred from the achievement of space travel, test by test and step by step, until one day we succeed, cost what it may."

Illness

In early 1913, Goddard became seriously ill with tuberculosis and had to leave his position at Princeton. He then returned to Worcester, where he began a prolonged process of recovery at home. His doctors did not expect him to live. He decided he should spend time outside in the fresh air and walk for exercise, and he gradually improved. When his nurse discovered some of his notes in his bed, he kept them, arguing, "I have to live to do this work."

It was during this period of recuperation, however, that Goddard began to produce some of his most important work. As his symptoms subsided, he allowed himself to work an hour per day with his notes made at Princeton. He was afraid that nobody would be able to read his scribbling should he succumb.

Foundational patents

In the technological and manufacturing atmosphere of Worcester, patents were considered essential, not only to protect original work but as documentation of first discovery. He began to see the importance of his ideas as intellectual property, and thus began to secure those ideas before someone else did—and he would have to pay to use them. In May 1913, he wrote descriptions concerning his first rocket patent applications. His father brought them to a patent lawyer in Worcester who helped him to refine his ideas for consideration. Goddard's first patent application was submitted in October 1913.

In 1914, his first two landmark patents were accepted and registered. The first, U.S. Patent 1,102,653, described a multi-stage rocket fueled with a solid "explosive material." The second, U.S. Patent 1,103,503, described a rocket fueled with a solid fuel (explosive material) or with liquid propellants (gasoline and liquid nitrous oxide). The two patents would eventually become important milestones in the history of rocketry. Overall, 214 patents were published, some posthumously by his wife.

Early rocketry research

Video clips of Goddard's launches and other events in his life

In the fall of 1914 Goddard's health had improved, and he accepted a part-time position as an instructor and research fellow at Clark University. His position at Clark allowed him to further his rocketry research. He ordered numerous supplies that could be used to build rocket prototypes for launch and spent much of 1915 in preparation for his first tests. Goddard's first test launch of a powder rocket came on an early evening in 1915 following his daytime classes at Clark. The launch was loud and bright enough to arouse the alarm of the campus janitor, and Goddard had to reassure him that his experiments, while being serious study, were also quite harmless. After this incident Goddard took his experiments inside the physics lab in order to limit any disturbance.

At the Clark physics lab Goddard conducted static tests of powder rockets to measure their thrust and efficiency. He found his earlier estimates to be verified; powder rockets were converting only about two percent of the thermal energy in their fuel into thrust and kinetic energy. At this point he applied de Laval nozzles, which were generally used with steam turbine engines, and these greatly improved efficiency. (Of the several definitions of rocket efficiency, Goddard measured in his laboratory what is today called the internal efficiency of the engine: the ratio of the kinetic energy of the exhaust gases to the available thermal energy of combustion, expressed as a percentage.) By mid-summer of 1915 Goddard had obtained an average efficiency of 40 percent with a nozzle exit velocity of 6728 feet (2051 meters) per second. Connecting a combustion chamber full of gunpowder to various converging-diverging expansion (de Laval) nozzles, Goddard was able in static tests to achieve engine efficiencies of more than 63% and exhaust velocities of over 7000 feet (2134 meters) per second.

Few would recognize it at the time, but this little engine was a major breakthrough. These experiments suggested that rockets could be made powerful enough to escape Earth and travel into space. This engine and subsequent experiments sponsored by the Smithsonian Institution were the beginning of modern rocketry and, ultimately, space exploration. Goddard realized, however, that it would take the more efficient liquid propellants to reach space.

Later that year, Goddard designed an elaborate experiment at the Clark physics lab and proved that a rocket would perform in a vacuum such as that in space. He believed it would, but many other scientists were not yet convinced. His experiment demonstrated that a rocket's performance actually decreases under atmospheric pressure.

In September 1906 he wrote in his notebook about using the repulsion of electrically charged particles (ions) to produce thrust. From 1916 to 1917, Goddard built and tested the first known experimental ion thrusters, which he thought might be used for propulsion in the near-vacuum conditions of outer space. The small glass engines he built were tested at atmospheric pressure, where they generated a stream of ionized air.

Smithsonian Institution sponsorship

By 1916, the cost of Goddard's rocket research had become too great for his modest teaching salary to bear. He began to solicit potential sponsors for financial assistance, beginning with the Smithsonian Institution, the National Geographic Society, and the Aero Club of America.

In his letter to the Smithsonian in September 1916, Goddard claimed he had achieved a 63% efficiency and a nozzle velocity of almost 2438 meters per second. With these performance levels, he believed a rocket could vertically lift a weight of 1 lb (0.45 kg) to a height of 232 miles (373 km) with an initial launch weight of only 89.6 lbs (40.64 kg). (Earth's atmosphere can be considered to end at 80 to 100 miles (130 to 160 km) altitude, where its drag effect on orbiting satellites becomes minimal.)

The Smithsonian was interested and asked Goddard to elaborate upon his initial inquiry. Goddard responded with a detailed manuscript he had already prepared, entitled A Method of Reaching Extreme Altitudes.

In January 1917, the Smithsonian agreed to provide Goddard with a five-year grant totaling US$5000. Afterward, Clark was able to contribute US$3500 and the use of their physics lab to the project. Worcester Polytechnic Institute also allowed him to use its abandoned Magnetics Laboratory on the edge of campus during this time, as a safe place for testing. WPI also made some parts in their machine shop.

Goddard's fellow Clark scientists were astonished at the unusually large Smithsonian grant for rocket research, which they thought was not real science. Decades later, rocket scientists who knew how much it cost to research and develop rockets said that he had received little financial support.

Two years later, at the insistence of Dr. Arthur G. Webster, the world-renowned head of Clark's physics department, Goddard arranged for the Smithsonian to publish the paper, A Method..., which documented his work.

While at Clark University, Goddard did research into solar power using a parabolic dish to concentrate the Sun's rays on a machined piece of quartz, that was sprayed with mercury, which then heated water and drove an electric generator. Goddard believed his invention had overcome all the obstacles that had previously defeated other scientists and inventors, and he had his findings published in the November 1929 issue of Popular Science.

Goddard's military rocket

Goddard loading a bazooka in 1918

Not all of Goddard's early work was geared toward space travel. As the United States entered World War I in 1917, the country's universities began to lend their services to the war effort. Goddard believed his rocket research could be applied to many different military applications, including mobile artillery, field weapons and naval torpedoes. He made proposals to the Navy and Army. No record exists in his papers of any interest by the Navy to Goddard's inquiry. However, Army Ordnance was quite interested, and Goddard met several times with Army personnel.

During this time, Goddard was also contacted, in early 1918, by a civilian industrialist in Worcester about the possibility of manufacturing rockets for the military. However, as the businessman's enthusiasm grew, so did Goddard's suspicion. Talks eventually broke down as Goddard began to fear his work might be appropriated by the business. However, an Army Signal Corps officer tried to make Goddard cooperate, but he was called off by General George Squier of the Signal Corps who had been contacted by Secretary of the Smithsonian Institution, Charles Walcott. Goddard became leery of working with corporations and was careful to secure patents to "protect his ideas." These events led to the Signal Corps sponsoring Goddard's work during World War I.

Goddard proposed to the Army an idea for a tube-based rocket launcher as a light infantry weapon. The launcher concept became the precursor to the bazooka. The rocket-powered, recoil-free weapon was the brainchild of Goddard as a side project (under Army contract) of his work on rocket propulsion.  Goddard, during his tenure at Clark University, and working at Mount Wilson Observatory for security reasons, designed the tube-fired rocket for military use during World War I. He and his co-worker, Dr. Clarence N. Hickman successfully demonstrated his rocket to the U.S. Army Signal Corps at Aberdeen Proving Ground, Maryland, on November 6, 1918, using two music stands for a launch platform. The Army was impressed, but the Compiègne Armistice was signed only five days later, and further development was discontinued as World War I ended.

The delay in the development of the bazooka and other weapons was a result of the long recovery period required from Goddard's serious bout with tuberculosis. Goddard continued to be a part-time consultant to the U.S. Government at Indian Head, Maryland, until 1923, but his focus had turned to other research involving rocket propulsion, including work with liquid fuels and liquid oxygen.

Later, the former Clark University researcher Dr. Clarence N. Hickman, and Army officers Col. Leslie Skinner and Lt. Edward Uhl continued Goddard's work on the bazooka. A shaped-charge warhead was attached to the rocket, leading to the tank-killing weapon used in World War II and to many other powerful rocket weapons.

A Method of Reaching Extreme Altitudes

In 1919 Goddard thought that it would be premature to disclose the results of his experiments because his engine was not sufficiently developed. Dr. Webster realized that Goddard had accomplished a good deal of fine work and insisted that Goddard publish his progress so far or he would take care of it himself, so Goddard asked the Smithsonian Institution if it would publish the report, updated with notes, that he had submitted in late 1916.

In late 1919, the Smithsonian published Goddard's groundbreaking work, A Method of Reaching Extreme Altitudes. The report describes Goddard's mathematical theories of rocket flight, his experiments with solid-fuel rockets, and the possibilities he saw of exploring Earth's atmosphere and beyond. Along with Konstantin Tsiolkovsky's earlier work, The Exploration of Cosmic Space by Means of Reaction Devices, which was not widely disseminated outside Russia, Goddard's report is regarded as one of the pioneering works of the science of rocketry, and 1750 copies were distributed worldwide. Goddard also sent a copy to individuals who requested one, until his personal supply was exhausted. Smithsonian aerospace historian Frank Winter said that this paper was "one of the key catalysts behind the international rocket movement of the 1920s and 30s."

Goddard described extensive experiments with solid-fuel rocket engines burning high-grade nitrocellulose smokeless powder. A critical breakthrough was the use of the steam turbine nozzle invented by the Swedish inventor Gustaf de Laval. The de Laval nozzle allows the most efficient (isentropic) conversion of the energy of hot gases into forward motion. By means of this nozzle, Goddard increased the efficiency of his rocket engines from two percent to 64 percent and obtained supersonic exhaust velocities of over Mach 7.

Though most of this work dealt with the theoretical and experimental relations between propellant, rocket mass, thrust, and velocity, a final section, entitled "Calculation of minimum mass required to raise one pound to an 'infinite' altitude," discussed the possible uses of rockets, not only to reach the upper atmosphere but to escape from Earth's gravitation altogether. He determined, using an approximate method to solve his differential equation of motion for vertical flight, that a rocket with an effective exhaust velocity of 7000 feet per second and an initial weight of 602 pounds would be able to send a one-pound payload to an infinite height. Included as a thought experiment was the idea of launching a rocket to the Moon and igniting a mass of flash powder on its surface, so as to be visible through a telescope. He discussed the matter seriously, down to an estimate of the amount of powder required. Goddard's conclusion was that a rocket with starting mass of 3.21 tons could produce a flash "just visible" from Earth, assuming a final payload weight of 10.7 pounds.

Goddard eschewed publicity, because he did not have time to reply to criticism of his work, and his imaginative ideas about space travel were shared only with private groups he trusted. He did, though, publish and talk about the rocket principle and sounding rockets, since these subjects were not too "far out." In a letter to the Smithsonian, dated March 1920, he discussed: photographing the Moon and planets from rocket-powered fly-by probes, sending messages to distant civilizations on inscribed metal plates, the use of solar energy in space, and the idea of high-velocity ion propulsion. In that same letter, Goddard clearly describes the concept of the ablative heat shield, suggesting the landing apparatus be covered with "layers of a very infusible hard substance with layers of a poor heat conductor between" designed to erode in the same way as the surface of a meteor.

Every vision is a joke until the first man accomplishes it; once realized, it becomes commonplace.

–Response to a reporter's question following criticism in The New York Times, 1920.

Publicity and criticism

The publication of Goddard's document gained him national attention from U.S. newspapers, most of it negative. Although Goddard's discussion of targeting the moon was only a small part of the work as a whole (eight lines on the next to last page of 69 pages), and was intended as an illustration of the possibilities rather than a declaration of intent, the papers sensationalized his ideas to the point of misrepresentation and ridicule. Even the Smithsonian had to abstain from publicity because of the amount of ridiculous correspondence received from the general public. David Lasser, who co-founded the American Rocket Society (ARS), wrote in 1931 that Goddard was subjected in the press to the "most violent attacks."

On January 12, 1920, a front-page story in The New York Times, "Believes Rocket Can Reach Moon", reported a Smithsonian press release about a "multiple-charge, high-efficiency rocket." The chief application envisaged was "the possibility of sending recording apparatus to moderate and extreme altitudes within the Earth's atmosphere", the advantage over balloon-carried instruments being ease of recovery, since "the new rocket apparatus would go straight up and come straight down." But it also mentioned a proposal "to [send] to the dark part of the new moon a sufficiently large amount of the most brilliant flash powder which, in being ignited on impact, would be plainly visible in a powerful telescope. This would be the only way of proving that the rocket had really left the attraction of the earth, as the apparatus would never come back, once it had escaped that attraction."

New York Times editorial

On January 13, 1920, the day after its front-page story about Goddard's rocket, an unsigned New York Times editorial, in a section entitled "Topics of the Times", scoffed at the proposal. The article, which bore the title "A Severe Strain on Credulity", began with apparent approval, but soon went on to cast serious doubt:

As a method of sending a missile to the higher, and even highest, part of the earth's atmospheric envelope, Professor Goddard's multiple-charge rocket is a practicable, and therefore promising device. Such a rocket, too, might carry self-recording instruments, to be released at the limit of its flight, and conceivable parachutes would bring them safely to the ground. It is not obvious, however, that the instruments would return to the point of departure; indeed, it is obvious that they would not, for parachutes drift exactly as balloons do.

The article pressed further on Goddard's proposal to launch rockets beyond the atmosphere:

[A]fter the rocket quits our air and really starts on its longer journey, its flight would be neither accelerated nor maintained by the explosion of the charges it then might have left. To claim that it would be is to deny a fundamental law of dynamics, and only Dr. Einstein and his chosen dozen, so few and fit, are licensed to do that. ... Of course, [Goddard] only seems to lack the knowledge ladled out daily in high schools.

The basis of that criticism was the then-common belief that thrust was produced by the rocket exhaust pushing against the atmosphere; Goddard realized that Newton's third law (reaction) was the actual principle and that thrust was possible in a vacuum.

Aftermath

A week after the New York Times editorial, Goddard released a signed statement to the Associated Press, attempting to restore reason to what had become a sensational story:

Too much attention has been concentrated on the proposed flash pow[d]er experiment, and too little on the exploration of the atmosphere. ... Whatever interesting possibilities there may be of the method that has been proposed, other than the purpose for which it was intended, no one of them could be undertaken without first exploring the atmosphere.

In 1924, Goddard published an article, "How my speed rocket can propel itself in vacuum", in Popular Science, in which he explained the physics and gave details of the vacuum experiments he had performed to prove the theory. But, no matter how he tried to explain his results, he was not understood by the majority. After one of Goddard's experiments in 1929, a local Worcester newspaper carried the mocking headline "Moon rocket misses target by 238,79912 miles."

Though the unimaginative public chuckled at the "moon man," his groundbreaking paper was read seriously by many rocketeers in America, Europe, and Russia who were stirred to build their own rockets. This work was his most important contribution to the quest to "aim for the stars."

Goddard worked alone with just his team of mechanics and machinists for many years. This was a result of the harsh criticism from the media and other scientists, and his understanding of the military applications which foreign powers might use. Goddard became increasingly suspicious of others and often worked alone, except during the two World Wars, which limited the impact of much of his work. Another limiting factor was the lack of support from the American government, military and academia, all failing to understand the value of the rocket to study the atmosphere and near space, and for military applications. As Germany became ever more war-like, he refused to communicate with German rocket experimenters, though he received more and more of their correspondence.

'A Correction'

Forty-nine years after its editorial mocking Goddard, on July 17, 1969—the day after the launch of Apollo 11The New York Times published a short item under the headline "A Correction." The three-paragraph statement summarized its 1920 editorial and concluded:

Further investigation and experimentation have confirmed the findings of Isaac Newton in the 17th Century and it is now definitely established that a rocket can function in a vacuum as well as in an atmosphere. The Times regrets the error.

First liquid-fueled flight

Goddard began considering liquid propellants, including hydrogen and oxygen, as early as 1909. He knew that hydrogen and oxygen was the most efficient fuel/oxidizer combination. Liquid hydrogen was not readily available in 1921, however, and he selected gasoline as the safest fuel to handle.

First static tests

Robert Goddard, bundled against the cold weather of March 16, 1926, holds the launching frame of his most notable invention — the first liquid-fueled rocket.

Goddard began experimenting with liquid oxidizer, liquid fuel rockets in September 1921, and successfully tested the first liquid propellant engine in November 1923. It had a cylindrical combustion chamber, using impinging jets to mix and atomize liquid oxygen and gasoline.

In 1924–25, Goddard had problems developing a high-pressure piston pump to send fuel to the combustion chamber. He wanted to scale up the experiments, but his funding would not allow such growth. He decided to forego the pumps and use a pressurized fuel feed system applying pressure to the fuel tank from a tank of inert gas, a technique used today. The liquid oxygen, some of which evaporated, provided its own pressure.

On December 6, 1925, he tested the simpler pressure feed system. He conducted a static test on the firing stand at the Clark University physics laboratory. The engine successfully lifted its own weight in a 27-second test in the static rack. It was a major success for Goddard, proving that a liquid fuel rocket was possible. The test moved Goddard an important step closer to launching a rocket with liquid fuel.

Goddard conducted an additional test in December, and two more in January 1926. After that, he began preparing for a possible launch of the rocket system.

First flight

Goddard launched the world's first liquid-fueled (gasoline and liquid oxygen) rocket on March 16, 1926, in Auburn, Massachusetts. Present at the launch were his crew chief Henry Sachs, Esther Goddard, and Percy Roope, who was Clark's assistant professor in the physics department. Goddard's diary entry of the event was notable for its understatement:

March 16. Went to Auburn with S[achs] in am. E[sther] and Mr. Roope came out at 1 p.m. Tried rocket at 2.30. It rose 41 feet & went 184 feet, in 2.5 secs., after the lower half of the nozzle burned off. Brought materials to lab. ...

His diary entry the next day elaborated:

March 17, 1926. The first flight with a rocket using liquid propellants was made yesterday at Aunt Effie's farm in Auburn. ... Even though the release was pulled, the rocket did not rise at first, but the flame came out, and there was a steady roar. After a number of seconds it rose, slowly until it cleared the frame, and then at express train speed, curving over to the left, and striking the ice and snow, still going at a rapid rate.

The rocket, which was later dubbed "Nell", rose just 41 feet during a 2.5-second flight that ended 184 feet away in a cabbage field, but it was an important demonstration that liquid fuels and oxidizers were possible propellants for larger rockets. The launch site is now a National Historic Landmark, the Goddard Rocket Launching Site.

Viewers familiar with more modern rocket designs may find it difficult to distinguish the rocket from its launching apparatus in the well-known picture of "Nell". The complete rocket is significantly taller than Goddard but does not include the pyramidal support structure which he is grasping. The rocket's combustion chamber is the small cylinder at the top; the nozzle is visible beneath it. The fuel tank, which is also part of the rocket, is the larger cylinder opposite Goddard's torso. The fuel tank is directly beneath the nozzle and is protected from the motor's exhaust by an asbestos cone. Asbestos-wrapped aluminum tubes connect the motor to the tanks, providing both support and fuel transport. This layout is no longer used, since the experiment showed that this was no more stable than placing the combustion chamber and nozzle at the base. By May, after a series of modifications to simplify the plumbing, the combustion chamber and nozzle were placed in the now classic position, at the lower end of the rocket.

Goddard determined early that fins alone were not sufficient to stabilize the rocket in flight and keep it on the desired trajectory in the face of winds aloft and other disturbing forces. He added movable vanes in the exhaust, controlled by a gyroscope, to control and steer his rocket. (The Germans used this technique in their V-2.) He also introduced the more efficient swiveling engine in several rockets, basically the method used to steer large liquid-propellant missiles and launchers today.

Lindbergh and Goddard

After launch of one of Goddard's rockets in July 1929 again gained the attention of the newspapers, Charles Lindbergh learned of his work in a New York Times article. At the time, Lindbergh had begun to wonder what would become of aviation (even space flight) in the distant future and had settled on jet propulsion and rocket flight as a probable next step. After checking with the Massachusetts Institute of Technology (MIT) and being assured that Goddard was a bona fide physicist and not a crackpot, he phoned Goddard in November 1929. Professor Goddard met the aviator soon after in his office at Clark University. Upon meeting Goddard, Lindbergh was immediately impressed by his research, and Goddard was similarly impressed by the flier's interest. He discussed his work openly with Lindbergh, forming an alliance that would last for the rest of his life. While having long since become reluctant to share his ideas, Goddard showed complete openness with those few who shared his dream, and whom he felt he could trust.

By late 1929, Goddard had been attracting additional notoriety with each rocket launch. He was finding it increasingly difficult to conduct his research without unwanted distractions. Lindbergh discussed finding additional financing for Goddard's work and lent his famous name to Goddard's work. In 1930 Lindbergh made several proposals to industry and private investors for funding, which proved all but impossible to find following the recent U.S. stock market crash in October 1929.

Guggenheim sponsorship

In the spring of 1930, Lindbergh finally found an ally in the Guggenheim family. Financier Daniel Guggenheim agreed to fund Goddard's research over the next four years for a total of $100,000 (~$1.9 million today). The Guggenheim family, especially Harry Guggenheim, would continue to support Goddard's work in the years to come. The Goddards soon moved to Roswell, New Mexico

Because of the military potential of the rocket, Goddard, Lindbergh, Harry Guggenheim, the Smithsonian Institution and others tried in 1940, before the U.S. entered World War II, to convince the Army and Navy of its value. Goddard's services were offered, but there was no interest, initially. Two young, imaginative military officers eventually got the services to attempt to contract with Goddard just prior to the war. The Navy beat the Army to the punch and secured his services to build variable-thrust, liquid-fueled rocket engines for jet-assisted take-off (JATO) of aircraft. These rocket engines were the precursors to the larger throttlable rocket plane engines that helped launch the space age.

Astronaut Buzz Aldrin wrote that his father, Edwin Aldrin Sr. "was an early supporter of Robert Goddard." The elder Aldrin was a student of physics under Goddard at Clark, and worked with Lindbergh to obtain the help of the Guggenheims. Buzz believed that if Goddard had received military support as Wernher von Braun's team had enjoyed in Germany, American rocket technology would have developed much more rapidly in World War II.

Lack of vision in the United States

Before World War II there was a lack of vision and serious interest in the United States concerning the potential of rocketry, especially in Washington. Although the Weather Bureau was interested beginning in 1929 in Goddard's rocket for atmospheric research, the Bureau could not secure governmental funding. Between the World Wars, the Guggenheim Foundation was the main source of funding for Goddard's research. Goddard's liquid-fueled rocket was neglected by his country, according to aerospace historian Eugene Emme, but was noticed and advanced by other nations, especially the Germans. Goddard showed remarkable prescience in 1923 in a letter to the Smithsonian. He knew that the Germans were very interested in rocketry and said he "would not be surprised if the research would become something in the nature of a race," and he wondered how soon the European "theorists" would begin to build rockets. In 1936, the U.S. military attaché in Berlin asked Charles Lindbergh to visit Germany and learn what he could of their progress in aviation. Although the Luftwaffe showed him their factories and were open concerning their growing airpower, they were silent on the subject of rocketry. When Lindbergh told Goddard of this behavior, Goddard said, "Yes, they must have plans for the rocket. When will our own people in Washington listen to reason?"

Most of the U.S.'s largest universities were also slow to realize rocketry's potential. Just before World War II, the head of the aeronautics department at MIT, at a meeting held by the Army Air Corps to discuss project funding, said that the California Institute of Technology (Caltech) "can take the Buck Rogers Job [rocket research]." In 1941, Goddard tried to recruit an engineer for his team from MIT but couldn't find one who was interested. There were some exceptions: MIT was at least teaching basic rocketry, and Caltech had courses in rocketry and aerodynamics. After the war, Dr. Jerome Hunsaker of MIT, having studied Goddard's patents, stated that "Every liquid-fuel rocket that flies is a Goddard rocket."

While away in Roswell, Goddard was still head of the physics department at Clark University, and Clark allowed him to devote most of his time to rocket research. Likewise, the University of California, Los Angeles (UCLA) permitted astronomer Samuel Herrick to pursue research in space vehicle guidance and control, and shortly after the war to teach courses in spacecraft guidance and orbit determination. Herrick began corresponding with Goddard in 1931 and asked if he should work in this new field, which he named astrodynamics. Herrick said that Goddard had the vision to advise and encourage him in his use of celestial mechanics "to anticipate the basic problem of space navigation." Herrick's work contributed substantially to America's readiness to control flight of Earth satellites and send men to the Moon and back.

Roswell, New Mexico

Charles Lindbergh took this picture of Robert H. Goddard's rocket, when he peered down the launching tower on September 23, 1935, in Roswell, New Mexico.
 
Goddard towing a rocket in Roswell

With new financial backing, Goddard eventually relocated to Roswell, New Mexico, in summer of 1930, where he worked with his team of technicians in near-isolation and relative secrecy for years. He had consulted a meteorologist as to the best area to do his work, and Roswell seemed ideal. Here they would not endanger anyone, would not be bothered by the curious and would experience a more moderate climate (which was also better for Goddard's health). The locals valued personal privacy, knew Goddard desired his, and when travelers asked where Goddard's facilities were located, they would likely be misdirected.

By September 1931, his rockets had the now familiar appearance of a smooth casing with tail-fins. He began experimenting with gyroscopic guidance and made a flight test of such a system in April 1932. A gyroscope mounted on gimbals electrically controlled steering vanes in the exhaust, similar to the system used by the German V-2 over 10 years later. Though the rocket crashed after a short ascent, the guidance system had worked, and Goddard considered the test a success.

A temporary loss of funding from the Guggenheims, as a result of the depression, forced Goddard in spring of 1932 to return to his much-loathed professorial responsibilities at Clark University. He remained at the university until the autumn of 1934, when funding resumed. Because of the death of the senior Daniel Guggenheim, the management of funding was taken on by his son, Harry Guggenheim. Upon his return to Roswell, he began work on his A series of rockets, 4 to 4.5 meters long, and powered by gasoline and liquid oxygen pressurized with nitrogen. The gyroscopic control system was housed in the middle of the rocket, between the propellant tanks.

The A-4 used a simpler pendulum system for guidance, as the gyroscopic system was being repaired. On March 8, 1935, it flew up to 1,000 feet, then turned into the wind and, Goddard reported, "roared in a powerful descent across the prairie, at close to, or at, the speed of sound." On March 28, 1935, the A-5 successfully flew vertically to an altitude of (0.91 mi; 4,800 ft) using his gyroscopic guidance system. It then turned to a nearly horizontal path, flew 13,000 feet and achieved a maximum speed of 550 miles per hour. Goddard was elated because the guidance system kept the rocket on a vertical path so well.

In 1936–1939, Goddard began work on the K and L series rockets, which were much more massive and designed to reach very high altitude. The K series consisted of static bench tests of a more powerful engine, achieving a thrust of 624 lbs in February 1936. This work was plagued by trouble with chamber burn-through. In 1923, Goddard had built a regeneratively cooled engine, which circulated liquid oxygen around the outside of the combustion chamber, but he deemed the idea too complicated. He then used a curtain cooling method that involved spraying excess gasoline, which evaporated around the inside wall of the combustion chamber, but this scheme did not work well, and the larger rockets failed. Goddard returned to a smaller design, and his L-13 reached an altitude of 2.7 kilometers (1.7 mi; 8,900 ft), the highest of any of his rockets. Weight was reduced by using thin-walled fuel tanks wound with high-tensile-strength wire.

Goddard experimented with many of the features of today's large rockets, such as multiple combustion chambers and nozzles. In November 1936, he flew the world's first rocket (L-7) with multiple chambers, hoping to increase thrust without increasing the size of a single chamber. It had four combustion chambers, reached a height of 200 feet, and corrected its vertical path using blast vanes until one chamber burned through. This flight demonstrated that a rocket with multiple combustion chambers could fly stably and be easily guided. In July 1937 he replaced the guidance vanes with a movable tail section containing a single combustion chamber, as if on gimbals (thrust vectoring). The flight was of low altitude, but a large disturbance, probably caused by a change in the wind velocity, was corrected back to vertical. In an August test the flight path was corrected seven times by the movable tail and was captured on film by Mrs Goddard.

From 1940 to 1941, Goddard worked on the P series of rockets, which used propellant turbopumps (also powered by gasoline and liquid oxygen). The lightweight pumps produced higher propellant pressures, permitting a more powerful engine (greater thrust) and a lighter structure (lighter tanks and no pressurization tank), but two launches both ended in crashes after reaching an altitude of only a few hundred feet. The turbopumps worked well, however, and Goddard was pleased.

When Goddard mentioned the need for turbopumps, Harry Guggenheim suggested that he contact pump manufacturers to aid him. None were interested, as the development cost of these miniature pumps was prohibitive. Goddard's team was therefore left on its own and from September 1938 to June 1940 designed and tested the small turbopumps and gas generators to operate the turbines. Esther later said that the pump tests were "the most trying and disheartening phase of the research."

Goddard was able to flight-test many of his rockets, but many resulted in what the uninitiated would call failures, usually resulting from engine malfunction or loss of control. Goddard did not consider them failures, however, because he felt that he always learned something from a test. Most of his work involved static tests, which are a standard procedure today, before a flight test. He wrote to a correspondent: "It is not a simple matter to differentiate unsuccessful from successful experiments. ... [Most] work that is finally successful is the result of a series of unsuccessful tests in which difficulties are gradually eliminated."

General Jimmy Doolittle

Jimmy Doolittle was introduced to the field of space science at an early point in its history. He recalls in his autobiography, "I became interested in rocket development in the 1930s when I met Robert H. Goddard, who laid the foundation. ... While with Shell Oil I worked with him on the development of a type of fuel. ... " Harry Guggenheim and Charles Lindbergh arranged for (then Major) Doolittle to discuss with Goddard a special blend of gasoline. Doolittle flew himself to Roswell in October 1938 and was given a tour of Goddard's shop and a "short course" in rocketry. He then wrote a memo, including a rather detailed description of Goddard's rocket. In closing he said, "interplanetary transportation is probably a dream of the very distant future, but with the moon only a quarter of a million miles away—who knows!" In July 1941, he wrote Goddard that he was still interested in his rocket propulsion research. The Army was interested only in JATO at this point. However, Doolittle and Lindbergh were concerned about the state of rocketry in the US, and Doolittle remained in touch with Goddard.

Shortly after World War II, Doolittle spoke concerning Goddard to an American Rocket Society (ARS) conference at which a large number interested in rocketry attended. He later stated that at that time "we [in the aeronautics field] had not given much credence to the tremendous potential of rocketry." In 1956, he was appointed chairman of the National Advisory Committee for Aeronautics (NACA) because the previous chairman, Jerome C. Hunsaker, thought Doolittle to be more sympathetic than other scientists and engineers to the rocket, which was increasing in importance as a scientific tool as well as a weapon. Doolittle was instrumental in the successful transition of the NACA to the National Aeronautics and Space Administration (NASA) in 1958. He was offered the position as first administrator of NASA, but he turned it down.

Launch history

Between 1926 and 1941, the following 35 rockets were launched:

Date Type Altitude in feet Altitude in meters Flight duration Notes
March 16, 1926 Goddard 1 41 12.5 2.5 s first liquid rocket launch
April 3, 1926 Goddard 1 49 15 4.2 s record altitude
December 26, 1928 Goddard 3 16 5 unknown
July 17, 1929 Goddard 3 90 27 5.5 s record altitude
December 30, 1930 Goddard 4 2000 610 unknown record altitude
September 29, 1931 Goddard 4 180 55 9.6 s
October 13, 1931 Goddard 4 1700 520 unknown
October 27, 1931 Goddard 4 1330 410 unknown
April 19, 1932 - 135 41 5 s
February 16, 1935 A series 650 200 unknown
March 8, 1935 A series 1000 300 12 s
March 28, 1935 A series 4800 1460 20 s record altitude
May 31, 1935 A series 7500 2300 unknown record altitude
June 25, 1935 A series 120 37 10 s
July 12, 1935 A series 6600 2000 14 s
October 29, 1935 A series 4000 1220 12 s
July 31, 1936 L series, Section A 200 60 5 s
October 3, 1936 L-A 200 60 5 s
November 7, 1936 L-A 200 60 unknown 4 thrust chambers
December 18, 1936 L series, Section B 3 1 unknown Veered horizontally immediately after launch
February 1, 1937 L-B 1870 570 20.5 s
February 27, 1937 L-B 1500 460 20 s
March 26, 1937 L-B 8000-9000 2500–2700 22.3 s Highest altitude achieved
April 22, 1937 L-B 6560 2000 21.5 s
May 19, 1937 L-B 3250 990 29.5 s
July 28, 1937 L-series, Section C 2055 630 28 s Movable tail

steering

August 26, 1937 L-C 2000 600 unknown Movable tail
November 24, 1937 L-C 100 30 unknown
March 6, 1938 L-C 525 160 unknown
March 17, 1938 L-C 2170 660 15 s
April 20, 1938 L-C 4215 1260 25.3 s
May 26, 1938 L-C 140 40 unknown
August 9, 1938 L-C 4920 (visual)
3294 (barograph)
1500
1000
unknown
August 9, 1940 P-series, Section C 300 90 unknown
May 8, 1941 P-C 250 80 unknown
Some of the parts of Goddard's rockets

Analysis of results

As an instrument for reaching extreme altitudes, Goddard's rockets were not very successful; they did not achieve an altitude greater than 2.7 km in 1937, while a balloon sonde had already reached 35 km in 1921. By contrast, German rocket scientists had achieved an altitude of 2.4 km with the A-2 rocket in 1934, 8 km by 1939 with the A-5, and 176 km in 1942 with the A-4 (V-2) launched vertically, reaching the outer limits of the atmosphere and into space.

Goddard's pace was slower than the Germans' because he did not have the resources they did. Simply reaching high altitudes was not his primary goal; he was trying, with a methodical approach, to perfect his liquid fuel engine and subsystems such as guidance and control so that his rocket could eventually achieve high altitudes without tumbling in the rare atmosphere, providing a stable vehicle for the experiments it would eventually carry. He had built the necessary turbopumps and was on the verge of building larger, lighter, more reliable rockets to reach extreme altitudes carrying scientific instruments when World War II intervened and changed the path of American history. He hoped to return to his experiments in Roswell after the war.

Though by the end of the Roswell years much of his technology had been replicated independently by others, he introduced new developments to rocketry that were used in this new enterprise: lightweight turbopumps, variable-thrust engine (in U.S.), engine with multiple combustion chambers and nozzles, and curtain cooling of combustion chamber.

Although Goddard had brought his work in rocketry to the attention of the United States Army, between World Wars, he was rebuffed, since the Army largely failed to grasp the military application of large rockets and said there was no money for new experimental weapons. German military intelligence, by contrast, had paid attention to Goddard's work. The Goddards noticed that some mail had been opened, and some mailed reports had gone missing. An accredited military attaché to the US, Friedrich von Boetticher, sent a four-page report to the Abwehr in 1936, and the spy Gustav Guellich sent a mixture of facts and made-up information, claiming to have visited Roswell and witnessed a launch. The Abwehr was very interested and responded with more questions about Goddard's work. Guellich's reports did include information about fuel mixtures and the important concept of fuel-curtain cooling, but thereafter the Germans received very little information about Goddard.

The Soviet Union had a spy in the U.S. Navy Bureau of Aeronautics. In 1935, she gave them a report Goddard had written for the Navy in 1933. It contained results of tests and flights and suggestions for military uses of his rockets. The Soviets considered this to be very valuable information. It provided few design details, but gave them the direction and knowledge about Goddard's progress.

Annapolis, Maryland

Navy Lieutenant Charles F. Fischer, who had visited Goddard in Roswell earlier and gained his confidence, believed Goddard was doing valuable work and was able to convince the Bureau of Aeronautics in September 1941 that Goddard could build the JATO unit the Navy desired. While still in Roswell, and before the Navy contract took effect, Goddard began in September to apply his technology to build a variable-thrust engine to be attached to a PBY seaplane. By May 1942, he had a unit that could meet the Navy's requirements and be able to launch a heavily loaded aircraft from a short runway. In February, he received part of a PBY with bullet holes apparently acquired in the Pearl Harbor attack. Goddard wrote to Guggenheim that "I can think of nothing that would give me greater satisfaction than to have it contribute to the inevitable retaliation."

In April, Fischer notified Goddard that the Navy wanted to do all its rocket work at the Engineering Experiment Station at Annapolis. Esther, worried that a move to the climate of Maryland would cause Robert's health to deteriorate faster, objected. But the patriotic Goddard replied, "Esther, don't you know there's a war on?" Fischer also questioned the move, as Goddard could work just as well in Roswell. Goddard simply answered, "I was wondering when you would ask me." Fischer had wanted to offer him something bigger—a long range missile—but JATO was all he could manage, hoping for a greater project later. It was a case of a square peg in a round hole, according to a disappointed Goddard.

Goddard and his team had already been in Annapolis a month and had tested his constant-thrust JATO engine when he received a Navy telegram, forwarded from Roswell, ordering him to Annapolis. Lt. Fischer asked for a crash effort. By August, his engine was producing 800 lbs of thrust for 20 seconds, and Fischer was anxious to try it on a PBY. On the sixth test run, with all bugs worked out, the PBY, piloted by Fischer, was pushed into the air from the Severn River. Fischer landed and prepared to launch again. Goddard had wanted to check the unit, but radio contact with the PBY had been lost. On the seventh try, the engine caught fire. The plane was 150 feet up when flight was aborted. Because Goddard had installed a safety feature at the last minute, there was no explosion and no lives were lost. The problem's cause was traced to hasty installation and rough handling. Cheaper, safer solid fuel JATO engines were eventually selected by the armed forces. An engineer later said, "Putting [Goddard's] rocket on a seaplane was like hitching an eagle to a plow."

Goddard's first biographer Milton Lehman notes:

In its 1942 crash effort to perfect an aircraft booster, the Navy was beginning to learn its way in rocketry. In similar efforts, the Army Air Corps was also exploring the field [with GALCIT]. Compared to Germany's massive program, these beginnings were small, yet essential to later progress. They helped develop a nucleus of trained American rocket engineers, the first of the new breed who would follow the professor into the Age of Space.

In August 1943, President Atwood at Clark wrote to Goddard that the university was losing the acting head of the Physics Department, was taking on "emergency work" for the Army, and he was to "report for duty or declare the position vacant." Goddard replied that he believed he was needed by he Navy, was nearing retirement age, and was unable to lecture because of his throat problem, which did not allow him to talk above a whisper. He regretfully resigned as Professor of Physics and expressed his deepest appreciation for all Atwood and the Trustees had done for him and indirectly for the war effort. In June he had gone to see a throat specialist in Baltimore, who recommended that he not talk at all, to give his throat a rest.

The station, under Lt Commander Robert Truax, was developing another JATO engine in 1942 that used hypergolic propellants, eliminating the need for an ignition system. Chemist Ensign Ray Stiff had discovered in the literature in February that aniline and nitric acid burned fiercely immediately when mixed. Goddard's team built the pumps for the aniline fuel and the nitric acid oxidizer and participated in the static testing. The Navy delivered the pumps to Reaction Motors (RMI) to use in developing a gas generator for the pump turbines. Goddard went to RMI to observe testing of the pump system and would eat lunch with the RMI engineers. (RMI was the first firm formed to build rocket engines and built engines for the Bell X-1 rocket plane and Viking (rocket). RMI offered Goddard one-fifth interest in the company and a partnership after the war. Goddard went with Navy people in December 1944 to confer with RMI on division of labor, and his team was to provide the propellant pump system for a rocket-powered interceptor because they had more experience with pumps. He consulted with RMI from 1942 through 1945. Though previously competitors, Goddard had a good working relationship with RMI, according to historian Frank H. Winter.

The Navy had Goddard build a pump system for Caltech's use with acid-aniline propellants. The team built a 3000-lb thrust engine using a cluster of four 750-lb thrust motors. They also developed 750-lb engines for the Navy's Gorgon guided interceptor missile (experimental Project Gorgon). Goddard continued to develop the variable-thrust engine with gasoline and lox because of the hazards involved with the hypergolics.

Despite Goddard's efforts to convince the Navy that liquid-fueled rockets had greater potential, he said that the Navy had no interest in long-range missiles. However, the Navy asked him to perfect the throttleable JATO engine. Goddard made improvements to the engine, and in November it was demonstrated to the Navy and some officials from Washington. Fischer invited the spectators to operate the controls; the engine blasted out over the Severn at full throttle with no hesitation, idled, and roared again at various thrust levels. The test was perfect, exceeding the Navy's requirements. The unit was able to be stopped and restarted, and it produced a medium thrust of 600 pounds for 15 seconds and a full thrust of 1,000 pounds for over 15 seconds. A Navy Commander commented that "It was like being Thor, playing with thunderbolts." Goddard had produced the essential propulsion control system of the rocket plane. The Goddards celebrated by attending the Army-Navy football game and attending the Fischers' cocktail party.

This engine was the basis of the Curtiss-Wright XLR25-CW-1 two-chamber, 15,000-pound variable-thrust engine that powered the Bell X-2 research rocket plane. After World War II, Goddard's team and some patents went to Curtiss-Wright Corporation. "Although his death in August 1945 prevented him from participating in the actual development of this engine, it was a direct descendent of his design." Clark University and the Guggenheim Foundation received the royalties from the use of the patents. In September 1956, the X-2 was the first plane to reach 126,000 feet altitude and in its last flight exceeded Mach 3 (3.2) before losing control and crashing. The X-2 program advanced technology in areas such as steel alloys and aerodynamics at high Mach numbers.

V-2

Don't you know about your own rocket pioneer? Dr. Goddard was ahead of us all.

Wernher von Braun, when asked about his work, following World War II

In the spring of 1945, Goddard saw a captured German V-2 ballistic missile, in the naval laboratory in Annapolis, Maryland, where he had been working under contract. The unlaunched rocket had been captured by the US Army from the Mittelwerk factory in the Harz mountains and samples began to be shipped by Special Mission V-2 on 22 May 1945.

After a thorough inspection, Goddard was convinced that the Germans had "stolen" his work. Though the design details were not exactly the same, the basic design of the V-2 was similar to one of Goddard's rockets. The V-2, however, was technically far more advanced than the most successful of the rockets designed and tested by Goddard. The Peenemünde rocket group led by Wernher von Braun may have benefited from the pre-1939 contacts to a limited extent, but had also started from the work of their own space pioneer, Hermann Oberth; they also had the benefit of intensive state funding, large-scale production facilities (using slave labor), and repeated flight-testing that allowed them to refine their designs. Oberth was a theorist and had never built a rocket, but he tested small liquid propellant thrust chambers in 1929-30 which were not advancements in the "state of the art." In 1922 Oberth asked Goddard for a copy of his 1919 paper and was sent one.

Nevertheless, in 1963, von Braun, reflecting on the history of rocketry, said of Goddard: "His rockets ... may have been rather crude by present-day standards, but they blazed the trail and incorporated many features used in our most modern rockets and space vehicles". He once recalled that "Goddard's experiments in liquid fuel saved us years of work, and enabled us to perfect the V-2 years before it would have been possible." After World War II von Braun reviewed Goddard's patents and believed they contained enough technical information to build a large missile.

Three features developed by Goddard appeared in the V-2: (1) turbopumps were used to inject fuel into the combustion chamber; (2) gyroscopically controlled vanes in the nozzle stabilized the rocket until external vanes in the air could do so; and (3) excess alcohol was fed in around the combustion chamber walls, so that a blanket of evaporating gas protected the engine walls from the combustion heat. 

The Germans had been watching Goddard's progress before the war and became convinced that large, liquid fuel rockets were feasible. General Walter Dornberger, head of the V-2 project, used the idea that they were in a race with the U.S. and that Goddard had "disappeared" (to work with the Navy) as a way to persuade Hitler to raise the priority of the V-2.

Goddard's secrecy

Goddard avoided sharing details of his work with other scientists and preferred to work alone with his technicians. Frank Malina, who was then studying rocketry at the California Institute of Technology, visited Goddard in August 1936. Goddard hesitated to discuss any of his research, other than that which had already been published in Liquid-Propellant Rocket Development. Theodore von Kármán, Malina's mentor at the time, was unhappy with Goddard's attitude and later wrote, "Naturally we at Caltech wanted as much information as we could get from Goddard for our mutual benefit. But Goddard believed in secrecy. ... The trouble with secrecy is that one can easily go in the wrong direction and never know it." However, at an earlier point, von Kármán said that Malina was "highly enthusiastic" after his visit and that Caltech made changes to their liquid-propellant rocket, based on Goddard's work and patents. Malina remembered his visit as friendly and that he saw all but a few components in Goddard's shop.

Goddard's concerns about secrecy led to criticism for failure to cooperate with other scientists and engineers. His approach at that time was that independent development of his ideas without interference would bring quicker results even though he received less technical support. George Sutton, who became a rocket scientist working with von Braun's team in the late 1940s, said that he and his fellow workers had not heard of Goddard or his contributions and that they would have saved time if they had known the details of his work. Sutton admits that it may have been their fault for not looking for Goddard's patents and depending on the German team for knowledge and guidance; he wrote that information about the patents was not well distributed in the U.S. at that early period after World War II, though Germany and the Soviet Union had copies of some of them. (The Patent Office did not release rocket patents during World War II.) However, the Aerojet Engineering Corporation, an offshoot of the Guggenheim Aeronautical Laboratory at Caltech (GALCIT), filed two patent applications in Sep 1943 referencing Goddard's U.S. Patent 1,102,653 for the multistage rocket.

By 1939, von Kármán's GALCIT had received Army Air Corps funding to develop rockets to assist in aircraft take-off. Goddard learned of this in 1940, and openly expressed his displeasure at not being considered. Malina could not understand why the Army did not arrange for an exchange of information between Goddard and Caltech since both were under government contract at the same time. Goddard did not think he could be of that much help to Caltech because they were designing rocket engines mainly with solid fuel, while he was using liquid fuel.

Goddard was concerned with avoiding the public criticism and ridicule he had faced in the 1920s, which he believed had harmed his professional reputation. He also lacked interest in discussions with people who had less understanding of rocketry than he did, feeling that his time was extremely constrained. Goddard's health was frequently poor, as a result of his earlier bout of tuberculosis, and he was uncertain about how long he had to live He felt, therefore, that he hadn't the time to spare arguing with other scientists and the press about his new field of research, or helping all the amateur rocketeers who wrote to him. In 1932 Goddard wrote to H. G. Wells:

How many more years I shall be able to work on the problem, I do not know; I hope, as long as I live. There can be no thought of finishing, for "aiming at the stars", both literally and figuratively, is a problem to occupy generations, so that no matter how much progress one makes, there is always the thrill of just beginning.

Goddard spoke to professional groups, published articles and papers and patented his ideas; but while he discussed basic principles, he was unwilling to reveal the details of his designs until he had flown rockets to high altitudes and thus proven his theory. He tended to avoid any mention of space flight, and spoke only of high-altitude research, since he believed that other scientists regarded the subject as unscientific. GALCIT saw Goddard's publicity problems and that the word "rocket" was "of such bad repute" that they used the word "jet" in the name of JPL and the related Aerojet Engineering Corporation.

Many authors writing about Goddard mention his secrecy, but neglect the reasons for it. Some reasons have been noted above. Much of his work was for the military and was classified. There were some in the U.S. before World War II that called for long-range rockets, and in 1939 Major James Randolph wrote a "provocative article" advocating a 3000-mile range missile. Goddard was "annoyed" by the unclassified paper as he thought the subject of weapons should be "discussed in strict secrecy."

However, Goddard's tendency to secrecy was not absolute, nor was he totally uncooperative. In 1945 GALCIT was building the WAC Corporal for the Army. But in 1942 they were having trouble with their liquid propellant rocket engine's performance (timely, smooth ignition and explosions). Frank Malina went to Annapolis in February and consulted with Goddard and Stiff, and they arrived at a solution to the problem (hypergolic propellant), which resulted in the successful launch of the high-altitude research rocket in October 1945.

During the First and Second World Wars, Goddard offered his services, patents, and technology to the military, and made some significant contributions. Just before the Second World War several young Army officers and a few higher-ranking ones believed Goddard's research was important but were unable to generate funds for his work.

Toward the end of his life, Goddard, realizing he was no longer going to be able to make significant progress alone in his field, joined the American Rocket Society and became a director. He made plans to work in the budding US aerospace industry (with Curtiss-Wright), taking most of his team with him.

Personal life

On June 21, 1924, Goddard married Esther Christine Kisk (March 31, 1901 – June 4, 1982), a secretary in Clark University's President's office, whom he had met in 1919. She became enthusiastic about rocketry and photographed some of his work as well as aided him in his experiments and paperwork, including accounting. They enjoyed going to the movies in Roswell and participated in community organizations such as the Rotary and the Woman's Club. He painted the New Mexican scenery, sometimes with the artist Peter Hurd, and played the piano. She played bridge, while he read. Esther said Robert participated in the community and readily accepted invitations to speak to church and service groups. The couple did not have children. After his death, she sorted out Goddard's papers, and secured 131 additional patents on his work.

Concerning Goddard's religious views, he was raised as an Episcopalian, though he was not outwardly religious. The Goddards were associated with the Episcopal church in Roswell, and he attended occasionally. He once spoke to a young people's group on the relationship of science and religion.

Goddard's serious bout with tuberculosis weakened his lungs, affecting his ability to work, and was one reason he liked to work alone, in order to avoid argument and confrontation with others and use his time fruitfully. He labored with the prospect of a shorter than average life span. After arriving in Roswell, Goddard applied for life insurance, but when the company doctor examined him he said that Goddard belonged in a bed in Switzerland (where he could get the best care). Goddard's health began to deteriorate further after moving to the humid climate of Maryland to work for the Navy. He was diagnosed with throat cancer in 1945. He continued to work, able to speak only in a whisper until surgery was required, and he died in August of that year in Baltimore, Maryland. He was buried in Hope Cemetery in his home town of Worcester, Massachusetts.

Legacy

Influence

Asiacentrism

From Wikipedia, the free encyclopedia

Asiacentrism (also Asiacentricity) is an ethnocentric and economic perspective that regards Asia to be either superior, central, or unique relative to other regions. This ideological stance may take the form of ascribing to Asia significance or supremacy at the cost of the rest of the world. The concept arose in the context of a projected Asian Century, the expected economic and cultural dominance of Asia (primarily China) in the 21st century, in the 1990s.

In 1902, Chinese scholar Liang Qichao remarked that Asia is "immeasurably vast and mighty", compared to a "shallow and small" Europe, as he predicted Asia to regain a powerful position in the world.

Some commentators have cited the effective response to the COVID-19 pandemic in Asia as a sign of superiority of Asia. Indian commentator Parag Khanna and UK politician David Howell noted that Asian societies evolved to technocratic governments which would be better at problem solving and provide more stability.

Economic

The World's Economic Centre of Gravity 1980-2050.

It is projected that the world's economic center of gravity will move back to Asia, between India and China by 2050, spurred by the economic growth of East Asian economies. Historically, the economic center of gravity is estimated to have been in what is nowadays northern Pakistan in the 11th century, having moved west until the 1980s.

The combined GDP of Asia is also projected to surpass that of the rest of the world around 2020, a position which the continent had lost in the 19th century.

Asian American studies

Paul Wong, Meera Manvi, and Takeo Hirota Wong proposed "Asiacentrism" in the 1995 special issue of Amerasia Journal on "Thinking Theory in Asian American Studies." They envisioned Asiacentrism both as a critique of hegemonic Eurocentrism in theory building in the humanities and social sciences and as a post-Orientalist epistemological paradigm in Asian American Studies. There is a need to tap into Asian traditions of thought for analyzing Asian American behaviors and for advancing global knowledge in the human interest. The objective is to explore a common core of Asian worldviews and values that overlap in their influence on particular regions, nations, and communities. In their view, Asiacentrism may be able to offer an alternative Asian perspective grounded in an awareness of the dynamics of a postcolonial world.

It is possible to argue that Asian American Studies has, since its inception, permitted itself to be conceptually incarcerated in a hegemonic Eurocentric culture and world view. Not only is the English language serving as the lingua franca of Asian American Studies, but it is easily evident that many scholars in Asian American Studies do not regard the acquisition of at least one Asian language, as a second language, an important part of their training, thereby curtailing their communicative and research competence with the majority of Asian Americans, whose primary language is not English. While much scholarship has been devoted to "... present voices from our (Asian American) past which were never silent, but often ignored, minimalized, and marginalized by traditional historical accounts of the United States," there has been no serious attempt to contextualize this scholarship in what may be termed the "deep structure" of a shared Asiacentric perspective.

Wong, Manvi, and Wong also submitted that Asiacentrism can be a paradigmatic way of integrating Asian American Studies and Asian Studies by acknowledging the colonial histories, recognizing the common interests, and recovering the cultural roots. They stressed that Asian American Studies should play an important role in decolonizing Asian Studies by interrogating its Eurocentric legacies.

Scholars committed to the development of an Asiacentric paradigm face a challenge no less daunting than the Afrocentrists. The Euro-American colonial history in Asia has obviously left a deep imprint on Asian Studies Scholarship…. In theorizing about Asian cultures and societies, the Eurocentric view has only been subjected to serious critiques in recent decades. By proposing the development of an Asiacentric perspective, we are consciously suggesting that Asian American Studies also has a role to play in a field of Asian Studies stripped of its colonial legacy. Interestingly, the Pan-Africanists have always recognized the common interests and the unity of African American Studies and African Studies in decolonization and the recovery of roots.

Communication studies

Yoshitaka Miike, Professor of Intercultural Communication at the University of Hawaii at Hilo and Past Chair of the International and Intercultural Communication Division of the National Communication Association, is considered as the founding theorist of Asiacentricity in the discipline of communication. He was inspired by Molefi Kete Asante, who is one of the early pioneers in the fields of intercultural and interracial communication. Asante's Afrocentric idea as well as Wong, Manvi, and Wong's Asiacentric reflection led Miike to coin the term Asiacentricity and outline an Asiacentric project in culture and communication studies in 2003. He was later influenced by Maulana Karenga’s Kawaida philosophy, which emphasizes the role of culture for self-understanding and self-assertion and the importance of ethics for human freedom and flourishing.

Miike defined Asiacentricity as "the self-conscious act of centering Asian languages, religions/philosophies, histories, and aesthetics when addressing Asian people and phenomena." According to him, Asiacentricity "insists on revivifying and revitalizing diverse Asian cultural traditions as theoretical resources in order to capture Asians as subjects and actors of their own cultural realities rather than objects and spectators in the lived experiences of others."

Simply put, Asiacentricity is the idea of centering, not marginalizing, Asian languages, religions/philosophies, and histories in theory-making and storytelling about Asian communicative life. Asiacentricity aims to encourage careful and critical engagements of Asian communicators with their own cultural traditions for self-understanding, self-expression, communal development, and cross-cultural dialogue. Intraculturally, it helps Asians embrace the positive elements of their cultural heritage and transform negative practices according to their ethical ideals. Interculturally, it helps Asians find "a place to stand," so to speak, and provides the basis of equality and mutuality in the global community.

Borrowing from Daisetz Suzuki's words, Miike stated that Asiacentricity is essentially "the idea of being deep and open," that is, the idea of being rooted in our own culture and, at the same time, open to other cultures. He differentiated Asiacentricity as a particularist position from Asiacentrism as a universalist ideology and maintained that Asiacentricity is a legitimate culture-centric approach to cultural Asia and people of Asian descent, while Asiacentrism is an ethnocentric approach to non-Asian worlds and people of non-Asian heritage. In Miike's conceptualization, therefore, Asiacentrists are not cultural chauvinists and separatists.

Asiacentricity is neither a hegemonic Asiacentrism nor an Asian version of ethnocentric Eurocentrism. Asiacentricity does not present the Asian worldview as the only universal frame of reference and impose it on non-Asians. Hence, Asiacentrists should be alert to Park's (2001) warning: "An idea is not good merely because it is old or because it is new. It is not necessarily good because it is an Eastern idea or a Western idea, or just because it is ours" (p. 8). Asiacentrists thus should not deny the value of other non-Asiacentric perspectives on Asians. Nevertheless, they must reject the hegemonic ideology that non-Asiacentric theoretical standpoints are superior to Asiacentric ones and therefore can grossly neglect the latter in the discussion and discourse surrounding Asian people and phenomena. They must reject the hegemonic ideology that the Asian version of humanity can be judged solely from the Eurocentric vision of humanity.

Miike identified six dimensions of Asiacentricity: (1) an assertion of Asians as subjects and agents; (2) the centrality of the collective and humanistic interests of Asia and Asians in the process of knowledge reconstruction about the Asian world; (3) the placement of Asian cultural values and ideals at the center of inquiry into Asian thought and action; (4) the groundedness in Asian historical experiences; (5) an Asian theoretical orientation to data; and (6) an Asian ethical critique and corrective of the dislocation and displacement of Asian people and phenomena.

In Miike's comprehensive outline, Asiacentricity (1) generates theoretical knowledge that corresponds to Asian communication discourse, (2) focuses on the multiplicity and complexity of Asian communicative experience, (3) reflexively constitutes and critically transforms Asian communication discourse, (4) theorizes how common aspects of humanity are expressed and understood in Asian cultural particularities, and (5) critiques Eurocentric biases in theory and research and helps Asian researchers overcome academic dependency.

Miike's contention is that there has been the established hierarchical relationship between "Western theories" and "non-Western texts" in Eurocentric scholarship, where non-Western cultures remain as peripheral targets of data analysis and rhetorical criticism and fail to emerge as central resources of theoretical insight and humanistic inspiration. Miike thus insisted that Asiacentric scholarship reconsider Asian cultures as "theories for knowledge reconstruction," not as "texts for knowledge deconstruction." Such an Asiacentric approach, according to him, would make it possible for both Asian and non-Asian researchers to theorize as Asians speak in Asian languages, as Asians are influenced by Asian religious-philosophical worldviews, as Asians struggle to live in Asian historical experiences, and as Asians feel ethically good and aesthetically beautiful.

For the purpose of elucidating the psychology of Asian communicators and enunciating the dynamics of Asian communication, therefore, Asiacentrists ought to revalorize (a) Asian words as key concepts and their etymologies as cultural outlooks and instructive insights, (b) Asian religious-philosophical teachings as behavioral principles and codes of ethics, (c) Asian histories as multiple layers of contextualization and recurrent patterns of continuity and change, and (d) Asian aesthetics as analytical frameworks for space-time arrangement, nonverbal performance, and emotional pleasure.

Miike also synthesized a large body of literature in the field of Asian communication theory while paying homage to such pioneers as Anantha Babbili, Guo-Ming Chen, Godwin C. Chu, Wimal Dissanayake, D. Shelton A. Gunaratne, Satoshi Ishii, Young Yun Kim, D. Lawrence Kincaid, Hamid Mowlana, Louis Nordstrom, Robert T. Oliver, Tulsi B. Saral, Robert Shuter, K. S. Sitaram, William J. Starosta, Majid Tehranian, Muneo Yoshikawa, and June Ock Yum. He urged Asiacentric research to overcome "comparative Eurocentrism" and direct more attention to common insights gained from non-Eurocentric comparisons. In his opinion, five types of alternative non-Eurocentric comparisons can enlarge the theoretical horizons of Asian communication research: (1) continent-diaspora comparisons; (2) within-region comparisons; (3) between-region comparisons; (4) diachronic comparisons; and (5) co-cultural domestic comparisons.

Asiacentric studies of South Asia, Southeast Asia, and West Asia are underrepresented in the current literature. These regions are at the crossroads of Asian civilizations, offering rich historical insights into Asian intercultural exchanges and multicultural co-existence. Future theorizing and research on South Asia, Southeast Asia, and West Asia from Asiacentric vantage points will not only enhance an understanding of cultural dynamics in these areas but also enunciate Asian models of intercultural dialogue and multicultural society.

Cool Japan

From Wikipedia, the free encyclopedia
 
 Cool Japan (クールジャパン, Kūru Japan) is a term used by the Japanese government with the support of Japanese trade bodies seeking to expand its culture industry.

It is seen as a soft power strategy by the government to expand the country's pop culture to markets across the globe and improve Japan's image. It is also discreetly used as a means to forget Japan's historical actions during World War II after its surrender.

Origins

Starting in 1980, following the emergence of the Japanese Ministry of Foreign Affairs (MOFA), Japan began to increase its nation branding efforts through the release of a television series titled Oshin, a Japanese soap opera. Oshin was distributed at no cost outside of Japan, and was well-received in 46 countries. Through the success of Oshin and multiple other television shows, Japan successfully established the idea of "Cool Japan" as a method of establishing and improving the country's cultural perception.

In a 2002 article in Foreign Policy titled "Japan's Gross National Cool", Douglas McGray wrote of Japan "reinventing superpower" as its cultural influence expanded internationally, despite the economic and political problems of the "lost decade". Surveying youth culture and the role of J-pop, manga, anime, video games, fashion, film, consumer electronics, architecture, cuisine, and phenomena of kawaii ("cuteness") such as Hello Kitty, McGray highlighted Japan's considerable cultural soft power, posing the question of what message the country might project. He also argued that Japan's recession may even have boosted its national cool, due to the partial discrediting of erstwhile rigid social hierarchies and big-business career paths.

Adoption

Taken up in the international media, with The New York Times running a retrospect "Year in Ideas: Pokémon Hegemon", an increasing number of more reform-minded government officials and business leaders in Japan began to refer to the country's "gross national cool" and to adopt the unofficial slogan "Cool Japan". In a 2005 press conference, the Ministry of Foreign Affairs linked the idea to Bhutan's concept of Gross National Happiness.

The phrase gained greater exposure in the mid-noughties as NHK began a series entitled Cool Japan Hakkutsu: Kakkoii Nippon!, which by the end of 2009 had reached over 100 episodes. Academic initiatives include the establishment of a "Cool Japan" research project at the Massachusetts Institute of Technology, while some western universities have reported an increase in the number of applicants for Japanese Studies courses due to the "cool" effect.

The adoption of Cool Japan has also spurred changes in culture studies. As a result of the fascination of Cool Japan with Japanese youth culture and schoolgirls, a new wave of studies called 'girl studies' focuses specifically on the experience of girls and the girls-at-heart. Previously a subject of adolescent psychology or feminism, girl studies emerged from Cool Japan to include an interdisciplinary analysis of girl culture.

Creative Industries Promotion Office

The Japanese government has identified the culture industry as one of five potential areas of growth. In June 2010, the Ministry of Economy, Trade and Industry established a new Creative Industries Promotion Office to promote cultural and creative industries as a strategic sector "under the single, long term concept of "Cool Japan", to coordinate different government functions, and to cooperate with the private sector". The Ministry of Economy, Trade and Industry announced that Japanese pop culture is one of the key elements for Cool Japan and that pop culture includes idol, anime, and B class gourmet (B級グルメ).

The deputy director described its mission as to "brand Japanese products with the uniqueness of Japanese culture", with a budget of ¥19 billion for 2011 alone. In the fiscal year 2008, public spending on cultural activities was ¥116.9 billion in South Korea, ¥477.5 billion in China, and ¥101.8 billion in Japan, forming 0.79%, 0.51%, and 0.12% of total government spending respectively. The fund was launched in 2013, and the Japanese government committed to the Cool Japan Fund ¥50 billion ($500 million) over 20 years, with a target of ¥60 billion ($600 million) via private investor partnerships. However, Nikkei Asian Review reported that within five years the fund "suffered pretax losses totaling 10 billion yen ($88.9 million)", and that many projects failed to deliver earnings. Since June 2018, the management has been led by former Sony Music Entertainment (Japan) CEO Naoki Kitagawa.

Timeline of notable endeavors

  • 2013
  • 2014
    • Traditional Japanese crafts showcased at Maison & Objet, the world's largest trade fair for interior goods and designs, to promote Japan's monodzukuri (manufacturing) culture.
    • WakuWaku Japan, Japanese satellite television channel that broadcasts Japanese programs to overseas viewers in Asia. It was a joint venture with broadcaster Sky Perfect JSAT who contributed ¥6.6 billion out of ¥11 billion, but failed to expand in multiple markets and generate viewership, with nearly ¥4 billion losses until 2017.
  • 2015
    • METI starts Nippon Quest, a website to showcase and disseminate unknown Japanese regional specialties to the world.
    • US cafes focused on Japanese tea, on which was spent ¥250 million for nearly 50% stake.
    • Funding of the development of content creators for anime and manga outside Japan by KADOKAWA Contents Academy Co., Ltd.
  • 2016
    • Isetan the Japan Store, a joint venture with Isetan to make a five-floor department store in Kuala Lumpur, Malaysia, to promote Japanese goods and services. However, lack of demand resulted with a loss of circa $4.5 million, and all Cool Japan Fund shares sold to Isetan Mitsukoshi Holdings.
  • 2018
    • The first investment with new management was $12.5 million in Tastemade, becoming a minority shareholder, to support making of content promoting Japanese food and destinations.
  • 2019
    • Cool Japan Fund invests US$30 million in American anime licensing company Sentai Holdings, aiming to provide support at the copyright level, and increasing the presence of anime in North America.

Criticism

A 2010 editorial in the Yomiuri Shimbun argued that the government was not doing enough to advance the country's business interests in this sphere, allowing South Korea to emerge as a competitor. The editorial highlighted structural inefficiencies, with the Ministry of Economy, Trade and Industry promoting "Cool Japan", the Ministry of Foreign Affairs responsible for cultural exchange, and the Ministry of Agriculture, Forestry and Fisheries in charge of Japanese foods. Lecturer Roland Kelts has also suggested that a failure to fully distinguish, brand and engage the overseas audience and market may mean that "Cool Japan" is "over". In 2011, Laura Miller has critiqued Cool Japan campaign as exploiting and misrepresenting youth subcultural fashion and language. In 2013, Nancy Snow referred to Cool Japan as a form of state-sponsored cultural retreading she calls Gross National Propaganda. Japanese singer-songwriter Gackt criticized the government in 2015 for having set up a huge budget, yet "have no idea where that money should go. It's no exaggeration to say it has fallen into a downward spiral of wasted tax money flowing into little known companies", and that such lack of support is causing Japan to "fall behind its Asian neighbors in terms of cultural exports". In 2016, Benjamin Boas pointed out that Cool Japan-branded efforts are often promoted without participation of foreigners, leaving out the perspectives of the very foreigners that they are trying to target.

In 2017, a senior executive and several other senior male employees of Cool Japan Fund Inc. were accused of sexual harassment targeting female employees of the fund. The employees formed a labor union in order to fight against sexual harassment. In the same year, Nikkei Asian Review journalist Yuta Saito criticized fund's ambitions because their "lack of strategy, discipline gives rise to unprofitable projects", and there's possible conflict of interest by the executives. In 2018, Japan Today reported that it was too soon to consider it "grossly incompetent or corrupt", but was at least "under-performing" for now.

Asian Century

From Wikipedia, the free encyclopedia
 
China and India have the two largest populations in the world, and are expected to grow rapidly economically.

The Asian Century is the projected 21st-century dominance of Asian politics and culture, assuming certain demographic and economic trends persist. The concept of Asian Century parallels the characterisation of the 19th century as Britain's Imperial Century, and the 20th century as the American Century.

A 2011 study by the Asian Development Bank found that 3 billion Asians could enjoy living standards similar to those in Europe today, and the region could account for over half of global output by the middle of this century. It warned, however, that the Asian Century is not preordained.

The growing importance and emphasis of unity in Asia, as well as maturing and progressive relationships among countries in the region further solidify the creation of the 21st Asian Century.

Origin

In 1924, Karl Haushofer used the term "Pacific age," envisaging the growth of Japan, China and India: "A giant space is expanding before our eyes with forces pouring into it which ... await the dawn of the Pacific age, the successor of the Atlantic age, the over-age Mediterranean and European era." The phrase Asian Century arose in the mid to late 1980s, and is attributed to a 1988 meeting with People's Republic of China (PRC) leader Deng Xiaoping and Indian Prime Minister Rajiv Gandhi in which Deng said that '[i]n recent years people have been saying that the next century will be the century of Asia and the Pacific, as if that were sure to be the case. I disagree with this view.' Prior to this, it made an appearance in a 1985 US Senate Committee on Foreign Relations hearing. It has been subsequently reaffirmed by Asian political leaders, and is now a popularly used term in the media.

Reasons

Asia's robust economic performance over the three decades preceding 2010, compared to that in the rest of the world, made perhaps the strongest case yet for the possibility of an Asian Century. Although this difference in economic performance had been recognised for some time, specific individual setbacks (e.g., the 1997 Asian financial crisis) tended to hide the broad sweep and general tendency. By the early 21st century, however, a strong case could be made that this stronger Asian performance was not just sustainable but held a force and magnitude that could significantly alter the distribution of power on the planet. Coming in its wake, global leadership in a range of significant areas—international diplomacy, military strength, technology, and soft power—might also, as a consequence, be assumed by one or more of Asia's nation states.

Among many scholars have provided factors that have contributed to the significant Asian development, Kishore Mahbubani provides seven pillars that rendered the Asian countries to excel and provided themselves with the possibility to become compatible with the Western counterparts. The seven pillars include: free-market economics, science and technology, meritocracy, pragmatism, culture of peace, rule of law and education.

Professor John West in his book 'Asian Century … on a Knife-edge' argues:

"Over the course of the twenty-first century, India could well emerge as Asia’s leading power. Already, India’s economy is growing faster than China’s, a trend which could continue, unless China gets serious about economic reform. Further, India’s population will overtake China’s in 2022 and could be some 50% higher by 2100, according to the UN".

In 2019 professor Chris Ogden, a Lecturer in Asian Security at the University of St Andrews, wrote that, "Although still behind relatively in terms of income per capita and infrastructure, as this wealth is translated into military, political, and institutional influence (via bodies such as the United Nations and the new Asian Infrastructure Investment Bank), Asia’s two largest powers will gain a structural centrality and importance that will make them critical global lynchpins. Expectant populations and vocal leaders are accelerating and underpinning this criticality, and—if the existential issues of environmental pollution and corruption can be overcome—herald the emergence of an Asian-centric, and China / India-centric, world order that will form of the essential basis of international affairs for many decades to come."

Demographics

Population growth in Asia is expected to continue through at least the first half of the 21st century, though it has slowed significantly since the late 20th century. At four billion people in the beginning of the 21st century, the Asian population is predicted to grow to more than five billion by 2050. While its percent of the world population is not expected to greatly change, North American and European shares of the global population are expected to decline.

Economics

The global contribution to world's GDP by major economies from 1 AD to 2003 AD according to Angus Maddison's estimates. Before 18th century, China and India were the two largest economies by GDP output.

Projected GDP of 7 largest economies in 2050.
 
Projected shares of global GDP by region to 2050
 
One of the busiest shopping streets in the world, Nanjing Road in Shanghai is an example of economic growth in mainland China, and its large consumer base.
 
India's middle-class population of 300 million is growing at an annual rate of 5%. Shown here is an upmarket area in South Mumbai.

The major driver is continued productivity growth in Asia, particularly in China and India, as living standards rise. Even without completely converging with European or North American living standards, Asia might produce half of the global GDP by 2050. This is a large shift compared to the immediate post-cold war, when North America and Europe combined produced half of the global GDP. A 2011 study by the Asian Development Bank stated that: "By nearly doubling its share of global gross domestic product (GDP) to 52 percent by 2050, Asia would regain the dominant economic position it held some 300 years ago.

The notion of the Asian Century assumes that Asian economies can maintain their momentum for another 40 years, adapt to shifting global economic and technological environment, and continually recreate comparative advantages. In this scenario, according to 2011 modelling by the Asian Development Bank Asia's GDP would increase from $17 trillion in 2010 to $174 trillion in 2050, or half of global GDP. In the same study, the Asian Development Bank estimates that seven economies would lead Asia's powerhouse growth; under the Asian Century scenario, the region would have no poor countries, compared with eight in 2011.

Since China's economic reforms in the late 1970s (in farm privatisation) and early 1990s (in most cities), the Chinese economy has enjoyed three decades of economic growth rates between 8 and 10%. The Indian economy began a similar albeit slower ascent at the end of the 1980s and early 1990s, and has averaged around 4% during this period, though growing slightly over 8% in 2005, and hitting 9.2% in 2006 before slowing to 6% in 2009, then reaching 8.9% in 2010.

Both of these developments involved policy of a degree of managed liberalisation of the economy as well as a turning outwards of the economy towards globalisation (both exports and attracting inward investment). The magnitude of this liberalisation and globalisation is still subject to debate. They were part of conscious decisions by key political leaders, especially in India and the PRC. Also, the populations of the two countries offer a potential market of over two and a quarter billion. The development of the internal consumer market in these two countries has been a major basis for economic development. This has enabled much higher national growth rates for China and India in comparison to Japan, the EU and even the US. The international cost advantage on goods and services, based on cheaper labor costs, has enabled these two countries to exert a global competitive pressure.

The term Easternization has been used to refer to the spread of oriental (mainly Japanese) management techniques to the West.

The trend for greater Asian economic dominance has also been based on the extrapolations of recent historic economic trends. Goldman Sachs, in its BRIC economic forecast, highlighted the trend towards mainland China becoming the largest and India the second largest economies by the year 2050 in terms of GDP. The report also predicted the type of industry that each nation would dominate, leading some to deem mainland China 'the industrial workshop of the world' and India 'one of the great service societies'. As of 2009, the majority of the countries that are considered newly industrialized are in Asia.

By 2050, the East Asian and South Asian economies will have increased by over 20 times. With that comes a rise in Human Development Index, the index used to measure the standards of living. India's HDI will approach .8. East Asia's would approach .94 or fairly close to the living standards of the western nations such as the EU and the US. This would mean that it would be rather difficult to determine the difference in wealth of the two. Because of East Asian and Indian populations, their economy would be very large, and if current trends continue, India's long-term population could approach double that of China. East Asia could surpass all western nations' combined economies as early as 2030. South Asia could soon follow if the hundreds of millions in poverty continue to be lifted into middle class.

Construction projects

The Taipei 101 skyscraper in Taipei, Taiwan, which was the tallest building in the world from 2004 to 2010.

It is projected that the most groundbreaking construction projects will take place in Asia within the approaching years. As a symbol of economic power, supertall skyscrapers have been erected in Asia, and more projects are currently being conceived and begun in Asia than in any other region of the world. Completed projects include: the Petronas Towers of Kuala Lumpur, the Shanghai World Financial Center, International Finance Centre in Hong Kong, Taipei 101 in Taiwan, the Burj Khalifa in Dubai, UAE, and the Shanghai Tower. Future buildings promise to be taller, such as the PNB 118 in Kuala Lumpur and Legacy Tower in Dhaka.

Culture

Culturally, the Asian century is symbolised by Indian genre films (Bollywood, Parallel Cinema), Hong Kong genre films (martial arts films, Hong Kong action cinema), Japanese animation, and the Korean Wave. The awareness of Asian cultures may be a part of a much more culturally aware world, as proposed in the Clash of Civilizations thesis. Equally, the affirmation of Asian cultures affects the identity politics of Asians in Asia and outside in the Asian diasporas.

The Gross National Cool of Japan is soaring; Japanese cultural products, including TV shows, are undoubtedly "in" among American audiences and have been for years. About 2.3 million people studied the language worldwide in 2003: 900,000 South Koreans, 389,000 Chinese, 381,000 Australians, and 140,000 Americans study Japanese in lower and higher educational institutions.

Feng shui books topped the nonfiction best-seller lists and feng shui schools have multiplied. Major banks and multinational corporations employ feng shui consultants to advise them on the organisation of their offices. There has been a readiness to supplement Eastern forms of medicine, therapy, and massage and reject traditional Western medicine in favor of techniques, such as acupressure and acupuncture. Practices such as moxibustion and shiatsu enjoy enormous popularity in the West. So do virtually all the Eastern martial arts, such as kung fu, judo, karate, aikido, taekwondo, kendo, jujitsu, tai chi, qigong, ba gua, and xing yi, with their many associated schools and subforms.

Asian cuisine is quite popular in the West due to Asian immigration and subsequent interest from non-Asians into Asian ingredients and food. Even small towns in Britain, Canada, Scandinavia, or the United States generally have at least one Indian or Chinese restaurant. Restaurants serving pan-Asian and Asian-inspired cuisine have also opened across North America, Australia and other parts of the world. P.F. Chang's China Bistro and Pei Wei Asian Diner which serve Asian and Asian-inspired food is found across the United States and in regards for the former, in other parts of the world as well. Asian-inspired food products have also been launched including from noodle brand, Maggi. In Australia, New Zealand, Ireland and the UK an Asian-inspired range of noodles known as Maggi Fusian and a long running range in Germany and Austria known as, Maggi Magic Asia includes a range of noodles inspired by food dishes found in China, Japan, Korea, India, Malaysia, Singapore, Indonesia and Thailand.

Yoga has gained popularity outside India and the rest of Asia and has entered mainstream culture in the Western world.

Though the use of English continues to spread, Asian languages are becoming more popular to teach and study outside the continent. The study of Chinese has recently gained greater attention in the United States, owing to a growing belief in the economic advantages of knowing it. It is being encouraged through the PRC's support of Confucius Institutes, which have opened in numerous nations to teach the Chinese language and culture.

Chinese has been rated as the second most used language on the internet with nearly a quarter speaking Chinese, Japanese came as fourth, and Korean as the tenth as of 2010. According to the CIA, China hosted the most users, India the third, Japan the sixth, and Indonesia as the tenth as of 2020.

India has the largest film industry in the world, and Indian Film Industry produces more films than Nollywood and Hollywood.

In the early years of the twentieth century very few people were vegetarians. The figure given for the United Kingdom during World War 2 was 100,000 out of a population of some 50 million – around 0.2 per cent of the total. By the 1990s the figure was estimated as between 4.2 percent and 11 percent of the British population and rising rapidly. As Porritt and Winner observe, as recently as the 1960s and early '70s, "being a vegetarian was considered distinctively odd," but "it is now both respectable and common place."

The spread of the Korean wave, particularly K-pop and Korean dramas, outside Asia has led to the establishment of services to sustain this demand. Viki and DramaFever are examples of services providing Korean dramas to international viewers alongside other Asian content. SBS PopAsia and Asian Pop Radio are two radio-related music services propagating the proliferation of K-pop throughout Australia. Apart from K-pop, Asian Pop Radio is also devoted to other Asian pop music originating from Indonesia, Thailand, Japan, Malaysia and Singapore. Similarly, SBS PopAsia focuses on other East Asian pop music from China and Japan and to some extent Southeast Asian pop music in conjunction with K-pop. The rising popularity of Asian-related content has resulted in "SBS PopAsia" becoming a brand name for SBS content such as TV shows and news originating from Asia such as China, South Korea, Japan and India.

The growing awareness and popularity of Eastern culture and philosophies in the West has led to Eastern cultural objects being sold in these countries. The most well known being statues of the Buddha which range from statues sold for the garden to items sold for the house. Statues of Hindu gods such as Ganesha and East Asian iconography such as the Yin and yang are also sold in many stores in Western countries. Ishka a chain store in Australia sells many Asian-origin content particularly from India. The selling of Eastern cultural objects has however been met by criticism, with some saying many who buy these items do not understand the significance of them and that it is a form of Orientalism.

Emojis which originated in Japan and later spread to other parts of Asia have now become mainstream in Western societies. Eastern emoticons particularly Japanese emoticons known as "kaomoji" have also become popular in the West in conjunction with Western-origin emoticons, resulting in a blend of the two. A 2006 study showed North American instant messaging users rated the importance of using emoticons much lower than Indian and East Asian users. However, by the 2010s, a 2013 questionnaire showed 74% of people in the US responded positively to the question, "Do you use stickers or emoji in messaging apps?” Characters used as emoticons that are used in certain Asian languages such as Kannada, an Indian language, has spread to and become popular to use on Western websites after initially being used on Japanese sites such as 2channel. Asian-origin characters that have become popular to use on Western websites include ಠ and ಥ (both of Kannada origin), ง (Thai origin), 益 (Chinese origin), ㅅ (Korean origin) and ヮ and ツ (both of Japanese origin), for example, which are all used with other symbols to create emoticons.

Religion

As recently as the 1950s, Crane Brinton, the distinguished historian of ideas, could dismiss "modern groups that appeal to Eastern wisdom" as being in effect "sectarian", "marginal", and "outside the main current of Western thought and feeling". Yet some Westerners have converted to Eastern religions or at least have shown an interest in them. An example is Maharishi Mahesh Yogi, whom the Beatles followed, first to Bangor in Wales in 1967, and subsequently to India to study Transcendental Meditation in 1968. The Dalai Lama, whose book The Art of Happiness became a best-seller, can attract huge crowds in New York's Central Park or London's Wembley Stadium.

Buddhism in some countries is the second biggest religion. FWBO is one of the biggest and fastest-growing Buddhist organisations in the West.

Belief in reincarnation has never been a part of official Christian or Jewish teaching, or at least, in Christianity, it has been a formal heresy since it was rejected by a narrow margin at the Second Council of Constantinople in AD 553. However nearly all polling in Western countries reveals significant levels of this belief. "Puzzled People" undertaken in the 1940s suggested that only 4 per cent of people in Britain believed in reincarnation. Geoffrey Gorer's survey, carried out a few years later, arrived at 5 percent (1955, p. 262). However, this figure had reached 18 percent by 1967 (Gallup, 1993), only to increase further to a sizable 29 percent by 1979, a good six-fold increase on the earlier "Puzzled People" figure. Eileen Barker has reported that around one-fifth of Europeans now say that they believe in reincarnation.

Karma, which has its roots in ancient India and is a key concept in Hinduism, Buddhism and other Eastern religions, has entered the cultural conscience of many in the Western world. John Lennon's 1970 single, "Instant Karma!" is credited towards the popularisation of karma in the Western world and is now a widely known and popular concept today giving rise to catchphrases and memes and figuring in other forms of Western popular culture.

Mindfulness and Buddhist meditation, both very popular in Asia, have gained mainstream popularity in the West.

Politics

The cargo of a container ship from East Asia being unloaded at the Jawaharlal Nehru Port in Navi Mumbai, India. Increasing economic integration of Asian countries has also brought them closer politically.

The global political position of China and to a lesser extent India has risen in international bodies and amongst the world powers, leading the United States and European Union to become more active in the process of engagement with these two countries. China is also a permanent member of the UN Security Council. Although India is not a permanent member, it is possible that it will become one or at the least gain a more influential position. Japan is also attempting to become a permanent member, though the attempts of both are opposed by other Asian countries (i.e. India's bid is opposed by Pakistan; Japan's bid is opposed by China, South Korea, North Korea).

An Asian regional bloc may be further developed in the 21st century around ASEAN and other bodies on the basis of free trade agreements. However, there is some political concern amongst the national leaderships of different Asian countries about PRC's hegemonic ambitions in the region. Another new organization, the East Asian Summit, could also possibly create an EU-like trade zone.

The Russian Prime Minister Yevgeny Primakov encouraged the idea of a triple alliance between Russia, the PRC and India first formulated by Indian strategist Madhav Das Nalapat in 1983, and supported the idea of a multipolar world. With the November 2006 visit of Hu Jintao to India, the idea seems to be gaining some momentum.

Human Capital

The 2007 World Bank Report on globalization notes that "rising education levels were also important, boosting Asian growth on average by 0.75 to 2 percentage points." The rapid expansion of human capital through quality education throughout Asia has played a significant role in experiencing "higher life expectancy and economic growth, and even to the quality of institutions and whether societies will make the transition into modern democracies".

3G (Global Growth Generators)

The Asian countries with the most promising growth prospects are: Bangladesh, China, India, Indonesia, Iraq, Mongolia, Philippines, Sri Lanka and Vietnam. Developing Asia is projected to be the fastest growing region until 2050, driven by population and income growth: 9 of 11 3G countries came from Asia. Vietnam has the highest Global Growth Generators Index, China is second with 0.81, followed by India's 0.71.

Based on a report from the HSBC Trade Confidence Index (TCI) and HSBC Trade Forecast, there are 4 countries with significant trade volume growth – Egypt, India, Vietnam and Indonesia – with growth is projected to reach at least 7.3 per cent per year until 2025.

Next Eleven

The Next Eleven (known also by the numeronym N-11) are the eleven countries – Bangladesh, Egypt, Indonesia, Iran, Mexico, Nigeria, Pakistan, Philippines, Turkey, South Korea, and Vietnam – identified by Goldman Sachs investment bank and economist Jim O'Neill in a research paper as having a high potential of becoming, along with the BRICs/BRICS, the world's largest economies in the 21st century. The bank chose these states, all with promising outlooks for investment and future growth, on 12 December 2005. At the end of 2011, the four major countries (Mexico, Indonesia, Nigeria and Turkey) also known as MINT, made up 73 percent of all Next Eleven GDP. BRIC GDP was $13.5 trillion, while MIKT GDP at almost 30 percent of that: $3.9 trillion.

Challenges to realising the Asian Century

Asia's growth is not guaranteed. Its leaders will have to manage multiple risks and challenges, particularly:

  • Growing inequality within countries, in which wealth and opportunities are confined to the upper echelons. This could undermine social cohesion and stability.
  • Many Asian countries like Pakistan will not be able to make the necessary investments in infrastructure, education and government policies that would help them avoid the Middle Income Trap.
  • Intense competition for finite natural resources, such as land, water, fuel or food, as newly affluent Asians aspire to higher standards of living.
  • Global warming and climate change, which could threaten agricultural production, coastal populations, and numerous major urban areas.
  • Geopolitical rivalry between China and India.
  • Rampant corruption, which plagues many Asian governments.
  • The direct impact of an aging population on continuous economic development (e.g. declining labour force, change of consumption patterns, strain on public finances)

Criticism

Despite forecasts that predict the rising economic and political strength of Asia, the idea of an Asian Century has faced criticism. This has included the possibility that the continuing high rate of growth could lead to revolution, economic slumps, and environmental problems, especially in mainland China.

Bayesian inference

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Bayesian_inference Bayesian inference ( / ...