Shockley won all these awards by the way:
- Nobel Prize in Physics (1956)
- Comstock Prize in Physics (1953)
- Oliver E. Buckley Condensed Matter Prize (1953)
- Wilheln Exner Medal (1963)
- IEEE Medal of Honor (1980)
I always thought Hewlett and Packard started Silicon Valley. However, I was watching
William Shockley on a PBS documentary and found "Silicon Valley: American experience"and found that actually William Shockley and a group of men all quit Beckman Labs one day and started Shockley Semiconductor and started the silicon chip revolution that now spans the world. The reason this could happen here is Stanford University which in the 1950s was THE pre-eminant University on the West Coast sort of like Harvard, Yale and all the other Ivy League institutions of the East Coast. Also, Stanford university even then was very much like MIT on the East Coast and now Cal Tech on the West Coast as well. From Cal Tech came Jet Propulsion Laboratory as well which excelled and still excels in Robotic Space ships with equipment landing on the moon and Mars as well as orbiting earth in space.
So, this happened only 9 years or so after Roswell in 1947. Also, you will notice that the first transistor was invented the same year as the Roswell UFO crash. I wonder how many centuries forward in progress this pushed the U.S. and world forward? It likely helped avoid a nuclear war that destroyed the whole planet by now. Colonel Corso of the DIA who worked with President Eisenhower said the government had him give people like "Shockley?" pieces of Roswell crash and had them reverse engineer them. He as an officer was told to tell the pioneers of electronics and chemistry that this was Soviet Technology and that they should reverse engineer it. They were never told where it really came from. So, the computer, Iphone, smartphone or Ipad or whatever you are watching this on has chips that evolved from being reverse engineered from the Roswell UFO Crash.
Later: I just found out from the documentary that Shockley actually was one of the inventors of the Transistor in 1947. So, he and his group At Bell Labs in New Jersey likely were given some of the first Roswell artifacts by the government in Washington D.C. You really had to be a physicist then to reverse engineer something like this so quickly like he obviously did then. LIkely no one in the U.S. had ever seen anything like this before. Being at the level of a Nobel Prize winner by 1956 and just look at all the other awards from 1953 on:
- Nobel Prize in Physics (1956)
- Comstock Prize in Physics (1953)
- Oliver E. Buckley Condensed Matter Prize (1953)
- Wilheln Exner Medal (1963)
- IEEE Medal of Honor (1980)
- The first high-frequency transistor was the surface-barrier germanium transistor developed by Philco in 1953, capable of operating up to 60 MHz. [16]
- The transistor, which permitted the first wave of electronic miniaturization, was invented by William Shockley, John Bardeen, and Walter Brattain in 1947.
- Like all good UFO stories, there is always the event that triggered the imagination. The Roswell story is no exception. Below is a brief synopsis of what took ...
- Roswell UFO incident; Roswell Daily Record, July 8, ... Charles Ziegler argued that the Roswell story has all the hallmarks of a traditional folk narrative.
From Wikipedia, the free encyclopedia
For other uses, see William Shockley (disambiguation).
William Shockley | |
---|---|
Born | William Bradford Shockley Jr. February 13, 1910 Greater London, England, United Kingdom |
Died | August 12, 1989 (aged 79) Stanford, California, United States |
Nationality | American |
Institutions | |
Alma mater | |
Doctoral advisor | John C. Slater |
Known for | |
Notable awards |
|
Shockley's attempts to commercialize a new transistor design in the 1950s and 1960s led to California's "Silicon Valley" becoming a hotbed of electronics innovation. In his later life, Shockley was a professor at Stanford and became a proponent of eugenics.[1][2]
Contents
Early life and education
Shockley was born in London, England, to American parents, and raised in his family's hometown of Palo Alto, California, from age three.[3] His father, William Hillman Shockley, was a mining engineer who speculated in mines for a living, and spoke eight languages. His mother, Mary (née Bradford), grew up in the American West, graduated from Stanford University, and became the first female US Deputy mining surveyor.[4]Shockley received his Bachelor of Science degree from Caltech in 1932. Shockley received his Ph.D. degree from MIT in 1936. The title of his doctoral thesis was Electronic Bands in Sodium Chloride. His thesis topic was suggested by his thesis advisor, John C. Slater.[5] After receiving his doctorate, Shockley joined a research group headed by Clinton Davisson at Bell Labs in New Jersey. The next few years were productive ones for Shockley. He published a number of fundamental papers on solid state physics in Physical Review. In 1938, he got his first patent, "Electron Discharge Device", on electron multipliers.[6]
Career
When World War II broke out, Shockley became involved in radar research at the Bell labs in Manhattan, New York. In May 1942, he took leave from Bell Labs to become a research director at Columbia University's Anti-Submarine Warfare Operations Group.[7] This involved devising methods for countering the tactics of submarines with improved convoying techniques, optimizing depth charge patterns, and so on. This project required frequent trips to the Pentagon and Washington, where Shockley met many high-ranking officers and government officials. In 1944, he organized a training program for B-29 bomber pilots to use new radar bomb sights. In late 1944 he took a three-month tour to bases around the world to assess the results. For this project, Secretary of War Robert Patterson awarded Shockley the Medal for Merit on October 17, 1946.[8]In July 1945, the War Department asked Shockley to prepare a report on the question of probable casualties from an invasion of the Japanese mainland. Shockley concluded:
If the study shows that the behavior of nations in all historical cases comparable to Japan's has in fact been invariably consistent with the behavior of the troops in battle, then it means that the Japanese dead and ineffectives at the time of the defeat will exceed the corresponding number for the Germans. In other words, we shall probably have to kill at least 5 to 10 million Japanese. This might cost us between 1.7 and 4 million casualties including 400,000 to 800,000 killed.[9]This report influenced the decision for the atomic bombings of Hiroshima and Nagasaki to force Japan to surrender without an invasion.[10]
Shockley was first to propose a lognormal distribution to model the creation process for scientific research papers.[11] He was an atheist.[12]
Development of transistor
Shortly after the end of the war in 1945, Bell Labs formed a solid state physics group, led by Shockley and chemist Stanley Morgan, which included John Bardeen, Walter Brattain, physicist Gerald Pearson, chemist Robert Gibney, electronics expert Hilbert Moore, and several technicians. Their assignment was to seek a solid-state alternative to fragile glass vacuum tube amplifiers. Its first attempts were based on Shockley's ideas about using an external electrical field on a semiconductor to affect its conductivity. These experiments failed every time in all sorts of configurations and materials. The group was at a standstill until Bardeen suggested a theory that invoked surface states that prevented the field from penetrating the semiconductor. The group changed its focus to study these surface states and they met almost daily to discuss the work. The rapport of the group was excellent, and ideas were freely exchanged.[13]By the winter of 1946 they had enough results that Bardeen submitted a paper on the surface states to Physical Review. Brattain started experiments to study the surface states through observations made while shining a bright light on the semiconductor's surface. This led to several more papers (one of them co-authored with Shockley), which estimated the density of the surface states to be more than enough to account for their failed experiments. The pace of the work picked up significantly when they started to surround point contacts between the semiconductor and the conducting wires with electrolytes. Moore built a circuit that allowed them to vary the frequency of the input signal easily. Finally they began to get some evidence of power amplification when Pearson, acting on a suggestion by Shockley, put a voltage on a droplet of glycol borate (a viscous chemical that did not evaporate, commonly used in electrolytic capacitors, and obtained by puncturing an example capacitor with a nail, using a hammer) placed across a P-N junction.[14]
Shockley, angered by not being included on the patent applications, secretly continued his own work to build a different sort of transistor based on junctions instead of point contacts; he expected this kind of design would be more likely to be commercially viable. The point contact transistor, he believed, would prove to be fragile and difficult to manufacture. Shockley was also dissatisfied with certain parts of the explanation for how the point contact transistor worked and conceived of the possibility of minority carrier injection. On February 13, 1948 another team member, John N. Shive, built a point contact transistor with bronze contacts on the front and back of thin wedge of germanium, proving that holes could diffuse through bulk germanium and not just along the surface as previously thought.[18]:153[19]:145 Shive's invention sparked[20] Shockley's invention of the junction transistor.[18]:143 A few months later he invented an entirely new, considerably more robust, type of transistor with a layer or 'sandwich' structure. This structure went on to be used for the vast majority of all transistors into the 1960s, and evolved into the bipolar junction transistor. Shockley later admitted that the workings of the team were "mixture of cooperation and competition." He also admitted that he kept some of his own work secret until his "hand was forced" by Shive's 1948 advance.[21] Shockley worked out a rather complete description of what he called the "sandwich" transistor, and a first proof of principle was obtained on April 7, 1949.
Meanwhile, Shockley worked on his magnum opus, Electrons and Holes in Semiconductors which was published as a 558-page treatise in 1950. The tome included Shockley's critical ideas of drift and diffusion and the differential equations that govern the flow of electrons in solid state crystals. Shockley's diode equation is also described. This seminal work became the reference text for other scientists working to develop and improve new variants of the transistor and other devices based on semiconductors.[22]
This resulted in his invention of the junction transistor, which was announced at a press conference on July 4, 1951.[23]
In 1951, he was elected a member of the National Academy of Sciences (NAS). He was forty-one years old; this was rather young for such an election. Two years later, he was chosen as the recipient of the prestigious Comstock Prize[24] for Physics by the NAS, and was the recipient of many other awards and honors.
The ensuing publicity generated by the "invention of the transistor" often thrust Shockley to the fore, much to the chagrin of Bardeen and Brattain. Bell Labs management, however, consistently presented all three inventors as a team. Though Shockley would correct the record where reporters gave him sole credit for the invention,[25] he eventually infuriated and alienated Bardeen and Brattain, and he essentially blocked the two from working on the junction transistor. Bardeen began pursuing a theory for superconductivity and left Bell Labs in 1951. Brattain refused to work with Shockley further and was assigned to another group. Neither Bardeen nor Brattain had much to do with the development of the transistor beyond the first year after its invention.[26]
Shockley Semiconductor
Main article: Shockley Semiconductor Laboratory
In 1956 Shockley moved from New Jersey to Mountain View, California to start Shockley Semiconductor Laboratory to live closer to his ailing mother in Palo Alto, California.[27][28] The company, a division of Beckman Instruments, Inc., was the first establishment working on silicon semiconductor devices in what came to be known as Silicon Valley."His way" could generally be summed up as domineering and increasingly paranoid. In one well-known incident, he claimed that a secretary's cut thumb was the result of a malicious act and he demanded lie detector tests to find the culprit.[29] After he received the Nobel Prize in 1956 his demeanor changed, as evidenced in his increasingly autocratic, erratic and hard-to-please management style.[30] In late 1957, eight of Shockley's researchers, who would come to be known as the "traitorous eight", resigned after Shockley decided not to continue research into silicon-based semiconductors.[31] They went on to form Fairchild Semiconductor, a loss from which Shockley Semiconductor never recovered. Over the course of the next 20 years, more than 65 new enterprises would end up having employee connections back to Fairchild.[32]
Personal life
Marriage and children
While still a student, Shockley married Iowan Jean Bailey in August 1933. In March 1934, the couple had a baby girl, Alison. Shockley became an accomplished rock climber, going often to the Shawangunks in the Hudson River Valley, where he pioneered a route across an overhang, known to this day as "Shockley's Ceiling."[14]Shockley was popular as a speaker, lecturer, and an amateur magician. He once 'magically' produced a bouquet of roses at the end of his address before the American Physical Society. He was also known in his early years for his elaborate practical jokes.[33]
Political views
See also: Flynn effect and History of the race and intelligence controversy
Late in his life, Shockley became intensely interested in questions of race, human intelligence, and eugenics.
He thought this work was important to the genetic future of the human
species and came to describe it as the most important work of his
career, even though expressing his views damaged his reputation.
Shockley argued that a higher rate of reproduction among the less
intelligent was having a dysgenic
effect, and that a drop in average intelligence would ultimately lead
to a decline in civilization. Shockley's published writings and lectures
to scientific organizations on this topic were partly based on the
writings of psychologist Cyril Burt and were funded by the Pioneer Fund. Shockley also proposed that individuals with IQs below 100 be paid to undergo voluntary sterilization.[34]Anthropologist Roger Pearson, whose writings are based on an evolutionary and racialist[35] approach, has defended Shockley in a self-published book co-authored with Shockley.[36] University of Wisconsin–Milwaukee professor Edgar G. Epps[37] argued that "William Shockley's position lends itself to racist interpretations".[38]
Genetics
He donated sperm to the Repository for Germinal Choice, a sperm bank founded by Robert Klark Graham in hopes of spreading humanity's best genes. The bank, called by the media the "Nobel Prize sperm bank," claimed to have three Nobel Prize-winning donors, though Shockley was the only one to publicly acknowledge his donation to the sperm bank. However, Shockley's controversial views brought the Repository for Germinal Choice a degree of notoriety and may have discouraged other Nobel Prize winners from donating sperm.[39]Relations with the media
In 1981 he filed a libel suit against the Atlanta Constitution after a science writer, Roger Witherspoon, compared Shockley's advocacy of a voluntary sterilization program to Nazi experiments on Jews. The suit took three years to go to trial. Shockley won the suit but received only one dollar in actual damages[40] and no punitive damages. Shockley's biographer Joel Shurkin, a science writer on the staff of Stanford University during those years, sums this up as saying that the statement was defamatory, but Shockley's reputation was not worth much by the time the trial reached a verdict.[41]Shockley taped his telephone conversations with reporters, and then sent the transcript to them by registered mail. At one point he toyed with the idea of making them take a simple quiz on his work before discussing the subject with them. His habit of saving all his papers, even laundry lists, provides abundant documentation for researchers on his life.[42]
A group of about thirty colleagues, who have met on and off since 1956, met at Stanford in 2002 to reminisce about their time with Shockley and his central role in sparking the information technology revolution, its organizer saying "Shockley is the man who brought silicon to Silicon Valley."[43]
Later years
When Shockley was eased out of the directorship of Shockley Semiconductor, he joined Stanford University, where in 1963 he was appointed the Alexander M. Poniatoff Professor of Engineering and Applied Science, in which position he remained until his retirement as professor emeritus in 1975.[44]Death
Shockley died in 1989 of prostate cancer.[45] By the time of his death he was almost completely estranged from most of his friends and family, except his wife who died in 2007. His children are reported to have learned of his death only through the print media.[46]Honors
- National Medal of Merit, for his war work in 1946.[8]
- Comstock Prize in Physics of the National Academy of Sciences in 1953.[47]
- First recipient of the Oliver E. Buckley Solid State Physics Prize of the American Physical Society in 1953.
- Co-recipient of the Nobel Prize in physics in 1956, along with Bardeen and Brattain. In his Nobel lecture, he gave full credit to Brattain and Bardeen as the inventors of the point-contact transistor. The three of them, together with wives and guests, had a rather raucous late-night champagne-fueled party to celebrate together.
- Holley Medal of the American Society of Mechanical Engineers in 1963.
- Wilhelm Exner Medal in 1963.[48]
- Honorary science doctorates from the University of Pennsylvania, Rutgers University in New Jersey, and Gustavus Adolphus Colleges in Minnesota.
- Maurice Liebman Memorial Prize from the Institute of Radio Engineers (now the Institute of Electrical and Electronics Engineers IEEE) in 1980.
- Named by Time Magazine as one of the 100 most influential people of the 20th century.
- Listed at #3 on the Boston Globe's 2011 MIT150 list of the top 150 innovators and ideas in the 150-year history of MIT.
Patents
Shockley was granted over ninety US patents. Some notable ones are:- US 2502488 Semiconductor Amplifier. Apr. 4, 1950; his first granted patent involving transistors.
- US 2569347 Circuit element utilizing semiconductive material. Sept. 25, 1951; His earliest applied for (June 26, 1948) patent involving transistors.
- US 2655609 Bistable Circuits. Oct. 13, 1953; Used in computers.
- US 2787564 Forming Semiconductive Devices by Ionic Bombardment. Apr. 2, 1957; The diffusion process for implantation of impurities.
- US 3031275 Process for Growing Single Crystals. Apr. 24, 1962; Improvements on process for production of basic materials.
- US 3053635 Method of Growing Silicon Carbide Crystals. Sept. 11, 1962; Exploring other semiconductors.
Bibliography
Prewar scientific articles by Shockley
- An Electron Microscope for Filaments: Emission and Adsorption by Tungsten Single Crystals, R. P. Johnson and W. Shockley, Phys. Rev. 49, 436 - 440 (1936) doi:10.1103/PhysRev.49.436
- Optical Absorption by the Alkali Halides, J. C. Slater and W. Shockley, Phys. Rev. 50, 705 - 719 (1936) doi:10.1103/PhysRev.50.705
- Electronic Energy Bands in Sodium Chloride, William Shockley, Phys. Rev. 50, 754 - 759 (1936) doi:10.1103/PhysRev.50.754
- The Empty Lattice Test of the Cellular Method in Solids, W. Shockley, Phys. Rev. 52, 866 - 872 (1937) doi:10.1103/PhysRev.52.866
- On the Surface States Associated with a Periodic Potential, William Shockley, Phys. Rev. 56, 317 - 323 (1939) doi:10.1103/PhysRev.56.317
- The Self-Diffusion of Copper, J. Steigman, W. Shockley and F. C. Nix, Phys. Rev. 56, 13 - 21 (1939) doi:10.1103/PhysRev.56.13
Books by Shockley
- Shockley, William – Electrons and holes in semiconductors, with applications to transistor electronics, Krieger (1956) ISBN 0-88275-382-7.
- Shockley, William and Gong, Walter A – Mechanics Charles E. Merrill, Inc. (1966).
- Shockley, William and Pearson, Roger – Shockley on Eugenics and Race: The Application of Science to the Solution of Human Problems Scott-Townsend (1992) ISBN 1-878465-03-1.
Further reading
- Riordan, Michael; Hoddeson, Lillian (1997). Crystal Fire: The Invention of the Transistor and the Birth of the Information Age. Sloan Technology Series. New York: Norton. ISBN 978-0-393-04124-8. Lay summary – Technology and Culture review by Arthur P. Molella (10 December 2014).
- Shurkin, Joel (2006). Broken Genius: The Rise and Fall of William Shockley, Creator of the Electronic Age. Macmillan. ISBN 978-1-4039-8815-7. Lay summary (10 December 2014).
- Tucker, William H. (2007) [first published 2002]. The funding of scientific racism: Wickliffe Draper and the Pioneer Fund. University of Illinois Press. ISBN 978-0-252-07463-9. Lay summary (10 December 2014).
Notes
- Editor, ÖGV. (2015). Wilhelm Exner Medal. Austrian Trade Association. ÖGV. Austria.
Other notes
- Park, Lubinski & Benbow 2010, "There were two young boys, Luis Alvarez and William Shockley, who were among the many who took Terman's tests but missed the cutoff score. Despite their exclusion from a study of young 'geniuses,' both went on to study physics, earn PhDs, and win the Nobel prize."
- Leslie 2000, "We also know that two children who were tested but didn't make the cut -- William Shockley and Luis Alvarez -- went on to win the Nobel Prize in Physics. According to Hastorf, none of the Terman kids ever won a Nobel or Pulitzer."
- Shurkin 2006, p. 13 (See also "The Truth About the 'Termites'" Kaufman, S. B. 2009)
- Simonton 1999, p. 4 "When Terman first used the IQ test to select a sample of child geniuses, he unknowingly excluded a special child whose IQ did not make the grade. Yet a few decades later that talent received the Nobel Prize in physics: William Shockley, the cocreator of the transistor. Ironically, not one of the more than 1,500 children who qualified according to his IQ criterion received so high an honor as adults."
- Eysenck 1998, pp. 127–128 "Terman, who originated those 'Genetic Studies of Genius', as he called them, selected ... children on the basis of their high IQs; the mean was 151 for both sexes. Seventy-seven who were tested with the newly translated and standardized Binet test had IQs of 170 or higher—well at or above the level of Cox's geniuses. What happened to these potential geniuses—did they revolutionize society? ... The answer in brief is that they did very well in terms of achievement, but none reached the Nobel Prize level, let alone that of genius. ... It seems clear that these data powerfully confirm the suspicion that intelligence is not a sufficient trait for truly creative achievement of the highest grade."
References
- Brittain, J.E. (1984). "Becker and Shive on the transistor". Proceedings of the IEEE 72 (12): 1695. doi:10.1109/PROC.1984.13075. ISSN 0018-9219. Retrieved 2 January 2015.
an observation that William Shockley interpreted as confirmation of his concept of that junction transistor
- Eysenck, Hans (1998). Intelligence: A New Look. New Brunswick (NJ): Transaction Publishers. ISBN 978-0-7658-0707-6.
- Giangreco, D. M. (1997). "Casualty Projections for the U.S. Invasions of Japan, 1945-1946: Planning and Policy Implications". Journal of Military History 61 (3): 521. doi:10.2307/2954035. ISSN 0899-3718.
- Goodheart, Adam (2 July 2006). "10 Days That Changed History". New York Times. Retrieved 2 January 2015.
- Leslie, Mitchell (July–August 2000). "The Vexing Legacy of Lewis Terman". Stanford Magazine. Retrieved 5 June 2013.
- Park, Gregory; Lubinski, David; Benbow, Camilla P. (2 November 2010). "Recognizing Spatial Intelligence". Scientific American. Retrieved 5 June 2013.
- Shurkin, Joel (2006). Broken Genius: The Rise and Fall of William Shockley, Creator of the Electronic Age. London: Macmillan. ISBN 978-1-4039-8815-7. Lay summary (2 June 2013).
- Simonton, Dean Keith (1999). Origins of genius: Darwinian perspectives on creativity. Oxford: Oxford University Press. ISBN 978-0-19-512879-6. Lay summary (14 August 2010).
- Riordan, Michael; Hoddeson, Lillian (1997). Crystal Fire: The Invention of the Transistor and the Birth of the Information Age. Sloan Technology Series. New York: Norton. ISBN 978-0-393-04124-8. Lay summary – Technology and Culture review by Arthur P. Molella (10 December 2014).
- Saxon, Wolfgang (14 August 1989). "William B. Shockley, 79, Creator of Transistor and Theory on Race". New York Times. Retrieved 2 January 2015.
He drew further scorn when he proposed financial rewards for the genetically disadvantaged if they volunteered for sterilization.
- Shockley, William (1952). "Contributors to Proceedings of the I.R.E.". Proceedings of the I.R.E.: 1611. http://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=04050875
- Sparks, Morgan; Hogan, Lester; Linville, John (1991). "[Obituary:] William Shockley". Physics Today 44 (6): 130–132. Bibcode:1991PhT....44f.130S. doi:10.1063/1.2810155. ISSN 0031-9228.
- Tucker, William H. (2007) [first published 2002]. The funding of scientific racism: Wickliffe Draper and the Pioneer Fund. University of Illinois Press. ISBN 978-0-252-07463-9. Lay summary (10 December 2014).
External links
Wikimedia Commons has media related to William Shockley. |
Wikiquote has quotations related to: William Shockley |
- National Academy of Sciences biography
- Nobel biography
- Nobel Lecture
- PBS biography
- Gordon Moore. Biography of William Shockley Time Magazine
- Interview with Shockley biographer Joel Shurkin
- History of the transistor
- William Shockley (IEEE Global History Network)
- Shockley and Bardeen-Brattain patent disputes
- William Shockley vs. Francis Cress-Welsing (Tony Brown Show, 1974)
- Works by or about William Shockley in libraries (WorldCat catalog)
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'mixture of cooperation and competition' and 'Shockley, eager to make his own contribution, said he kept some of his own work secret until "my hand was forced" in early 1948 by an advance reported by John Shive, another Bell Laboratories researcher'
In 1955, the physicist William Shockley set up a semiconductor laboratory in Mountain View, partly to be near his mother in Palo Alto. ...
The co-inventor of the transistor and the founder of the valley's first chip company, William Shockley, moved to Palo Alto, Calif., because his mother lived there. ...
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(help)He drew further scorn when he proposed financial rewards for the genetically disadvantaged if they volunteered for sterilization.
https://en.wikipedia.org/wiki/William_Shockley
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