Alfred Lee Loomis
Alfred Lee Loomis (November 4, 1887 – August 11, 1975) was an American attorney, investment banker, philanthropist, scientist/physicist, inventor of the LORAN Long Range Navigation System, and a lifelong patron of scientific research. He established the Loomis Laboratory in Tuxedo Park, New York, and his role in the development of radar is considered instrumental in the Allied victory in World War II. He invented the Aberdeen Chronograph for measuring muzzle velocities,[1] contributed significantly (perhaps critically, according to Luis Alvarez[2]) to the development of a ground-controlled approach technology for aircraft, and participated in preliminary meetings of the Manhattan Project. Loomis also made contributions to biological instrumentation. Working with Edmund Newton Harvey he co-invented the microscope centrifuge,[3] and pioneered techniques for electroencephalography.[4] In 1937, he discovered the sleep K-complex brainwave.[5][6]
Early years
Born in Manhattan, Loomis was the son of Julia Josephine Stimson and Henry Patterson Loomis, and grandson of Alfred Lebbeus Loomis. There were prominent members of society on both sides of his family; primarily they were physicians. Alfred's parents separated when he was very young, and his father died when Alfred was in college. His first cousin was Henry Stimson, who held cabinet-level positions in the administrations of William Howard Taft, Herbert Hoover, Franklin Roosevelt, and Harry S. Truman. From the boy's early years, Stimson exerted considerable influence on Loomis.
Loomis attended Phillips Academy and studied mathematics and science at Yale University.[7] He graduated cum laude from Harvard Law School in 1912. Immediately following his graduation, Loomis married and began practicing corporate law in the firm of Winthrop and Stimson, where he was very successful.
His wife was Elizabeth Ellen Farnsworth of Dedham, Massachusetts, from a prominent Boston society family, whom he wed on June 22, 1912. They had three sons: Alfred Lee Jr., William Farnsworth, and Henry.
In 1908 he became a hereditary member of the Rhode Island Society of the Cincinnati.
In 1917, Alfred Loomis and Landon K. Thorne, the wealthy husband of Loomis's sister Julia, purchased 17,000 acres (69 km2) of Hilton Head Island, which they established as a private preserve for riding, boating, fishing, and hunting. The centerpiece of the property was the old Honey Horn Plantation. Loomis's hobbies included automobiles and yachting, including the racing of America's Cup yachts against the Vanderbilts and Astors.
Military service and a new career in finance
After the United States entered World War I in 1917, Loomis volunteered for military service. He was commissioned as a captain, and rose to the rank of lieutenant colonel. He worked in ballistics at the Aberdeen Proving Ground in Maryland, where he invented the Aberdeen Chronograph, the first instrument to measure accurately the muzzle velocity of artillery shells, and portable enough to be used on the battlefield. At Aberdeen he met and worked with a Johns Hopkins physicist, Robert W. Wood, under whose influence Loomis's long-standing interest in inventing and gadgetry evolved into the serious pursuit of experimental and practical physics.
In the 1920s, Loomis collaborated with his brother-in-law, Landon K. Thorne, rather than returning to the practice of law. They acquired Bonbright and Company and brought it from the verge of bankruptcy to becoming a preeminent U. S. investment banking-house specializing in public utilities. They became very wealthy by financing electric companies as these began to establish the electrical infrastructure of rural America, and Loomis sat on the boards of several banks and electric utilities. Loomis and Thorne pioneered the concept of the holding company, consolidating many of the electric companies that operated on the East Coast of the United States. Loomis further increased his fortune via insider trading practices that now are illegal.
In 1928, anticipating the coming Wall Street Crash of 1929, he, his partner, and his firm had converted their investments into cash—having determined that the market had risen so dramatically that it was unsustainable and a crash was inevitable. Once the stock market crash had bankrupted the majority of speculators, while Wall Street floundered, he and his firm became even wealthier as a result of purchasing stocks cheaply after they had plummeted in value and few people had the cash to reinvest. While Senatorial hearings sought to tar him for the success of his prudent strategy, no substantive charges were ever brought, and he actually worked closely with FDR and his administration in preparing the country's technological base for war, using his many contacts in New York finance, as well as generous sums from his own considerable fortune, to finance the early developments in radar, before government money could be provided.
Loomis Laboratory at Tuxedo Park
Taking advantage of his considerable wealth, Loomis increasingly indulged his interest in science. He established a personal laboratory near his mansion within the exclusive enclave of Tuxedo Park, New York. He and his small staff conducted pioneering studies in spectrometry, high-frequency sound and capillary waves, electro-encephalography, and the precise measurement of time, chronometry.[8][9]
Eventually Loomis was elected to the National Academy of Sciences for his work in physics.
His laboratory was the best of its kind, containing equipment that few universities could afford. His reputation spread quickly, particularly in Europe, where money for science was scarce. Loomis often sent first-class tickets to famous European scientists so that they could travel to the United States to meet with their peers and collaborate on projects. They would be picked up at the airport or train station and brought to Tuxedo Park in his limousine. At first, some in the scientific community called him an "eccentric dabbler," but soon his laboratory became the meeting place for some of the most accomplished scientists of the time, such as Albert Einstein, Werner Heisenberg, Niels Bohr, James Franck, and Enrico Fermi. Scientists who worked personally with him were convinced of his capability and industry. His wealth, connections, and charm all made him highly persuasive.[10]
His Tuxedo Park laboratory was nicknamed the "Tower House" and "The Palace of Science". He turned this Tuxedo Park laboratory into a meeting place for the most visionary minds of the twentieth century; Albert Einstein, and the aforementioned scientists. Today this location is the home of The Tube Museum New York.[11]
He was awarded the Franklin Institute's John Price Wetherill Medal in 1934 along with E. Newton Harvey.
In 1939, Loomis began a collaboration with Ernest Lawrence and was instrumental in financing Lawrence's project to construct a 184-inch (4.7 m) cyclotron. By this time, Loomis had become a prominent figure in experimental physics and had moved his Tuxedo Park operations to Cambridge, Massachusetts, where he established a joint operation with the Massachusetts Institute of Technology (MIT).[12]
Additionally, Loomis' 1937 house in Tuxedo Park by architect William Lescaze is regarded as an early experiment in double-skin facade construction. This house included "an elaborate double envelope" with a 2-foot-deep air space conditioned by a separate system from the house itself. The object was to maintain high humidity levels inside.[13]
Loomis in World War Two
In the late 1930s, Loomis's scientific team turned their attention to radio detection studies, building a crude microwave radar which they deployed in the back of a van. They drove it to a golf course and aimed it at the neighboring highway in order to track automobiles, then took it to the local airport, where they tracked small aircraft.
Loomis had visited the United Kingdom and knew many of the British scientists who were working on radar. Britain, at war with Germany, was being bombed nightly by the German Luftwaffe, while America was trying to stay out of the war. British scientists had developed the cavity magnetron, which allowed their radar to be made small enough for installation in aircraft. In 1940, the British Tizard Mission visited the United States, seeking help to mass-manufacture the technology they had invented.
On hearing that the British magnetron had a thousand times the output of the best American transmitter, Loomis invited its developers to Tuxedo Park. Because he had performed more work in this area than anyone else in the country, Loomis was appointed by Vannevar Bush to the National Defense Research Committee as chairman of the Microwave Committee and vice-chairman of Division D (Detection, Controls, Instruments). Within a month, he had selected a building on the MIT campus in which to equip a laboratory, dubbing it the MIT Radiation Laboratory, usually referred to as the Radiation Laboratory and later known simply as the Rad Lab. He pressed for the development of radar in spite of the Army's initial skepticism, and arranged funding for the Rad Lab until federal money was allocated.
The MIT Rad Lab was managed by its director, Lee DuBridge. Meanwhile, Loomis assumed his customary function of eliminating the obstacles to research and providing the encouragement that was needed at a time when success still remained elusive. The resulting 10-cm radar was a key technology that enabled the sinking of U-boats, spotted incoming German bombers for the British, and provided cover for the D-Day landing. Loomis took advantage of all his business acumen and industry contacts to ensure that no time was wasted in its development. DuBridge later commented, "Radar won the war; the atom bomb ended it."
Originally known as "LRN" for Loomis Radio Navigation, LORAN was invented by Loomis. It was the most widely used long-range navigation system until the advent of GPS (which was developed from it and became available to the public only in 2000), and LORAN is being enhanced and retained as a land-based alternative to the satellite-based system. The system was developed at the laboratory and is based on a pulsed hyperbolic system using a master and two slave stations. A world network of stations once existed. The current LORAN system has been phased out in the United States and Canada. The United States Coast Guard (USCG) and Canadian Coast Guard (CCG) ceased transmitting LORAN-C (and joint CHAYKA) signals in 2010.
Loomis also made a significant contribution to the development of ground-controlled approach technology, a precursor of today's instrument-landing systems that use radar to enable ground controllers to "talk down" aircraft pilots and help them to land safely when poor visibility makes visual landings difficult or impossible. Even untrained persons forced into the unexpected position of having to pilot an aircraft in an emergency, have been guided to land safely using this technology.
Legacy and later years
President Roosevelt lauded the value of Loomis's work, describing him as being the civilian who was second perhaps only to Churchill, in facilitating the Allied victory in World War II.
Loomis was elected to the National Academy of Sciences in 1940, and received several honorary degrees: from Wesleyan University he received a D.Sc. in 1932, from Yale University an M.Sc. in 1933, and from the University of California an LL.D. in 1941.
Loomis was married to Ellen Farnsworth for over thirty years; she was beautiful, delicate, and often suffered from debilitating depression, eventually developing dementia. They had three children, Alfred, Jr., a pioneering investor, two-time winner of the Bermuda Race and head of the winning America's Cup syndicate in 1977; Henry, head of the Corporation for Public Broadcasting and Farnsworth, a physician and professor at Brandeis (Farnsworth's grandson is Reed Hastings, co-founder of Netflix). He had an affair with a colleague's wife, Manette Hobart, and in 1945 he divorced Ellen and immediately married Manette, scandalizing New York society. At this point he completely changed his lifestyle, eschewing his multiple residences and numerous servants, and settling into a single household in which he and his wife shared a relationship that was characterized by its domesticity. They remained married until Alfred Loomis died more than thirty years later.
Loomis, always a very private person who avoided publicity, retreated from public life entirely after closing the Rad Lab and finishing his related obligations in 1947. He retired to East Hampton, with Manette, and never granted another interview.
Patents
- External shoe tree, 1914 U.S. Patent 1,106,465[15]
- Net, 1916 U.S. Patent 1,184,466[16]
- Toy, 1917 U.S. Patent 1,222,005[17]
- Chronograph, 1921 U.S. Patent 1,376,890[18]
- Method and apparatus for forming emulsions and the like, 1929 U.S. Patent 1,734,975[19]
- Microscope centrifuge, 1933 U.S. Patent 1,907,803[20]
Publications
Projectiles
- The Measurement of Projectile Velocities.[21]
Sound Waves and Ultrasound
- A Sonic Interferometer for Liquids.[22]
- Spectra of High-frequency Discharges in Super-vacuum Tubes.[23]
- The physical and biological effects of high-frequency sound-waves of great intensity.[24]
- The chemical effects of high frequency sound waves I. A preliminary survey.[25]
- CXXII. The velocity of sound in liquids at high frequencies by the sonic interferometer.[26]
- Further observations on the effect of high frequency sound waves on living matter.[27]
- The destruction of luminous bacteria by high frequency sound waves.[28]
- The relation of frequency to the physiological effects of ultra-high frequency currents.[29]
- DIELECTRIC LOSS IN ELECTROLYTE SOLUTIONS IN HIGH FREQUENCY.[30]
Animal Studies
- An attempt to induce mutation in Drosophila melanogaster by means of supersonic vibrations.[31]
- The intrinsic rhythm of the turtle's heart studied with a new type of chronograph, together with the effects of some drugs and hormones.[32]
- High speed photomicrography of living cells subjected to supersonic vibrations.[33]
Miscellaneous
- The pressure of aqueous vapour in the alveolar air.[34]
Time Measurement
- Time, The precise measurement of.[35]
- Modern developments in precision clocks.[36]
- An apparent lunar effect in time determinations at Greenwich and Washington.[37]
- Further investigations of an apparent lunar effect in time determinations.[38]
Brain and Sleep Studies
- Potential rhythms of the cerebral cortex during sleep.[39]
- Further observations on the potential rhythms of the cerebral cortex during sleep.[40]
- Electrical potentials of the human brain.[41]
- Brain potentials during hypnosis.[42]
- Cerebral states during sleep, as studied by human brain potentials.[43]
- Changes in human brain potentials during the onset of sleep.[44]
References
- ↑ Loomis, Alfred L., Agnew, Paul G., Klopsteg Paul E., Stannard, Winfield H. (3 May 1921). "Chronograph." U.S. Patent No. 1,376,890. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Alvarez, Luis W. (1980). "Alfred Lee Loomis". National Academy of Sciences. Biographical memoirs. 51. Washington D.C.: National Academies Press. pp. 308–341.
- ↑ "Patent Number 1,907,803". Retrieved 2008-09-15.
- ↑ "Harvey, Edmund Newton". Retrieved 2008-09-15.
- ↑ Loomis AL, Harvey EN, Hobart GA. Cerebral states during sleep as studies by human brain potentials. J Exp Psychol 1937;21:127–44.abstract
- ↑ Colrain IM. (2005). The K-complex: a 7-decade history. Sleep. 28(2):255-73. PMID 16171251
- ↑ "Notable Alumni: Short List". Retrieved 23 September 2012.
- ↑ Alvarez, Luis W. (1980), Alfred Lee Loomis 1887–1975 (PDF), Washington D.C.: National Academy of Sciences, retrieved 17 May 2013
- ↑ Conant, Jennet. (2003). Tuxedo Park: A Wall Street Tycoon and the Secret Palace of Science That Changed the Course of World War II. Simon and Schuster. New York, NY.
- ↑ Conant, Jennet. (2003). Tuxedo Park: A Wall Street Tycoon and the Secret Palace of Science That Changed the Course of World War II. Simon and Schuster. New York, NY.
- ↑ The book TUXEDO PARK by Jennet Conant ISBN 0-684-87287-0 talks about the Tower House on Crows Nest Road, Tuxedo Park, New York.
- ↑ Conant, Jennet. (2003). Tuxedo Park: A Wall Street Tycoon and the Secret Palace of Science That Changed the Course of World War II. Simon and Schuster. New York, NY.
- ↑ Braham, William (2005). "Active Glass Walls: A Typological and Historical Account".
- ↑ Archived September 22, 2008, at the Wayback Machine.
- ↑ Loomis, Alfred Lee . (11 August 1914). “External shoe tree.” U.S. Patent 1,106,465. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Loomis, Alfred Lee and Mcvickar, Henry L. (23 May 1916). “Net.” U.S. Patent 1,184,466. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Loomis, Alfred Lee. (10 April 1917). “Toy.” U.S. Patent 1,222,005. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Loomis, Alfred L., Agnew, Paul G., Klopsteg Paul E., Stannard, Winfield H. (3 May 1921). "Chronograph." U.S. Patent 1,376,890. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Loomis, Alfred L. and Wood, Robert Williams. (12 November 1929). "Method and apparatus for forming emulsions and the like." U.S. Patent 1,734,975. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Loomis, Alfred Lee and Newton, Harvey Edmund. (9 May 1933). “Microscope centrifuge.” U.S. Patent 1,907,803. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Klopsteg, Paul E., and Alfred L. Loomis. "The Measurement of Projectile Velocities." American Institute of Electrical Engineers, Transactions of the 39.1 (1920): 337-358.
- ↑ Hubbard, John C., and Alfred L. Loomis. "A Sonic Interferometer for Liquids." Nature. 120 (1927): 189.
- ↑ Wood, R. W., and A. L. Loomis. "Spectra of High-frequency Discharges in Super-vacuum Tubes." Nature. 120 (1927): 510.
- ↑ Wood, Robert Williams, and Alfred L. Loomis. "XXXVIII. The physical and biological effects of high-frequency sound-waves of great intensity." Philosophical Magazine Series 7. 4.22 (1927): 417-436.
- ↑ Richards, William T., and Alfred L. Loomis. "The chemical effects of high frequency sound waves I. A preliminary survey." Journal of the American Chemical Society. 49.12 (1927): 3086-3100.
- ↑ Hubbard, John C., and A. L. Loomis. "CXXII. The velocity of sound in liquids at high frequencies by the sonic interferometer." The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science. 5.33 (1928): 1177-1190.
- ↑ Harvey, E. Newton, Ethel Browne Harvey, and Alfred L. Loomis. "Further observations on the effect of high frequency sound waves on living matter." The Biological Bulletin. 55.6 (1928): 459-469.
- ↑ Harvey, E. Newton, and Alfred L. Loomis. "The destruction of luminous bacteria by high frequency sound waves." Journal of Bacteriology. 17.5 (1929): 373.
- ↑ Christie, Ronald V. and Alfred L. Loomis. "The relation of frequency to the physiological effects of ultra-high frequency currents." The Journal of experimental medicine. 49.2 (1929): 303-321.
- ↑ Richards, William T., and Alfred L. Loomis. "DIELECTRIC LOSS IN ELECTROLYTE SOLUTIONS IN HIGH FREQUENCY." Proceedings of the National Academy of Sciences of the United States of America. 15.7 (1929): 587.
- ↑ Hersh, A. H., Enoch Karrer, and Alfred L. Loomis. "An attempt to induce mutation in Drosophila melanogaster by means of supersonic vibrations." American Naturalist. (1930): 552-559.
- ↑ Loomis, Alfred L., E. Newton Harvey, and C. MacRae. "The intrinsic rhythm of the turtle's heart studied with a new type of chronograph, together with the effects of some drugs and hormones." The Journal of general physiology. 14.1 (1930): 105-115.
- ↑ Harvey, E. Newton, and Alfred L. Loomis. "High speed photomicrography of living cells subjected to supersonic vibrations." The Journal of general physiology. 15.2 (1931): 147.
- ↑ Christie, Ronald V., and Alfred L. Loomis. "The pressure of aqueous vapour in the alveolar air." The Journal of physiology. 77.1 (1932): 35-48.
- ↑ Loomis, Alfred L. "Time, The precise measurement of." Monthly Notices of the Royal Astronomical Society. 91 (1931): 569.
- ↑ Loomis, Alfred L., and W. A. Marrison. "Modern developments in precision clocks." Electrical Engineering. 51.2 (1932): 132-132.
- ↑ Loomis, A. L., and Harlan True Stetson. "An apparent lunar effect in time determinations at Greenwich and Washington. Monthly Notices of the Royal Astronomical Society. 93 (1933): 444.
- ↑ Loomis, Alfred Lee, and Harlan True Stetson. "Further investigations of an apparent lunar effect in time determinations." Monthly Notices of the Royal Astronomical Society. 95 (1935): 452.
- ↑ Loomis, Alfred L., E. Newton Harvey, and Garret Hobart. "Potential rhythms of the cerebral cortex during sleep." Science. (1935).
- ↑ Loomis, Alfred L., E. Newton Harvey, and Garret Hobart. "Further observations on the potential rhythms of the cerebral cortex during sleep." Science. (1935).
- ↑ Loomis, Alfred L., E. Newton Harvey, and Garret Hobart. "Electrical potentials of the human brain." Journal of experimental Psychology. 19.3 (1936): 249.
- ↑ Loomis, Alfred L., E. Newton Harvey, and Garret Hobart. "Brain potentials during hypnosis." Science. (1936).
- ↑ Loomis, Alfred L., E. Newton Harvey, and G. A. Hobart. "Cerebral states during sleep, as studied by human brain potentials." Journal of experimental psychology. 21.2 (1937): 127.
- ↑ Davis, H., Davis, P. A., Loomis, A. L., Harvey, E. N., & Hobart, G. (1937). Changes in human brain potentials during the onset of sleep. Science.
Further reading
- Alvarez, Luis W. (1980). "Alfred Lee Loomis". National Academy of Sciences. Biographical memoirs. 51. Washington D.C.: National Academies Press. pp. 308–341.
- Conant, Jennet (2002). Tuxedo Park: A Wall Street Tycoon and the Secret Palace of Science That Changed the Course of World War II. New York: Simon & Schuster. hardcover: ISBN 0-684-87287-0, paperback: ISBN 0-684-87288-9
External links
Wikimedia Commons has media related to Alfred Lee Loomis. |
- "The Consummate Amateur". Retrieved 2008-09-18. - A review of Tuxedo Park in American Scientist pointing out a few errors and exaggerations in the book.
- "Inside the "Cloistered Fiefdom" of an Unrelenting Gentleman Scientist". Retrieved 2008-09-15. - A review of Tuxedo Park at SIAM news.
- Booknotes interview with Conant on Tuxedo Park: A Wall Street Tycoon and the Secret Palace of Science that Changed the Course of World War II, June 9, 2002.
- National Academy of Sciences Biographical Memoir