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Luis Walter Alvarez
Alvarez with a magnetic monopole detector in 1969
Born	(1911-06-13)June 13, 1911 San Francisco, California, U.S.
Died	September 1, 1988(1988-09-01) (aged 77) Berkeley, California, U.S.
Education	University of Chicago (BS, MS, PhD)
Known for	Accelerator mass spectrometry, Alvarez hypothesis, AN/CPS-1, Electron capture, Exploding-bridgewire detonator, Ground-controlled approach, Linear particle accelerator, Liquid hydrogen bubble chamber, Muon-catalyzed fusion, Muon tomography, Isolation of helium-3, Isolation of tritium, Measurement of neutron magnetic moment
Spouses	Geraldine Smithwick ​ ​(m. 1936; div. 1957)​ Janet L. Landis ​(m. 1958)​
Awards	Collier Trophy (1945) Medal for Merit (1947) John Scott Medal (1953) Albert Einstein Award (1961) National Medal of Science (1963) Pioneer Award (1963) Michelson–Morley Award (1965) Nobel Prize in Physics (1968) Enrico Fermi Award (1987)
Scientific career
Fields	Physics
Institutions	University of California, Berkeley
Doctoral advisor	Arthur Compton
Signature

Luis Walter Alvarez (June 13, 1911 – September 1, 1988) was an American experimental physicist, inventor, and professor who was awarded the Nobel Prize in Physics in 1968 for his discovery of resonance states in particle physics using the hydrogen bubble chamber. In 2007 the American Journal of Physics commented, "Luis Alvarez was one of the most brilliant and productive experimental physicists of the twentieth century."

After receiving his PhD from the University of Chicago in 1936, Alvarez went to work for Ernest Lawrence at the Radiation Laboratory at the University of California, Berkeley. Alvarez devised a set of experiments to observe K-electron capture in radioactive nuclei, predicted by the beta decay theory but never before observed. He produced tritium using the cyclotron and measured its lifetime. In collaboration with Felix Bloch, he measured the magnetic moment of the neutron.

In 1940, Alvarez joined the MIT Radiation Laboratory, where he contributed to a number of World War II radar projects, from early improvements to Identification friend or foe (IFF) radar beacons, now called transponders, to a system known as VIXEN for preventing enemy submarines from realizing that they had been found by the new airborne microwave radars. The radar system for which Alvarez is best known and which has played a major role in aviation, most particularly in the post war Berlin airlift, was Ground Controlled Approach (GCA). Alvarez spent a few months at the University of Chicago working on nuclear reactors for Enrico Fermi before coming to Los Alamos to work for Robert Oppenheimer on the Manhattan project. Alvarez worked on the design of explosive lenses, and the development of exploding-bridgewire detonators. As a member of Project Alberta, he observed the Trinity nuclear test from a B-29 Superfortress, and later the bombing of Hiroshima from the B-29 The Great Artiste.

After the war Alvarez was involved in the design of a liquid hydrogen bubble chamber that allowed his team to take millions of photographs of particle interactions, develop complex computer systems to measure and analyze these interactions, and discover entire families of new particles and resonance states. This work resulted in his being awarded the Nobel Prize in 1968. He was involved in a project to x-ray the Egyptian pyramids to search for unknown chambers. With his son, geologist Walter Alvarez, he developed the Alvarez hypothesis which proposes that the extinction event that wiped out the non-avian dinosaurs was the result of an asteroid impact.

Early life

Luis Walter Alvarez was born into a Roman Catholic family in San Francisco on June 13, 1911, the second child and oldest son of Walter C. Alvarez, a physician, and his wife Harriet née Smyth, and a grandson of Luis F. Álvarez, a Spanish physician, born in Asturias, Spain, who lived in Cuba for a while and finally settled in the United States, who found a better method for diagnosing macular leprosy. He had an older sister, Gladys, a younger brother, Bob, and a younger sister, Bernice. His aunt, Mabel Alvarez, was a California artist specializing in oil painting.

He attended Madison School in San Francisco from 1918 to 1924, and then San Francisco Polytechnic High School. In 1926, his father became a researcher at the Mayo Clinic, and the family moved to Rochester, Minnesota, where Alvarez attended Rochester High School. He had always expected to attend the University of California, Berkeley, but at the urging of his teachers at Rochester, he instead went to the University of Chicago, where he received his bachelor's degree in 1932, his master's degree in 1934, and his PhD in 1936. As an undergraduate, he belonged to the Phi Gamma Delta fraternity. As a postgraduate he moved to Gamma Alpha.

In 1932, as a graduate student at Chicago, he discovered the field of physics and had the rare opportunity to use the equipment of legendary physicist Albert A. Michelson. Alvarez also constructed an apparatus of Geiger counter tubes arranged as a cosmic ray telescope, and under the aegis of his faculty advisor Arthur Compton, conducted an experiment in Mexico City to measure the so-called East–West effect of cosmic rays. Observing more incoming radiation from the west, Alvarez concluded that primary cosmic rays were positively charged. Compton submitted the resulting paper to the Physical Review, with Alvarez's name at the top.

Alvarez was an agnostic even though his father had been a deacon in a Congregational church.

Early work

Alvarez's sister, Gladys, worked for Berkeley physicist Ernest Lawrence as a part-time secretary, and mentioned Alvarez to Lawrence. Lawrence then invited Alvarez to tour the Century of Progress exhibition in Chicago with him. After he completed his oral exams in 1936, Alvarez, now engaged to be married to Geraldine Smithwick, asked his sister to see if Lawrence had any jobs available at the Radiation Laboratory. A telegram soon arrived from Gladys with a job offer from Lawrence. This started a long association with the University of California, Berkeley. Alvarez and Smithwick were married in one of the chapels at the University of Chicago and then headed for California. They had two children, Walter and Jean. They were divorced in 1957. On December 28, 1958, he married Janet L. Landis, and had two more children, Donald and Helen.

At the Radiation Laboratory he worked with Lawrence's experimental team, which was supported by a group of theoretical physicists headed by Robert Oppenheimer. Alvarez devised a set of experiments to observe K-electron capture in radioactive nuclei, predicted by the beta decay theory but never observed. Using magnets to sweep aside the positrons and electrons emanating from his radioactive sources, he designed a special purpose Geiger counter to detect only the "soft" X-rays coming from K capture. He published his results in the Physical Review in 1937.

When deuterium (hydrogen-2) is bombarded with deuterium, the fusion reaction yields either tritium (hydrogen-3) plus a proton or helium-3 plus a neutron (
H
+
H
→
H
+ p or
He
+ n). This is one of the most basic fusion reactions, and the foundation of the thermonuclear weapon and the current research on controlled nuclear fusion. At that time the stability of these two reaction products was unknown, but based on existing theories Hans Bethe thought that tritium would be stable and helium-3 unstable. Alvarez proved the reverse by using his knowledge of the details of the 60-inch cyclotron operation. He tuned the machine to accelerate doubly ionized helium-3 nuclei and was able to get a beam of accelerated ions, thus using the cyclotron as a kind of super mass spectrometer. As the accelerated helium came from deep gas wells where it had been for millions of years, the helium-3 component had to be stable. Afterwards Alvarez produced the radioactive tritium using the cyclotron and the
H
+
H
reaction and measured its lifetime.

In 1938, again using his knowledge of the cyclotron and inventing what are now known as time-of-flight techniques, Alvarez created a mono-energetic beam of thermal neutrons. With this he began a long series of experiments, collaborating with Felix Bloch, to measure the magnetic moment of the neutron. Their result of μ₀ = 1.93±0.02 μ_N, published in 1940, was a major advance over earlier work.

World War II

Radiation Laboratory

The British Tizard Mission to the United States in 1940 demonstrated to leading American scientists the successful application of the cavity magnetron to produce short wavelength pulsed radar. The National Defense Research Committee, established only months earlier by President Franklin Roosevelt, created a central national laboratory at the Massachusetts Institute of Technology (MIT) for the purpose of developing military applications of microwave radar. Lawrence immediately recruited his best "cyclotroneers", among them Alvarez, who joined this new laboratory, known as the Radiation Laboratory, on November 11, 1940. Alvarez contributed to a number of radar projects, from early improvements to Identification Friend or Foe (IFF) radar beacons, now called transponders, to a system known as VIXEN for preventing enemy submarines from realizing that they had been found by the new airborne microwave radars. Enemy submarines would wait until the radar signal was getting strong and then submerge, escaping attack. But VIXEN transmitted a radar signal whose strength was the cube of the distance to the submarine so that as they approached the sub, the signal—as measured by the sub—got progressively weaker, and the sub assumed the plane was getting farther away and did not submerge.

One of the first projects was to build equipment to transition from the British long-wave radar to the new microwave centimeter-band radar made possible by the cavity magnetron. In working on the Microwave Early Warning system (MEW), Alvarez invented a linear dipole array antenna that not only suppressed the unwanted side lobes of the radiation field but also could be electronically scanned without the need for mechanical scanning. This was the first microwave phased-array antenna, and Alvarez used it not only in MEW but in two additional radar systems. The antenna enabled the Eagle precision bombing radar to support precision bombing in bad weather or through clouds. It was completed rather late in the war; although a number of B-29s were equipped with Eagle and it worked well, it came too late to make much difference.

The radar system for which Alvarez is best known and which has played a major role in aviation, most particularly in the post-war Berlin airlift, was Ground Controlled Approach (GCA). Using Alvarez's dipole antenna to achieve a very high angular resolution, GCA allows ground-based radar operators to watch special precision displays to guide a landing airplane to the runway by transmitting verbal commands to the pilot. The system was simple, direct, and worked well, even with previously untrained pilots. It was so successful that the military continued to use it for many years after the war, and it was still in use in some countries in the 1980s. Alvarez was awarded the National Aeronautic Association's Collier Trophy in 1945 "for his conspicuous and outstanding initiative in the concept and development of the Ground Control Approach system for safe landing of aircraft under all weather and traffic conditions".

Alvarez spent the summer of 1943 in England testing GCA, landing planes returning from battle in bad weather, and also training the British in the use of the system. While there he encountered the young Arthur C. Clarke, who was an RAF radar technician. Clarke subsequently used his experiences at the radar research station as the basis for his novel Glide Path, which contains a thinly disguised version of Alvarez. Clarke and Alvarez developed a long-term friendship.

Manhattan Project

In the fall of 1943, Alvarez returned to the United States with an offer from Robert Oppenheimer to work at Los Alamos on the Manhattan Project. However, Oppenheimer suggested that he first spend a few months at the University of Chicago working with Enrico Fermi before coming to Los Alamos. During these months, General Leslie Groves asked Alvarez to think of a way that the US could find out if the Germans were operating any nuclear reactors, and, if so, where they were. Alvarez suggested that an airplane could carry a system to detect the radioactive gases that a reactor produces, particularly xenon-133. The equipment did fly over Germany, but detected no radioactive xenon because the Germans had not built a reactor capable of a chain reaction. This was the first idea of monitoring fission products for intelligence gathering. It would become extremely important after the war.

As a result of his radar work and the few months spent with Fermi, Alvarez arrived at Los Alamos in the spring of 1944, later than many of his contemporaries. The work on the "Little Boy" (a uranium bomb) was far along so Alvarez became involved in the design of the "Fat Man" (a plutonium bomb). The technique used for uranium, that of forcing the two sub-critical masses together using a type of gun, would not work with plutonium because the high level of background spontaneous neutrons would cause fissions as soon as the two parts approached each other, so heat and expansion would force the system apart before much energy has been released. It was decided to use a nearly critical sphere of plutonium and compress it quickly by explosives into a much smaller and denser core, a technical challenge at the time.

To create the symmetrical implosion required to compress the plutonium core to the required density, thirty-two explosive charges were to be simultaneously detonated around the spherical core. Using conventional explosive techniques with blasting caps, progress towards achieving simultaneity to within a small fraction of a microsecond was discouraging. Alvarez directed his graduate student, Lawrence H. Johnston, to use a large capacitor to deliver a high voltage charge directly to each explosive lens, replacing blasting caps with exploding-bridgewire detonators. The exploding wire detonated the thirty-two charges to within a few tenths of a microsecond. The invention was critical to the success of the implosion-type nuclear weapon. He also supervised the RaLa Experiments. Alvarez later wrote that:

With modern weapons-grade uranium, the background neutron rate is so low that terrorists, if they had such material, would have a good chance of setting off a high-yield explosion simply by dropping one half of the material onto the other half. Most people seem unaware that if separated U-235 is at hand, it's a trivial job to set off a nuclear explosion, whereas if only plutonium is available, making it explode is the most difficult technical job I know.

Again working with Johnston, Alvarez's last task for the Manhattan Project was to develop a set of calibrated microphone/transmitters to be parachuted from an aircraft to measure the strength of the blast wave from the atomic explosion, so as to allow the scientists to calculate the bomb's energy. After being commissioned as a lieutenant colonel in the United States Army, he observed the Trinity nuclear test from a B-29 Superfortress that also carried fellow Project Alberta members Harold Agnew and Deak Parsons (who were respectively commissioned at the rank of captain).

Flying in the B-29 Superfortress The Great Artiste in formation with the Enola Gay, Alvarez and Johnston measured the blast effect of the Little Boy bomb which was dropped on Hiroshima. A few days later, again flying in The Great Artiste, Johnston used the same equipment to measure the strength of the Nagasaki explosion.

Bubble chamber

Returning to the University of California, Berkeley as a full professor, Alvarez had many ideas about how to use his wartime radar knowledge to improve particle accelerators. Though some of these were to bear fruit, the "big idea" of this time would come from Edwin McMillan with his concept of phase stability which led to the synchrocyclotron. Refining and extending this concept, the Lawrence team would build the world's then-largest proton accelerator, the Bevatron, which began operating in 1954. Though the Bevatron could produce copious amounts of interesting particles, particularly in secondary collisions, these complex interactions were hard to detect and analyze at the time.

Seizing upon a new development to visualize particle tracks, created by Donald Glaser and known as a bubble chamber, Alvarez realized the device was just what was needed, if only it could be made to function with liquid hydrogen. Hydrogen nuclei, which are protons, made the simplest and most desirable target for interactions with the particles produced by the Bevatron. He began a development program to build a series of small chambers, and championed the device to Ernest Lawrence.

The Glaser device was a small glass cylinder (1 cm × 2 cm) filled with ether. By suddenly reducing the pressure in the device, the liquid could be placed into a temporary superheated state, which would boil along the disturbed track of a particle passing through. Glaser was able to maintain the superheated state for a few seconds before spontaneous boiling took place. The Alvarez team built chambers of 1.5 in, 2.5 in, 4 in, 10 in, and 15 in using liquid hydrogen, and constructed of metal with glass windows, so that the tracks could be photographed. The chamber could be cycled in synchronization with the accelerator beam, a picture could be taken, and the chamber recompressed in time for the next beam cycle.

This program built a liquid hydrogen bubble chamber almost 7 feet (2.1 meters) long, employed dozens of physicists and graduate students together with hundreds of engineers and technicians, took millions of photographs of particle interactions, developed computer systems to measure and analyze the interactions, and discovered families of new particles and resonance states. This work resulted in the Nobel Prize in Physics for Alvarez in 1968, "For his decisive contributions to elementary particle physics, in particular the discovery of a large number of resonant states, made possible through his development of the technique of using hydrogen bubble chambers and data analysis."

Scientific detective work

In 1964, Alvarez proposed what became known as the High Altitude Particle Physics Experiment (HAPPE), originally conceived as a large superconducting magnet carried to high altitude by a balloon in order to study extremely high-energy particle interactions. In time the focus of the experiment changed toward the study of cosmology and the role of both particles and radiation in the early universe. This work was a large effort, carrying detectors aloft with high-altitude balloon flights and high-flying U-2 aircraft, and an early precursor of the COBE satellite-born experiments on the cosmic background radiation (which resulted in the award of the 2006 Nobel Prize, shared by George Smoot and John Mather).

Alvarez proposed muon tomography in 1965 to search the Egyptian pyramids for unknown chambers. Using naturally occurring cosmic rays, his plan was to place spark chambers, standard equipment in the high-energy particle physics of this time, beneath the Pyramid of Khafre in a known chamber. By measuring the counting rate of the cosmic rays in different directions the detector would reveal the existence of any void in the overlaying rock structure.

Alvarez assembled a team of physicists and archeologists from the United States and Egypt, the recording equipment was constructed and the experiment carried out, though it was interrupted by the 1967 Six-Day War. Restarted after the war, the effort continued, recording and analyzing the penetrating cosmic rays until 1969, when he reported to the American Physical Society that no chambers had been found in the 19% of the pyramid surveyed.

In November 1966, Life magazine published a series of photographs from the 1963 "Zapruder film", believed to be the most complete document of the assassination of John F. Kennedy. Alvarez, an expert in optics and photoanalysis, became intrigued by the pictures and began to study what could be learned from the film. Alvarez demonstrated both in theory and experiment that the backward snap of the President's head was consistent with his being shot from behind being called the "jet-effect" theory. Alvarez's theory was later refined and corroborated by other researchers. Alvarez also investigated the timing of the gunshots and the shockwave that disturbed the camera, and the speed of the camera, pointing out a number of details that the FBI photo analysts either overlooked or got wrong. He produced a paper intended as a tutorial, with informal advice for the physicist intent on arriving at the truth of the case.

Dinosaur extinction hypothesis

In 1980 Alvarez and his son, geologist Walter Alvarez, along with nuclear chemists Frank Asaro and Helen Michel, "uncovered a calamity that literally shook the Earth and is one of the great discoveries about Earth's history".

During the 1970s, Walter Alvarez was doing geologic research in central Italy. There he had located an outcrop on the walls of a gorge whose limestone layers included strata both above and below the Cretaceous–Paleogene boundary. Exactly at the boundary is a thin layer of clay. Walter told his father that the layer marked where the dinosaurs and much else became extinct and that nobody knew why, or what the clay was about—it was a big mystery, and he intended to solve it.

Alvarez had access to the nuclear chemists at the Lawrence Berkeley Laboratory and was able to work with Frank Asaro and Helen Michel, who used the technique of neutron activation analysis to study the clay. In 1980, Alvarez, Alvarez, Asaro, and Michel published a seminal paper proposing an extraterrestrial cause for the Cretaceous-Paleogene extinction (then called the Cretaceous-Tertiary extinction). In the years following the publication of their article, the clay was also found to contain soot, glassy spherules, shocked quartz crystals, microscopic diamonds, and rare minerals formed only under conditions of great temperature and pressure.

Publication of the 1980 paper brought criticism from the geologic community, and an often acrimonious scientific debate ensued. Ten years later, after Alvarez's death, evidence was found of a large impact crater off the coast of the Yucatán peninsula in Mexico, providing support for the theory. Other researchers later found that the end-Cretaceous extinction of the dinosaurs may have occurred rapidly in geologic terms, over thousands of years, rather than millions of years as had previously been supposed. While alternative extinction theories have been proposed, including increased volcanism at the Deccan Traps, the impact crater theory remains dominant among relevant scholars.

Aviation

In his autobiography, Alvarez said, "I think of myself as having had two separate careers, one in science and one in aviation. I've found the two almost equally rewarding." An important contributor to this was his enjoyment of flying. He learned to fly in 1933, later earning instrument and multi-engine ratings. Over the next 50 years he accumulated over 1000 hours of flight time, most of it as pilot in command. He said, "I found few activities as satisfying as being pilot in command with responsibility for my passengers' lives."

Alvarez made numerous professional contributions to aviation. During World War II he led the development of multiple aviation-related technologies. Several of his projects are described above, including Ground Controlled Approach (GCA) for which he was awarded the Collier Trophy in 1945. He also held the basic patent for the radar transponder, for which he assigned rights to the U.S. government for $1.

Later in his career Alvarez served on multiple high level advisory committees related to civilian and military aviation. These included a Federal Aviation Administration task group on future air navigation and air traffic control systems, the President's Science Advisory Committee Military Aircraft Panel, and a committee studying how the scientific community could help improve the United States' capabilities for fighting a nonnuclear war.

Alvarez's aviation responsibilities led to many adventures. For example, while working on GCA he became the first civilian to fly a low approach with his view outside the cockpit obstructed. He also flew many military aircraft from the co-pilot's seat, including a B-29 Superfortress and a Lockheed F-104 Starfighter. In addition, he survived a crash during World War II as a passenger in a Miles Master.

Other activities

Alvarez was a member of the JASON Defense Advisory Group and the Bohemian Club.

Death

Alvarez died on September 1, 1988, of complications from a succession of recent operations for esophageal cancer. His remains were cremated, and his ashes were scattered over Monterey Bay. His papers are in The Bancroft Library at the University of California, Berkeley.

In popular culture

A thinly-disguised version of Alvarez appears in Sir Arthur C. Clarke's 1963 novel Glide Path.

In the 2023 film Oppenheimer, directed by Christopher Nolan, Alvarez was portrayed by actor Alex Wolff.

Awards and honors

• Fellow of the American Physical Society (1939) and President (1969)
• Collier Trophy of the National Aeronautics Association (1946)
• Member of the National Academy of Sciences (1947)
• Medal for Merit (1947)
• Fellow of the American Philosophical Society (1953)
• Fellow of the American Academy of Arts and Sciences (1958)
• California Scientist of the Year (1960)
• Albert Einstein Award (1961)
• Golden Plate Award of the American Academy of Achievement (1961)
• National Medal of Science (1963)
• Michelson Award (1965)
• Nobel Prize in Physics (1968)
• Member of the National Academy of Engineering (1969)
• University of Chicago Alumni Medal (1978)
• National Inventors Hall of Fame (1978)
• Enrico Fermi award of the US Department of Energy (1987)
• IEEE Honorary Membership (1988)
• The Boy Scouts of America named their Cub Scout SUPERNOVA award for Alvarez (2012)
• Minor planet 3581 Alvarez is named after him and his son, Walter Alvarez.

Selected publications

• "Two-element variable-power spherical lens", Patent US3305294A (December 1964)

Patents

• Golf training device
• Electronuclear Reactor
• Optical range finder with variable angle exponential prism
• Two-element variable-power spherical lens
• Variable-power lens and system
• Subatomic particle detector with liquid electron multiplication medium
• Method of making Fresnelled optical element matrix
• Optical element of reduced thickness
• Method of forming an optical element of reduced thickness
• Deuterium tagged articles such as explosives and method for detection thereof
• Stabilized zoom binocular
• Stand alone collision avoidance system
• Television viewer
• Stabilized zoom binocular
• Optically stabilized camera lens system
• Nitrogen detection
• Inertial pendulum optical stabilizer

Citations

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70. "National Medal of Science". American Institute of Physics. Archived from the original on August 8, 2016. Retrieved March 21, 2012.
71. "The Michelson Lectures and Award" (PDF). Case Western Reserve University. Archived from the original (PDF) on November 13, 2015. Retrieved March 21, 2012.
72. "Dr. Luis W. Alvarez". National Academy of Engineering. Retrieved April 17, 2011.
73. "Alumni Awards winners". University of Chicago. Archived from the original on October 18, 2014. Retrieved March 21, 2012.
74. "Hall of Fame / Inventor Profile – Luis Walter Alvarez". National Inventors Hall of Fame. Archived from the original on July 6, 2010. Retrieved March 21, 2012.
75. "Luis Alvarez, 1987". The Enrico Fermi Award. US Department of Energy. Archived from the original on November 1, 2014. Retrieved April 17, 2011.
76. "IEEE Honorary membership recipients" (PDF). IEEE. Archived from the original (PDF) on June 19, 2010. Retrieved April 17, 2011.
77. "Boy Scout award requirements". Archived from the original on July 30, 2016. Retrieved January 20, 2015.
78. "(3581) Alvarez". Dictionary of Minor Planet Names. Springer. 2003. p. 301. doi:10.1007/978-3-540-29925-7_3580. ISBN 978-3-540-29925-7.
79. Alvarez, Luis W. (March 4, 1958). "Golf training device". U.S. Patent No. 2,825,569. Washington, DC: U.S. Patent and Trademark Office.
80. Lawrence, E. O., McMillan, E. M., & Alvarez, L. W. (1960). Electronuclear Reactor (No. US 2933442).
81. Alvarez, L. W. (January 24, 1967). "Optical range finder with variable angle exponential prism". U.S. Patent No. 3,299,768. Washington, DC: U.S. Patent and Trademark Office.
82. Alvarez, Luis W. (February 21, 1967). "Two-element variable-power spherical lens". U.S. Patent 3,305,294. Washington, DC: U.S. Patent and Trademark Office.
83. Alvarez, Luis W., and William E. Humphrey. (April 21, 1970). "Variable-power lens and system". U.S. Patent No. 3,507,565. Washington, DC: U.S. Patent and Trademark Office.
84. Alvarez, Luis W., Stephen E. Derenzo, Richard A. Muller, Robert G. Smits, and Haim Zaklad. (April 25, 1972). "Subatomic particle detector with liquid electron multiplication medium". U.S. Patent No. 3,659,105. Washington, DC: U.S. Patent and Trademark Office.
85. Alvarez, L. (June 19, 1973). "Method of making fresnelled optical element matrix". U.S. Patent No. 3,739,455. Washington, DC: U.S. Patent and Trademark Office.
86. Alvarez, L. (August 6, 1974). "Optical element of reduced thickness". U.S. Patent No. 3,827,798. Washington, DC: U.S. Patent and Trademark Office.
87. Alvarez, L. (August 13, 1974). "Method of forming an optical element of reduced thickness". U.S. Patent No. 3,829,536. Washington, DC: U.S. Patent and Trademark Office.
88. Alvarez, Luis W.,(February 17, 1981). "Deuterium tagged articles such as explosives and method for detection thereof". U.S. Patent No. 4,251,726. Washington, DC: U.S. Patent and Trademark Office.
89. Alvarez, Luis W., and Schwemin, Arnold J. (February 23, 1982). "Stabilized zoom binocular". U.S. Patent No. 4,316,649 . Washington, DC: U.S. Patent and Trademark Office.
90. Alvarez, Luis W. (February 23, 1982). "Stand alone collision avoidance system". U.S. Patent No. 4,317,119. Washington, DC: U.S. Patent and Trademark Office.
91. Alvarez, Luis W., (August 16, 1983). "Television viewer". U.S. Patent No. 4,399,455. Washington, DC: U.S. Patent and Trademark Office.
92. Alvarez, Luis W., and Schwemin, Arnold J. (November 29, 1983). "Stabilized zoom binocular". U.S. Patent No. 4,417,788. Washington, DC: U.S. Patent and Trademark Office.
93. Alvarez, Luis W., and Schwemin, Arnold J. (October 7, 1986). "Optically stabilized camera lens system". U.S. Patent No. 4,615,590. Washington, DC: U.S. Patent and Trademark Office.
94. Alvarez, Luis W. (July 12, 1988). "Nitrogen detection". U.S. Patent No. 4,756,866. Washington, DC: U.S. Patent and Trademark Office.
95. Alvarez, Luis W., and Sporer, Stephen F. (March 27, 1990). "Inertial pendulum optical stabilizer". U.S. Patent No. 4,911,541. Washington, DC: U.S. Patent and Trademark Office.

General references

• Alvarez, L. W. (1987). Alvarez: Adventures of a Physicist. Basic Books. ISBN 0-465-00115-7 – via Internet Archive.
• Heilbron, J. L.; Seidel, R. W. (1989). Lawrence and His Laboratory. University of California Press. ISBN 0-520-06426-7.
• Trower, W. P. (2009). Luis Walter Alvarez 1911–1988 (PDF). Biographical Memoirs. National Academy of Sciences. Retrieved March 21, 2013.
• Trower, W. P. (1987). Discovering Alvarez: Selected Works of Luis W. Alvarez with Commentary by His Students and Colleagues. University of Chicago Press. ISBN 0-226-81304-5.

External links

• Luis Walter Alvarez on Nobelprize.org including the Nobel Lecture, December 11, 1968, "Recent Developments in Particle Physics"
• About Luis Alvarez
• IEEE interview with Johnston, patentholder of the exploding-bridgewire detonator
• Weisstein, Eric Wolfgang (ed.). "Alvarez, Luis W. (1911–1988)". ScienceWorld.
• Annotated bibliography for Luis Alvarez from the Alsos Digital Library for Nuclear Issues Archived August 28, 2006, at the Wayback Machine
• Garwin, Richard L., 1992, "Memorial Tribute For Luis W. Alvarez" in Memorial Tributes, National Academy of Engineering, Vol. 5. Washington, D.C.: National Academy Press.
• Biography and Bibliographic Resources, from the Office of Scientific and Technical Information, United States Department of Energy
• Oral History interview transcript with Luiz Alvarez on 14 Feb 1967, American Institute of Physics, Niels Bohr Library and Archives
• Oral History interview transcript with Luiz Alvarez on 15 February 1967, American Institute of Physics, Niels Bohr Library and Archives

v t e Laureates of the Nobel Prize in Physics
1901–1925	1901: Röntgen 1902: Lorentz / Zeeman 1903: Becquerel / P. Curie / M. Curie 1904: Rayleigh 1905: Lenard 1906: J. J. Thomson 1907: Michelson 1908: Lippmann 1909: Marconi / Braun 1910: Van der Waals 1911: Wien 1912: Dalén 1913: Kamerlingh Onnes 1914: Laue 1915: W. L. Bragg / W. H. Bragg 1916 1917: Barkla 1918: Planck 1919: Stark 1920: Guillaume 1921: Einstein 1922: N. Bohr 1923: Millikan 1924: M. Siegbahn 1925: Franck / Hertz
1926–1950	1926: Perrin 1927: Compton / C. Wilson 1928: O. Richardson 1929: De Broglie 1930: Raman 1931 1932: Heisenberg 1933: Schrödinger / Dirac 1934 1935: Chadwick 1936: Hess / C. D. Anderson 1937: Davisson / G. P. Thomson 1938: Fermi 1939: Lawrence 1940 1941 1942 1943: Stern 1944: Rabi 1945: Pauli 1946: Bridgman 1947: Appleton 1948: Blackett 1949: Yukawa 1950: Powell
1951–1975	1951: Cockcroft / Walton 1952: Bloch / Purcell 1953: Zernike 1954: Born / Bothe 1955: Lamb / Kusch 1956: Shockley / Bardeen / Brattain 1957: C. N. Yang / T. D. Lee 1958: Cherenkov / Frank / Tamm 1959: Segrè / Chamberlain 1960: Glaser 1961: Hofstadter / Mössbauer 1962: Landau 1963: Wigner / Goeppert Mayer / Jensen 1964: Townes / Basov / Prokhorov 1965: Tomonaga / Schwinger / Feynman 1966: Kastler 1967: Bethe 1968: Alvarez 1969: Gell-Mann 1970: Alfvén / Néel 1971: Gabor 1972: Bardeen / Cooper / Schrieffer 1973: Esaki / Giaever / Josephson 1974: Ryle / Hewish 1975: A. Bohr / Mottelson / Rainwater
1976–2000	1976: Richter / Ting 1977: P. W. Anderson / Mott / Van Vleck 1978: Kapitsa / Penzias / R. Wilson 1979: Glashow / Salam / Weinberg 1980: Cronin / Fitch 1981: Bloembergen / Schawlow / K. Siegbahn 1982: K. Wilson 1983: Chandrasekhar / Fowler 1984: Rubbia / Van der Meer 1985: von Klitzing 1986: Ruska / Binnig / Rohrer 1987: Bednorz / Müller 1988: Lederman / Schwartz / Steinberger 1989: Ramsey / Dehmelt / Paul 1990: Friedman / Kendall / R. Taylor 1991: de Gennes 1992: Charpak 1993: Hulse / J. Taylor 1994: Brockhouse / Shull 1995: Perl / Reines 1996: D. Lee / Osheroff / R. Richardson 1997: Chu / Cohen-Tannoudji / Phillips 1998: Laughlin / Störmer / Tsui 1999: 't Hooft / Veltman 2000: Alferov / Kroemer / Kilby
2001– present	2001: Cornell / Ketterle / Wieman 2002: Davis / Koshiba / Giacconi 2003: Abrikosov / Ginzburg / Leggett 2004: Gross / Politzer / Wilczek 2005: Glauber / Hall / Hänsch 2006: Mather / Smoot 2007: Fert / Grünberg 2008: Nambu / Kobayashi / Maskawa 2009: Kao / Boyle / Smith 2010: Geim / Novoselov 2011: Perlmutter / Schmidt / Riess 2012: Wineland / Haroche 2013: Englert / Higgs 2014: Akasaki / Amano / Nakamura 2015: Kajita / McDonald 2016: Thouless / Haldane / Kosterlitz 2017: Weiss / Barish / Thorne 2018: Ashkin / Mourou / Strickland 2019: Peebles / Mayor / Queloz 2020: Penrose / Genzel / Ghez 2021: Parisi / Hasselmann / Manabe 2022: Aspect / Clauser / Zeilinger 2023: Agostini / Krausz / L'Huillier 2024: Hopfield / Hinton

v t e Manhattan Project
Timeline
Sites	Ames Berkeley Chicago (Site A) Dayton Hanford Inyokern Los Alamos Montreal New York Oak Ridge Salt Wells Pilot Plant Trinity Wendover Heavy water sites
Administrators	Vannevar Bush Arthur Compton James B. Conant Priscilla Duffield Thomas Farrell Leslie Groves John Lansdale Ernest Lawrence James Marshall Franklin Matthias Dorothy McKibbin Kenneth Nichols Robert Oppenheimer Deak Parsons Boris Pash William Purnell Frank Spedding Charles Thomas Paul Tibbets Bud Uanna Harold Urey Stafford Warren Ed Westcott Roscoe Wilson
Scientists	Luis Alvarez Robert Bacher Hans Bethe Aage Bohr Niels Bohr Norris Bradbury James Chadwick John Cockcroft Charles Critchfield Harry Daghlian John R. Dunning Enrico Fermi Richard Feynman Val Fitch James Franck Klaus Fuchs Maria Goeppert Mayer George Kistiakowsky George Koval Willard Libby Edwin McMillan Mark Oliphant George B. Pegram Norman Ramsey Jr. Isidor Isaac Rabi James Rainwater Bruno Rossi Glenn Seaborg Emilio Segrè Louis Slotin Henry DeWolf Smyth Leo Szilard Edward Teller Stanisław Ulam John von Neumann John Wheeler Eugene Wigner Robert Wilson Leona Woods Chien-Shiung Wu
Operations	Alsos Mission Bombings of Hiroshima and Nagasaki Operation Crossroads Operation Peppermint Project Alberta Silverplate 509th Composite Group Enola Gay Bockscar The Great Artiste
Weapons	Fat Man Little Boy Pumpkin bomb Thin Man
Related topics	African Americans Atomic Energy Act of 1946 Bismuth phosphate process British contribution Calutron Girls Chicago Pile-1 Demon core Einstein–Szilard letter Franck Report Interim Committee K-25 Project Los Alamos Primer Nobel Prize laureates Oppenheimer security hearing Plutonium Quebec Agreement RaLa Experiment S-1 Executive Committee S-50 Project Smyth Report Uranium X-10 Graphite Reactor Y-12 Project
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