H. Richard Crane

Q: What Schools Are Affiliated With H. Richard Crane

H. Richard Crane is affiliated with the following schools: California Institute of Technology, University of Michigan, Stanford University

H. Richard Crane's AcademicInfluence.com Rankings

H. Richard Crane

Physics

#1153

World Rank

#1817

Historical Rank

#512

USA Rank

physics Degrees

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Physics

H. Richard Crane's Degrees

Masters Physics Stanford University
Bachelors Physics Stanford University

Why Is H. Richard Crane Influential?

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According to Wikipedia, Horace Richard Crane was an American physicist, the inventor of the Race Track Synchrotron, a recipient of President Ronald Reagan's National Medal of Science "for the first measurement of the magnetic moment and spin of free electrons and positrons". He was also noted for proving the existence of neutrinos. The National Academy of Sciences called Crane "an extraordinary physicist". The University of Michigan called him "one of the most distinguished experimental physicists of the 20th century". Crane was a chairman of the department of physics and a professor of physics at the University of Michigan, a member of the National Academy of Sciences.

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H. Richard Crane's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

University of Michigan Radiocarbon Dates X (1956) (132)
University of Michigan Radiocarbon Dates XIV (1958) (107)
Precision Measurement of the g Factor of the Free Electron (1963) (72)
High-Energy Accelerators (1955) (58)
University of Michigan Radiocarbon Dates XII (1958) (56)
ATTAINMENT OF VERY HIGH ENERGY BY MEANS OF INTERSECTING BEAMS OF PARTICLES (1956) (46)
AN EXPERIMENTAL MEASUREMENT OF THE GYROMAGNETIC RATIO OF THE FREE ELECTRON (1954) (44)
SEARCH FOR AN ELECTRIC DIPOLE MOMENT OF THE ELECTRON (1959) (42)
Measurement of the g Factor of Free, High-Energy Electrons (1961) (39)
The Energy and Momentum Relations in the Beta-Decay, and the Search for the Neutrino (1948) (33)
Measurements of the Mobilities of the Negative Ions in Oxygen and in Mixtures of Oxygen with the Noble Gases, Hydrogen, Nitrogen, and Carbon Dioxide (1957) (30)
University of Michigan Radiocarbon Dates IV (1959) (27)
Antiquity of the Sandia Culture: Carbon-14 Measurements. (1955) (27)
University of Michigan Radiocarbon Dates V (1960) (24)
Radioactive iodine concentration in the fetal human thyroid gland from fall-out. (1960) (22)
Further Experiments on the Recoil of the Nucleus in Beta-Decay (1939) (21)
Further experiments with artificially produced radioactive substances (1934) (20)
The emission of negative electrons from lithium and fluorine bombarded with deuterons (1935) (20)
The Emission of Negative Electrons from Boron Bombarded by Deuterons (1935) (18)
Radioactivity from carbon and boron oxide bombarded with deutons and the conversion of positrons into radiation (1934) (18)
University of Michigan Radiocarbon Dates VI (1961) (17)
New Experimental Evidence for the Existence of a Neutrino (1938) (17)
The Multiple Scattering of Fast Electrons (1939) (15)
Artificial Production of Neutrons (1933) (14)
Production of neutrons by high speed deutons (1933) (13)
University of Michigan Radiocarbon Dates VII (1962) (13)
The Racetrack: A Proposed Modification of the Synchrotron (1946) (13)
THE g FACTOR OF THE ELECTRON. (1968) (13)
ARTIFICIAL PRODUCTION OF RADIO-ACTIVE SUBSTANCES. (1934) (13)
Short Foucault pendulum: A way to eliminate the precession due to ellipticity (1981) (12)
CO2‐CS2 Geiger Counter (1961) (12)
University of Michigan Radiocarbon Dates XIII (1970) (11)
Direct Measurement of the g Factor of the Free Positron (1966) (11)
Foucault pendulum ‘‘wall clock’’ (1995) (10)
The Single Scattering of Electrons in Gases (1945) (9)
On the production of neutrons from lithium (1933) (8)
Delayed Emission of Electrons from the Cathode in a Counter When Operated above the Plateau (1949) (8)
Cloud chamber studies of the gamma-radiation from lithium bombarded with protons (1935) (7)
University of Michigan Radiocarbon Dates IX (1964) (7)
Problems for Introductory Physics (1969) (7)
The Beta-Ray Spectra of Several Slow Neutron-Activated Substances (1936) (7)
Disintegration of boron by deutons and by protons (1934) (7)
The Beta-Ray Spectra of Li8 and B12 (1937) (7)
An Attempt to Observe the Absorption of Neutrinos (1939) (6)
Gamma-Rays from Carbon Bombarded with Deutons (1934) (6)
Experiments on the Design of Synchrotron Magnets (1947) (6)
The Foucault pendulum as a murder weapon and a physicist’s delight (1990) (6)
The stirling engine—173 years old and running (1990) (6)
University of Michigan Radiocarbon Dates XI (1966) (6)
Gamma-rays from the disintegration of beryllium by deuterons and protons - Beryllium bombarded with deuterons (1935) (6)
Experiments on the Gamma-Radiation from Lithium and Fluorine Bombarded with Protons (1937) (6)
The Use of Radioactive Elements as Tracers in Physiology (1939) (6)
Direct Centrifugation onto Electron Microscope Specimen Films (1944) (6)
Gamma-rays from boron bombarded with protons (1935) (5)
The Absorption of High Energy Electrons. Part III (1937) (5)
Chattering, the chatterring, and the hula hoop (1992) (5)
Evidence for a Particle of Intermediate Mass (1938) (5)
A Cloud Chamber Study of the Compton Effect (1936) (5)
What can a dimple do for a skipping stone (1988) (5)
High energy gamma-rays from lithium and fluorine bombarded with protons (1934) (5)
On the Creation of Pairs or Positrons by Fast Electrons (1939) (5)
An Automatic Counter for Age Determination by the C14 Method. (1952) (5)
Experiments in Teaching Captives (1966) (4)
Alignment of the Earth's Magnetic Field with the Axis of Rotation and Reversals of Polarity: Laboratory Experiments on a Mechanism. (1974) (4)
Disintegration of Beryllium by Deutons (1934) (4)
What does the drinking bird know about jet lag (1989) (4)
The Pair Internal Conversion Coefficient in the F+H′ Reaction and Measurements on the Gamma-Ray Spectrum (1939) (4)
The Absorption of High Energy Electrons. IV (1939) (4)
Evidence of an Excited State in the Alpha-Particle (1934) (4)
Current Status of the Identification Problem: the Archaeological Viewpoint. In: the Identification of Non-Artifactual Archaeological Materials (1957) (4)
Transmutation of lithium by deutons and its bearing on the mass of the neutron (1934) (4)
Cloud Chamber for Nuclear Disintegration Studies (1937) (4)
How We Happened to Measure g–2: A Tale of Serendipity (2000) (4)
Folded-Path Doppler and the Measurement of Blood Flow. (1999) (3)
The Pop-Pop boat (1997) (3)
The masses of Be8, Be9 and B11, as determined from transmutation data (1935) (3)
Discharge of a Geiger Counter at Voltages above the Plateau (1949) (3)
Gamma-Rays from Lithium Bombarded with Protons (1934) (3)
Gamma-Rays from Nitrogen Bombarded with Deuterons (1935) (3)
Gamma-Rays from B+D (1939) (3)
Gamma-Rays from Beryllium and Nitrogen Bombarded with Deuterons (1940) (3)
University of Michigan Radiocarbon Dates VIII (1963) (3)
University of Michigan Radiocarbon Dates XV (1972) (3)
Better Teaching with Better Problems and Exams (1969) (3)
Uncommon uses of the stereoscope (1987) (2)
An Experiment toward Establishing Communication from Audience to Lecturer (1961) (2)
Creative Thinking and Experimenting (1960) (2)
Opportunities in geophysics (1971) (2)
Making light bulbs last forever (1983) (2)
High Potential Apparatus for Nuclear Disintegration Experiments (1937) (2)
Three intuition teasers (1991) (2)
Brrrr! The origin of the wind chill factor (1989) (2)
g‐2 techniques: Past evolution and future prospects (1976) (2)
The Gamma-Radiation from Lithium Bombarded with Protons (1937) (2)
The air bag: An exercise in Newton’s laws (1985) (2)
Students Do Not Think Physics Is “Relevant.” What Can We Do About It? (1968) (2)
The quartz watch with digital readout (1994) (2)
How Things Work (1992) (2)
How Things Work: A Spinning Top, Lenz's Law and Electric Watches. (1984) (1)
Why your gas tank doesn’t overflow (1987) (1)
Multiple Scattering of Fast Electrons: A Correction (1939) (1)
(Abstract) the CO2–CS2 Geiger Counter and its Use in C14 Dating (1961) (1)
David M. Dennison (1976) (1)
Response of the Oersted Medalist (1977) (1)
The Energy Loss of Electrons in Carbon and the Decay of the Mesotron (1940) (1)
A Shadow Casting Unit for the RCA Electron Microscope (1945) (1)
Light Source for Cloud Chamber Illumination (1937) (1)
Bar codes are on everything—What do they say? (1986) (1)
A tornado in a soda bottle and angular momentum in the Washbasin (1987) (1)
Reception of Pictures from the Weather Satellites Using Homemade Equipment. (1969) (1)
Is the Momentum a Sufficient Description of a Photon or an Electron (1937) (1)
How things work: A tower that seems to levitate (1996) (1)
DATING OF RELICS BY RADIOCARBON ANALYSIS (1951) (1)
An Example of the Relativity Change of Mass with Speed (1938) (1)
The quartz analog watch: A wonder machine (1993) (1)
Automatic Stabilization of the Overvoltage on a Geiger Counter (1949) (1)
The Absorption Coefficient of 5.8-Mev Gamma-Radiation in Aluminum (1939) (1)
Note on Making Beryllium Targets (1938) (1)
Frisbees, can lids, and gyroscopic effects (1983) (1)
A thermometer whose memory is a one-sided magnet (1999) (1)
How lumps of steel shape themselves into near‐perfect spheres (1986) (1)
Mini-motors Driven by Waves. (1994) (0)
ANNOUNCEMENTS, NEWS AND NOTES: Leonard I. Schiff Oersted Medalist for 1965 (1966) (0)
Physics in the copy machine (1984) (0)
Have you picked a lock lately (1984) (0)
New life for an old device: The ring interferometer (1986) (0)
How Antilock Brakes May Save You from a Spin. (1994) (0)
How to measure the flow of liquids (1989) (0)
An Introduction: Sherwood K. Haynes (1974) (0)
Help for forgetful car owners and lazy yo‐yo throwers (1988) (0)
How things work. Digital electronic balances: mass or weight? (1991) (0)
Edward M. Purcell: Oersted Medalist for 1967 (1967) (0)
What is the secret of ‘‘maintenance‐free’’ car batteries? (1985) (0)
A Method of Photographing a Cloud Chamber between the Poles of an Iron Magnet (1947) (0)
University of Michigan synchrotron project : progress report : September 1, 1954, to August 1, 1955. (1955) (0)
How to lift a ship without doing much work (1985) (0)
Physics from Dripping Water. (1995) (0)
Light, dark, or burned? Two automatic toasters (1984) (0)
Time and place: Longitude (1996) (0)
How does the honeybee sense polarization (1990) (0)
More about structures of sticks and string (1997) (0)
Metal locators and related devices (1984) (0)
Body volume measured by sound waves (1987) (0)
How Things Work: Light, Dark, or Burned? Two Automatic Toasters. (1984) (0)
How to rotate a ball from the inside (1988) (0)
Removal of Scratches from Photographic Film (1937) (0)
Miss Seeton by Moonlight (2000) (0)
How Things Work: New Watches and New Capacitors. (1996) (0)
The Lock Everybody Has Opened. (1996) (0)
Proceedings of the American Association of Teachers: Summer Meeting at the University of Wisconsin, Madison, Wisconsin 18–20 June 1964 (1965) (0)
How things work—Never throw a 2‐inch speaker away: It has many uses (1992) (0)
A Simple Design for a Cloud Chamber (1937) (0)
H. William and AIP (1987) (0)
How things work: A plywood goose that seems to fly (1986) (0)
Maintaining the Geometrical Alignment of a Large Accelerator (1956) (0)
Your (not always) friendly traffic signals (1984) (0)
Research activities in synchrotron and g-factor experiments : progress report (1956) (0)
A magnetic compass with no moving parts (1988) (0)
Locating the studs in a wall (1985) (0)
How Things Work. Mystery Glow-Ball: When Is a Battery Not a Battery?. (1989) (0)
Smart ignition systems on modern cars (1986) (0)
Leonard I. Schiff: Oersted Medalist for 1965 (1966) (0)
Proceedings of the American Association of Teachers: Thirty-Fourth Annual Meeting, Hotel Statler Hilton and the Manhattan Center, New York City, 27–30 January 1965 (1965) (0)
Some of the physics of cardiac pacemakers (1986) (0)
Popping bimetal can keep you warm or cool (1998) (0)
How Things Work: Physics in the Copy Machine. (1984) (0)
How Things Work--Doppler Radar: The Speed of the Air in a Tornado. (1989) (0)
On electric shocks and spinning eggs (1989) (0)
25 years later: time of self‐examination (1973) (0)
Penguins on an escalator (1987) (0)
The Doppler ball: A novel use of the piezo‐electric field (1988) (0)
How everyday things work (1985) (0)
Frisbees, can lids, and gyroscopic effects [Phys. Teach.21, 325 (May 1983)] (2004) (0)
FINAL REPORT, UNIVERSITY OF MICHIGAN CYCLOTRON (1952) (0)
Flourescent lights: A few basic facts (1985) (0)
Three‐dimensional moiré patterns (1987) (0)
Sensing the rotation of the Earth (1992) (0)
The frictionless bird and the aerodynamic tortoise (1993) (0)
The University of Michigan racetrack synchrotron, February 1, 1950 : progress report (1950) (0)
Edward M. Purcell: Oersted Medalist for 1967 [Reprinted from Am. J. Phys. 35 (6), 479–480 (1967)] (1997) (0)
How a cable car turns a corner (1986) (0)
What makes a fishing spinner spin (1991) (0)
An engine that runs on light (1989) (0)
Transient magnetic effects in a scale model of the earth's core. (1977) (0)
A Reply to the Above Note by L. Wertenstein (1938) (0)
The cold night sky (1984) (0)
Use of Zeeman Splitting in Positronium as a Means of Polarization Analysis in an Experiment on the g Factor of the Free Positron (1967) (0)
Reception of Pictures From the Weather Satellites Using Homemade Equipment, Part I: Something About the Orbits. (1969) (0)
The first mechanical clock and its primitive escapement (1998) (0)
The VT Fuze, from Half a Century Ago. (1996) (0)
Ionization smoke alarms (1984) (0)
Additional Stabilization for the Beam Current in the RCA Type B Electron Microscope (1945) (0)
Robert R. Davis and Physics Today (1965) (0)
How Things Work: Metal Locators and Related Devices. (1984) (0)
How things work: A light brighter than the sun (1996) (0)
University of Michigan cyclotron : final report (1952) (0)
Reaching steady‐state employment (1972) (0)
Liquid crystal displays: watches, calculators and (soon) cars (1983) (0)
Why shake your fever thermometer?—and more (1998) (0)
University of Michigan synchrotron project : progress report : September 1, 1953, to September 1, 1954 (1954) (0)
The hydraulic ram: How to make water go uphill (1987) (0)
Note on the Existence of Heavy Beta-Rays (1938) (0)
How to pump blood without a heart (1984) (0)
Bad timing in swimming races: A physicist to the rescue (1999) (0)

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What Schools Are Affiliated With H. Richard Crane?

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