Arthur L. Robinson

Arthur L. Robinson's AcademicInfluence.com Rankings

Arthur L. Robinson

Chemistry

#4747

World Rank

#5836

Historical Rank

Chemical Engineering

#627

World Rank

#647

Historical Rank

Physical Chemistry

#749

World Rank

#804

Historical Rank

chemistry Degrees

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Chemistry

Arthur L. Robinson's Degrees

PhD Materials Science Stanford University
Bachelors Chemical Engineering California Institute of Technology

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Arthur L. Robinson'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

Solid-state batteries enter EV fray (2014) (77)
GaAs Readied for High-Speed Microcircuits. (1983) (71)
Powerful New Magnet Material Found: Several groups in Japan and the United States independently hit upon the same iron-based compound, which is already going to market. (1984) (39)
History of Synchrotron Radiation (2015) (35)
New superconductors for a supercomputer. (1982) (31)
A Rescue for Wisconsin's Synchrotron Source: Three years after its completion, Aladdin glows only feebly; to get more light out requires new NSF money and help from DOE accelerator experts. (1985) (28)
Flexible PVF2 Film: An Exceptional Polymer for Transducers. (1978) (28)
Advanced Light Source (2002) (26)
New ways to make microcircuits smaller. (1980) (26)
Is Diamond the New Wonder Material?: American researchers growing diamond films are scrambling to catch up with their Soviet and Japanese counterparts with the help of money from the Star Wars office. (1986) (20)
Looking for a needle in a haystack. (1981) (20)
A long-range plan for nuclear science. (1980) (20)
One Billion Transistors on a Chip?: The annual rate of increase in numbers of transistors on a chip is slowing as theoretical limits are neared, but there may be a billion by the year 2000. (1984) (19)
Electron Microscope Inventors Share Nobel Physics Prize: Ernst Ruska built the first electron microscope in 1931; Gerd Binnig and Heinrich Rohrer developed the scanning tunneling microscope 50 years later. (1986) (19)
Metallurgy: extraordinary alloys that remember their past. (1976) (19)
Particle physics: new evidence from Germany for fifth quark. (1978) (18)
Now Four Laboratories Have Squeezed Light: But a group at the University of Texas at Austin, reporting a 42% reduction in the noise recorded by a detector, is the second-lap leader in the squeezing sweepstakes. (1986) (17)
An oxygen key to the new superconductors. (1987) (17)
CMOS Future for Microelectronic Circuits: Low power consumption of complementary metal-oxide-semiconductor integrated circuits drives next stage of ultraminiaturization. (1984) (14)
Image Reconstruction (I): Computerized X-Ray Scanners (1975) (14)
Physicists try to find order in chaos. (1982) (14)
Computational chemistry: getting more from a minicomputer. (1976) (14)
Array processors: maxi number crunching for a mini price. (1979) (13)
Materials Scientists Seek a Unified Voice: The rise of materials science as a recognizable discipline paralleled the growth of the Materials Research Laboratories now run by NSF, but funding and identity problems remain. (1987) (13)
The Macromolecular Crystallography Facility at the Advanced Light Source (1995) (12)
Atoms in Strong Laser Fields Obey the Rules: Experimentalists and theorists now agree that the multiple ionization of rare gas atoms by infrared, visible, or ultraviolet laser light takes place one electron at a time. (1986) (12)
Fractal Fingers in Viscous Fluids: Highly unstable viscous fingers break up into many-branched structures that are suggestive of fractal geometry. (1985) (12)
Bell Labs Generates Squeezed Light: Quantum fluctuations set a minimum noise level in optical signals, but nonlinear optics provides a way to squeeze below this limit. (1985) (12)
Laser annealing: processing semiconductors without a furnace. (1978) (12)
An Optical Measurement of Berry's Phase: Overlooked for 60 years, a phase factor that can creep into quantum mechanical wave functions has implications in areas ranging from molecular physics to unified field theories. (1986) (11)
A Chemical Route to Advanced Ceramics: The secret to improving a ceramic material is to control its structure at very small length scales in an early stage of fabrication; chemistry may be the way to achieve this goal. (1986) (11)
More people are talking to computers as speech recognition enters the real world. (1979) (11)
When Are Viscous Fingers Stable?: Recent research concludes that a single, stable finger can form when a lower viscosity fluid pushes against one of higher viscosity. (1985) (11)
Impact of electronics on employment: productivity and displacement effects. (1977) (10)
Energy storage (I): using electricity more efficiently. (1974) (10)
HPLC: The New King of Analytical Chemistry? (1979) (9)
IBM Drops Superconducting Computer Project: Problems with a high-speed memory chip would delay a Josephson junction computer long enough for semiconductors to catch up. (1983) (9)
X-ray Holography Experiment Planned. (1982) (8)
Tournament competition fuels computer chess. (1979) (8)
Computers: First the Maxi, Then the Mini, Now It's the Micro. (1974) (8)
Are VLSI Microcircuits Too Hard to Design? (1980) (8)
Infrared photochemistry (I): laser-catalyzed reactions. (1976) (8)
Computing Without Dissipating Energy: Computers are machines and should be subject to thermodynamics; what is the minimum energy needed for computation? (1984) (8)
High-resolution imaging with soft x-rays. (1982) (8)
CERN Sets Intermediate Vector Boson Hunt. (1981) (7)
Energy Storage (II): Developing Advanced Technologies. (1974) (7)
Synchrotron Radiation (I): A Light for All Seasons (1975) (7)
Image Reconstruction (II): Computerized Scanner Explosion (1975) (7)
Nanocomputers from organic molecules? (1983) (7)
A Spatially Resolved Surface Spectroscopy: A scanning tunneling microscope not only images atoms on surfaces, it may also yield local surface electronic and vibrational spectra. (1985) (7)
More superconductivity questions than answers. (1987) (6)
New evidence at wayne state for superconductivity at 240 k. (1987) (6)
Analytical chemistry: using lasers to detect less and less. (1978) (6)
Superconductivity: surpassing the hydrogen barrier. (1974) (6)
Giant corporations from tiny chips grow. (1980) (6)
Antiferromagnetism Observed in La2CuO4: Magnetism and superconductivity are usually mutually exclusive, but they seem to be intimately related in the new high-temperature superconducting compounds. (1987) (6)
High Spatial Resolution Ion Microprobe: With focused scanning ion beams, researchers can now make elemental maps with 400-angstrom resolution by secondary ion mass spectrometry. (1984) (6)
Glassy Metals: No Longer a Laboratory Curiosity (1973) (6)
Fermilab installing superconducting magnets. (1982) (5)
Critical phenomena: experiments show theory on right track. (1977) (5)
IBM Images Surfaces by Electron Tunneling. (1983) (5)
Computer chess: belle sweeps the board. (1980) (5)
Will u.s. Skip neutron scattering derby? (1981) (5)
Consensus on Silicon Surface Structure Near: Experiment and theory support a recent Japanese model of the elusive structure of a clean silicon surface, thereby bringing a journey of a quarter century close to its end. (1986) (5)
Surface science (I): a way to tell where the atoms are. (1977) (5)
Perilous times for u.s. Microcircuit makers. (1980) (5)
Pushing the frontiers of lithium-ion batteries raises safety questions (2016) (5)
CERN Gives Nod to Four LEP Detectors. (1982) (5)
Multiple Quantum Wells for Optical Logic: Structures comprising alternating layers of gallium arsenide--based semiconductors are candidates for the optical analog of transistors. (1984) (5)
Spatial quantization in three dimensions. (1985) (5)
Infrared Photochemistry (II): Multiphoton Isotope Separation. (1976) (5)
CERN Vector Boson Hunt Successful: Between them, two groups of physicists have collected 90 W's and 10 Z0's whose properties fit the predictions of the electro-weak theory. (1983) (5)
Problems with ultraminiaturized transistors. (1980) (5)
A Superconductivity Happening: Amid a rock concert atmosphere, a late-night session at the March American Physical Society meeting draws a huge crowd to hear the latest on the new superconductors. (1987) (5)
Crystal Anisotropy Directs Solidification: Simplified mathematical models of solidification elevate crystalline anisotropy to main player in selecting dendritic growth patterns. (1984) (5)
Loophole closed in quantum mechanics test. (1983) (5)
Superconducting electronics: toward an ultrafast computer. (1978) (5)
The ALS — A third-generation light source (1990) (5)
Amorphous silicon: a new direction for semiconductors. (1977) (5)
Demonstrating Single Photon Interference: Even a single photon can manifest both wave and particle natures according to quantum theory, but demonstrating this is not so straightforward. (1986) (5)
A Silicon Solution for Gallium Arsenide IC's: Epitaxial growth of crystalline gallium arsenide layers on silicon wafers could combine the best properties of both semiconductors in future high-speed microelectronic chips. (1986) (4)
Plug pulled on chemistry computer center. (1980) (4)
Electron microscopy: imaging molecules in three dimensions. (1976) (4)
A nuclear puzzle emerges at berkeley. (1980) (4)
Experimental Memory Chips Reach 1 Megabit: As they become larger, memories become an increasingly important part of the integrated circuit business, technologically and economically. (1984) (4)
National synchrotron light source readied. (1981) (4)
Atomic beams probe surface vibrations. (1982) (4)
Atomic-Resolution TEM Images of Surfaces: The newest electron microscopes that crack the 2-angstrom barrier can resolve atom positions on metal and semiconductor surfaces. (1985) (4)
Nuclear Science: X-ray Evidence for Superheavy Elements. (1976) (4)
Superconductor Claim Raised to 94 K: A joint effort by researchers at the University of Alabama in Huntsville and the University of Houston yields the first superconductor to operate above liquid nitrogen temperature. (1987) (4)
New Test of Variable Gravitational Constant: Two groups using same data put new limits on how much G can vary with time, making Dirac's Large Numbers Hypothesis less likely. (1983) (4)
Neutron scattering: a new national facility at oak ridge. (1978) (4)
How to Do EXAFS in Your Own Laboratory. (1979) (4)
CERN Council Defers LEP Approval. (1981) (4)
Micromainframe is newest computer on a chip. (1981) (4)
Berkeley Advanced Materials Center OK'd. (1983) (4)
Advanced storage batteries: progress, but not electrifying. (1976) (4)
Soft X-ray Laser at Lawrence Livermore Lab: An extensive battery of diagnostic tests makes Livermore's the first well-documented x-ray laser; Princeton is not far behind. (1984) (4)
Record High-Temperature Superconductors Claimed: Several groups have reported evidence for superconductivity at temperatures up to 70 K in samples containing lanthanum, copper, oxygen, and either barium or another group IIA metal. (1987) (4)
Colonizing Mars: the age of planetary engineering begins. (1977) (4)
Synchrotron radiation assessed. (1982) (4)
Plasmas Produce Very Intense X-ray Pulses. (1979) (3)
Transistors Head for the Trenches: Space on the surface of a random access memory chip is limited; vertical transistors on trench walls permit denser packing. (1986) (3)
DESY Looks to an International Future. (1981) (3)
Is a diamond really forever? (1979) (3)
The long and short of lasers (I): the far infrared. (1974) (3)
Chalcogenide glasses: a decade of dissension and progress. (1977) (3)
Physicists Give ISABELLE a Yes, But . . (1981) (3)
Surface Science (II): An X-ray Probe for Adsorbed Molecules. (1977) (3)
Communicating with computers by voice. (1979) (3)
MIT Patents IR Laser Photochemistry. (1976) (3)
Bose-Einstein Condensate in Hydrogen (1998) (3)
Synchrotron Radiation (II): Formidable Competition Overseas (1975) (3)
LIMS Is Next Step in Laboratory Automation. (1983) (3)
Multiple minicomputers: inexpensive and reliable computing. (1975) (3)
Zeta particle in question. (1985) (3)
Stereology: promise of a more quantitative microscopy. (1974) (3)
Microscopy with Spin-Polarized Electrons: NBS scientists combine a novel detector of spin-polarized electrons with a field-emission SEM to image the magnetic structure of surfaces. (1985) (3)
Atomic Physics Tests Lorentz Invariance: Accurate measurements of the frequencies of atomic transitions lead to tighter limits on the velocity dependence of the laws of physics. (1985) (3)
Elementary particles: classical mechanics to the rescue? (1977) (3)
New evidence for fifth quark. (1979) (3)
Computer films: adding an extra dimension to research. (1978) (3)
Ballistic Electron Transport Seen in GaAs: Ballistic electrons are not slowed by collisions; but an ultrahigh-speed transistor using them is conjectural. (1986) (3)
Making nondestructive evaluation a science. (1979) (3)
New magnets enhance synchrotron radiation. (1983) (3)
Electron microscope center opens at berkeley. (1981) (2)
A 16-Megabit Memory Chip from Japan (1987) (2)
An overview of the ALS (1991) (2)
Batteries for energy generation and storage: A perspective from MIT professor and entrepreneur Yet-Ming Chiang (2011) (2)
A new route to oxide superconductors. (1987) (2)
Chemical dynamics: accurate quantum calculations at last. (1976) (2)
CERN Resets Particle Hunt to October. (1982) (2)
The new physics: quarks, leptons, and quantum field theories. (1978) (2)
Mixed Marks for Berkeley Materials Center: A DOE panel's recommendations could threaten construction of the synchrotron light source that was to be NCAM's centerpiece. (1983) (2)
Major materials facilities ranked. (1984) (2)
Lithium primary cells: serendipitous search for a new laser leads to an advanced battery. (1974) (2)
Portable elemental analyzers pushed. (1980) (2)
New testing methods could boost air safety. (1979) (2)
Synchrotron radiation: large demand spurs new facilities. (1977) (2)
Using time to measure length. (1983) (2)
LEP Revolution Under Way at CERN. (1982) (2)
Nuclear evidence that neutrinos have mass. (1980) (2)
Imaging unaltered cell structures with x-rays. (1987) (2)
Chemical Coat Helps Semiconductor Prospects: An irksome feature of the surface of gallium arsenide limits the performance of transistors in microcircuits, but new chemical treatments offer hope for relief. (1987) (2)
High Energy Physics: A Proliferation of Quarks and Lepton (1977) (2)
Energy sweepstakes: fusion gets a chance. (1980) (2)
Can Physicists Clean Up Coal's Act? (1981) (2)
Budget crunch hits high energy physics. (1980) (2)
Choosing the Next Synchrotron Light Source: Berkeley's proposal for a new Advanced Light Source accelerates plans for new facilities at existing centers; a DOE committee will sort it all out. (1983) (2)
First experimental confirmation of Dirac cones in borophene (2017) (2)
Antiprotons Captured at CERN: An American--West German group has stored hundreds of antiprotons in a Penning trap; a precision measurement of the antiproton's inertial mass is next on the agenda. (1986) (2)
Advanced Light Source Compendium of User Abstracts and Technical Reports 1998 (1999) (2)
Speech is another microelectronics conquest. (1979) (2)
First Neutrons from Rutherford Lab's SNS: Although it will take 2 years of commissioning to reach full intensity, the Spallation Neutron Source will be the world's most powerful. (1985) (2)
U.S. Electronics Needs New Strategy: The traditional strategy that combines the short-term focus of industrial laboratories with the long-range perspective of universities apparently is not up to the Japanese challenge. (1986) (2)
Congress Critical of Foot-Dragging on Critical Materials (1986) (2)
New Synchrotron Light Sources Sputtering: Murphy's Law, high expectations, and a shortage of funds and accelerator physicists add up to exasperating delays at Brookhaven and Wisconsin. (1983) (2)
Can Synchrotron Light Save the Chip Industry?: With U.S. integrated circuit companies reeling under Japanese competition, a new x-ray patterning technology may help, but to make it happen a cooperative plan is needed. (1986) (2)
Fuel efficiency drives the auto industry to reduce vehicle weight (2019) (2)
Superbends expand the scope of Berkeley's ALS (2002) (2)
LEP Detector Competition Opens at CERN. (1982) (2)
Stanford pulls off a novel accelerator. (1982) (2)
Scientific opportunities at the advanced light source (1989) (2)
Artificial intelligence comes to atlantic city. (1983) (2)
Commercialization of Superconductors Spurs International Competition (1987) (2)
Femtosecond Laser Annealing of Silicon: The thermal melting and recrystallization processes invoked at slower speeds fail for subpicosecond pulses, a new twist on an old controversy. (1984) (2)
Sodium Atoms Stopped and Confined: Particles in a fast-moving atomic beam can be stopped in their tracks by laser light and subsequently confined in space for a second or so. (1985) (2)
International Competition Drives DESY. (1981) (2)
Bell labs transistor sets a speed record. (1986) (2)
Particle physics: evidence for magnetic monopole obtained. (1975) (2)
The return of the vacuum tube. (1986) (2)
Human-powered flight: californians claim kremer prize. (1977) (2)
Wisconsin unveils its magic lamp. (1981) (2)
Quantum mechanics passes another test. (1982) (2)
Free Electron Lasers Show Their Power: The efficiency of millimeter-wave lasers that convert energy from high-current electron beams into intense radiation is growing. (1984) (2)
Position-Sensitive Detectors: An "Electronic Film" for X-rays. (1978) (2)
Particle theory: stanford electron experiment closes options. (1978) (2)
Another New Particle: Charmed Quarks Look Better Than Ever (1976) (2)
Slower magnetic fusion pace set. (1982) (2)
A beamline for macromolecular crystallography at the Advanced Light Source (1995) (2)
Niobium-germanium: becoming a practical superconductor. (1974) (2)
A Model Synchrotron Light Source in Berlin: Users want photons on a reliable schedule; Berlin's electron storage ring (BESSY) provides 2400 hours of bright ultraviolet light yearly. (1985) (1)
CERN Physicists Have Evidence of Z0. (1983) (1)
Laser light in the extreme ultraviolet. (1983) (1)
X-ray Drought Ending at Brookhaven's NSLS: The flux from the x-ray ring at the National Synchrotron Light Source has reached a respectable level and experiments are finally under way. (1985) (1)
Automotive electronics: computerized engine control. (1976) (1)
The 1984 pittsburgh conference: a special instrumentation report: personal computers attract lab software. (1984) (1)
How Does Fluid Flow Become Turbulent?: Myriad instabilities that precede turbulence in a simple model (Tylor-Couette flow) defy understanding 60 years after the first one was found. (1983) (1)
American physical society panel gives a long-term yes to electricity from the sun. (1979) (1)
Myriad ways to measure small particles. (1981) (1)
NSF Unplugs Wisconsin Synchrotron Source. (1985) (1)
Ceramics: brittle materials for high temperature structures. (1975) (1)
DESY Opens New Synchrotron Light Lab. (1981) (1)
The ALS-a high-brightness XUV synchrotron radiation source (1991) (1)
Bright Synchrotron Sources Evolve: While funding is not yet assured for all the third-generation synchrotron sources, accelerator scientists are struggling to design a machine that can provide ultrahigh-brightness light. (1987) (1)
Far IR Free Electron Laser at Santa Barbara: An electrostatic accelerator whose beam recirculates helps make a high-power tunable laser for an underdeveloped spectral region. (1984) (1)
Glasnost Comes to Soviet Physics: An article in the magazine Literaturnaya Gazeta publicizes a decade-long misdirection of high-pressure physics research and has some barbed words for the way Soviet science works. (1987) (1)
High-temperature superconductors change the game (2012) (1)
Prospects for proprietary synchrotron radiation research. (1979) (1)
Semiconductors: epitaxial growth of laser diodes. (1975) (1)
What is unified in unified field theories. (1979) (1)
Magnetic Monopole Reconsidered: Another Interpretation (1975) (1)
Prospects for Physics in The 1990's Surveyed: A National Academy of Sciences report says that American physics has been a highly diversified and productive enterprise, but continued excellence cannot be taken for granted. (1986) (1)
Laser light "cools" sodium atoms to 0.07 k. (1982) (1)
Spotting the Atoms in Grain Boundaries: To know how the boundaries between crystals affect polycrystalline structural and electronic materials, it is necessary to know quantitatively where the atoms are. (1986) (1)
High-power infrared free electron lasers. (1984) (1)
Soft X-ray Spectromicroscopy: Materials Characterization on a Microscale (1997) (1)
Fermilab Tests Its Antiproton Factory: Physics experiments with the world's highest energy proton antiproton collider will begin a year from now. (1985) (1)
Four Groups Build More Efficient Atom Traps: Hydrogen, sodium, and cesium atoms can now be cooled and stored for up to 20 minutes with some combination of a laser, a magnetic field, and a helium dilution refrigerator. (1987) (1)
CERN Reports First Vector Boson Evidence. (1983) (1)
Ternary compounds: a promising way to make superconductors. (1977) (1)
Pulsed neutron sources okayed. (1982) (1)
Microelectronics: lithographic technologies progress. (1975) (1)
Research News: Are VLSI Microcircuits Too Hard to Design?. (1980) (1)
Tunable Far IR Molecular Lasers Developed: Stimulated Raman scattering associated with a series of closely spaced rotational states is the key to wavelength tunability. (1985) (1)
Third generation synchrotron light sources (1994) (1)
IBM Superconductor Leaps Current Hurdle: Passage of more than 1 million amperes per square centimeter through oriented, crystalline films erases any doubts about low critical currents in the 90 K ceramic superconductors. (1987) (1)
Workshop on molecular environmental science in the soft x-ray region (1997) (1)
Los Alamos Neutron Source Meets First Test: Storing a beam in the proton storage ring means a world-class source is in sight, but money for an experimental hall is lacking. (1985) (1)
A Way to End the IC Designer Shortage. (1980) (1)
New Strategic Plan Takes the ALS into the Future (2006) (1)
ALS renewal moves forward (2007) (1)
Crystal-growing in space: significance still up in the air. (1975) (1)
Free Electron Laser Success Explained: A Livermore-Berkeley group finally publishes an account of the tapered-undulator experiment that has focused so much interest on high-power free electron lasers for missile defense. (1987) (1)
Momentum Builds for New Synchrotron Source: A national steering committee will guide the proposed $160-million x-ray center through the mazes of technical and political approval. (1985) (1)
A national facility for making submicron structures. (1977) (1)
Semiconductor competition: airing the u.s.-Japan issues. (1978) (1)
A private electron storage ring: big science goes commercial. (1978) (1)
Physics journals adopt new policy. (1980) (1)
Neutrons Clarify Superconductors: Neutron scattering experiments reveal a two-dimensional antiferromagnetic behavior that is consistent with an electron spin model of high-temperature superconductors. (1987) (1)
Research opportunities in atomic physics at the Advanced Light Source (1989) (1)
Stanford synchrotron x-ray beamline dedicated. (1986) (1)
Third-Generation Synchrotron Sources: X-Rays of Unprecedented Brightness for Scientific and Industrial Applications (1996) (1)
Fermilab Energy Saver Hits 500 GeV. (1983) (1)
The Physics of High Finance (1994) (1)
X-ray Diffraction in Two Dimensions: Glancing x-rays at very low angles isolates a surface-specific signal and allows structural studies of two-dimensional physical systems. (1983) (1)
Relativity: experiments increase confidence in einstein. (1975) (1)
Quantum Jumps Seen In a Single Ion: Researchers can monitor an infrequently occurring quantum transition in a single ion as it happens by measuring the fluorescence due to a frequently occurring transition. (1986) (1)
Superconductor race heats up. (1987) (1)
1980 nobel prize in physics to cronin and fitch. (1980) (1)
Experiments Begin at Daresbury's SRS. (1981) (1)
Telecommunications: u.s. Applications fall short. (1973) (1)
Brewing fuels in a solar furnace (2013) (1)
Basic research in the air force: a tale of two laboratories. (1975) (1)
Fractional quantum numbers in solids. (1983) (1)
ERAB Panel Ranks Major Materials Facilities. (1985) (1)
Materials hurdles for advanced nuclear reactors (2015) (1)
Fusion energy in our time. (1980) (1)
PETRA and PEP: Two Machines Race to Probe the New Physics. (1978) (1)
What is a transistor? (1980) (1)
Ceramics (II): Making Gas Turbines from Brittle Materials. (1975) (1)
Chemists' first try at big science. (1976) (1)
How many solvents is the limit for HPLC? (1981) (1)
A Visible Free Electron Laser in France: A string of firsts for an Orsay-Stanford collaboration: the first free electron laser in the visible, in a storage ring, and in Europe. (1983) (1)
Accident Stalls Test at CERN. (1982) (1)
The Long and Short of Lasers (II): The Vacuum Ultraviolet. (1974) (1)
Surface analysis: multiple techniques for monolayers. (1976) (1)
Sixth international conference on x-ray microscopy (1999) (1)
Cornell evidence for fifth quark. (1980) (1)
Probing interfaces involving liquids. (1987) (1)
Microcomputers: the great electronic mouse race. (1978) (1)
The 1985 pittsburgh conference: a special instrumentation report. (1985) (0)
Superconductivity: Surpassing the Hydrogen Barrier (1974) (0)
Berkeley Lab's ALS generates Femtosecond Synchrotron Radiation (2000) (0)
Video--a new approach to chart recorders. (1980) (0)
Wisconsin Synchrotron Ring Back in Business (1986) (0)
Laser Extremes Probe Atoms and Molecules: Atomic and molecular physicists find that many frontiers of their field are defined by the advancing state of the art of laser technology. (1985) (0)
Cambridge Latin Course: Unit 4 (1989) (0)
A computer is more than chips. (1982) (0)
Wiggler magnet shakes light from electrons. (1979) (0)
Focus: Bose-Einstein Condensate in Hydrogen (1998) (0)
Cornell submicron facility dedicated. (1981) (0)
Artificial Intelligence Comes to Atlantic City (1983) (0)
Vacuum Ultraviolet Synchrotron Confusion (1985) (0)
Doing Crystallography in Six Dimensions (1985) (0)
ALS construction passes halfway mark (1990) (0)
At last there is a way to take it with you. (1980) (0)
Ion beam analysis. (1976) (0)
Microelectronics: Defense Department Looks to the 1980's. (1978) (0)
Microfabrication Is Not Only for Electronics (1983) (0)
Spain Rejoins CERN After 14-Year Absence (1982) (0)
Theoretical physics institute gets go ahead. (1979) (0)
Superheavy elements: confirmation fails to materialize. (1977) (0)
China switches from protons to electrons. (1982) (0)
Materials science. (1973) (0)
The shift to advanced materials:GM’s Alan Taub surveys future of the auto industry (2012) (0)
The Advanced Light Source: A new tool for research in atomic and molecular physics (1991) (0)
Third NSF decadal report presents challenges for polymer field (2017) (0)
Energy research disaster averted. (1980) (0)
ALS users' Association Eleventh Annual Meeting (1996) (0)
Medical Genetics: Genetic Disorders of Man . Richard M. Goodman, Ed. Little, Brown, Boston, 1970. xviii, 1010 pp., illus. $38.50. (1971) (0)
Proton-antiproton collisions at fermilab. (1985) (0)
Sodium atoms trapped with laser light. (1986) (0)
A Board‐Certified Physicist in Radiation Therapy (1993) (0)
DORIS Gets a Facelift. (1981) (0)
National science board okays theory center. (1983) (0)
Spain Rejoins CERN After 14-Year Absence. (1982) (0)
From materials research to climate change: David Eaglesham assesses the solar energy industry (2012) (0)
VUV-12 conference in San Francisco (1998) (0)
Values of Fundamental Constants Adjusted: Since many of the fundamental physical constants are related, when new measurements of improved accuracy accumulate, it is necessary to adjust the values of all to make them consistent. (1987) (0)
16-femtosecond pulse from laser is shortest yet. (1984) (0)
An "NRCC" for Industrial Chemists? (1980) (0)
CERN Finds Evidence for Top Quark. (1984) (0)
Testing Superposition in Quantum Mechanics: Several recent experiments explore the range of validity of the linear superposition principle in quantum mechanics; not yet answered is whether it applies to macroscopic objects. (1986) (0)
Where Are the Atoms in the Icosahedral Phase?: Researchers disagree on whether it is even possible to specify atomic positions; they do not know whether the icosahedral phase is more like a glass or a quasi-periodic crystal. (1986) (0)
Wisconsin synchrotron ring back in business. (1986) (0)
Laser-Cooling Mercury Ions Via Beryllium (1986) (0)
New funding sparks battery research. (1976) (0)
The advanced light source at Lawrence Berkeley Laboratory---A high-brightness soft x-ray synchrotron-radiation facility (1990) (0)
The Macromolecular Crystallography Facility: World Class Protein Crystallography (1999) (0)
1998-2001 Advanced Light Source Science Highlights (on CD) (2002) (0)
Synchrotron x-rays probe coronary arteries. (1986) (0)
Automated motion analysis system. (1985) (0)
Sodium atoms stopped and confined (1985) (0)
Notes from Other Offices (1975) (0)
Rough going for lasers at the pittsburgh conference. (1981) (0)
Optical communications: specialized applications appear first. (1973) (0)
A Physicist Carves a Niche in Industrial Ecology (1993) (0)
Synchrotron Radiation Takes Over at Orsay: Once a small, piggyback operation, the LURE laboratory now has exclusive use of all Orsay accelerators and is building a new one. (1985) (0)
Research opportunities at the Advanced Light Source (1991) (0)
Scientific program of the advanced light source at LBL (1992) (0)
David A. Shirley symposium at Berkeley lab (1999) (0)
Using synchrotron light for magnetic scattering. (1985) (0)
ERAB Panel Ranks Major Materials Facilities (1985) (0)
A Free Electron Laser in the Visible: Researchers from Stanford and TRW use the high-quality electron beam from a superconducting linear accelerator and a novel energy-doubling scheme to make visible light. (1987) (0)
High-temperature superconductor hints. (1987) (0)
Proprietary Research: DOE Says, "We Can Be Very Friendly". (1978) (0)
National Science Board Okays Theory Center (1983) (0)
Workshop on analytical applications of synchrotron radiation (1995) (0)
Energy storage. I. Using electricity more efficiently. [Pumped hydroelectric, compressed air, and electric batteries] (1974) (0)
Particle-in-Cell and Hybrid Simulation (2013) (0)
New Accelerators: Cornell Gets an Electron Storage Ring (1977) (0)
The Advanced Light Source Upgrade (2003) (0)
Video—A New Approach to Chart Recorders (1980) (0)
Physicists dream about a computer network. (1981) (0)
Radiation Pressure Acceleration of Ions (2009) (0)
Precision Positronium Spectroscopy Tests QED (1984) (0)
First anniversary of ALS completion (1994) (0)
X-ray microimaging for the life sciences (1989) (0)
Theory Center Awaits NSF Word on Renewal. (1983) (0)
Laser-cooling mercury ions via beryllium. (1986) (0)
Brookhaven magnet progress. (1982) (0)
Technical publishing workstation. (1984) (0)
Cytogenetics: Human Chromosome Methodology . Jorge J. Yunis, Ed. Academic Press, New York, 1965. xiv + 258 pp. Illus. $8.50. (1965) (0)
Particle theorists in a quandary. (1982) (0)
Smart Instruments: Microprocessors Not the Whole Story (1977) (0)
Mastering the Physics of Disaster (1994) (0)
Academics victims in fusion politics tangle. (1979) (0)
Argonne's Pulsed Neutron Source Turned On. (1981) (0)
Budget cuts may cost u.s. One accelerator. (1981) (0)
Yale accelerator to be dedicated. (1987) (0)
Exploiting Resistive Guiding for Fast Ignition (2012) (0)
Persistence Pays Off in the Form of a New Product (1981) (0)
An ALS accelerator review and a beam-line prototype (1989) (0)
Charge density waves seen in potassium. (1986) (0)
Electron-hole droplets: a unique form of matter. (1974) (0)
Phase Transition Seen at Alloy Grain Boundary: Cornell researchers have evidence for the proposition that gold in an iron alloy bicrystal preferentially collects at the grain boundary and triggers a change in its structure. (1986) (0)
Do the Japanese Make Better IC's? (1980) (0)
Synchrotron Light for X-ray Lithography: Researchers in West Berlin are building a miniature electron storage ring to test this new microcircuit fabrication technology. (1985) (0)
Persistence pays off in the form of a new product. (1981) (0)
Snapshots of an oxide heterojunction reveal an interfacial atomic shuffle (2018) (0)
Deep geothermal ambitions in Norway (2013) (0)
First electron beam symbolizes progress at ALS (1989) (0)
Ion beams for compositional analysis. (1985) (0)
Workshop on detectors for synchrotron radiation (2001) (0)
Budget Cuts May Cost U.S. One Accelerator (1981) (0)
Focus: A New Theory of Etching (1999) (0)
Myriad Ways to Measure Small Particles (1981) (0)
STM Evidence for Silicon (111). (1986) (0)
Wisconsin Storage Ring Reaches 120 Milliamps: After long delays, the "1-GeV ring" now generates respectable VUV-XUV intensities, but continued funding is uncertain. (1986) (0)
Cornell cancels accelerator plan. (1982) (0)
Unexpected Zeta Particle Baffles Physicists: The finding by an American-European collaboration working in Germany may point the way beyond the "Standard Model" of particle physics. (1984) (0)
Delayed choice supports quantum theory. (1986) (0)
ALS users' meeting (1988) (0)
Cheap Electricity May Save 200 Brookhaven Jobs (1981) (0)
Choosing an array processor. (1979) (0)
Bell Labs Transistor Sets a Speed Record (1986) (0)
Chemical science at the Advanced Light Source (1999) (0)
Nuclear Squeeze at Lawrence Berkeley Lab: High-energy collisions at the Bevalac between niobium nuclei yield the first direct evidence that nuclear matter can be compressed. (1984) (0)
Al-li-cu icosahedral phase. (1986) (0)
Elementary particles: neutrino experiments suggest charm. (2003) (0)
Maintaining Brazil's ethanol fuel momentum (2010) (0)
Preface: 13th International Fast Ignition Workshop (2015) (0)
OTA Touts Advanced Structural Materials. (1986) (0)
Microfabrication is not only for electronics. (1983) (0)
The Advanced Light Source Upgrade - eScholarship (2003) (0)
New cornell accelerator stores first beam. (1979) (0)
Using Synchrotron Light for Magnetic Scattering (1985) (0)
Sodium Atoms Trapped With Laser Light (1986) (0)
The Advanced Light Source: A third-generation Synchrotron Radiation Source (2002) (0)
The ALS (Advanced Light Source): A third generation light source (1989) (0)
Timing Subpicosecond Electronic Processes: Using the same ultrashort light pulse from a laser to generate and then detect an electrical signal is the key to high-speed measurement. (1984) (0)
The Atomic and Molecular Facility on Beamline 10.0.1 at the Advanced Light Source (1999) (0)
16-Femtosecond Pulse from Laser Is Shortest Yet (1984) (0)
Synchrotron light sources: A powerful tool for science and technology (1996) (0)
Berkeley advanced light source (1988) (0)
Multi-atom resonant photoemission: A new way to directly identify neighbor atoms in materials (1999) (0)
Quantum electrodynamics: excited state of positronium. (1975) (0)
The 1979 pittsburgh conference: a special instrument report. (1979) (0)
How Does Fluid Flow Become Turbulent (1983) (0)
A New Theory of Etching (1999) (0)
Doing crystallography in six dimensions. (1985) (0)
Superfast Time-Resolved Optical Spectroscopy (1984) (0)
Niobium-Germanium: Becoming a Practical Superconductor (1974) (0)
Perilous Times for U. S. Microcircuit Makers : Science (1988) (0)
Cheap electricity may save 200 brookhaven jobs. (1981) (0)
China Switches from Protons to Electrons (1982) (0)
Lukewarm Yes for LBL Light Source. (1983) (0)
Science and technology: the next 50 years. (1973) (0)
Response : Ion Beam Analysis (1976) (0)
ISABELLE Spending Questioned. (1982) (0)
Mapping chaos in particle revolutions (2000) (0)
Unified gauge theories: an atomic-fly in the ointment. (1977) (0)
Evidence for Free Quarks Won't Go Away. (1981) (0)
Up Close: Advanced Light Source at Lawrence Berkeley Laboratory (1988) (0)
Thin Film Optics: Still in the Exploratory Stage (1973) (0)
The ALSA High-Brightness XUV Synchrotron Radiation Source (2013) (0)
Satisfying our global energy appetite: Former DOE Under Secretary Raymond Orbach looks ahead (2011) (0)

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