John J. Gilman

Q: What Schools Are Affiliated With John J. Gilman

John J. Gilman is affiliated with the following schools: University of California, Berkeley, Illinois Institute of Technology, University of California, Los Angeles, Columbia University

John J. Gilman's AcademicInfluence.com Rankings

John J. Gilman

Engineering

#2324

World Rank

#3216

Historical Rank

#776

USA Rank

Materials Science

#280

World Rank

#283

Historical Rank

#34

USA Rank

engineering Degrees

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Engineering

John J. Gilman's Degrees

PhD Materials Science University of California, Berkeley
Masters Materials Science University of California, Berkeley
Bachelors Materials Science University of California, Berkeley

Why Is John J. Gilman Influential?

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According to Wikipedia, Jack Gilman was a world-renowned material scientist in the field of mechanical properties of solids. In his lifetime he made major contributions to many areas of the field including dislocation behaviour of ceramics, disclination behaviour of polymers, and production of metal glasses.

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John J. Gilman'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

Designing Superhard Materials (2005) (565)
The art and science of growing crystals (1963) (419)
Osmium diboride, an ultra-incompressible, hard material. (2005) (362)
Micromechanics of Flow in Solids (1969) (305)
Mechanical behavior of metallic glasses (1975) (188)
Double‐Cantilever Cleavage Mode of Crack Propagation (1964) (140)
Dynamical Dislocation Theory of Crystal Plasticity. I. The Yield Stress (1965) (132)
Design of hard crystals (2006) (125)
Dislocation Multipoles and Their Role in Strain-Hardening (1964) (114)
Chemistry and Physics of Mechanical Hardness (2009) (111)
Shear-induced metallization (1993) (89)
Insulator-metal transitions at microindentations (1992) (86)
Why Silicon Is Hard (1993) (85)
Chemical reactions at detonation fronts in solids (1995) (82)
Electronic Basis of the Strength of Materials (2003) (79)
Rapidly solidified materials (1987) (75)
Mechanism of shear-induced metallization (1995) (63)
Chemical and physical ”hardness” (1997) (61)
Micromechanics of shear banding (1994) (53)
Structure and Properties of Energetic Materials (1992) (52)
Stress dependences of dislocation velocities (1969) (49)
Dynamical Dislocation Theory of Crystal Plasticity. II. Easy Glide and Strain Hardening (1965) (42)
Influence of dislocation dipoles on physical properties (1964) (37)
Lithium Dihydrogen Fluoride—An Approach to Metallic Hydrogen (1971) (36)
Physical chemistry of intrinsic hardness (1996) (35)
Structures of ferrous eutectic liquids (1978) (32)
Mechanochemistry (1996) (30)
Dynamic fracture by spallation in metals (1970) (29)
Basalt columns: Large scale constitutional supercooling? (2009) (26)
Electronic Basis of the Strength of Materials: Mechanics of cracks (2003) (25)
Fast, faster, and fastest cracks (1998) (25)
Dislocation Dynamics and the Response of Materials to Impact (1968) (23)
Fracture in Solids (1960) (22)
Equilibrium of extended dislocations within edge dislocation dipoles (1964) (20)
Mechanism of the Koehler dislocation multiplication process (1997) (18)
Plasmons at shock fronts (1999) (18)
Contraction of extended dislocations at high speeds (2001) (17)
Oxide Surface Films on Metal Crystals (2004) (17)
Cohesion in ball lightning (2003) (16)
Stock Price and Optimum Research Spending (1978) (16)
Why diamond is very hard (2002) (15)
Cleavage, ductility and tenacity in crystals (2012) (15)
Bulk stiffnesses of metals (1971) (15)
Mechanical States of Solids (2002) (15)
Electronic basis of hardness and phase transformations (covalent crystals) (2008) (14)
The limiting speeds of dislocations (2000) (13)
Metallization at Microindentations (1992) (12)
Determining the Optimum Level for R&D Spending (1986) (12)
Materials science. Designing superhard materials. (2005) (12)
Osmium Diboride, an Ultra‐Incompressible, Hard Material. (2005) (12)
Strain markings in alpha-brass (1953) (10)
Inventivity: The art and science of research management (1992) (10)
Method for monitoring the mechanical state of a material (1990) (9)
Research Management Today (1991) (9)
Origins of the outstanding mechanical properties of diamond (2002) (9)
Up Close: Center for Advanced Materials at Lawrence Berkeley Laboratory (1986) (8)
Market Penetration Rates and Their Effect on Value : Research Management (1982) (8)
During detonation chemistry may precede heat (2006) (8)
Dislocation Motion in a Viscous Medium (1968) (8)
Dynamical Behavior of Dislocations (1968) (7)
Chemical theory of dislocation mobility (2005) (7)
The Nature of Ceramics (1967) (7)
Electronic Basis of the Strength of Materials: Contents (2003) (7)
Debris dipoles and low-temperature internal friction in crystals (1962) (6)
Optimization of Inventivity (1985) (6)
Electro-plastic effect in semiconductors (2000) (6)
IN DEFENSE OF THE METALLIC BOND (1999) (6)
Metallic Glasses (1980) (6)
Fine structure in zinc twins (1955) (5)
Fracture of Metals, Polymers, and Glasses (1967) (5)
Mechanisms of Shear-Induced Solid-State Reactions (1996) (5)
THE PLASTIC WAVE MYTH (1992) (5)
Research as Investment (1996) (5)
Strength of spider silk. (1996) (5)
Bond modulus and stability of covalent solids (2006) (5)
Effect of grain size on crack propagation (1960) (4)
Surface Effects in the Slip and Twinning of Metal Monocrystals (1952) (4)
Computation vs knowledge in materials innovation (2001) (4)
Shear‐induced polymerization of benzene (2008) (4)
Effect of a Copper Surface Film on Twinning in Zinc Mono-crystals (1952) (4)
Risk Was His Friend: Edison's Legacy to Innovation Leaders (1995) (4)
Importance of dislocation cores in fatigue fracture (2008) (4)
Responses of Condensed Matter to Impact (2003) (4)
Note broken sticks—why mergers may fail to garner market share (1992) (3)
Electronic Basis of the Strength of Materials: Macroscopic plastic deformation (2003) (3)
Panel Discussion: Session I (1966) (3)
The elastic stiffnesses of Fe-Ni-C martensites (1971) (3)
PROPERTIES OF AMORPHOUS METALS.OVERVIEW OF THE TECHNOLOGY AND SIGNIFICANCE OF METALLIC GLASSES (1980) (3)
Why Covalent Ceramics are Hard (1993) (3)
Growth of Oriented Square Zinc Monocrystals (1955) (3)
The Unique Strength of Diamond (1995) (3)
Direct Evidence Of Chemical Reactions Induced By Shear-Strains (2003) (3)
Wiley Series on Processing of Engineering Materials (2009) (2)
PLASTIC RESPONSE OF SOLIDS. (1967) (2)
Possible role of dispersion forces in fracture (2005) (2)
DEMAND CHARTS - TOOLS FOR PLANNING (1985) (2)
The limiting speeds of dislocations (2000) (2)
Early Research, Development, and Commercialization of Metallic Glasses (1984) (2)
Materials processing: opportunities and challenges (1972) (2)
Price Trends as a Guide to Research Planning (1980) (2)
Athermal Fracture of Covalent Bonds (1998) (2)
Who Needs Enemies (1998) (2)
Factors that Affect Development Investment Values (1978) (2)
Toward physically-based rate laws for dislocations (2002) (2)
Cohesion in Ball Lightning and Cook Plasmas (2004) (2)
The Navy Way (1996) (1)
Comments “On dislocation kinetics” (1965) (1)
Chapter 3. Chemical Bonding (2009) (1)
A Simplified Vacuum Furnace for Growing Metallic Monocrystals (1951) (1)
Some recent developments of dynamic techniques for wind tunnels (1966) (1)
IMPORTANCE OF STABLE EFFORT FOR RESEARCH PRODUCTIVITY (1985) (1)
The microdynamics of plastic flow (1974) (1)
Metallization and insulization during impact (1992) (1)
Ball Lightning and Plasma Cohesion (2003) (1)
‘Pathological Science’: Erroneous Epilogue? (1990) (1)
Plasmon diagnosis of shock and detonation fronts (2001) (1)
Fracture of solids : proceedings of an international conference sponsored by the Institute of Metals Division, American Institute of Mining, Metallurgical, and Petroleum Engineers, Maple Valley, Washington, August 21-24, 1962 (1963) (1)
Application of Pure Bending Moments to Crystals (1956) (1)
Utility of the Plasmon Theory of Surface and Interfacial Energies (2013) (1)
Surface Effect in the Cleavage of Zinc Monocrystals (1951) (1)
Elastic - plastic impact (some persistent misconceptions) (2001) (1)
Heisenberg's Principle (2001) (0)
In Defense of the Random Selection of Research Projects (1996) (0)
Flutter of crack tips (1995) (0)
Electronic Basis of the Strength of Materials: Intermolecular cohesion (2003) (0)
Unified View of Flow Mechanisms in Materials (0)
ENTHUSIASMS AND REALITIES IN ADVANCED MATERIALS (1987) (0)
Influence of research on corporate success (1978) (0)
HOW MUCH DOES RESEARCH INCREASE THE MARKET VALUE OF A COMPANY (1985) (0)
Utility Defines Materials vs. Substances (1998) (0)
Edison's Legacy to Research Management (1994) (0)
Electronic Basis of the Strength of Materials: Nature of elastic stiffness (2003) (0)
Electronic Basis of the Strength of Materials: Entropic elasticity (polymers) (2003) (0)
Electronic Basis of the Strength of Materials: Universality and unification (2003) (0)
Electronic Basis of the Strength of Materials: Quantum states (2003) (0)
Comprar Chemistry and Physics of Mechanical Hardness | John J. Gilman | 9780470226520 | Wiley (2009) (0)
Abstracts of Articles published in Materials Research Innovations 1 (2) (1998) (0)
Perils of Ignoring Inventors (1995) (0)
Fracture of metals, polymers, and glasses; proceedings. (1967) (0)
Effect of a Prequench on the Martensite Reaction in Tool Steel (1952) (0)
Electronic Basis of the Strength of Materials: Bulk modulus (2003) (0)
Fracture of metals, polymers, and glasses : proceedings of the 4th symposium held Jan. 31 - Feb. 1, 1966 at Boston, Mass (1967) (0)
The Three Most Important Factors in Research Management (1995) (0)
ADVANCED MATERIALS SYSTEMS AS COMMERICAL OPPORTUNITIES (1987) (0)
Return on Research Expenditures—Lessons of a Minimal Model (1993) (0)
Combinatorial vs. Sequential Research Strategies (1999) (0)
Madison Avenue Materials (1997) (0)
Photovoltaics' Promise Still Less Than Sunny? (1994) (0)
Editorial (2005) (0)
Reply to comments “On the fine structure in twins” (1961) (0)
Benjamin Franklin and the Ideal Research Organization (1997) (0)
Topology of phase changes via bond-bending (2008) (0)
Central Bureaucracy Stifles Good Research (1991) (0)
Spins, Phonons, and Hardness (1995) (0)
Structure and properties of energetic materials : symposium held November 30-December 2, 1992, Boston, Massachusetts, U.S.A. (1993) (0)
Method for Measuring Sonic Dislocation Velocities (1963) (0)
Electronic Basis of the Strength of Materials: Introduction (2003) (0)
Electronic Basis of the Strength of Materials: Shear modulus (2003) (0)
Dislocation motion in phonon liquids (2009) (0)
Metal‐Metalloids (Hard Metals) (2009) (0)
Stock Price and Optimum Research Spending : R&D Management (1988) (0)
Strength of Spider Silk (1996) (0)
Research in a Service Economy (1996) (0)
Electronic Basis of the Strength of Materials: Periodic patterns of electrons (2003) (0)
Fracture of Metals, Polymers, & Glasses (1967) (0)
CHEMICAL AND PHYSICAL HARDNESS OF SOLIDS (2004) (0)
Mechanisms Underlying Hardness Numbers (2004) (0)
The Critical Importance Of Discounted Cash Flow (2006) (0)
A Simple Recording Tensile Machine for Metal Monocrystals (1952) (0)
What do Good Research Organizations and Good Jazz Combos Have in Common (1996) (0)
Properties of electrons (2001) (0)
Six Management Routes to More Productive Research (1994) (0)
Inventivity, Development, Commercialization, and Research Policy (1993) (0)
Electronic Basis of the Strength of Materials: Microscopic plastic deformation (2003) (0)
Dr. Deming Says (1995) (0)
Electronic Basis of the Strength of Materials: Dislocation mobility (2003) (0)
Simple Metals and Alloys (2009) (0)
Beyond “Hockey Stick” Strategic Planning (1996) (0)
Inventions and corporate size (1980) (0)
A Research Manager's Most Important Word (1994) (0)
The Challenge of Writing Science History (1994) (0)
Impedance Matching in Research Management (1995) (0)
Technology May Be the Answer—But Is Technology Transfer the Question? (1993) (0)
Kapitza Had It Right (2004) (0)
Electronic Basis of the Strength of Materials: Cohesion of atoms (2003) (0)
Elasticity and Plasticity: Some Similarity; much Difference (2001) (0)
Market Shares and Research Policy (1998) (0)
Deformation potentials and plasmon energies-measures of sensitivity (2008) (0)
Calculating buckyballs and nanotubes (2000) (0)
Electronic Basis of the Strength of Materials: Preface (2003) (0)
Mechanical behavior of crystalline solids; proceedings of a symposium April 28-29, 1962 (1963) (0)
Electronic Basis of the Strength of Materials: Generalized stress (2003) (0)
METALLIC GLASSES AND THEIR DESCENDANTS (1986) (0)
Electronic Basis of the Strength of Materials: Elastic coefficients (2003) (0)
Engineering Is Too Important To Be Left To Scientists (2005) (0)
Strain-induced chemical reactions (2008) (0)
Simulations Versus Realities (1998) (0)
Planning With Demand Charts (1987) (0)
Optimization of Inventivity : Research Management (1987) (0)
Montroll’s Laws and Technology Transfer (1995) (0)
Electronic Basis of the Strength of Materials: Fracturing rates (2003) (0)
Agenda Discussion: Mechanical and Chemical Properties (1986) (0)
Electronic Basis of the Strength of Materials: Intramolecular cohesion (2003) (0)
NOVEL METHOD FOR CONSTRUCTING TETRAHEDRAL FRAMES (1988) (0)
Crack Dynamics and Grain Size (1994) (0)
DILEMMAS OF EXTERNAL VENTURES (1986) (0)
The Tyranny of Overhead (1995) (0)
The Research Manager's Dilemma (1994) (0)
Market Shares and Strategic Planning (1994) (0)
Dislocation Motions and the Yield Strengths of Solids (1961) (0)
Electronic Basis of the Strength of Materials: Surface and interfacial energies (2003) (0)
Phase transitions induced by mechanical compression (2003) (0)
The Bond Modulus and the Stability of Solids (2005) (0)
METHOD FOR MEASURING SINIC DISLOCATION VELOCITIES (1962) (0)
Edison and His Laboratory (1999) (0)

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What Schools Are Affiliated With John J. Gilman?

John J. Gilman is affiliated with the following schools:

John J. Gilman's Academic­Influence.com Rankings