Adrian P. Sutton

What is he best known for?

The fields of study he is best known for:

• Quantum mechanics
• Electron
• Atom

His primary areas of investigation include Condensed matter physics, Grain boundary, Electronic structure, Tight binding and Electron. His Condensed matter physics research incorporates themes from Electrical conductor, Atomic units and Silicon. His work deals with themes such as Geometry and Multicomponent systems, which intersect with Grain boundary.

Adrian P. Sutton has included themes like Lattice constant and Ground state in his Electronic structure study. As a part of the same scientific study, Adrian P. Sutton usually deals with the Tight binding, concentrating on Hamiltonian and frequently concerns with Energetics, Pair potential, Fermi level and Quantum transport. His work on Stopping power as part of general Electron research is often related to Non-blocking I/O and Particle radiation, thus linking different fields of science.

His most cited work include:

• Electron-energy-loss spectra and the structural stability of nickel oxide: An LSDA+U study (6355 citations)
• Interfaces in Crystalline Materials (1538 citations)
• Long-range Finnis–Sinclair potentials (936 citations)

What are the main themes of his work throughout his whole career to date?

Adrian P. Sutton mostly deals with Condensed matter physics, Grain boundary, Dislocation, Molecular dynamics and Statistical physics. His Condensed matter physics research is multidisciplinary, relying on both Crystallography and Silicon. His study in the field of Misorientation is also linked to topics like Boundary.

The study incorporates disciplines such as Composite material and Classical mechanics in addition to Molecular dynamics. His Statistical physics research includes themes of Kinetic Monte Carlo and Dynamic Monte Carlo method. His work carried out in the field of Electronic structure brings together such families of science as Scanning tunneling microscope, Electron, Quantum tunnelling and Atomic physics.

He most often published in these fields:

• Condensed matter physics (30.52%)
• Grain boundary (15.66%)
• Dislocation (13.25%)

What were the highlights of his more recent work (between 2012-2021)?

• Dislocation (13.25%)
• Mechanics (6.83%)
• Plasticity (4.42%)

In recent papers he was focusing on the following fields of study:

Dislocation, Mechanics, Plasticity, Composite material and Condensed matter physics are his primary areas of study. Adrian P. Sutton has researched Dislocation in several fields, including Molecular dynamics, Nucleation, Zirconium alloy, Classical mechanics and Vacancy defect. His Plasticity research incorporates elements of Deformation, Computational chemistry, Relaxation and Shock.

The concepts of his Condensed matter physics study are interwoven with issues in Crystallography, Point and Fission. His research in Fracture toughness focuses on subjects like Deflection, which are connected to Grain boundary. His Zirconium study frequently draws connections between related disciplines such as Atomic physics.

Between 2012 and 2021, his most popular works were:

• Theory and simulation of the diffusion of kinks on dislocations in bcc metals (51 citations)
• A dynamic discrete dislocation plasticity method for the simulation of plastic relaxation under shock loading (43 citations)
• The mechanisms governing the activation of dislocation sources in aluminum at different strain rates (42 citations)

In his most recent research, the most cited papers focused on:

• Quantum mechanics
• Electron
• Atom

Adrian P. Sutton spends much of his time researching Dislocation, Shock, Mechanics, Molecular dynamics and Condensed matter physics. His Dislocation research is multidisciplinary, incorporating perspectives in Normal mode, Crystallographic defect, Phonon scattering and Classical mechanics. His Shock study also includes fields such as

• Collective motion, Structural engineering, Classification of discontinuities and Current most often made with reference to Plasticity,
• Dynamics which intersects with area such as Transformation, Phase and Chemical physics,
• Relaxation which is related to area like Nucleation, Strain, Deformation and Statistical physics.

His study in Molecular dynamics is interdisciplinary in nature, drawing from both Motion, Energy, Composite material, Dislocation creep and Coupling. His work on Temperature independent as part of his general Condensed matter physics study is frequently connected to Hessian matrix, thereby bridging the divide between different branches of science. His Nuclear magnetic resonance research is multidisciplinary, incorporating perspectives in Zirconium, Lambda, Dipole, Lattice and Atomic physics.

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