David Pines

What is he best known for?

The fields of study he is best known for:

• Quantum mechanics
• Electron
• Condensed matter physics

His primary areas of investigation include Condensed matter physics, Superconductivity, Electron, Cuprate and Antiferromagnetism. His research in the fields of Fermi liquid theory overlaps with other disciplines such as Exchange interaction. His studies in Superconductivity integrate themes in fields like Spin-½, Kondo effect, Electrical resistivity and conductivity, Coupling and State of matter.

His Electron research incorporates elements of Canonical transformation and Atomic physics. In his research, Knight shift and Nuclear quadrupole resonance is intimately related to Phenomenological model, which falls under the overarching field of Cuprate. His study in Antiferromagnetism is interdisciplinary in nature, drawing from both Magnetic susceptibility and Omega.

His most cited work include:

• The theory of quantum liquids (2458 citations)
• Elementary excitations in solids (1368 citations)
• A Collective Description of-Electron Interactions: III. Coulomb Interactions in a Degenerate Electron Gas (1109 citations)

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

David Pines spends much of his time researching Condensed matter physics, Superconductivity, Electron, Quasiparticle and Cuprate. As part of his studies on Condensed matter physics, David Pines often connects relevant subjects like Quantum mechanics. His research links Inelastic neutron scattering with Superconductivity.

His research investigates the connection with Electron and areas like Quantum which intersect with concerns in Strongly correlated material. His Quasiparticle study frequently intersects with other fields, such as Scattering. His Antiferromagnetism study combines topics in areas such as Magnetic susceptibility, Electrical resistivity and conductivity, Knight shift and Omega.

He most often published in these fields:

• Condensed matter physics (49.58%)
• Superconductivity (35.46%)
• Electron (19.94%)

What were the highlights of his more recent work (between 2001-2019)?

• Condensed matter physics (49.58%)
• Superconductivity (35.46%)
• Electron (19.94%)

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

His primary areas of investigation include Condensed matter physics, Superconductivity, Electron, Quasiparticle and Quantum. His work on Antiferromagnetism and Fermi liquid theory as part of his general Condensed matter physics study is frequently connected to Scaling, thereby bridging the divide between different branches of science. His Antiferromagnetism study integrates concerns from other disciplines, such as Spin–lattice relaxation, Room-temperature superconductor, Transition temperature and k-nearest neighbors algorithm.

His study on Superconductivity is covered under Quantum mechanics. His Electron research incorporates themes from Magnetic susceptibility, Spins, Knight shift and Thermal conduction. His Quantum research is multidisciplinary, incorporating perspectives in Phase transition and Coherence.

Between 2001 and 2019, his most popular works were:

• The pseudogap: friend or foe of high Tc? (367 citations)
• Superconductivity without phonons (363 citations)
• Superconductivity without phonons (363 citations)

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

• Quantum mechanics
• Electron
• Condensed matter physics

David Pines spends much of his time researching Condensed matter physics, Superconductivity, Quantum mechanics, Quantum and Fermi liquid theory. His Condensed matter physics research integrates issues from Strongly correlated material and Electron. His Electron research includes elements of Thermal conduction and Magnetic field.

His research integrates issues of Spins and Quantum spin liquid in his study of Superconductivity. His Quantum research is multidisciplinary, incorporating elements of Fermi Gamma-ray Space Telescope and Antiferromagnetism. His studies in Fermi liquid theory integrate themes in fields like Quantum critical point and Fermi surface.

This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.