His scientific interests lie mostly in Glass transition, Chemical physics, Polymer, Condensed matter physics and Relaxation. His Glass transition research includes themes of Differential scanning calorimetry, Molecule, Polymer science and Fragility. His Chemical physics study incorporates themes from Crystallography, Atmospheric temperature range, Ionic conductivity, Protein dynamics and Relaxation.
His studies deal with areas such as Nanoparticle, Nanotechnology and Polymer chemistry as well as Polymer. His biological study spans a wide range of topics, including Spectral line, Raman scattering, Glass forming and Light scattering. His study on Relaxation is mostly dedicated to connecting different topics, such as Dielectric.
Alexei P. Sokolov spends much of his time researching Polymer, Chemical physics, Glass transition, Raman spectroscopy and Chemical engineering. The study incorporates disciplines such as Nanoparticle, Nanotechnology, Polymer chemistry, Electrolyte and Membrane in addition to Polymer. The concepts of his Chemical physics study are interwoven with issues in Relaxation, Neutron scattering, Ionic conductivity, Dielectric spectroscopy and Ionic liquid.
The Neutron scattering study which covers Protein dynamics that intersects with Crystallography. He works mostly in the field of Ionic conductivity, limiting it down to topics relating to Ionic bonding and, in certain cases, Conductivity, as a part of the same area of interest. His Glass transition study integrates concerns from other disciplines, such as Light scattering, Relaxation, Condensed matter physics, Dielectric and Fragility.
Alexei P. Sokolov focuses on Polymer, Chemical engineering, Chemical physics, Ionic liquid and Glass transition. His Polymer research is multidisciplinary, relying on both Nanoparticle, Nanotechnology, Membrane and Polymer chemistry. His study in Chemical engineering is interdisciplinary in nature, drawing from both Oxide, Electrolyte, Anode, Ethylene oxide and Electrochemistry.
His Chemical physics study also includes
The scientist’s investigation covers issues in Polymer, Nanoparticle, Chemical engineering, Chemical physics and Glass transition. His studies in Polymer integrate themes in fields like Membrane, Nanotechnology and Polymer chemistry. His research in Nanoparticle tackles topics such as Layer which are related to areas like Dielectric spectroscopy, Vinyl acetate, Relaxation, Volume and Polymer free.
His Chemical engineering research incorporates themes from Electrolyte, Oxide, Organic chemistry and Anode. His Chemical physics research is multidisciplinary, incorporating perspectives in Range, Ionic liquid, Thermal diffusivity, Porous medium and Conductivity. His research in Glass transition intersects with topics in Rigidity, Phase, Dielectric and Molecular dynamics.
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The nature of boson peak in Raman scattering in glasses
V.K. Malinovsky;A.P. Sokolov.
Solid State Communications (1986)
Dynamics of strong and fragile glass formers: Differences and correlation with low-temperature properties.
A. P. Sokolov;E. Rössler;A. Kisliuk;D. Quitmann.
Physical Review Letters (1993)
Medium-range order in glasses: Comparison of Raman and diffraction measurements.
A. P. Sokolov;A. Kisliuk;M. Soltwisch;D. Quitmann.
Physical Review Letters (1992)
Role of Chemical Structure in Fragility of Polymers: A Qualitative Picture
Kumar Kunal;Christopher G. Robertson;Sebastian Pawlus;Steven F. Hahn.
Dynamics at the Polymer/Nanoparticle Interface in Poly(2-vinylpyridine)/Silica Nanocomposites
Adam P. Holt;Philip J. Griffin;Vera Bocharova;Alexander L. Agapov.
Universality of the dynamic crossover in glass-forming liquids: a "magic" relaxation time.
V. N. Novikov;A. P. Sokolov.
Physical Review E (2003)
Onsets of Anharmonicity in Protein Dynamics
J. H. Roh;V. N. Novikov;R. B. Gregory;J. E. Curtis.
Physical Review Letters (2005)
Universal Form of the Low-Energy (2 to 10 meV) Vibrational Spectrum of Glasses
V. K. Malinovsky;V. N. Novikov;P. P. Parshin;A. P. Sokolov.
Conductivity and mechanical properties of well-dispersed single-wall carbon nanotube/polystyrene composite
T.-E. Chang;A. Kisliuk;S.M. Rhodes;W.J. Brittain.
Microscopic Mechanism of reinforcement in single-wall carbon nanotube/polypropylene nanocomposite
T.E. Chang;Lars Rosgaard Jensen;A. Kisliuk;R.B. Pipes.
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