University of Massachusetts Amherst
2008 - Fellow of American Physical Society (APS) Citation For pioneering contributions to the theory and practice of Monte Carlo simulations for strongly correlated quantum and classical systems, the invention of the worm algorithm and diagrammatic Monte Carlo techniques, and fundamental theoretical results on superfluid phenomena in quantum gases, liquids, and solids
His primary scientific interests are in Monte Carlo method, Condensed matter physics, Superfluidity, Quantum Monte Carlo and Quantum mechanics. The study incorporates disciplines such as Helium-4, Algorithm and Statistical physics in addition to Monte Carlo method. His Condensed matter physics research is multidisciplinary, incorporating perspectives in Open quantum system and Ground state.
Boris Svistunov interconnects Quantum technology, Quantum dynamics, Phase, Vortex and Quantum phase transition in the investigation of issues within Superfluidity. His studies deal with areas such as Phase diagram, Bose–Hubbard model, Filling factor, Dynamic Monte Carlo method and Effective mass as well as Quantum Monte Carlo. His Quantum mechanics research is multidisciplinary, incorporating elements of Turbulence and Quantum electrodynamics.
His primary areas of study are Condensed matter physics, Superfluidity, Quantum mechanics, Monte Carlo method and Quantum Monte Carlo. His Condensed matter physics research incorporates themes from Supersolid, Boson and Ground state. His Superfluidity research integrates issues from Phase transition, Quantum phase transition, Symmetry, Phase diagram and Vortex.
His study ties his expertise on Mathematical physics together with the subject of Quantum mechanics. His Monte Carlo method study combines topics from a wide range of disciplines, such as Fermion, Statistical physics, Fermi gas and Feynman diagram. His study explores the link between Quantum Monte Carlo and topics such as Monte Carlo molecular modeling that cross with problems in Dynamic Monte Carlo method.
Boris Svistunov mainly investigates Theoretical physics, Condensed matter physics, Monte Carlo method, Superfluidity and Diagrammatic reasoning. His work investigates the relationship between Theoretical physics and topics such as Quantum that intersect with problems in Field, Universality and Quasiparticle. His research in Condensed matter physics tackles topics such as Ground state which are related to areas like Scale of temperature, Ultracold atom and Antiferromagnetism.
His Monte Carlo method research incorporates elements of Probability and statistics, Physical system, Bin and Charge. Superfluidity is a primary field of his research addressed under Quantum mechanics. His Feynman diagram study incorporates themes from Quantum Monte Carlo and Series.
Boris Svistunov focuses on Fermi gas, Monte Carlo method, Statistical physics, Monte Carlo algorithm and Diagrammatic reasoning. His study in Fermi gas is interdisciplinary in nature, drawing from both Fermi Gamma-ray Space Telescope, Quantum electrodynamics and Unitarity. While working on this project, Boris Svistunov studies both Monte Carlo method and Crossover.
His research integrates issues of Quantum Monte Carlo, Series, Normal phase and Ultraviolet in his study of Statistical physics. He has researched Monte Carlo algorithm in several fields, including Sign and Feynman diagram. The concepts of his Atomic physics study are interwoven with issues in Hubbard model and Condensed matter physics.
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Counterflow superfluidity of two-species ultracold atoms in a commensurate optical lattice.
A. B. Kuklov;B. V. Svistunov.
Physical Review Letters (2003)
Solutions of the Two-Dimensional Hubbard Model: Benchmarks and Results from a Wide Range of Numerical Algorithms
J. P. F. LeBlanc;Andrey E. Antipov;Federico Becca;Ireneusz W. Bulik.
Physical Review X (2015)
Exact, complete, and universal continuous-time worldline Monte Carlo approach to the statistics of discrete quantum systems
Nikolai Prokof'ev;Boris Svistunov;Tupitsyn.
Journal of Experimental and Theoretical Physics (1998)
Worm Algorithms for Classical Statistical Models
Nikolay Prokof'ev;Boris Svistunov.
Physical Review Letters (2001)
Phase diagram and thermodynamics of the three-dimensional Bose-Hubbard model
B Capogrosso-Sansone;Nikolai Prokof'ev;Boris Svistunov.
Physical Review B (2007)
Diagrammatic quantum Monte Carlo study of the Fröhlich polaron
A. S. Mishchenko;N. V. Prokof'ev;A. Sakamoto;B. V. Svistunov.
Physical Review B (2000)
Worm algorithm and diagrammatic Monte Carlo: a new approach to continuous-space path integral Monte Carlo simulations.
M Boninsegni;Nikolai Prokof'ev;Nikolai Prokof'ev;Nikolai Prokof'ev;Boris Svistunov;Boris Svistunov.
Physical Review E (2006)
Critical Temperature and Thermodynamics of Attractive Fermions at Unitarity
Evgeni Burovski;Nikolay Prokof'ev;Nikolay Prokof'ev;Nikolay Prokof'ev;Boris Svistunov;Boris Svistunov;Matthias Troyer.
Physical Review Letters (2006)
“Worm” algorithm in quantum Monte Carlo simulations☆
N.V Prokof'ev;B.V Svistunov;I.S Tupitsyn.
Physics Letters A (1998)
Worm algorithm for continuous-space path integral monte carlo simulations
Massimo Boninsegni;Nikolay Prokof'ev;Boris Svistunov.
Physical Review Letters (2006)
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