Terapevticheskii Arkhiv.
Vol. 87.
2015.
P. 84-89
Numerical simulation of relaxation of quantum thermal fluctuations
A generalization of quantum-mechanical equations expressed in the hydrodynamic form by introducing terms that involve the diffusion velocity at zero and finite temperatures, as well as the diffusion pressure energy in a warm vacuum, into the Lagrangian density has been proposed. It is used as a basis for constructing a system of equations similar to the Euler equations, but making allowance for quantum-mechanical and thermal effects, for the model of one-dimensional hydrodynamics. The equations obtained generalize the equations of the Nelson stochastic mechanics. A numerical analysis of the solutions of this system allowed a conclusion to be drawn about its validity for the description of the relaxation of quantum thermal fluctuations. © O.N. GOLUBJEVA, S.V. SIDOROV, V.G. BAR’YAKHTAR, 2015.
Authors
Golubjeva O.N.
1
,
Sidorov S.V.
1
,
Bar’Yakhtar V.G.2
Journal
Publisher
National Academy of Sciences of Ukraine
Number of issue
10
Language
English
Pages
1062-1074
Status
Published
Link
Volume
60
Year
2015
Organizations
- 1 People’s Friendship University of Russia, Moscow, 117198, Russian Federation
- 2 Institute Of Magnetism, Nat. Acad. Of Sci. Of Ukraine, 36 Academician Vernadsky Blvd, Kyiv, 03142, Ukraine
Keywords
(ℏ,k)-dynamics; Cold and warm vacua; Diffusion pressure energy density; Drift and diffusion velocities; Effective action; Numerical analysis; Quantum thermostat; Self-diffusion
Date of creation
19.10.2018
Date of change
19.10.2018
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Other records
Acta Crystallographica Section E: Crystallographic Communications.
International Union of Crystallography.
Vol. 71.
2015.
P. o729-o730