Fluctuation-electromagnetic interaction under dynamic and thermal nonequilibrium conditions

This systematic review summarizes theoretical developments related to the relativistic and nonrelativistic fluctuation-electromagnetic interaction of bodies of different temperature moving translationally and (or) rotationally relative to one another. The small particle-plate and small particle—vacuum background configurations are considered as the basic ones. A method is presented for calculating the basic characteristics of this interaction, namely, the conservative-dissipative forces and torques, the heating (cooling) rates, and the intensities of the thermal and nonthermal radiation fluxes that arise under "Cherenkov friction" conditions. Experimental results and possible applications are discussed.

Keywords: fluctuation-electromagnetic interaction of moving bodies, Casimir friction, quantum friction, thermal and nonthermal radiation under translational-rotational motion of particles in vacuum
PACS: 41.20.−q, 42.50.Wk, 44.40.+a (all)
DOI: 10.3367/UFNe.2016.12.038006
URL: https://ufn.ru/en/articles/2017/6/b/
Web of Science

000409222900002
Scopus

2-s2.0-85029172070
ADS NASA

2017PhyU...60..559D
Citation: Dedkov G V, Kyasov A A "Fluctuation-electromagnetic interaction under dynamic and thermal nonequilibrium conditions" Phys. Usp. 60 559–585 (2017)

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Received: 1st, August 2016, revised: 28th, November 2016, accepted: 8th, December 2016

Оригинал: Дедков Г В, Кясов А А «Флуктуационно-электромагнитное взаимодействие в условиях динамической и тепловой неравновесности» УФН 187 599–627 (2017); DOI: 10.3367/UFNr.2016.12.038006

References (205) Cited by (27) Similar articles (20) ↓

A.I. Volokitin, B.N.J. Persson “Radiative heat transfer and noncontact friction between nanostructures” 50 879–906 (2007)
E.A. Vinogradov, I.A. Dorofeyev “Thermally stimulated electromagnetic fields of solids” 52 425–459 (2009)
B.V. Sokolenko, N.V. Shostka, O.S. Karakchieva “Optical tweezers and manipulators. Modern concepts and future prospects” 65 812–833 (2022)
M.L. Ter-Mikhaelyan “High energy electromagnetic processes in amorphous and inhomogeneous media” 46 1231–1252 (2003)
I.A. Vasil’eva “Stationary radiation of objects with scattering media” 44 1255–1282 (2001)
A.G. Kyurkchan, B.Yu. Sternin, V.E. Shatalov “Singularities of continuation of wave fields” 39 1221–1242 (1996)
V.E. Fortov, A.G. Khrapak et al “Dusty plasmas” 47 447–492 (2004)
I.Yu. Kobzarev, L.B. Okun “On the photon mass” 11 338–341 (1968)
M.A. Leontovich “Evolution of the concepts of magnetic and electric lines of force” 7 877–880 (1965)
M.M. Gurevich “Spectral distribution of radiant energy” 5 908–912 (1963)
G.M. Strakhovskii, N.V. Kravtsov “Strong magnetic fields” 3 260–272 (1960)
G.V. Dedkov “Nanotribology: experimental facts and theoretical models” 43 541–572 (2000)
V.M. Mostepanenko, N.N. Trunov “The Casimir effect and its applications” 31 965–987 (1988)
S.B. Dabagov “Channeling of neutral particles in micro- and nanocapillaries” 46 1053–1075 (2003)
D.V. Kazantsev, E.V. Kuznetsov et al “Apertureless near-field optical microscopy” 60 259–275 (2017)
M.I. Shliomis “Magnetic fluids” 17 153–169 (1974)
S.I. Blinnikov, A.D. Dolgov “Cosmological acceleration” 62 529–567 (2019)
V.L. Ginzburg “Certain theoretical aspects of radiation due to superluminal motion in a Medium” 2 874–893 (1960)
P.I. Arseev, N.S. Maslova “Electron — vibration interaction in tunneling processes through single molecules” 53 1151–1169 (2010)
L.S. Uspenskaya, A.L. Rakhmanov “Dynamical magnetic structures in superconductors and ferromagnets” 55 639–656 (2012)

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