Self-force on moving electric and magnetic dipoles: dipole radiation, Vavilov-Cerenkov radiation, friction with a conducting surface, and the Einstein-Hopf effect
Self-force on moving electric and magnetic dipoles: dipole radiation, Vavilov-Cerenkov radiation, friction with a conducting surface, and the Einstein-Hopf effect
The classical electromagnetic self-force on an arbitrary time-dependent electric or magnetic dipole moving with constant velocity in vacuum, and in a medium, is considered. Of course, in vacuum there is no net force on such a particle. Rather, because of loss of mass by the particle due to radiation, the self-force precisely cancels this inertial effect, and thus the spectral distribution of the energy radiated by dipole radiation is deduced without any consideration of radiation fields or of radiation reaction, in both the nonrelativistic and relativistic regimes. If the particle is moving in
a homogeneous medium faster than the speed of light in the medium, Vavilov-Cerenkov radiation results. This is derived for the different polarization states, in agreement with the earlier results of Frank. The friction experienced by a point (time-independent) dipole moving parallel to an imperfectly conducting surface is examined. Finally, the relativistic quantum/thermal Einstein-Hopf effect is rederived. We obtain a closed form for the spectral distribution of the force, and demonstrate that, even if the atom and the blackbody background have independent temperatures, the force is indeed a drag when the imaginary part of the polarizability is proportional to a power of the frequency. The unifying theme of these investigations is that friction on an atom requires a dissipative mechanism, be it through radiation or resistivity in the environment.
043347
Milton, Kimball A.
32b2e838-92a4-4f2d-a33d-ab54ddaf8e08
Day, Hannah
8d06c3bd-772c-40d1-812b-5fd9c9b7edbe
Li, Yang
0fc31bbe-98b1-4955-a63b-10ae4338b8f3
Guo, Xin
3f89f94f-15ae-4a6d-962a-4fbfdc099541
Kennedy, Gerard
47b61664-2d2d-45fa-a73a-5af7a7c740cd
9 December 2020
Milton, Kimball A.
32b2e838-92a4-4f2d-a33d-ab54ddaf8e08
Day, Hannah
8d06c3bd-772c-40d1-812b-5fd9c9b7edbe
Li, Yang
0fc31bbe-98b1-4955-a63b-10ae4338b8f3
Guo, Xin
3f89f94f-15ae-4a6d-962a-4fbfdc099541
Kennedy, Gerard
47b61664-2d2d-45fa-a73a-5af7a7c740cd
Milton, Kimball A., Day, Hannah, Li, Yang, Guo, Xin and Kennedy, Gerard
(2020)
Self-force on moving electric and magnetic dipoles: dipole radiation, Vavilov-Cerenkov radiation, friction with a conducting surface, and the Einstein-Hopf effect.
Physical Review Research, 2 (4), .
(doi:10.1103/PhysRevResearch.2.043347).
Abstract
The classical electromagnetic self-force on an arbitrary time-dependent electric or magnetic dipole moving with constant velocity in vacuum, and in a medium, is considered. Of course, in vacuum there is no net force on such a particle. Rather, because of loss of mass by the particle due to radiation, the self-force precisely cancels this inertial effect, and thus the spectral distribution of the energy radiated by dipole radiation is deduced without any consideration of radiation fields or of radiation reaction, in both the nonrelativistic and relativistic regimes. If the particle is moving in
a homogeneous medium faster than the speed of light in the medium, Vavilov-Cerenkov radiation results. This is derived for the different polarization states, in agreement with the earlier results of Frank. The friction experienced by a point (time-independent) dipole moving parallel to an imperfectly conducting surface is examined. Finally, the relativistic quantum/thermal Einstein-Hopf effect is rederived. We obtain a closed form for the spectral distribution of the force, and demonstrate that, even if the atom and the blackbody background have independent temperatures, the force is indeed a drag when the imaginary part of the polarizability is proportional to a power of the frequency. The unifying theme of these investigations is that friction on an atom requires a dissipative mechanism, be it through radiation or resistivity in the environment.
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Accepted/In Press date: 5 November 2020
Published date: 9 December 2020
Identifiers
Local EPrints ID: 445398
URI: http://eprints.soton.ac.uk/id/eprint/445398
ISSN: 2643-1564
PURE UUID: 13412a5e-d10f-460e-b755-5c27c97160bd
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Date deposited: 07 Dec 2020 17:32
Last modified: 17 Mar 2024 02:59
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Contributors
Author:
Kimball A. Milton
Author:
Hannah Day
Author:
Yang Li
Author:
Xin Guo
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