Quantum self-propulsion of an inhomogeneous object out of thermal equilibrium
Quantum self-propulsion of an inhomogeneous object out of thermal equilibrium
In an earlier paper, we explored how quantum vacuum torque can arise: a body or nanoparticle that is out of thermal equilibrium with its environment experiences a spontaneous torque. But this requires that the body be composed of nonreciprocal material, which seems to necessitate the presence of an external influence, such as a magnetic field. Then the electric polarizability of the particle has a real part that is nonsymmetric. Thiseffect occurs to first order in the polarizability. To that order, no self-propulsive force can arise. Here, we consider second-order effects, and show that spontaneous forces can arise in vacuum, without requiring exotic electromagnetic properties. Thermal nonequilibrium is still necessary, but the electric susceptibility of the body need only be inhomogeneous. We investigate four examples of such a body: a needle composed of distinct halves; a sphere and a ball, each hemisphere being made of a different substance; and a thin slab, each face of whichis different. The results found are consistent with previous numerical investigations. Here, we take into account the skin depth of metal surfaces. We also consider the frictional forces that would cause the body to acquire a terminal velocity, which might be observable. More likely to be important is relaxation to thermal equilibrium, which can still lead to a terminal velocity that might be experimentally verifiable. A general treatment of such forces on a moving body, expressed in momentum space, is provided, which incorporates both propulsive and frictional forces. The source of the propulsive force is the nonsymmetric pattern of radiation from different parts of the body, the higher reflectivity of the metal portion playing a crucial role.
Milton, Kimball A.
32b2e838-92a4-4f2d-a33d-ab54ddaf8e08
Pourtolami, Nima
b43c7cb9-06b9-4dde-ba1a-8936230f6d04
Kennedy, Gerard
47b61664-2d2d-45fa-a73a-5af7a7c740cd
11 October 2024
Milton, Kimball A.
32b2e838-92a4-4f2d-a33d-ab54ddaf8e08
Pourtolami, Nima
b43c7cb9-06b9-4dde-ba1a-8936230f6d04
Kennedy, Gerard
47b61664-2d2d-45fa-a73a-5af7a7c740cd
Milton, Kimball A., Pourtolami, Nima and Kennedy, Gerard
(2024)
Quantum self-propulsion of an inhomogeneous object out of thermal equilibrium.
Physical Review A, 110 (4), [042814].
(doi:10.1103/PhysRevA.110.042814).
Abstract
In an earlier paper, we explored how quantum vacuum torque can arise: a body or nanoparticle that is out of thermal equilibrium with its environment experiences a spontaneous torque. But this requires that the body be composed of nonreciprocal material, which seems to necessitate the presence of an external influence, such as a magnetic field. Then the electric polarizability of the particle has a real part that is nonsymmetric. Thiseffect occurs to first order in the polarizability. To that order, no self-propulsive force can arise. Here, we consider second-order effects, and show that spontaneous forces can arise in vacuum, without requiring exotic electromagnetic properties. Thermal nonequilibrium is still necessary, but the electric susceptibility of the body need only be inhomogeneous. We investigate four examples of such a body: a needle composed of distinct halves; a sphere and a ball, each hemisphere being made of a different substance; and a thin slab, each face of whichis different. The results found are consistent with previous numerical investigations. Here, we take into account the skin depth of metal surfaces. We also consider the frictional forces that would cause the body to acquire a terminal velocity, which might be observable. More likely to be important is relaxation to thermal equilibrium, which can still lead to a terminal velocity that might be experimentally verifiable. A general treatment of such forces on a moving body, expressed in momentum space, is provided, which incorporates both propulsive and frictional forces. The source of the propulsive force is the nonsymmetric pattern of radiation from different parts of the body, the higher reflectivity of the metal portion playing a crucial role.
Text
selfprop
- Accepted Manuscript
More information
Accepted/In Press date: 28 August 2024
Published date: 11 October 2024
Identifiers
Local EPrints ID: 496815
URI: http://eprints.soton.ac.uk/id/eprint/496815
ISSN: 2469-9926
PURE UUID: 4a65847e-9d8a-43fe-ba9d-1ec45b3d6286
Catalogue record
Date deposited: 08 Jan 2025 07:10
Last modified: 10 Jan 2025 02:42
Export record
Altmetrics
Contributors
Author:
Kimball A. Milton
Author:
Nima Pourtolami
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
