Negative Casimir entropies in nanoparticle interactions

Negative entropy has been known in Casimir systems for some time. For example, it can occur between parallel metallic plates modeled by a realistic Drude permittivity. Less well known is that negative entropy can occur purely geometrically, say between a perfectly conducting sphere and a conducting...

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Bibliographic Details
Published in:Journal of physics. Condensed matter 2015-06, Vol.27 (21), p.214003-214003
Main Authors: Milton, Kimball A, Guérout, Romain, Ingold, Gert-Ludwig, Lambrecht, Astrid, Reynaud, Serge
Format: Article
Language:English
Subjects:
Casimir entropy
Casimir interaction
Casimir-Polder entropy
High Energy Physics - Theory
nanoparticle entropy
Physics
Quantum Physics
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Summary:Negative entropy has been known in Casimir systems for some time. For example, it can occur between parallel metallic plates modeled by a realistic Drude permittivity. Less well known is that negative entropy can occur purely geometrically, say between a perfectly conducting sphere and a conducting plate. The latter effect is most pronounced in the dipole approximation, which is reliable when the size of the sphere is small compared to the separation between the sphere and the plate. Therefore, here we examine cases where negative entropy can occur between two electrically and magnetically polarizable nanoparticles or atoms, which need not be isotropic, and between such a small object and a conducting plate. Negative entropy can occur even between two perfectly conducting spheres, between two electrically polarizable nanoparticles if there is sufficient anisotropy, between a perfectly conducting sphere and a Drude sphere, and between a sufficiently anisotropic electrically polarizable nanoparticle and a transverse magnetic conducting plate.
ISSN:0953-8984
1361-648X
DOI:10.1088/0953-8984/27/21/214003