Surface Screening in the Casimir Force

Ana M. Contreras-Reyes; Ansgar Liebsch; C. H. Hargreaves; E. I. Kats; E. I. Kats; E. M. Lifshitz; E. M. Lifshitz; F. Forstmann; H. B. G. Casimir; J. A. Stratton; L. D. Landau; M. G. Cotram; Neil W. Ashcroft; P. Halevi; V. M. Mostepanenko; V. M. Mostepanenko; W. Luis Mochán; W. Luis Mochán; W. Luis Mochán; Yu. A. Il’inskii

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Surface Screening in the Casimir Force

Authors: Ana M. Contreras-Reyes
Ansgar Liebsch
C. H. Hargreaves
E. I. Kats
E. I. Kats
E. M. Lifshitz
E. M. Lifshitz
F. Forstmann
H. B. G. Casimir
J. A. Stratton
L. D. Landau
M. G. Cotram
Neil W. Ashcroft
P. Halevi
V. M. Mostepanenko
V. M. Mostepanenko
W. Luis Mochán
W. Luis Mochán
W. Luis Mochán
Yu. A. Il’inskii
Publication date: 27 September 2005
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We calculate the corrections to the Casimir force between two metals due to the spatial dispersion of their response functions. We employ model-independent expressions for the force in terms of the optical coefficients. We express the non-local corrections to the Fresnel coefficients employing the surface

d_\perp

parameter, which accounts for the distribution of the surface screening charge. Within a self-consistent jellium calculation, spatial dispersion increases the Casimir force significatively for small separations. The nonlocal correction has the opposite sign than previously predicted employing hydrodynamic models and assuming abruptly terminated surfaces.Comment: 5 pages, 2 figure

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