Repulsive Casimir and Casimir–Polder forces

Casimir and Casimir?Polder repulsions have been known for more than 50 years. The general ?Lifshitz? configuration of parallel semi-infinite dielectric slabs permits repulsion if they are separated by a dielectric fluid that has a value of permittivity that is intermediate between those of the dielectric slabs. This was indirectly confirmed in the 1970s, and more directly by Capasso?s group recently. It has also been known for many years that electrically and magnetically polarizable bodies can experience a repulsive quantum vacuum force. More amenable to practical application are situations where repulsion could be achieved between ordinary conducting and dielectric bodies in vacuum. The status of the field of Casimir repulsion with emphasis on some recent developments will be surveyed. Here, stress will be placed on analytic developments, especially on Casimir?Polder (CP) interactions between anisotropically polarizable atoms, and CP interactions between anisotropic atoms and bodies that also exhibit anisotropy, either because of anisotropic constituents, or because of geometry. Repulsion occurs for wedge-shaped and cylindrical conductors, provided the geometry is sufficiently asymmetric, that is, either the wedge is sufficiently sharp or the atom is sufficiently far from the cylinder.This article is part of a special issue of Journal of Physics A: Mathematical and Theoretical in honour of Stuart Dowker?s 75th birthday devoted to ?Applications of zeta functions and other spectral functions in mathematics and physics?.

[1]  J. Schwinger,et al.  Casimir self-stress on a perfectly conducting spherical shell , 1978 .

[2]  K. Milton,et al.  Casimir-Polder repulsion near edges: wedge apex and a screen with an aperture , 2011, 1103.4386.

[3]  E. B. Kolomeisky,et al.  Weyl problem and Casimir effects in spherical shell geometry , 2011, 1110.0421.

[4]  Karl Joulain,et al.  Casimir force between designed materials: What is possible and what not , 2004, quant-ph/0407153.

[5]  Vassilios Yannopapas,et al.  First-principles study of Casimir repulsion in metamaterials. , 2009, Physical review letters.

[6]  M. Kardar,et al.  Casimir forces between cylinders at different temperatures , 2012, 1202.1167.

[7]  J. Zanelli Chern–Simons forms in gravitation theories , 2012, 1208.3353.

[8]  G. L. Klimchitskaya,et al.  Exact Casimir–Polder potential between a particle and an ideal metal cylindrical shell and the proximity force approximation , 2011, 1103.3922.

[9]  M. Maghrebi Diagrammatic expansion of the Casimir energy in multiple reflections: Theory and applications , 2010, 1012.1060.

[10]  Electromagnetic vacuum energy for two parallel slabs in terms of surface, waveguide, and photonic modes , 2011, 1111.6356.

[11]  C. Soukoulis,et al.  Repulsive Casimir force in chiral metamaterials. , 2009, Physical review letters.

[12]  K. Milton,et al.  Scalar Casimir energies of tetrahedra and prisms , 2012, 1202.0908.

[13]  F. Rosa,et al.  Dispersion forces between an atom and a perfectly conducting wedge , 2008, 0801.2416.

[14]  K. Milton,et al.  Casimir energies of cylinders: Universal function , 2010, 1008.4778.

[15]  Steven G. Johnson,et al.  Casimir repulsion between metallic objects in vacuum. , 2010, Physical review letters.

[16]  Stefan Yoshi Buhmann,et al.  Erratum: Thermal Casimir-Polder shifts in Rydberg atoms near metallic surfaces [Phys. Rev. A 82, 010901(R) (2010)] , 2010 .

[17]  A. Grushin,et al.  Tunable Casimir repulsion with three-dimensional topological insulators. , 2010, Physical review letters.

[18]  A. Lambrecht,et al.  Casimir repulsion and metamaterials , 2008, 0801.3223.

[19]  S. Stringari,et al.  New asymptotic behavior of the surface-atom force out of thermal equilibrium. , 2005, Physical review letters.

[20]  P. Milonni,et al.  Casimir-Lifshitz theory and metamaterials. , 2008, Physical review letters.