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Open Quantum Systems Decoherence
Casimir Forces in a Piston Geometry at Zero and Finite Temperatures
arXiv
Authors: M. P. Hertzberg, R. L. Jaffe, M. Kardar, A. Scardicchio
Year
2007
Paper ID
50436
Status
Preprint
Abstract Read
~2 min
Abstract Words
130
Citations
N/A
Abstract
We study Casimir forces on the partition in a closed box (piston) with perfect metallic boundary conditions. Related closed geometries have generated interest as candidates for a repulsive force. By using an optical path expansion we solve exactly the case of a piston with a rectangular cross section, and find that the force always attracts the partition to the nearest base. For arbitrary cross sections, we can use an expansion for the density of states to compute the force in the limit of small height to width ratios. The corrections to the force between parallel plates are found to have interesting dependence on the shape of the cross section. Finally, for temperatures in the range of experimental interest we compute finite temperature corrections to the force (again assuming perfect boundaries).
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- This paper contributes to the Open Quantum Systems & Decoherence research area in the Quantum Articles archive.
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- We study Casimir forces on the partition in a closed box (piston) with perfect metallic boundary conditions.
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