Reversible compression of an optical piston through Kramers dynamics
Reversible compression of an optical piston through Kramers dynamics
We study the reversible crossover between stable and bistable phases of an over-damped Brownian bead inside an optical piston. The interaction potentials are solved developing a method based on Kramers' theory that exploits the statistical properties of the stochastic motion of the bead. We evaluate precisely the energy balance of the crossover. We show that the deformation of the optical potentials induced by the compression of the piston is related to a production of heat which measures the non-adiabatic character of the crossover. This reveals how specific thermodynamic processes can be designed and controlled with a high level of precision by tailoring the optical landscapes of the piston.
9 pages, 9 figures
FOS: Physical sciences, Physics - Optics, Optics (physics.optics)
FOS: Physical sciences, Physics - Optics, Optics (physics.optics)
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