Engineering a thermal squeezed reservoir by energy-level modulation

Ephraim Shahmoon; Gershon Kurizki

doi:10.1103/PhysRevA.87.013841

Engineering a thermal squeezed reservoir by energy-level modulation

Ephraim Shahmoon, Gershon Kurizki

Department of Chemical and Biological Physics

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

We show that a thermal reservoir can effectively act as a squeezed reservoir on atoms that are subject to energy-level modulation. For sufficiently fast and strong modulation, for which the rotating-wave approximation is broken, the resulting squeezing persists at long times. These effects are analyzed by a master equation that is valid beyond the rotating-wave approximation. As an example we consider a two-level atom in a cavity with Lorentzian linewidth, subject to sinusoidal energy modulation. A possible realization of these effects is discussed for Rydberg atoms.

Original language	English
Article number	013841
Journal	Physical Review A
Volume	87
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.87.013841
State	Published - 30 Jan 2013

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1103/PhysRevA.87.013841

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abstract = "We show that a thermal reservoir can effectively act as a squeezed reservoir on atoms that are subject to energy-level modulation. For sufficiently fast and strong modulation, for which the rotating-wave approximation is broken, the resulting squeezing persists at long times. These effects are analyzed by a master equation that is valid beyond the rotating-wave approximation. As an example we consider a two-level atom in a cavity with Lorentzian linewidth, subject to sinusoidal energy modulation. A possible realization of these effects is discussed for Rydberg atoms.",

author = "Ephraim Shahmoon and Gershon Kurizki",

note = "DIP; ISF; Wolfgang Pauli InstituteWe would like to thank Ido Almog and Serge Rosenblum for fruitful discussions. We acknowledge the support of DIP, ISF, and the Wolfgang Pauli Institute (E.S.).",

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N2 - We show that a thermal reservoir can effectively act as a squeezed reservoir on atoms that are subject to energy-level modulation. For sufficiently fast and strong modulation, for which the rotating-wave approximation is broken, the resulting squeezing persists at long times. These effects are analyzed by a master equation that is valid beyond the rotating-wave approximation. As an example we consider a two-level atom in a cavity with Lorentzian linewidth, subject to sinusoidal energy modulation. A possible realization of these effects is discussed for Rydberg atoms.

AB - We show that a thermal reservoir can effectively act as a squeezed reservoir on atoms that are subject to energy-level modulation. For sufficiently fast and strong modulation, for which the rotating-wave approximation is broken, the resulting squeezing persists at long times. These effects are analyzed by a master equation that is valid beyond the rotating-wave approximation. As an example we consider a two-level atom in a cavity with Lorentzian linewidth, subject to sinusoidal energy modulation. A possible realization of these effects is discussed for Rydberg atoms.

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Engineering a thermal squeezed reservoir by energy-level modulation

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