Optical Stark decelerator for molecules with a traveling potential well

Lianzhong Deng; Shunyong Hou; Jianping Yin

doi:10.1103/PhysRevA.95.033409

Optical Stark decelerator for molecules with a traveling potential well

Lianzhong Deng, Shunyong Hou, Jianping Yin

Institute for Advanced Study in Precision Spectroscopy

East China Normal University

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

2 Scopus citations

Abstract

We propose a versatile scheme to slow supersonically cooled molecules using a decelerating potential well, obtained by steering a focusing laser beam onto a pair of spinning reflective mirrors under a high-speed brake. The longitudinal motion of molecules in the moving red-detuned light field is analyzed and their corresponding phase-space stability is investigated. Trajectories of CH4 molecules under the influence of the potential well are simulated using the Monte Carlo method. For instance, with a laser beam of power 20 kW focused onto a spot of waist radius 40-100 μm, corresponding to a peak laser intensity on the order of ∼108W/cm2, a CH4 molecule of ∼250m/s can be decelerated to ∼10m/s over a distance of a few centimeters on a time scale of hundreds of microseconds.

Original language	English
Article number	033409
Journal	Physical Review A
Volume	95
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevA.95.033409
State	Published - 10 Mar 2017

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title = "Optical Stark decelerator for molecules with a traveling potential well",

abstract = "We propose a versatile scheme to slow supersonically cooled molecules using a decelerating potential well, obtained by steering a focusing laser beam onto a pair of spinning reflective mirrors under a high-speed brake. The longitudinal motion of molecules in the moving red-detuned light field is analyzed and their corresponding phase-space stability is investigated. Trajectories of CH4 molecules under the influence of the potential well are simulated using the Monte Carlo method. For instance, with a laser beam of power 20 kW focused onto a spot of waist radius 40-100 μm, corresponding to a peak laser intensity on the order of ∼108W/cm2, a CH4 molecule of ∼250m/s can be decelerated to ∼10m/s over a distance of a few centimeters on a time scale of hundreds of microseconds.",

author = "Lianzhong Deng and Shunyong Hou and Jianping Yin",

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AU - Hou, Shunyong

AU - Yin, Jianping

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N2 - We propose a versatile scheme to slow supersonically cooled molecules using a decelerating potential well, obtained by steering a focusing laser beam onto a pair of spinning reflective mirrors under a high-speed brake. The longitudinal motion of molecules in the moving red-detuned light field is analyzed and their corresponding phase-space stability is investigated. Trajectories of CH4 molecules under the influence of the potential well are simulated using the Monte Carlo method. For instance, with a laser beam of power 20 kW focused onto a spot of waist radius 40-100 μm, corresponding to a peak laser intensity on the order of ∼108W/cm2, a CH4 molecule of ∼250m/s can be decelerated to ∼10m/s over a distance of a few centimeters on a time scale of hundreds of microseconds.

AB - We propose a versatile scheme to slow supersonically cooled molecules using a decelerating potential well, obtained by steering a focusing laser beam onto a pair of spinning reflective mirrors under a high-speed brake. The longitudinal motion of molecules in the moving red-detuned light field is analyzed and their corresponding phase-space stability is investigated. Trajectories of CH4 molecules under the influence of the potential well are simulated using the Monte Carlo method. For instance, with a laser beam of power 20 kW focused onto a spot of waist radius 40-100 μm, corresponding to a peak laser intensity on the order of ∼108W/cm2, a CH4 molecule of ∼250m/s can be decelerated to ∼10m/s over a distance of a few centimeters on a time scale of hundreds of microseconds.

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DO - 10.1103/PhysRevA.95.033409

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Optical Stark decelerator for molecules with a traveling potential well

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