Using a direct simulation Monte Carlo approach to model collisions in a buffer gas cell

Maximilian J. Doppelbauer; Otto Schullian; Jerome Loreau; Nathalie Vaeck; Ad Van Der Avoird; Christopher J. Rennick; Timothy P. Softley; Brianna R. Heazlewood

doi:10.1063/1.4974253

Using a direct simulation Monte Carlo approach to model collisions in a buffer gas cell

Maximilian J. Doppelbauer, Otto Schullian, Jerome Loreau, Nathalie Vaeck, Ad Van Der Avoird, Christopher J. Rennick, Timothy P. Softley, Brianna R. Heazlewood

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Abstract

A direct simulation Monte Carlo (DSMC) method is applied to model collisions between He buffer gas atoms and ammonia molecules within a buffer gas cell. State-to-state cross sections, calculated as a function of the collision energy, enable the inelastic collisions between He and NH₃ to be considered explicitly. The inclusion of rotational-state-changing collisions affects the translational temperature of the beam, indicating that elastic and inelastic processes should not be considered in isolation. The properties of the cold molecular beam exiting the cell are examined as a function of the cell parameters and operating conditions; the rotational and translational energy distributions are in accord with experimental measurements. The DSMC calculations show that thermalisation occurs well within the typical 10-20 mm length of many buffer gas cells, suggesting that shorter cells could be employed in many instances - yielding a higher flux of cold molecules.

Original language	English
Article number	044302
Journal	Journal of Chemical Physics
Volume	146
Issue number	4
Early online date	23 Jan 2017
DOIs	https://doi.org/10.1063/1.4974253
Publication status	Published - 28 Jan 2017

ASJC Scopus subject areas

Physics and Astronomy(all)
Physical and Theoretical Chemistry

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abstract = "A direct simulation Monte Carlo (DSMC) method is applied to model collisions between He buffer gas atoms and ammonia molecules within a buffer gas cell. State-to-state cross sections, calculated as a function of the collision energy, enable the inelastic collisions between He and NH3 to be considered explicitly. The inclusion of rotational-state-changing collisions affects the translational temperature of the beam, indicating that elastic and inelastic processes should not be considered in isolation. The properties of the cold molecular beam exiting the cell are examined as a function of the cell parameters and operating conditions; the rotational and translational energy distributions are in accord with experimental measurements. The DSMC calculations show that thermalisation occurs well within the typical 10-20 mm length of many buffer gas cells, suggesting that shorter cells could be employed in many instances - yielding a higher flux of cold molecules.",

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AU - Doppelbauer, Maximilian J.

AU - Schullian, Otto

AU - Loreau, Jerome

AU - Vaeck, Nathalie

AU - Van Der Avoird, Ad

AU - Rennick, Christopher J.

AU - Softley, Timothy P.

AU - Heazlewood, Brianna R.

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AB - A direct simulation Monte Carlo (DSMC) method is applied to model collisions between He buffer gas atoms and ammonia molecules within a buffer gas cell. State-to-state cross sections, calculated as a function of the collision energy, enable the inelastic collisions between He and NH3 to be considered explicitly. The inclusion of rotational-state-changing collisions affects the translational temperature of the beam, indicating that elastic and inelastic processes should not be considered in isolation. The properties of the cold molecular beam exiting the cell are examined as a function of the cell parameters and operating conditions; the rotational and translational energy distributions are in accord with experimental measurements. The DSMC calculations show that thermalisation occurs well within the typical 10-20 mm length of many buffer gas cells, suggesting that shorter cells could be employed in many instances - yielding a higher flux of cold molecules.

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Using a direct simulation Monte Carlo approach to model collisions in a buffer gas cell

Abstract

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