A detailed account of the measurements of cold collisions in a molecular synchrotron

Aernout P. P. van der Poel; Hendrick L. Bethlem

doi:10.1140/epjti/s40485-018-0048-y

A detailed account of the measurements of cold collisions in a molecular synchrotron

Aernout P. P. van der Poel, Hendrick L. Bethlem

Research output: Contribution to Journal › Review article › Academic › peer-review

Abstract

We have recently demonstrated a general and sensitive method to study low energy collisions that exploits the unique properties of a molecular synchrotron (Van der Poel et al., Phys Rev Lett 120:033402, 2018). In that work, the total cross section for ND3 + Ar collisions was determined from the rate at which ammonia molecules were lost from the synchrotron due to collisions with argon atoms in supersonic beams. This paper provides further details on the experiment. In particular, we derive the model that was used to extract the relative cross section from the loss rate, and present measurements to characterize the spatial and velocity distributions of the stored ammonia molecules and the supersonic argon beams.

Original language	English
Journal	EPJ Techniques and Instrumentation
Volume	5
DOIs	https://doi.org/10.1140/epjti/s40485-018-0048-y
Publication status	Published - 11 Jul 2018

Keywords

Cold molecules
Stark deceleration
Collisions
Molecular beams

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title = "A detailed account of the measurements of cold collisions in a molecular synchrotron",

abstract = "We have recently demonstrated a general and sensitive method to study low energy collisions that exploits the unique properties of a molecular synchrotron (Van der Poel et al., Phys Rev Lett 120:033402, 2018). In that work, the total cross section for ND3 + Ar collisions was determined from the rate at which ammonia molecules were lost from the synchrotron due to collisions with argon atoms in supersonic beams. This paper provides further details on the experiment. In particular, we derive the model that was used to extract the relative cross section from the loss rate, and present measurements to characterize the spatial and velocity distributions of the stored ammonia molecules and the supersonic argon beams.",

keywords = "Cold molecules, Stark deceleration, Collisions, Molecular beams",

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AU - van der Poel, Aernout P. P.

AU - Bethlem, Hendrick L.

PY - 2018/7/11

Y1 - 2018/7/11

N2 - We have recently demonstrated a general and sensitive method to study low energy collisions that exploits the unique properties of a molecular synchrotron (Van der Poel et al., Phys Rev Lett 120:033402, 2018). In that work, the total cross section for ND3 + Ar collisions was determined from the rate at which ammonia molecules were lost from the synchrotron due to collisions with argon atoms in supersonic beams. This paper provides further details on the experiment. In particular, we derive the model that was used to extract the relative cross section from the loss rate, and present measurements to characterize the spatial and velocity distributions of the stored ammonia molecules and the supersonic argon beams.

AB - We have recently demonstrated a general and sensitive method to study low energy collisions that exploits the unique properties of a molecular synchrotron (Van der Poel et al., Phys Rev Lett 120:033402, 2018). In that work, the total cross section for ND3 + Ar collisions was determined from the rate at which ammonia molecules were lost from the synchrotron due to collisions with argon atoms in supersonic beams. This paper provides further details on the experiment. In particular, we derive the model that was used to extract the relative cross section from the loss rate, and present measurements to characterize the spatial and velocity distributions of the stored ammonia molecules and the supersonic argon beams.

KW - Cold molecules

KW - Stark deceleration

KW - Collisions

KW - Molecular beams

U2 - 10.1140/epjti/s40485-018-0048-y

DO - 10.1140/epjti/s40485-018-0048-y

M3 - Review article

SN - 2195-7045

VL - 5

JO - EPJ Techniques and Instrumentation

JF - EPJ Techniques and Instrumentation

ER -

A detailed account of the measurements of cold collisions in a molecular synchrotron

Abstract

Keywords

UN SDGs

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