AI Article Synopsis
- Merging codirectional beams with higher translational energies enables the study of molecular collisions at very low relative kinetic energies, like in the milliKelvin range.
- This technique offers greater intensity and a broader chemical scope compared to methods that require slowing both collision partners.
- The assessment focuses on the collision energy range and resolution achievable for thermal molecular beams, influenced by the velocity distributions of the merged beams, including both standard and a unique rotating supersonic source method.
Article Abstract
Molecular collisions can be studied at very low relative kinetic energies, in the milliKelvin range, by merging codirectional beams with much higher translational energies, extending even to the kiloKelvin range, provided that the beam speeds can be closely matched. This technique provides far more intensity and wider chemical scope than methods that require slowing both collision partners. Previously, at far higher energies, merged beams have been widely used with ions and/or neutrals formed by charge transfer. Here, we assess for neutral, thermal molecular beams the range and resolution of collision energy that now appears attainable, determined chiefly by velocity spreads within the merged beams. Our treatment deals both with velocity distributions familiar for molecular beams formed by effusion or supersonic expansion, and an unorthodox variant produced by a rotating supersonic source capable of scanning the lab beam velocity over a wide range.
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| http://dx.doi.org/10.1063/1.4739315 | DOI Listing |
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