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Very slow expansion of an ultracold plasma formed in a seeded supersonic molecular beam of NO

Abstract:
The double-resonant laser excitation of nitric oxide, cooled to 1 K in a seeded supersonic molecular beam, yields a gas of 1012 molecules per cubic centimeter in a single selected Rydberg state. This population evolves to produce prompt free electrons, and a durable cold plasma of electrons and intact NO+ ions. This plasma travels with the molecular beam through a field-free region to encounter a grid. The atomic weight of the expansion gas controls the beam velocity and hence the flight time from the interaction region to the grid. Monitoring electron production as the plasma traverses this grid measures its longitudinal width as a function of flight time. Comparing these widths to the width of the laser beam that defines the initial size of the illuminated volume allows us to gauge the rate of expansion of the plasma. We find that the plasma created from the evolution of a Rydberg gas of NO expands at a small but measurable rate, and that this rate of expansion accords with the Vlasov equations for an initial electron temperature of Te 7 K. © 2009 The American Physical Society.

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Publisher copy:
10.1103/PhysRevA.79.062706

Authors

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Institution:
University of Oxford
Division:
MPLS
Department:
Chemistry
Role:
Author


Journal:
Physical Review A - Atomic, Molecular, and Optical Physics More from this journal
Volume:
79
Issue:
6
Publication date:
2009-06-09
DOI:
EISSN:
1094-1622
ISSN:
1050-2947


Language:
English
Pubs id:
pubs:295081
UUID:
uuid:f547ecaf-052c-4a05-aba2-232f3e423def
Local pid:
pubs:295081
Source identifiers:
295081
Deposit date:
2013-11-17
ARK identifier:

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