Ultracold chemistry in supersonic beams. When two atoms or molecules interact at very low collision energies and therefore very cold effective temperatures, the reactants’ de Broglie wavelengths become comparable to their separation. In that regime, theory says the classical notion of bouncing billiard balls breaks down; instead, one reactant can tunnel quantum mechanically—through an angular-momentum or energy barrier, for example—to chemically react with the other. But the experimental realization of such quantum effects lags far behind the theory, largely because of the difficulty of cooling neutral atoms and molecules. So quantum chemists make fast molecular beams of different species by letting high-pressure gas adiabatically expand into vacuum through a small orifice. Researchers have set up reactive encounters by intersecting two such internally cold molecular beams. In that way, temperatures as low as 5 K have been reached, with hints of quantum behavior. Now a group of chemical physicists at the...
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1 December 2012
December 01 2012
Citation
Stephen G. Benka; Ultracold chemistry in supersonic beams. Physics Today 1 December 2012; 65 (12): 21. https://doi.org/10.1063/PT.3.1811
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