Quantum-State Controlled Chemical Reactions of Ultracold Potassium-Rubidium Molecules

How does a chemical reaction proceed at ultralow temperatures? Can simple quantum mechanical rules such as quantum statistics, single partial-wave scattering, and quantum threshold laws provide a clear understanding of the molecular reactivity under a vanishing collision energy? Starting with an opt...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2010-02, Vol.327 (5967), p.853-857
Hauptverfasser: Ospelkaus, S, Ni, K.-K, Wang, D, de Miranda, M.H.G, Neyenhuis, B, Quéméner, G, Julienne, P.S, Bohn, J.L, Jin, D.S, Ye, J
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Sprache:eng
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Zusammenfassung:How does a chemical reaction proceed at ultralow temperatures? Can simple quantum mechanical rules such as quantum statistics, single partial-wave scattering, and quantum threshold laws provide a clear understanding of the molecular reactivity under a vanishing collision energy? Starting with an optically trapped near-quantum-degenerate gas of polar ⁴⁰K⁸⁷Rb molecules prepared in their absolute ground state, we report experimental evidence for exothermic atom-exchange chemical reactions. When these fermionic molecules were prepared in a single quantum state at a temperature of a few hundred nanokelvin, we observed p-wave-dominated quantum threshold collisions arising from tunneling through an angular momentum barrier followed by a short-range chemical reaction with a probability near unity. When these molecules were prepared in two different internal states or when molecules and atoms were brought together, the reaction rates were enhanced by a factor of 10 to 100 as a result of s-wave scattering, which does not have a centrifugal barrier. The measured rates agree with predicted universal loss rates related to the two-body van der Waals length.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.1184121