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Deviation from Universality in Collisions of Ultracold $^6$Li$_2$ Molecules

Collisions of $^6$Li$_2$ molecules with free $^6$Li atoms reveal a striking deviation from universal predictions based on long-range van der Waals interactions. Li$_2$ closed-channel molecules are formed in the highest vibrational state near a narrow Feshbach resonance, and decay via two-body collisions with Li$_2$, Li, and Na. For Li$_2$+Li$_2$ and Li$_2$+Na, the decay rates agree with the universal predictions of the quantum Langevin model. In contrast, the rate for Li$_2$+Li is exceptionally small, with an upper bound ten times smaller than the universal prediction. This can be explained by the low density of available decay states in systems of light atoms [G. Quéméner, J.-M. Launay, and P. Honvault, Phys. Rev. A \textbf{75}, 050701 (2007)], for which such collisions have not been studied before.

preprint2013arXivOpen access
Tout T. WangMyoung-Sun HeoTimur M. RvachovDylan A. CottaWolfgang Ketterle
physics.atom-phcond-mat.quant-gas
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Tout T. WangMyoung-Sun HeoTimur M. RvachovDylan A. CottaWolfgang Ketterle

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