Is a retarded electron transfer shorter lived?
ORAL
Abstract
The Barium-Rubidium Interaction Experiment observes short lifetimes of central barium cations at ultracold temperatures due to electron transfer from the surrounding Bose-Einstein condensate of neutral rubidium atoms.
The question arises whether the coherence of the environment would at all play a role in fundamental interactions if the central cation is that short-lived.
This contribution presents semi-relativistic quantumelectrodynamic reasoning on the net-effect of the ultracold rubidium environment on the lifetime of the central barium cation.
Noteworthy is this result because it provides a generalization of resonant energy transfer theory simultaneously with a roadmap to an experimental confirmation of contributing coherence effects from the surrounding condensate on central impurities in a Bose-Einstein condensate.
The question arises whether the coherence of the environment would at all play a role in fundamental interactions if the central cation is that short-lived.
This contribution presents semi-relativistic quantumelectrodynamic reasoning on the net-effect of the ultracold rubidium environment on the lifetime of the central barium cation.
Noteworthy is this result because it provides a generalization of resonant energy transfer theory simultaneously with a roadmap to an experimental confirmation of contributing coherence effects from the surrounding condensate on central impurities in a Bose-Einstein condensate.
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Publication: part of a multilateral research initiative between the KU Leuven in Belgium, and the Colorado School of Mines in the US on modelling of energy transfer in condensates with impurities, with experimental support by the BaRbIE project at Uni Ulm, Germany.<br>
Presenters
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Axel Molle
KU Leuven, Belgium
Authors
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Axel Molle
KU Leuven, Belgium