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Challenges and constraints of dynamically emerged source and sink in atomtronic circuits: From closed-system to open-system approaches

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arxiv 1609.00468 v1 pith:256RGNII submitted 2016-09-02 cond-mat.quant-gas quant-ph

Challenges and constraints of dynamically emerged source and sink in atomtronic circuits: From closed-system to open-system approaches

classification cond-mat.quant-gas quant-ph
keywords sinkemergedpotentialsourceatomsbosonsdynamicallysystems
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While batteries offer electronic source and sink in electronic devices, atomic analogues of source and sink and their theoretical descriptions have been a challenge in cold-atom systems. Here we consider dynamically emerged local potentials as controllable source and sink for bosonic atoms. Although a sink potential can collect bosons in equlibrium and indicate its usefulness in the adiabatic limit, sudden switching of the potential exhibits low effectiveness in pushing bosons into it. This is due to conservation of energy and particle in isolated systems such as cold atoms. By varying the potential depth and interaction strength, the systems can further exhibit averse response, where a deeper emerged potential attracts less bosonic atoms into it. To explore possibilities for improving the effectiveness, we investigate what types of system-environment coupling can help bring bosons into a dynamically emerged sink, and a Lindblad operator corresponding to local cooling is found to serve the purpose.

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