We investigate the heat transport and the control of heat current among two
spatially separated trapped Bose-Einstein Condensates (BEC), each of them at a
different temperature. To allow for heat transport among the two independent
BECs we consider a link made of two harmonically trapped impurities, each of
them interacting with one of the BECs. Since the impurities are spatially
separated, we consider long-range interactions between them, namely a
dipole-dipole coupling. We study this system under theoretically suitable and
experimentally feasible assumptions/parameters. The dynamics of these
impurities is treated within the framework of the quantum Brownian motion
model, where the excitation modes of the BECs play the role of the heat bath.
We address the dependence of heat current and current-current correlations on
the physical parameters of the system. Interestingly, we show that heat
rectification, i.e., the unidirectional flow of heat, can occur in our system,
when a periodic driving on the trapping frequencies of the impurities is
considered. Therefore, our system is a possible setup for the implementation of
a phononic circuit. Motivated by recent developments on the usage of BECs as
platforms for quantum information processing, our work offers an alternative
possibility to use this versatile setting for information transfer and
processing, within the context of phononics, and more generally in quantum
thermodynamics.Comment: 33 pages, 4 Figure

Charalambous, Christos

Garcia-March, Miguel-Angel

Lewenstein, Maciej

Mehboudi, Mohammad

English

arXiv

[EN] We investigate the heat transport and the control of heat current among two spatially separated trapped Bose-Einstein Condensates (BECs), each of them at a different temperature. To allow for heat transport among the two independent BECs we consider a link made of two harmonically trapped impurities, each of them interacting with one of the BECs. Since the impurities are spatially separated, we consider long-range interactions between them, namely a dipole-dipole coupling. We study this system under theoretically suitable and experimentally feasible assumptions/parameters. The dynamics of these impurities is treated within the framework of the quantum Brownian motion model, where the excitation modes of the BECs play the role of the heat bath. We address the dependence of heat current and current-current correlations on the physical parameters of the system. Interestingly, we show that heat rectification, i.e. the unidirectional flow of heat, can occur in our system, when a periodic driving on the trapping frequencies of the impurities is considered. Therefore, our system is a possible setup for the implementation of a phononic circuit. Motivated by recent developments on the usage of BECs as platforms for quantum information processing, our work offers an alternative possibility to use this versatile setting for information transfer and processing, within the context of phononics, and more generally in quantum thermodynamics.We thank fruitful discussions with Andreu Riera-Campeny. We acknowledge the Spanish Ministry MINECO (National Plan 15 Grant: FISICATEAMO No. FIS2016-79508-P, SEVEROOCHOA No. SEV-2015-0522), the Ministry of Education of Spain (FPI Grant BES-2015-071803), European Social Fund, Fundacio Cellex, Generalitat de Catalunya (AGAUR Grant No. 2017 SGR 1341 and CERCA/Program), ERC AdG OSYRIS and NOQIA, EU FETPRO QUIC, and the National Science Centre, Poland-Symfonia Grant No. 2016/20/W/ST4/00314. MM acknowledges support from the Spanish MINECO (QIBEQI FIS2016-80773-P and Severo Ochoa SEV-2015-0522), Fundacio Privada Cellex, and the Generalitat de Catalunya (CERCA Program and SGR1381).Charalambous, C.; Garcia March, MA.; Mehboudi, M.; Lewenstein, M. (2019). Heat current control in trapped Bose-Einstein Condensates. NEW JOURNAL OF PHYSICS. 21:1-18. https://doi.org/10.1088/1367-2630/ab383211821Terraneo, M., Peyrard, M., & Casati, G. (2002). Controlling the Energy Flow in Nonlinear Lattices: A Model for a Thermal Rectifier. 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Charalambous, C.

Garcia March, Miguel Angel

Mehboudi, M.

Lewenstein, M.

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Heat current control in trapped Bose-Einstein Condensates

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Heat current control in trapped BEC

Heat current control in trapped BEC

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