Superadiabatic quantum friction suppression in finite-time thermodynamics
POSTER
Abstract
Optimal performance of thermal machines is reached by suppressing friction. Friction in quantum thermodynamics results from fast driving schemes that generate nonadiabatic excitations. The far-from-equilibrium dynamics of quantum devices can be tailored by shortcuts to adiabaticity to suppress quantum friction. We experimentally demonstrate friction-free superadiabatic strokes with a trapped unitary Fermi gas as a working substance and establish the equivalence between the superadiabatic mean work and its adiabatic value.
S. Deng et al., Shortcuts to adiabaticity in the strongly-coupled regime: nonadiabatic control of a unitary Fermi gas, Phys. Rev. A 97, 013628 (2018)
S. Deng et al., Superadiabatic quantum friction suppression in finite-time thermodynamics, Science Advances 4, eaar5909 (2018)
P. Diao et al., Shortcuts to adiabaticity in Fermi gases, New J. Phys. 20, 105004 (2018)
S. Deng et al., Shortcuts to adiabaticity in the strongly-coupled regime: nonadiabatic control of a unitary Fermi gas, Phys. Rev. A 97, 013628 (2018)
S. Deng et al., Superadiabatic quantum friction suppression in finite-time thermodynamics, Science Advances 4, eaar5909 (2018)
P. Diao et al., Shortcuts to adiabaticity in Fermi gases, New J. Phys. 20, 105004 (2018)
Presenters
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Adolfo Del Campo
University of Massachusetts Boston, University of Massachusetts, Physics, University of Massachusetts Boston
Authors
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Shujin Deng
East China Normal University
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Aurelia Chenu
Theoretical Division, Los Alamos National Laboratory, Los Alamos National Laboratory
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Pengpeng Diao
East China Normal University
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Fang Li
East China Normal University
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Shi Yu
East China Normal University
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Ivan Coulamy
Universidade Federal Fluminense
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Adolfo Del Campo
University of Massachusetts Boston, University of Massachusetts, Physics, University of Massachusetts Boston
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Haibin Wu
East China Normal University