Scalling theory of quantum ratchet in low temperature limit
ORAL
Abstract
Directionality of responses in noncentrosymmetric materials is a central issue in condensed matter physics. The quantum dynamics of particles in an asymmetric washboard potential with dissipation is a typical system.
Previous study on the 2nd order mobility have shown the rich physics in this system, the sign reversal of the rectified current and quantum to classical crossover, for instance. However, the relations with the quantum phase transition taking place at certain strength of the dissipation above which the system goes to a localized state, is still a nontrivial issue.
Here, we clarified the detailed low temperature behavior of the steady velocity and mobility of a particle under the ratchet potential both analytically and numerically. The exponent in the power law dependence for arbitrary order mobility is determined and summarized in simple scaling forms. The relations to the quantum phase transition is also discussed.
Previous study on the 2nd order mobility have shown the rich physics in this system, the sign reversal of the rectified current and quantum to classical crossover, for instance. However, the relations with the quantum phase transition taking place at certain strength of the dissipation above which the system goes to a localized state, is still a nontrivial issue.
Here, we clarified the detailed low temperature behavior of the steady velocity and mobility of a particle under the ratchet potential both analytically and numerically. The exponent in the power law dependence for arbitrary order mobility is determined and summarized in simple scaling forms. The relations to the quantum phase transition is also discussed.
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Presenters
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Keita Hamamoto
Department of Applied Physics, University of Tokyo, University of Tokyo
Authors
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Keita Hamamoto
Department of Applied Physics, University of Tokyo, University of Tokyo
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Takamori Park
University of Tokyo
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Hiroaki Ishizuka
Department of Applied Physics, University of Tokyo, University of Tokyo
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Naoto Nagaosa
University of Tokyo, Riken CEMS, Department of Applied Physics, University of Tokyo, RIKEN Center for Emergent Matter Science (CEMS), RIKEN CEMS, Center for Emergent Matter Science, RIKEN, RIKEN, Department of applied physics, The University of Tokyo, Department of Applied Physics, Universtiy of Tokyo, University of Tokyo