Conductance fluctuations in chaotic systems with tunnel barriers

Waltner, Daniel and Kuipers, Jack and Jacquod, Philippe and Richter, Klaus (2012) Conductance fluctuations in chaotic systems with tunnel barriers. PHYSICAL REVIEW B, 85 (2): 024302. ISSN 1098-0121,

Full text not available from this repository.

Abstract

Quantum effects are expected to disappear in the short-wavelength, semiclassical limit. As a matter of fact, recent investigations of transport through quantum chaotic systems have demonstrated the exponential suppression of the weak localization corrections to the conductance and of the Fano factor for shot noise when the Ehrenfest time tau(E) exceeds the electronic dwell time tau(D). On the other hand, conductance fluctuations, an effect of quantum coherence, retain their universal value in the limit tau(E)/tau(D) -> infinity, when the system is ideally coupled to external leads. Motivated by this intriguing result we investigate conductance fluctuations through quantum chaotic cavities coupled to external leads via (tunnel) barriers of arbitrary transparency Gamma. Using the trajectory-based semiclassical theory of transport, we find that the linear tau(E) dependence of the conductance variance shows a nonmonotonous, sinusoidal behavior as a function of Gamma. Most notably, we find an increase of the conductance fluctuations with tau(E), above their universal value, for Gamma less than or similar to 0.5. These results, confirmed by numerical simulations, show that, contrary to common wisdom, effects of quantum coherence may increase in the semiclassical limit, under special circumstances.

Item Type: Article
Uncontrolled Keywords: CLASSICAL TRAJECTORIES; WEAK-LOCALIZATION; SCATTERING-THEORY; QUANTUM CHAOS; SHOT-NOISE; DIVERGENCE;
Subjects: 500 Science > 530 Physics
Divisions: Physics > Institute of Theroretical Physics > Chair Professor Richter > Group Klaus Richter
Depositing User: Dr. Gernot Deinzer
Date Deposited: 20 May 2020 10:16
Last Modified: 20 May 2020 10:16
URI: https://pred.uni-regensburg.de/id/eprint/19371

Actions (login required)

View Item View Item
pred is powered by EPrints 3.4 which is developed by the School of Electronics and Computer Science at the University of Southampton. More information and software credits.