Time-Reversal Symmetry and Universal Conductance Fluctuations in a Driven Two-Level System

Author(s)

Gustavsson, Simon; Bylander, Jonas; Oliver, William D.

Abstract

In the presence of time-reversal symmetry, quantum interference gives strong corrections to the electric conductivity of disordered systems. The self-interference of an electron wave function traveling time-reversed paths leads to effects such as weak localization and universal conductance fluctuations. Here, we investigate the effects of broken time-reversal symmetry in a driven artificial two-level system. Using a superconducting flux qubit, we implement scattering events as multiple Landau-Zener transitions by driving the qubit periodically back and forth through an avoided crossing. Interference between different qubit trajectories gives rise to a speckle pattern in the qubit transition rate, similar to the interference patterns created when coherent light is scattered off a disordered potential. Since the scattering events are imposed by the driving protocol, we can control the time-reversal symmetry of the system by making the drive waveform symmetric or asymmetric in time. We find that the fluctuations of the transition rate exhibit a sharp peak when the drive is time symmetric, similar to universal conductance fluctuations in electronic transport through mesoscopic systems.

Date issued

2013-01

URI

http://hdl.handle.net/1721.1/77166

Department

Lincoln Laboratory
Massachusetts Institute of Technology. Research Laboratory of Electronics

Journal

Physical Review Letters

Publisher

American Physical Society

Citation

Gustavsson, Simon, Jonas Bylander, and William D. Oliver. “Time-Reversal Symmetry and Universal Conductance Fluctuations in a Driven Two-Level System.” Physical Review Letters 110.1 (2013). © 2013 American Physical Society

Version: Final published version

ISSN

0031-9007

1079-7114