Electron spin relaxation by hyperfine interaction in a double quantum dot

Alex Johnson; Jason Petta; Jacob Taylor; Charles Marcus; Mikhail Lukin; Amir Yacoby; Micah Hanson; Art Gossard

Electron spin relaxation by hyperfine interaction in a double quantum dot

ORAL

Abstract

We use a pulsed-gate technique to measure singlet-triplet relaxation in a GaAs/AlGaAs few-electron double quantum dot at low magnetic field. Electrostatic pulses are applied to probe the time dynamics of the (1,1) to (0,2) charge state transition, while average dot occupation is measured by nearby quantum point contact charge sensors. In the (0,2) configuration only a spin singlet is allowed, blocking the transition from (1,1) if a triplet state is initially formed, but relaxation is strongly enhanced near zero magnetic field. We attribute this enhancement to different nuclear environments in each dot, and extract an average effective Overhauser field of ~3 mT. This implies a spin dephasing time of ~30 ns in this system.

^*We acknowledge funding from ARO, NSF, and DARPA

March 23, 2005, 6:00 AM – March 23, 2005, 6:12 AM

Authors

Alex Johnson
Jason Petta
Jacob Taylor
- Harvard University
Charles Marcus
- Harvard University
Mikhail Lukin
- Harvard University
Amir Yacoby
- Weizmann Institute
- Harvard University and Weizmann Institute
- Department of Condensed Matter Physics, Weizmann Institute of Science, Israel
- Weizmann Institute of Science, Rehovot 76100, Israel
Micah Hanson
Art Gossard
- UCSB
- University of California at Santa Barbara
- University of California, Santa Barbara
- Materials and ECE Departments, UCSB