Relaxation and dephasing in a two-electron ^{13}C nanotube double quantum dot

Charles Marcus; Hugh Churchill; Ferdinand Kuemmeth; Jennifer Harlow; Andrew Bestwick; Emmanuel Rashba; Karsten Flensberg; Carolyn Stwertka; Thiti Taychatanapat; Susan Watson

Relaxation and dephasing in a two-electron $^{13}$C nanotube double quantum dot

ORAL

Abstract

We use charge sensing of Pauli blockade (including spin and isospin) in a two-electron $^{13}$C nanotube double quantum dot to measure relaxation and dephasing times. The relaxation time, $T_1$, first decreases with parallel magnetic field then goes through a minimum in a field of 1.4 T. We attribute both results to the spin-orbit-modified electronic spectrum of carbon nanotubes, which suppresses hyperfine mediated relaxation and enhances relaxation due to soft phonons. The inhomogeneous dephasing time, $T_2^*$, is consistent with previous data on hyperfine coupling strength in $^{13}$C nanotubes. This work was supported by the National Science Foundation under grant no.~NIRT 0210736 and the GRFP, ARO/iARPA, the Department of Defense, and Harvard's Center for Nanoscale Systems.

March 17, 2009, 3:06 PM – March 17, 2009, 3:18 PM

Authors

Charles Marcus
- Harvard University
- Department of Physics, Harvard University, MA
Hugh Churchill
- Harvard University
Ferdinand Kuemmeth
- Harvard University
Jennifer Harlow
- JILA, University of Colorado and NIST
- Harvard University
Andrew Bestwick
- Harvard University
Emmanuel Rashba
- Harvard University
Karsten Flensberg
- University of Copenhagen
Carolyn Stwertka
- Harvard University
Thiti Taychatanapat
- Harvard University
Susan Watson
- Harvard University and Middlebury College