Few-electron physics in Double quantum dots in carbon nanotubes

Javier von Stecher; Bernhard Wunsch; Mikhail Lukin; Eugene Demler; Ana Maria Rey

Few-electron physics in Double quantum dots in carbon nanotubes

POSTER

Abstract

Recent experimental progress on few-electron quantum dots (also known as artificial atoms) has allowed the controllable manipulation of the spin degrees of freedom of the confined electrons. Such control is at the heart of semiconductor-based spintronics and quantum-information proposals. Double-well quantum dot in~semiconducting carbon nanotubes exhibit rich physics due to the additional valley degree of freedom. Here, we study the few-electron spectrum of a carbon-nanotube double quantum dot with spin-orbit coupling. We find that Coulomb interactions can cause strong correlation effects which lead to different ground state transitions. In particular, we show that such strong correlations can produce the disappearance of the Pauli blockade in transport experiments and an interaction-induced ferromagnetic ground state.

Authors

Javier von Stecher

JILA and Department of Physics, University of Colorado, Boulder, Colorado
Bernhard Wunsch

Physics Department, Harvard University, Cambridge-MA, 20138
Mikhail Lukin

Harvard, ITAMP, Harvard Physics Dpt, CUA, Physics Dept., Harvard U., Harvard University, Physics Department, Harvard University, Cambridge-MA, 20138, Physics Department, Harvard University, Cambridge-MA, 20138.
Eugene Demler

Physics Department, Harvard University, Cambridge-MA, 20138, Physics Department, Harvard University, Cambridge-MA, 20138., Harvard University
Ana Maria Rey

University of Colorado, JILA, NIST, JILA, University of Colorado at Boulder, JILA, NIST, and the University of Colorado, JILA and Department of Physics, University of Colorado, Boulder, Colorado, JILA, NIST and Department of Physics, University of Colorado