Chemical Doping and Electron-Hole Conduction Asymmetry in Graphene Devices

Roksana Golizadeh Mojarad; Damon Farmer; Vasili Perebeinos; Yu-Ming Lin; George S. Tulevski; James C. Tsang; Ali Afzali; Phaedon Avouris

Chemical Doping and Electron-Hole Conduction Asymmetry in Graphene Devices

ORAL

Abstract

We investigate polyethylene imine and diazonium salts as stable, complementary dopants on graphene. Transport in graphene devices doped with these molecules exhibits asymmetry in electron and hole conductance. The conductance of one carrier is preserved, while the conductance of the other carrier decreases. Simulations based on nonequilibrium Green's function formalism suggest that the origin of this asymmetry is imbalanced carrier injection from the graphene electrodes caused by misalignment of the electrode and channel neutrality points.

March 16, 2009, 1:27 PM – March 16, 2009, 1:39 PM

Authors

Roksana Golizadeh Mojarad
- Purdue University
Damon Farmer
- IBM
- IBM T.J. Watson Research Center
Vasili Perebeinos
- IBM T.J. Watson Research Center
Yu-Ming Lin
- IBM T.J. Watson Research Center
George S. Tulevski
- IBM T.J. Watson Research Center
James C. Tsang
- IBM T.J. Watson Research Center
Ali Afzali
- IBM T.J. Watson Research Center
Phaedon Avouris
- IBM T.J. Watson Research Center