This paper presents full-quantum 3-D simulations predicting the electrical performance of nanowire tunnel-FETs based on III-V hetero-junctions. Our calculations exploit an eight-band k.p Hamiltonian within the nonequilibrium Green's functions formalism and include phonon scattering. It is shown that the on-current of GaSb/InAs hetero-junction tunnel-FETs is limited by quantum confinement effects on the bandstructure induced by the small nanowire diameter necessary to preserve an optimal electrostatic integrity at short gate lengths. To circumvent this problem, additional on-current improvements with no substantial subthreshold swing degradation can be achieved by engineering the source region through the insertion of an InAs/GaSb/InAs quantum well along the transport direction. Such a design option is predicted to provide on/off-current ratios larger than 10(7) even at V-DD = 300 mV.
Exploiting Hetero-Junctions to Improve the Performance of III-V Nanowire Tunnel-FETs
Pala M;
2015-01-01
Abstract
This paper presents full-quantum 3-D simulations predicting the electrical performance of nanowire tunnel-FETs based on III-V hetero-junctions. Our calculations exploit an eight-band k.p Hamiltonian within the nonequilibrium Green's functions formalism and include phonon scattering. It is shown that the on-current of GaSb/InAs hetero-junction tunnel-FETs is limited by quantum confinement effects on the bandstructure induced by the small nanowire diameter necessary to preserve an optimal electrostatic integrity at short gate lengths. To circumvent this problem, additional on-current improvements with no substantial subthreshold swing degradation can be achieved by engineering the source region through the insertion of an InAs/GaSb/InAs quantum well along the transport direction. Such a design option is predicted to provide on/off-current ratios larger than 10(7) even at V-DD = 300 mV.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
