Tuning carrier mobility of phosphorene nanoribbons by edge passivation and strain

Abstract Using first-principles calculations, we have studied the effects of different edge passivation groups on the carrier mobility of the phosphorene nanoribbons (PNRs) and strain effect on the transport property in passivated PNRs. The numerical results show that the size-dependent carrier mobility of passivated PNRs is not very sensitive to the different passivation groups, such as hydrogen (H), fluorine (F) and chlorine (Cl), but strongly associated with the orientation of nanoribbons. Passivated armchair-PNR has much larger carrier mobility than passivated zigzag-PNR at the similar ribbon width. With increasing ribbon width, the electron mobility of passivated PNRs can be further enhanced. We also find that the anisotropy of carrier mobility in passivated PNRs can be reversed by applying tensile strain resulting from order switching of the conduction bands around Fermi level.