Effects of phonon confinement on electron transport in Si nanowire and armchair-edge graphene nanoribbon transistors: A dissipative quantum-transport study

Abstract

Electronic transport in low-dimensional structures, such as thin bodies, nanosheets, nanoribbons and nanowires, is strongly affected by electron and phonon confinement, in addition to interface roughness. Here we use a quantum-transport formulation based on empirical pseudopotentials and the Master equation to study the effect of the phonon boundary conditions on the electron transport in field effect transistors (FETs) based on a small cross-section (3×3 cells) Si nanowire (NW) and a 10 armchair graphene nanoribbon (10-aGNR). For the dispersion of the confined phonons we employ a simple empirical model based on the folding of the bulk phonon dispersion that approximates the results of the elastic-continuum model at long wavelengths. We consider two extreme cases for their boundary conditions: clamped boundary conditions (CBCs) or free-standing (FSBCs). We find that phonon confinement affects more severely the Si nanowires than graphene nanoribbons. In particular, for 3×3 SiNW-FETs, CBCs result in a higher room-temperature electron mobility than FSBCs, a result consistent with what previously reported. On the contrary, in the off-equilibrium conditions seen in gate-all-around (GAA) 3×3 SiNW-FETs with 7~nm gate-length, FSBCs yield a higher on-current than what is obtained assuming CBCs. However, for 10-aGNR-FETs, both the electron mobility and the on-current are higher when assuming FSBCs.

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