Valley Engineering in Bilayer WSe2 Gate-All-Around Transistors

Abstract

In bilayer WSe2, interlayer coupling reduces the K--Γ valley splitting to ΔKΓ ≈ kBT at room temperature, placing two hole-transport channels of markedly different effective mass in near-thermal equilibrium. We combine density functional theory (DFT) with spin--orbit coupling and an analytical two-valley device model to quantify how this near-degeneracy governs hole transport in gate-all-around (GAA) field-effect transistors. Three main results are obtained: (i)~the subthreshold swing is protected near 60~mV~dec-1 by quantum-capacitance screening independently of layer number; (ii)~the effective mobility is set by the K-to-Γ valley occupation ratio and decreases monotonically with layer number; and (iii)~in the bilayer, compressive biaxial strain simultaneously enhances the on-current, suppresses the off-current, and improves the on/off ratio from ≈69 to ≈156, while the subthreshold swing remains near the thermionic limit. This decoupling of on-state performance from switching slope is inaccessible through conventional mobility engineering and establishes a concrete design principle: valley-engineering sensitivity is maximized when ΔKΓ ≈ kBT, the condition most naturally satisfied by bilayer WSe2 at room temperature and zero strain, making it the optimal channel for valley-engineered GAA transistors.