Control of valley polarization in monolayer MoS2 by optical helicity

TL;DR

This paper demonstrates that circularly polarized light can dynamically control valley polarization in monolayer MoS2, enabling potential valleytronic devices with long-lived valley states.

Contribution

It introduces a method for optical control of valley polarization in MoS2, achieving complete and long-lasting valley polarization, which was not previously demonstrated.

Findings

Achieved complete valley polarization using circularly polarized light.

Valley polarization persists for longer than 1 nanosecond.

Demonstrated optical control as a viable method for valleytronics in MoS2.

Abstract

Electronic and spintronic devices rely on the fact that free charge carriers in solids carry electric charge and spin, respectively. There are, however, other properties of charge carriers that might be exploited in new families of devices. In particular, if there are two or more conduction (or valence) band extrema in momentum space, then confining charge carriers in one of these valleys allows the possibility of valleytronic devices. Such valley polarization has been demonstrated by using strain and magnetic fields, but neither of these approaches allow for dynamic control. Recently, optical control of valley occupancy in graphene with broken inversion symmetry has been proposed but remains experimentally difficult to realize. Here we demonstrate that optical pumping with circularly-polarized light can achieve complete dynamic valley polarization in monolayer MoS2, a two dimensional (2D) non-centrosymmetric crystal with direct energy gaps at two valleys. Moreover, this polarization is retained for longer than 1 ns. Our results demonstrate the viability of optical valley control and valley-based electronic and optoelectronic applications in MoS2 monolayers.