Electrically tunable second harmonic generation in atomically thin ReS2

TL;DR

This paper demonstrates electrically tunable second harmonic generation in atomically thin ReS2, enabling dynamic control of nonlinear optical responses for advanced optoelectronic applications.

Contribution

It reveals the first experimental demonstration of electrically tunable SHG in ReS2, leveraging its unique crystal structure and interlayer charge transfer.

Findings

SHG can be induced in odd-layer ReS2 flakes via electric field.

Electric field can modulate SHG amplitude by over an order of magnitude.

First-principles calculations explain the hyperpolarizability modification.

Abstract

Electrical tuning of second-order nonlinearity in optical materials is attractive to strengthen and expand the functionalities of nonlinear optical technologies, though its implementation remains elusive. Here, we report the electrically tunable second-order nonlinearity in atomically thin ReS2 flakes benefiting from their distorted 1T crystal structure and interlayer charge transfer. Enabled by the efficient electrostatic control of the few-atomic-layer ReS2, we show that second harmonic generation (SHG) can be induced in odd-number-layered ReS2 flakes which are centrosymmetric and thus without intrinsic SHG. Moreover, the SHG can be precisely modulated by the electric field, reversibly switching from almost zero to an amplitude more than one order of magnitude stronger than that of the monolayer MoS2. For the even-number-layered ReS2 flakes with the intrinsic SHG, the external electric field could be leveraged to enhance the SHG. We further perform the first-principles calculations which suggest that the modification of in-plane second-order hyperpolarizability by the redistributed interlayer-transferring charges in the distorted 1T crystal structure underlies the electrically tunable SHG in ReS2. With its active SHG tunability while using the facile electrostatic control, our work may further expand the nonlinear optoelectronic functions of two-dimensional materials for developing electrically controllable nonlinear optoelectronic devices.