The role of device asymmetries and Schottky barriers on the helicity-dependent photoresponse of 2D phototransistors

Jorge Quereda,Caspar H Van Der Wal,Bart J Van Wees,Marcos H D Guimarães,Talieh S Ghiasi,Jan Hidding

doi:10.1038/s41699-020-00194-w

Jorge Quereda, Caspar H Van Der Wal + Show 4 more

Open Access

https://doi.org/10.1038/s41699-020-00194-w

Copy DOI

Abstract

Circular photocurrents (CPC), namely circular photogalvanic (CPGE) and photon drag effects, have recently been reported both in monolayer and multilayer transition metal dichalcogenide (TMD) phototransistors. However, the underlying physics for the emergence of these effects are not yet fully understood. In particular, the emergence of CPGE is not compatible with the D3h crystal symmetry of two-dimensional TMDs, and should only be possible if the symmetry of the electronic states is reduced by influences such as an external electric field or mechanical strain. Schottky contacts, nearly ubiquitous in TMD-based transistors, can provide the high electric fields causing a symmetry breaking in the devices. Here, we investigate the effect of these Schottky contacts on the CPC by characterizing the helicity-dependent photoresponse of monolayer MoSe2 devices both with direct metal-MoSe2 Schottky contacts and with h-BN tunnel barriers at the contacts. We find that, when Schottky barriers are present in the device, additional contributions to CPC become allowed, resulting in emergence of CPC for illumination at normal incidence.

Highlights

Two-dimensional (2D) transition metal dichalcogenides (TMDs) offer a privileged material platform for the realization of ultrathin and efficient optoelectronics[1,2]
In a seminal theory work[29], Moore and Orenstein showed that the presence of a nonzero Berry curvature in a 2D system can lead to the emergence of CPGE under illumination normal to the crystal npj 2D Materials and Applications (2021) 13
Symmetry of this CPC is compatible with contributions from Berry curvature-induced CPGE, the observed signal could be explained by the emergence of helicity-dependent photovoltaic effects near the metal–MoSe2 interfaces

Summary

Introduction

Two-dimensional (2D) transition metal dichalcogenides (TMDs) offer a privileged material platform for the realization of ultrathin and efficient optoelectronics[1,2]. It was recently shown that when a monolayer TMD (1L-TMD) is illuminated at an oblique angle with respect to the crystal plane, a helicity-dependent photocurrent (circular photocurrent, CPC) emerges. This effect has been attributed to circular photogalvanic (CPGE) and photon drag (CPDE) effects[10,11,12] and opens exciting possibilities for the realization of 2D self-powered optoelectronic and opto-spintronic devices

Methods

Results

Conclusion