Manipulating Photogalvanic Effects in Two-Dimensional Multiferroic Breathing Kagome Materials

TL;DR

This paper demonstrates how electric and magnetic fields can control and switch photogalvanic effects in two-dimensional multiferroic breathing kagome materials, exemplified by monolayer Nb3I8, for advanced optoelectronic applications.

Contribution

It introduces a method to selectively manipulate shift and injection currents in 2D multiferroic kagome materials using electric and magnetic fields, revealing new control mechanisms.

Findings

Shift current is unaffected by magnetic order.

Injection current is related to valley polarization and controlled by magnetic field.

Photocurrents can be reversed by out-of-plane electric field.

Abstract

Multiferroic materials, known for their multiple tunable orders, present an exceptional opportunity to manipulate nonlinear optical responses, which are sensitive to symmetry. In this study, we propose leveraging electric and magnetic fields to selectively control and switch specific types of photogalvanic effects in two-dimensional multiferroic breathing kagome materials. Taking monolayer Nb3I8 as an example, we demonstrate that the shift current, characterized by the real-space shift of electrons and holes, is predominantly unaffected by magnetic order. In contrast, injection current, featured by quantum metric dipole in momentum space, is closely related to valley polarization which can be controlled by magnetic field. Furthermore, both photocurrents can be reversed by out-of-plane electric field via the lattice breathing. Our findings reveal the potential of multiferroic beathing kagome structures for multifunctional optoelectronic applications and sensors.