Photocurrent as a multi-physics diagnostic of quantum materials

TL;DR

Photocurrent serves as a versatile, multi-physics diagnostic tool for quantum materials, revealing electronic states, quantum geometry, and scattering processes across various scales.

Contribution

This review introduces photocurrent as a wavefunction-sensitive, multi-physics probe capable of characterizing complex quantum material properties and processes.

Findings

Photocurrent links light-matter interaction with quantum geometry.

It can resolve bandstructure and topological features.

Photocurrent diagnostics can disentangle carrier scattering and enable remote sensing.

Abstract

The photoexcitation life-cycle from incident photon (and creation of photoexcited electron hole pair) to ultimate extraction of electrical current is a complex multi-physics process spanning across a range of spatio-temporal scales of quantum materials. While often viewed through a device-technology lens, photocurrent is a key observable of the life-cycle that is sensitive to a myriad of physical processes across these scales. As a result, photocurrent is emerging as a versatile probe of electronic states, Bloch band quantum geometry, quantum kinetic processes, and device characteristics of quantum materials. This review outlines the key multi-physics principles of photocurrent diagnostics. In particular, we describe how the fundamental link between light-matter interaction and quantum geometry renders photocurrent a wavefunction-sensitive probe capable of resolving bandstructure and characterizing topological materials. We further highlight the sensitivity of the photoexcitation life-cycle to relaxational processes which in turn enables photocurrent to disentangle distinct types of carrier scattering that can range from femtosecond to nanosecond timescales. We survey the intrinsically nonlocal character of photocurrent collection that allows new types remote sensing protocols and photocurrent nanoscopy. These distinctive features underscore photocurrent diagnostics as a novel multi-physics probe for a growing class of quantum materials with properties governed by physics spanning multiple spatio-temporal scales.