High Harmonic Spectroscopy from Lower-Order to Higher-Order Topological Insulators

TL;DR

This paper explores how high-harmonic spectroscopy can be used to detect topological phases in various topological insulators, including higher-order ones, revealing both its potential and limitations.

Contribution

It extends theoretical analysis of high-harmonic generation to higher-order topological insulators using three models, highlighting signatures and challenges in identifying topological states.

Findings

Helicity, circular dichroism, and ellipticity can indicate topological phases in Chern and topological insulators.

No clear topological signatures are observed in the harmonic spectrum of higher-order topological insulators.

Harmonic enhancement by 2-3 orders in topological semimetal phase of Kagome lattice.

Abstract

Over the last decade, high-harmonic spectroscopy has been successfully extended to the study of ultrafast electron motion in solids, shedding light on fundamental processes such as Bloch oscillations and higher-order nonlinear phenomena. In this work, we present theoretical studies of high-harmonic spectroscopy applied to topological materials including higher-order ones, focusing on several key observables associated with high-harmonic generation - namely, helicity, circular dichroism, and ellipticity dependence. We extend current all-optical measurement approaches from lower-order topological insulators (LOTIs) to higher-order topological insulators (HOTIs), employing three distinct models: a Haldane model for Chern insulators, Kane-Mele model for topological insulators, and a breathing Kagome lattice for HOTIs. This work aims to resolve whether helicity, circular dichroism, and ellipticity dependence can reveal signatures of topological states. For the Chern insulators and topological insulators, we find that these observables can indeed capture topological phases. In contrast, for HOTIs, no clear signatures of topology emerge in the harmonic spectrum, suggesting that a more careful analysis is required to identify topological invariants in higher-order topological insulators. In particular, for the topological semimetal phase, we find a harmonic enhancement by two to three orders of magnitude in the Kagome lattice. Our study delineates the conditions under which high-harmonic spectroscopy serves as a unique tool for diagnosing topological phases, particularly for those associated with topological corner states.