Light-induced electronic polarization in antiferromagnetic Cr2O3

TL;DR

This study demonstrates that linearly polarized light can induce ultrafast electronic symmetry breaking in antiferromagnetic Cr2O3, creating a controllable dipole moment without affecting the crystal or spin structure.

Contribution

It reveals a novel optical method to induce and control electronic symmetry breaking in antiferromagnetic materials via ultrafast light pulses.

Findings

Light induces in-plane symmetry breaking in Cr2O3

The symmetry change occurs on an ultrafast electronic timescale

The induced dipole moment can be controlled by incident light

Abstract

In a solid, the electronic subsystem can exhibit incipient order with lower point group symmetry than the crystal lattice. External fields that couple to electronic order parameters have rarely been investigated, however, despite their potential importance to inducing exotic effects. Here, we show that when inversion symmetry is broken by the antiferromagnetic (AFM) order in Cr2O3, transmitting a linearly polarized light pulse through the crystal gives rise to an in-plane rotational symmetry breaking (from C3 to C1) via optical rectification. Using interferometric time-resolved second harmonic generation, we show that the ultrafast timescale of the symmetry reduction is indicative of a purely electronic response; the underlying spin and crystal structures remain unaffected. The symmetry-broken state exhibits a dipole moment, and its polar axis can be controlled with the incident light. Our results establish a coherent nonlinear optical protocol by which to break electronic symmetries and produce unconventional electronic effects in solids.