Giant modulation of optical nonlinearity by Floquet engineering

Strong periodic driving with light offers the potential to coherently manipulate the properties of quantum materials on ultrafast timescales. Recently, strategies have emerged to drastically alter electronic and magnetic properties by optically inducing non-trivial band topologies(1-6), emergent spin interactions(7-11) and even superconductivity(12). However, the prospects and methods of coherently engineering optical properties on demand are far less understood(13). Here we demonstrate coherent control and giant modulation of optical nonlinearity in a van der Waals layered magnetic insulator, manganese phosphorus trisulfide (MnPS3). By driving far off-resonance from the lowest on-site manganese d-d transition, we observe a coherent on-off switching of its optical second harmonic generation efficiency on the timescale of 100 femtoseconds with no measurable dissipation. At driving electric fields of the order of 10(9) volts per metre, the on-off ratio exceeds 10, which is limited only by the sample damage threshold. Floquet theory calculations(14) based on a single-ion model of MnPS3 are able to reproduce the measured driving field amplitude and polarization dependence of the effect. Our approach can be applied to a broad range of insulating materials and could lead to dynamically designed nonlinear optical elements.

Automated summary

Strong periodic driving with light provides the potential to manipulate quantum materials coherently on ultrafast timescales, with recent strategies demonstrating the alteration of electronic and magnetic properties through optical methods. In a van der Waals layered magnetic insulator MnPS3, coherent control and giant modulation of optical nonlinearity have been achieved by driving far off-resonance, showing an on-off ratio exceeding 10. This approach could lead to dynamically designed nonlinear optical elements in a broad range of insulating materials.