Multiple optical frequency-conversions in few-layer GaSe assisted by a photonic crystal cavity

TL;DR

This paper demonstrates multiple optical frequency conversions in few-layer GaSe using a photonic crystal cavity, enabling efficient nonlinear processes at low power levels, including SHG, SFG, cascaded SFGs, and third harmonic generation.

Contribution

It introduces a novel cavity-enhanced approach to achieve multiple second-order nonlinear processes in 2D materials with low power, including the first observation of cascaded processes in such materials.

Findings

Cavity enhancement factor for SHG exceeds 1,300.

Multiple nonlinear processes observed at microwatt power levels.

First demonstration of cascaded second-order nonlinear processes in 2D materials.

Abstract

While two-dimensional (2D) materials have intriguing second-order nonlinearities with ultrahigh coefficient and electrical tunability, their atomic layer thicknesses hinder explorations of other optical frequency-conversions (OFCs) than second harmonic generation (SHG) due to inefficient light-coupling and unachievable phase-matching. We report, by resonantly pumping a photonic crystal cavity integrated with a few-layer GaSe, it is possible to realize multiple second-order nonlinear processes in GaSe even with microwatts continuous wave pumps, including SHGs, sum-frequency generations (SFGs), cascaded SFGs and their induced third harmonic generations. These OFCs arise from the significant cavity-enhancements. The enhancement factor of a SHG process is estimated exceeding 1,300. The cascaded SFGs have comparably strong intensities with those of SHGs. To the best of our knowledge, this is the first observation of cascaded second-order nonlinear processes in 2D materials. The cavity-assisted OFCs could provide a view to study deterministic OFCs in 2D materials with low pump power and expand their optoelectronic applications to nonlinear regime.