Tuning Coherent Light Generation in 2D Semiconductors with Strong Laser Fields
Abstract
Light generation through optical harmonics plays a pivotal role in photonics, driving innovations in coherent light sources, biological imaging, and spectroscopy. Traditional methods for tuning optical harmonics, including electrostatic gating, are inherently slow, presenting a bottleneck for the performance of integrated photonic devices. While all-optical schemes offer faster tuning, they often rely on resonant excitation, limiting tunability to the relatively long lifetimes of excited electronic states. Here, we demonstrate a novel approach for all-optical control of harmonic generation in two-dimensional semiconductors by using strong, non-resonant laser pulses, with electric field amplitudes approaching 109 V/m. By harnessing the quantum-mechanical coupling of virtual excitons (electron-hole pairs) with photons below resonance, we achieve precise spectral and amplitude control of second- and third-harmonic generation. Additionally, the spectral tunability reaches Terahertz rates, limited by the control beam's pulse duration and multiphoton absorption. These results open new avenues for the development of tunable, compact coherent light sources and ultrafast information processing.
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