Rapid multiplex ultrafast nonlinear microscopy for material characterization

We demonstrate rapid imaging based on four-wave mixing (FWM) by assessing the quality of advanced materials through measurement of their nonlinear response, exciton dephasing, and exciton lifetimes. We use a WSe monolayer grown by chemical vapor deposition as a canonical example to demonstrate these...

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Veröffentlicht in:	Optics express 2022-12, Vol.30 (25), p.45008-45019
Hauptverfasser:	Purz, Torben L, Hipsley, Blake T, Martin, Eric W, Ulbricht, Ronald, Cundiff, Steven T
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Sprache:	eng
Schlagworte:	MATERIALS SCIENCE Optics
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creator	Purz, Torben L Hipsley, Blake T Martin, Eric W Ulbricht, Ronald Cundiff, Steven T
description	We demonstrate rapid imaging based on four-wave mixing (FWM) by assessing the quality of advanced materials through measurement of their nonlinear response, exciton dephasing, and exciton lifetimes. We use a WSe monolayer grown by chemical vapor deposition as a canonical example to demonstrate these capabilities. By comparison, we show that extracting material parameters such as FWM intensity, dephasing times, excited state lifetimes, and distribution of dark/localized states allows for a more accurate assessment of the quality of a sample than current prevalent techniques, including white light microscopy and linear micro-reflectance spectroscopy. We further discuss future improvements of the ultrafast FWM techniques by modeling the robustness of exponential decay fits to different spacing of the sampling points. Employing ultrafast nonlinear imaging in real-time at room temperature bears the potential for rapid in-situ sample characterization of advanced materials and beyond.
doi_str_mv	10.1364/OE.472054
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subjects	MATERIALS SCIENCE Optics
title	Rapid multiplex ultrafast nonlinear microscopy for material characterization
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