Random quasi-phase-matching in polycrystalline media and its effects on pulse coherence properties

Jiahui Gu; Aaron Schweinsberg; Laura Vanderhoef; Michael Tripepi; Anthony Valenzuela; Christopher Wolfe; Trenton R. Ensley; Enam Chowdhury; Miroslav Kolesik

doi:10.1364/OE.418198

Random quasi-phase-matching in polycrystalline media and its effects on pulse coherence properties

Jiahui Gu, Aaron Schweinsberg, Laura Vanderhoef, Michael Tripepi, Anthony Valenzuela, Christopher Wolfe, Trenton R. Ensley, Enam Chowdhury, Miroslav Kolesik

Optical Sciences

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Polycrystalline materials can mediate efficient frequency up-conversion for mid-infrared light. Motivated by the need to understand the properties of the harmonic and supercontinuum radiation from such media, we utilize realistic numerical simulations to reveal its complex temporal and spatial structure. We show that the generated radiation propagates in the form of long-duration pulse trains that can be difficult to compress and that optical filamentation in high-energy pulses gives rise to fine-structured beam profiles. We identify trends concerning pulse energy, sample length, and the microstructure of the material that can inform optimization for different applications.

Original language	English (US)
Pages (from-to)	7479-7493
Number of pages	15
Journal	Optics Express
Volume	29
Issue number	5
DOIs	https://doi.org/10.1364/OE.418198
State	Published - Mar 1 2021

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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title = "Random quasi-phase-matching in polycrystalline media and its effects on pulse coherence properties",

abstract = "Polycrystalline materials can mediate efficient frequency up-conversion for mid-infrared light. Motivated by the need to understand the properties of the harmonic and supercontinuum radiation from such media, we utilize realistic numerical simulations to reveal its complex temporal and spatial structure. We show that the generated radiation propagates in the form of long-duration pulse trains that can be difficult to compress and that optical filamentation in high-energy pulses gives rise to fine-structured beam profiles. We identify trends concerning pulse energy, sample length, and the microstructure of the material that can inform optimization for different applications.",

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AU - Gu, Jiahui

AU - Schweinsberg, Aaron

AU - Vanderhoef, Laura

AU - Tripepi, Michael

AU - Valenzuela, Anthony

AU - Wolfe, Christopher

AU - Ensley, Trenton R.

AU - Chowdhury, Enam

AU - Kolesik, Miroslav

PY - 2021/3/1

Y1 - 2021/3/1

N2 - Polycrystalline materials can mediate efficient frequency up-conversion for mid-infrared light. Motivated by the need to understand the properties of the harmonic and supercontinuum radiation from such media, we utilize realistic numerical simulations to reveal its complex temporal and spatial structure. We show that the generated radiation propagates in the form of long-duration pulse trains that can be difficult to compress and that optical filamentation in high-energy pulses gives rise to fine-structured beam profiles. We identify trends concerning pulse energy, sample length, and the microstructure of the material that can inform optimization for different applications.

AB - Polycrystalline materials can mediate efficient frequency up-conversion for mid-infrared light. Motivated by the need to understand the properties of the harmonic and supercontinuum radiation from such media, we utilize realistic numerical simulations to reveal its complex temporal and spatial structure. We show that the generated radiation propagates in the form of long-duration pulse trains that can be difficult to compress and that optical filamentation in high-energy pulses gives rise to fine-structured beam profiles. We identify trends concerning pulse energy, sample length, and the microstructure of the material that can inform optimization for different applications.

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Random quasi-phase-matching in polycrystalline media and its effects on pulse coherence properties

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