High-energy transient gas pinholes via saturated absorption

K. Ou; V. M. Perez-Ramirez; S. Cao; C. Redshaw; J. Lee; M. M. Wang; J. M. Mikhailova; P. Michel; M. R. Edwards

doi:10.1364/OL.547141

High-energy transient gas pinholes via saturated absorption

K. Ou, V. M. Perez-Ramirez, S. Cao, C. Redshaw, J. Lee, M. M. Wang, J. M. Mikhailova, P. Michel, M. R. Edwards

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

Abstract

This Letter presents a spatial filter based on saturated absorption in gas as an alternative to the solid pinhole in a lens-pinhole-lens filtering system. We develop an analytic model that describes this process and demonstrate spatial filtering with simulations and experiments. We show that an ultraviolet laser pulse focused through ozone will have its spatial profile cleaned if its peak fluence rises above the ozone saturation fluence. Specifically, we demonstrate that a 5 ns 266 nm beam with 4.2 mJ of the initial energy can be effectively cleaned by focusing through a 1.4% ozone-oxygen mixture, with about 76% of the main beam energy transmitted and 89% of the sidelobe energy absorbed. This process can be adapted to other gases and laser wavelengths, providing alignment-insensitive and damage-resistant pinholes for high-repetition-rate high-energy lasers.

Original language	English (US)
Pages (from-to)	1309-1312
Number of pages	4
Journal	Optics Letters
Volume	50
Issue number	4
DOIs	https://doi.org/10.1364/OL.547141
State	Published - Feb 15 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1364/OL.547141

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title = "High-energy transient gas pinholes via saturated absorption",

abstract = "This Letter presents a spatial filter based on saturated absorption in gas as an alternative to the solid pinhole in a lens-pinhole-lens filtering system. We develop an analytic model that describes this process and demonstrate spatial filtering with simulations and experiments. We show that an ultraviolet laser pulse focused through ozone will have its spatial profile cleaned if its peak fluence rises above the ozone saturation fluence. Specifically, we demonstrate that a 5 ns 266 nm beam with 4.2 mJ of the initial energy can be effectively cleaned by focusing through a 1.4% ozone-oxygen mixture, with about 76% of the main beam energy transmitted and 89% of the sidelobe energy absorbed. This process can be adapted to other gases and laser wavelengths, providing alignment-insensitive and damage-resistant pinholes for high-repetition-rate high-energy lasers.",

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AU - Ou, K.

AU - Perez-Ramirez, V. M.

AU - Cao, S.

AU - Redshaw, C.

AU - Lee, J.

AU - Wang, M. M.

AU - Mikhailova, J. M.

AU - Michel, P.

AU - Edwards, M. R.

PY - 2025/2/15

Y1 - 2025/2/15

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AB - This Letter presents a spatial filter based on saturated absorption in gas as an alternative to the solid pinhole in a lens-pinhole-lens filtering system. We develop an analytic model that describes this process and demonstrate spatial filtering with simulations and experiments. We show that an ultraviolet laser pulse focused through ozone will have its spatial profile cleaned if its peak fluence rises above the ozone saturation fluence. Specifically, we demonstrate that a 5 ns 266 nm beam with 4.2 mJ of the initial energy can be effectively cleaned by focusing through a 1.4% ozone-oxygen mixture, with about 76% of the main beam energy transmitted and 89% of the sidelobe energy absorbed. This process can be adapted to other gases and laser wavelengths, providing alignment-insensitive and damage-resistant pinholes for high-repetition-rate high-energy lasers.

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High-energy transient gas pinholes via saturated absorption

Abstract

All Science Journal Classification (ASJC) codes

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