Mid-wave infrared planar optical device via femtosecond laser ablation on a sulfur-based polymeric glass surface

Feng Liu; Liang Zhou; Huachao Cheng; Peng Li; Sheng Liu; Shan Mao; Chuan Jin; Xiangping Zhu; Jianlin Zhao

doi:10.1364/OME.459018

Mid-wave infrared planar optical device via femtosecond laser ablation on a sulfur-based polymeric glass surface

Feng Liu, Liang Zhou, Huachao Cheng, Peng Li, Sheng Liu, Shan Mao, Chuan Jin, Xiangping Zhu, Jianlin Zhao

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

7 Scopus citations

Abstract

Sulfur-based polymer materials are attractive for infrared (IR) applications, as they exhibit profoundly high IR transparency, low temperature processability, and higher refractive index relative to conventional organic polymers. In this paper, the laser induced surface damage threshold of such sulfur-based polymeric glass is experimentally studied with femtosecond laser pulse exposure. The single- and multi-shot laser damage thresholds are determined as 41.1 mJ/cm² and 32.4 mJ/cm², respectively, and line width of laser scanning is proved to be controllable by laser energy implantation dose. The results enrich the technical knowledge of such novel optical material, and predict its processability by laser surface inscription. While, the amplitude-type binary planar devices based on femtosecond laser ablation are fabricated, and their imaging abilities are performed both in visible light and mid-wave IR regions.

Original language	English
Pages (from-to)	2541-2549
Number of pages	9
Journal	Optical Materials Express
Volume	12
Issue number	7
DOIs	https://doi.org/10.1364/OME.459018
State	Published - 1 Jul 2022

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title = "Mid-wave infrared planar optical device via femtosecond laser ablation on a sulfur-based polymeric glass surface",

abstract = "Sulfur-based polymer materials are attractive for infrared (IR) applications, as they exhibit profoundly high IR transparency, low temperature processability, and higher refractive index relative to conventional organic polymers. In this paper, the laser induced surface damage threshold of such sulfur-based polymeric glass is experimentally studied with femtosecond laser pulse exposure. The single- and multi-shot laser damage thresholds are determined as 41.1 mJ/cm2 and 32.4 mJ/cm2, respectively, and line width of laser scanning is proved to be controllable by laser energy implantation dose. The results enrich the technical knowledge of such novel optical material, and predict its processability by laser surface inscription. While, the amplitude-type binary planar devices based on femtosecond laser ablation are fabricated, and their imaging abilities are performed both in visible light and mid-wave IR regions.",

author = "Feng Liu and Liang Zhou and Huachao Cheng and Peng Li and Sheng Liu and Shan Mao and Chuan Jin and Xiangping Zhu and Jianlin Zhao",

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T1 - Mid-wave infrared planar optical device via femtosecond laser ablation on a sulfur-based polymeric glass surface

AU - Liu, Feng

AU - Zhou, Liang

AU - Cheng, Huachao

AU - Li, Peng

AU - Liu, Sheng

AU - Mao, Shan

AU - Jin, Chuan

AU - Zhu, Xiangping

AU - Zhao, Jianlin

PY - 2022/7/1

Y1 - 2022/7/1

N2 - Sulfur-based polymer materials are attractive for infrared (IR) applications, as they exhibit profoundly high IR transparency, low temperature processability, and higher refractive index relative to conventional organic polymers. In this paper, the laser induced surface damage threshold of such sulfur-based polymeric glass is experimentally studied with femtosecond laser pulse exposure. The single- and multi-shot laser damage thresholds are determined as 41.1 mJ/cm2 and 32.4 mJ/cm2, respectively, and line width of laser scanning is proved to be controllable by laser energy implantation dose. The results enrich the technical knowledge of such novel optical material, and predict its processability by laser surface inscription. While, the amplitude-type binary planar devices based on femtosecond laser ablation are fabricated, and their imaging abilities are performed both in visible light and mid-wave IR regions.

AB - Sulfur-based polymer materials are attractive for infrared (IR) applications, as they exhibit profoundly high IR transparency, low temperature processability, and higher refractive index relative to conventional organic polymers. In this paper, the laser induced surface damage threshold of such sulfur-based polymeric glass is experimentally studied with femtosecond laser pulse exposure. The single- and multi-shot laser damage thresholds are determined as 41.1 mJ/cm2 and 32.4 mJ/cm2, respectively, and line width of laser scanning is proved to be controllable by laser energy implantation dose. The results enrich the technical knowledge of such novel optical material, and predict its processability by laser surface inscription. While, the amplitude-type binary planar devices based on femtosecond laser ablation are fabricated, and their imaging abilities are performed both in visible light and mid-wave IR regions.

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JO - Optical Materials Express

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Mid-wave infrared planar optical device via femtosecond laser ablation on a sulfur-based polymeric glass surface

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