Near‐Field‐Regulated Ultrafast Laser Supra‐Wavelength Structuring Directly on Ultrahard Metallic Glasses

Near‐Field‐Regulated Ultrafast Laser Supra‐Wavelength Structuring Directly on Ultrahard Metallic Glasses

The ultrafast‐laser‐matter interactions enable “top‐down” laser surface structuring, especially for materials difficult to process, with “bottom‐up” self‐organizing features. The subwavelength scenarios of laser‐induced structuring are improved in defects and long‐range order by applying positive/ne...

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Veröffentlicht in:Advanced materials (Weinheim) 2024-11, Vol.36 (45), p.e2405766-n/a
Hauptverfasser: Huang, Hanxuan, Song, Shijie, Liu, Yun, Liu, Zhenyu, Xiao, Zifeng, Li, Yanyang, Wang, Yi, Li, Ruifan, Zhao, Qianru, Wang, Xudong, Chen, Yu, Wang, Lei, Hou, Zhishan, Zhang, Peilei, Sun, Yun‐Lu
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Sprache:eng
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Amorphous materials
Coupling
Finite element method
infrared modulating surface
Infrared reflection
Laser ablation
Laser arrays
Lasers
laser‐matter interactions
LSPR near‐field optical regulation
Metallic glasses
Negative feedback
Positive feedback
ultrafast laser supra‐wavelength structuring
Ultrafast lasers
ultra‐hard metallic glass
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container_issue 45
container_start_page e2405766
container_title Advanced materials (Weinheim)
container_volume 36
creator Huang, Hanxuan
Song, Shijie
Liu, Yun
Liu, Zhenyu
Xiao, Zifeng
Li, Yanyang
Wang, Yi
Li, Ruifan
Zhao, Qianru
Wang, Xudong
Chen, Yu
Wang, Lei
Hou, Zhishan
Zhang, Peilei
Sun, Yun‐Lu
description The ultrafast‐laser‐matter interactions enable “top‐down” laser surface structuring, especially for materials difficult to process, with “bottom‐up” self‐organizing features. The subwavelength scenarios of laser‐induced structuring are improved in defects and long‐range order by applying positive/negative feedbacks. It is still hardly reported for supra‐wavelength laser structuring more associated with complicated thermo/hydro‐dynamics. For the first time to the knowledge, the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed supra‐wavelength micro/nano‐pores directly on ultra‐hard metallic glass is developed here. The plasmonic hot spots on pre‐structures, as the positive feedback, clamped the lateral geometries (i.e., position, size). Simultaneously, it drilled and self‐organized into micro/nano‐pore arrays by photo‐dynamic plasma ablation and Marangoni removal confined under specific femtosecond‐laser irradiation, as the negative feedback. The mechanisms and finite element modeling of the multi‐physical transduction (based on the two‐temperature model), the far‐field/near‐field coupling, and the polarization dependence during laser‐matter interactions are studied. Large‐area micro/nano‐pore arrays (centimeter scale or larger)  are manufactured with tunable periods (1–5 µm) and geometries (e.g., diameters of 500 nm–6 µm using 343, 515, and 1030 lasers, respectively). Consequently, the mid/far‐infrared reflectivity at 2.5–6.5 µm iss decreased from ≈80% to ≈5%. The universality of multi‐physical coupling and near‐field enhancements makes this approach widely applicable, or even irreplaceable, in various applications. This study develops the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed micro/nano‐pores as mid/far‐infrared‐modulating surfaces directly on ultra‐hard metallic glass. The high regularity self‐arrayed micro/nano‐pores has an adjustable period (1–5 µm) and geometric shape (diameter 500 nm–6 µm). It exhibits excellent infrared anti‐reflection characteristics, the reflectance at 2.5–6.5 µm has decreased from the original ≈80% to ≈5%.
doi_str_mv 10.1002/adma.202405766
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The mechanisms and finite element modeling of the multi‐physical transduction (based on the two‐temperature model), the far‐field/near‐field coupling, and the polarization dependence during laser‐matter interactions are studied. Large‐area micro/nano‐pore arrays (centimeter scale or larger)  are manufactured with tunable periods (1–5 µm) and geometries (e.g., diameters of 500 nm–6 µm using 343, 515, and 1030 lasers, respectively). Consequently, the mid/far‐infrared reflectivity at 2.5–6.5 µm iss decreased from ≈80% to ≈5%. The universality of multi‐physical coupling and near‐field enhancements makes this approach widely applicable, or even irreplaceable, in various applications. This study develops the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed micro/nano‐pores as mid/far‐infrared‐modulating surfaces directly on ultra‐hard metallic glass. 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The mechanisms and finite element modeling of the multi‐physical transduction (based on the two‐temperature model), the far‐field/near‐field coupling, and the polarization dependence during laser‐matter interactions are studied. Large‐area micro/nano‐pore arrays (centimeter scale or larger)  are manufactured with tunable periods (1–5 µm) and geometries (e.g., diameters of 500 nm–6 µm using 343, 515, and 1030 lasers, respectively). Consequently, the mid/far‐infrared reflectivity at 2.5–6.5 µm iss decreased from ≈80% to ≈5%. The universality of multi‐physical coupling and near‐field enhancements makes this approach widely applicable, or even irreplaceable, in various applications. This study develops the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed micro/nano‐pores as mid/far‐infrared‐modulating surfaces directly on ultra‐hard metallic glass. 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The subwavelength scenarios of laser‐induced structuring are improved in defects and long‐range order by applying positive/negative feedbacks. It is still hardly reported for supra‐wavelength laser structuring more associated with complicated thermo/hydro‐dynamics. For the first time to the knowledge, the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed supra‐wavelength micro/nano‐pores directly on ultra‐hard metallic glass is developed here. The plasmonic hot spots on pre‐structures, as the positive feedback, clamped the lateral geometries (i.e., position, size). Simultaneously, it drilled and self‐organized into micro/nano‐pore arrays by photo‐dynamic plasma ablation and Marangoni removal confined under specific femtosecond‐laser irradiation, as the negative feedback. The mechanisms and finite element modeling of the multi‐physical transduction (based on the two‐temperature model), the far‐field/near‐field coupling, and the polarization dependence during laser‐matter interactions are studied. Large‐area micro/nano‐pore arrays (centimeter scale or larger)  are manufactured with tunable periods (1–5 µm) and geometries (e.g., diameters of 500 nm–6 µm using 343, 515, and 1030 lasers, respectively). Consequently, the mid/far‐infrared reflectivity at 2.5–6.5 µm iss decreased from ≈80% to ≈5%. The universality of multi‐physical coupling and near‐field enhancements makes this approach widely applicable, or even irreplaceable, in various applications. This study develops the near‐field‐regulated ultrafast‐laser lithography of self‐arrayed micro/nano‐pores as mid/far‐infrared‐modulating surfaces directly on ultra‐hard metallic glass. The high regularity self‐arrayed micro/nano‐pores has an adjustable period (1–5 µm) and geometric shape (diameter 500 nm–6 µm). It exhibits excellent infrared anti‐reflection characteristics, the reflectance at 2.5–6.5 µm has decreased from the original ≈80% to ≈5%.</abstract><cop>Germany</cop><pub>Wiley Subscription Services, Inc</pub><pmid>39171420</pmid><doi>10.1002/adma.202405766</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0002-3011-5795</orcidid><orcidid>https://orcid.org/0000-0002-2342-5832</orcidid></addata></record>
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source Wiley Online Library Journals Frontfile Complete
subjects Amorphous materials
Coupling
Finite element method
infrared modulating surface
Infrared reflection
Laser ablation
Laser arrays
Lasers
laser‐matter interactions
LSPR near‐field optical regulation
Metallic glasses
Negative feedback
Positive feedback
ultrafast laser supra‐wavelength structuring
Ultrafast lasers
ultra‐hard metallic glass
title Near‐Field‐Regulated Ultrafast Laser Supra‐Wavelength Structuring Directly on Ultrahard Metallic Glasses
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