Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures
ABSTRACT Optical pressure, arising from the interaction between light and matter, is typically confined to the range of pico‐Newtons to nano‐Newtons, which limits its practical application in engineering. Here, we propose a two‐dimensional aluminum periodic rectangular nano‐structure designed to enh...
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| Format: | Article |
| Language: | English |
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Wiley
2025-03-01
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| Series: | Engineering Reports |
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| Online Access: | https://doi.org/10.1002/eng2.70046 |
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| author | Yukun Yuan Qiang Zhang Chunyang Gu Siyu Huang Fengzhou Fang |
| author_facet | Yukun Yuan Qiang Zhang Chunyang Gu Siyu Huang Fengzhou Fang |
| author_sort | Yukun Yuan |
| collection | DOAJ |
| description | ABSTRACT Optical pressure, arising from the interaction between light and matter, is typically confined to the range of pico‐Newtons to nano‐Newtons, which limits its practical application in engineering. Here, we propose a two‐dimensional aluminum periodic rectangular nano‐structure designed to enhance and regulate optical pressure through electromagnetic simulations. The distribution characteristics and underlying mechanisms of optical pressure on the nano‐structure's surface are analyzed. The findings reveal that when the dimensions of the nano‐structure are tuned to resonate with the incident field, the rectangular nano‐structure generates significantly enhanced optical pressure compared to a planar surface. Furthermore, the optical pressure can be precisely modulated by adjusting the geometric parameters of the nano‐structure, such as depth, width, and sidewall inclination angle. Our work provides a theoretical foundation for the design and optimization of advanced optical pressure sensors and demonstrates potential applications in precision laser power measurement, non‐destructive testing, and optical propulsion systems. |
| format | Article |
| id | doaj-art-b3ff403ca71c4483989d0f9cd3c9c6ca |
| institution | OA Journals |
| issn | 2577-8196 |
| language | English |
| publishDate | 2025-03-01 |
| publisher | Wiley |
| record_format | Article |
| series | Engineering Reports |
| spelling | doaj-art-b3ff403ca71c4483989d0f9cd3c9c6ca2025-08-20T01:49:58ZengWileyEngineering Reports2577-81962025-03-0173n/an/a10.1002/eng2.70046Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐StructuresYukun Yuan0Qiang Zhang1Chunyang Gu2Siyu Huang3Fengzhou Fang4Institute of Air Traffic Management Civil Aviation Flight University of China Sichuan ChinaInstitute of Air Traffic Management Civil Aviation Flight University of China Sichuan ChinaState Key Laboratory of Precision Measuring Technology & Instruments Tianjin University Tianjin ChinaState Key Laboratory of Precision Measuring Technology & Instruments Tianjin University Tianjin ChinaState Key Laboratory of Precision Measuring Technology & Instruments Tianjin University Tianjin ChinaABSTRACT Optical pressure, arising from the interaction between light and matter, is typically confined to the range of pico‐Newtons to nano‐Newtons, which limits its practical application in engineering. Here, we propose a two‐dimensional aluminum periodic rectangular nano‐structure designed to enhance and regulate optical pressure through electromagnetic simulations. The distribution characteristics and underlying mechanisms of optical pressure on the nano‐structure's surface are analyzed. The findings reveal that when the dimensions of the nano‐structure are tuned to resonate with the incident field, the rectangular nano‐structure generates significantly enhanced optical pressure compared to a planar surface. Furthermore, the optical pressure can be precisely modulated by adjusting the geometric parameters of the nano‐structure, such as depth, width, and sidewall inclination angle. Our work provides a theoretical foundation for the design and optimization of advanced optical pressure sensors and demonstrates potential applications in precision laser power measurement, non‐destructive testing, and optical propulsion systems.https://doi.org/10.1002/eng2.70046electromagnetic simulation methodoptical nano‐structureoptical pressureoptical pressure enhancementresonance |
| spellingShingle | Yukun Yuan Qiang Zhang Chunyang Gu Siyu Huang Fengzhou Fang Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures Engineering Reports electromagnetic simulation method optical nano‐structure optical pressure optical pressure enhancement resonance |
| title | Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures |
| title_full | Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures |
| title_fullStr | Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures |
| title_full_unstemmed | Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures |
| title_short | Analysis of Enhancement and Regulation of Surface Optical Pressure by Optical Nano‐Structures |
| title_sort | analysis of enhancement and regulation of surface optical pressure by optical nano structures |
| topic | electromagnetic simulation method optical nano‐structure optical pressure optical pressure enhancement resonance |
| url | https://doi.org/10.1002/eng2.70046 |
| work_keys_str_mv | AT yukunyuan analysisofenhancementandregulationofsurfaceopticalpressurebyopticalnanostructures AT qiangzhang analysisofenhancementandregulationofsurfaceopticalpressurebyopticalnanostructures AT chunyanggu analysisofenhancementandregulationofsurfaceopticalpressurebyopticalnanostructures AT siyuhuang analysisofenhancementandregulationofsurfaceopticalpressurebyopticalnanostructures AT fengzhoufang analysisofenhancementandregulationofsurfaceopticalpressurebyopticalnanostructures |