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| Simulation Study on the Influence of Microstructured Arrays on the
Emissivity of Surface Blackbody |
| CUI Shuang-long, ZHOU Yi-meng, XING Jian*, LI Yi, LI Wen-chao, HE Xue-lan |
School of Computer Science and Control Engineering,Northeast Forestry University, Harbin 150006,China
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Abstract As the core of the contemporary earth observation system, infrared remote sensing technology is of great significance for improving its performance. As the benchmark for the calibration of infrared detection equipment, the radiation characteristics of the blackbody radiation source directly affect the accuracy of the data, and the emissivity is one of the core parameters to measure the radiation capability of the blackbody. The traditional cavity blackbody is difficult to meet the requirements of calibration, and the surface blackbody provides a new solution for the radiation calibration of large-diameter systems through the plane structure design. Existing studies primarily focus on typical configurations such as V-shaped grooves, square cone arrays, and conical arrays, with emissivity testing relying heavily on experimental methods (such as Fourier transform infrared spectroscopy), leading to high R&D costs. To break through the bottleneck of experimental research, this article employs a ray-tracing approach to simulate light propagation within surface blackbody microstructures. By constructing an equivalent model with microstructure units and a simulation system incorporating 106-level light rays, it comprehensively analyzes geometric parameters (bottom to height ratio, size) and surface optical properties (coating emissivity, reflection component). Simulation results demonstrate that performance improvements in surface blackbodies primarily stem from structural design rather than size expansion. Reducing the bottom-to-height ratio of square cone arrays from 2∶3 to 2∶5 increased normal emissivity from 0.987 to 0.995, whereas a tenfold size increase yielded only a 0.000 01 emissivity gain. Regarding surface reflection, the near-specular reflection proportion exhibits significant structural dependence on uniformity. Increasing NSR from 0% to 25% improved uniformity by 231% for square cone arrays and 224% for V-shaped grooves, but decreased it by 316% for conical arrays. Comprehensive performance comparisons show that square cone and V-shaped groove structures offer substantial advantages over conical arrays. The analysis method used in this article can provide important theoretical support for the design of a surface blackbody.
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Received: 2025-03-16
Accepted: 2025-06-23
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Corresponding Authors:
XING Jian
E-mail: xingniat@sina.com
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[1] Liang S, Wang D, He T, et al. International Journal of Digital Earth, 2019, 12(7): 737.
[2] Ejemeyovwi D O, Achima B T, Ogwu C. NIU Journal of Social Sciences, 2023, 9(1): 117.
[3] LIN Mi-le, XIA Qian-hang, XIE Peng, et al(林米乐,夏千航,谢 鹏,等). Chinese Journal of Public Health(中国公共卫生), 2024, 40(5): 635.
[4] Hu Z, Hei H, Li X, et al. Infrared Physics & Technology, 2019, 103: 103082.
[5] Szpakowski D M, Jensen J L R. Remote Sensing, 2019, 11(22): 2638.
[6] Goswami B, Bhandari G, Goswami S. Modeling Earth Systems and Environment, 2021, 7: 1097.
[7] ZHANG Yu-feng, WU Yu-ling, WU Yuan-qing, et al(张宇峰,邬玉玲,吴元庆,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2023, 43(2): 389.
[8] Ko H Y, Wen B J, Tsa S F, et al. International Journal of Thermophysics, 2009, 30: 98.
[9] Zhang H, Zhu H. Proceedings of International Forum on Strategic Technology 2010, 2010, 361.
[10] Zhao Y, Wang J, Feng G, et al. International Journal of Thermophysics, 2020, 41: 71.
[11] Zhao Y, Wang J, He Y. Infrared Physics & Technology, 2023, 133: 104862.
[12] Lehman J, Yung C, Tomlin N, et al. Applied Physics Reviews, 2018, 5(1): 11103.
[13] Bae J Y, Choi W, Hong S J, et al. Sensors, 2020, 20(20): 5836.
[14] Shimizu Y, Koshikawa H, Imbe M, et al. Optics Express, 2020, 28(15): 22606.
[15] HU You-hua, HAO Xiao-peng, SIMA Rui-heng, et al(扈又华, 郝小鹏, 司马瑞衡, 等). Acta Metrologica Sinica(计量学报), 2021, 42(3): 314.
[16] Zhou J J, Hao X P, Wang X, et al. Optics Express, 2022, 30(12): 20859.
[17] Ji Y, Hao X, Sun Y, et al. International Journal of Thermophysics, 2022, 43(9): 142.
[18] Wang G, Xia C, Song J, et al. Optics Express, 2023, 31(11): 17878.
[19] Guo G, Hao X, Yu K, et al. Optics and Lasers in Engineering, 2024, 183: 108492.
[20] Song X, Duanmu Q-d, Dong W, et al. Proceedings of SPIE, 2019, 11337: 1133707.
[21] Wang G, Xia C, Hao X, et al. Proceedings of SPIE, 2023, 12565: 1256531.
[22] Song J, Hao X, Yuan Z, et al. Optics Express, 2020, 28(16): 23294.
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