[1]袁旦,张典典,黄豆豆,等.植被仿生材料的反射光谱调控研究现状与发展趋势[J].服装学报,2026,11(01):11-20.
 YUAN Dan,ZHANG Diandian,HUANG Doudou,et al.Research Status and Development Trends of Reflection SpectrumControl in Vegetation-Inspired Biomimetic Materials[J].Journal of Clothing Research,2026,11(01):11-20.
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植被仿生材料的反射光谱调控研究现状与发展趋势()

《服装学报》[ISSN:2096-1928/CN:32-1864/TS]

卷:
第11卷
期数:
2026年01期
页码:
11-20
栏目:
服装材料
出版日期:
2026-03-13

文章信息/Info

Title:
Research Status and Development Trends of Reflection SpectrumControl in Vegetation-Inspired Biomimetic Materials
作者:
袁旦1; 张典典2; 黄豆豆2; 周文*2
1.江苏联合职业技术学院无锡机电分院,江苏无锡214028;2.江南大学纺织科学与工程学院,江苏无锡214122
Author(s):
YUAN Dan1; ZHANG Diandian2; HUANG Doudou2; ZHOU Wen*2
(1. Wuxi Electromechanical Branch, Jiangsu Union Technical Institute, Wuxi 214028, China; 2. College of TextileScience and Engineering, Jiangnan University, Wuxi 214122, China)
分类号:
TB 34;TN 972.43
文献标志码:
A
摘要:
综述了高光谱伪装用植被仿生材料的反射光谱调控研究现状,简述植被反射光谱的典型特征与形成机制,归纳仿生材料光谱模拟性能的主要评价方法,重点分析高光谱伪装用植被仿生材料的结构设计原理与制备策略,探讨现有研究面临的瓶颈与挑战。分析表明,未来需通过构建图谱一体的综合评价体系,提升材料耐用性与便携性,并积极发展环境自适应变光谱伪装材料;应结合贸易风险管理措施推动技术成果转化,加快该类材料从实验室向迷彩服、伪装网等实际应用的转化,为对抗高光谱探测的植被型伪装技术发展提供参考。

参考文献/References:

[1] Zhu R X, Zhu H Z, Qin B, et al. Digital camouflage encom-passing optical hyperspectra and thermal infrared-terahertz-microwave tri-bands[J]. Nature Communications, 2025, 16: 8112.
[2] Lin Y P, Ren L Q, Yang X D, et al. Design and application of bionic camouflage materials simulating spectral reflection characte-ristics of plants: a review[J]. Applied Sciences, 2024, 14(11): 4404.
[3] Shaw G, Manolakis D. Signal processing for hyperspectral image exploitation[J]. IEEE Signal Processing Magazine, 2002, 19(1): 12-16.
[4] 路琪鑫. 纤维基仿植物叶片材料的结构设计、制备及高光谱性能研究[D]. 无锡: 江南大学, 2024.
[5] 吴忠倪, 张丽平, 柯莹, 等. 数码迷彩图案设计成型及伪装效果评价研究进展[J]. 服装学报, 2024, 9(2): 110-114.
Wu Zhongni, Zhang Liping, Ke Ying, et al. Research progress of digital camouflage pattern design, preparation and camouflage effect evaluation[J]. Journal of Clothing Research, 2024, 9(2): 110-114.(in Chinese)
[6] 祖梅, 鄢峰, 甘沅丰, 等. 模拟绿色植被光谱特征的高光谱伪装材料与技术研究进展[J]. 红外技术, 2022, 44(10): 1018-1026.
Zu Mei, Yan Feng, Gan Yuanfeng, et al. Progress on hyperspectral camouflage materials and techniques for spectral characteristic simulation of green vegetation[J]. Infrared Technology, 2022, 44(10): 1018-1026.(in Chinese)
[7] 蒋晓军, 吕绪良, 潘家亮, 等. 基于光学和红外特征模拟的植物仿生材料设计制备[J]. 光谱学与光谱分析, 2015, 35(7): 1835-1839.
Jiang Xiaojun, Lü Xuliang, Pan Jialiang, et al. Design and preparation of plant bionic materials based on optical and inf rared features simulation[J]. Spectroscopy and Spectral Analysis, 2015, 35(7): 1835-1839.(in Chinese)
[8] 张典典, 李敏, 关玉, 等. 仿植被可见光-近红外反射光谱特征的分散染料印花织物制备及其性能[J]. 纺织学报, 2023, 44(1): 142-148.
Zhang Diandian, Li Min, Guan Yu, et al. Preparation and performance of disperse dye printed fabrics with characteristics of vegetation-like Vis-NIR reflectance spectrum[J]. Journal of Textile Research, 2023, 44(1): 142-148.(in Chinese)
[9] Hu A R, Li M, Zhang L P, et al. Polyurethane-based bionic material simulating the Vis-NIR spectrum and thermal infrared properties of vegetation[J]. RSC Advances, 2019, 9(71): 41438-41446.
[10] Liu Z M, Wu W J, Hu B R. Design of biomimetic camouflage materials based on angiosperm leaf organs[J]. Science in China Series E: Technological Sciences, 2008, 51(11): 1902-1910.
[11] Xie D J, Zu M, Li M Y, et al. A hyperspectral camouflage colorant inspired by natural leaves[J]. Advanced Materials, 2023, 35(47): e2302973.
[12] Lu H P, Bai X Z, Wang Z X, et al. Hyperspectral camouflage coating using Palygorskite to simulate water absorption of healthy green leaves[J]. Materials Science in Semiconductor Processing, 2023, 156: 107293.
[13] Lü X J, Yuan L, Rao C S, et al. Structure and near-infrared spectral properties of mesoporous silica for hyperspectral camouflage materials[J]. Infrared Physics and Technology, 2023, 129: 104558.
[14] Xiao F F, Xu W D, Liu J, et al. Multi-response mixture design applied for the formulation of a textile green camouflage ink with reproduction of a leaf green[J]. Textile Research Journal, 2023, 93(17/18): 4115- 4125.
[15] Guo T, Hua W S, Liu X, et al. Comprehensive evaluation of optical camouflage effect based on hyperspectra[J]. Laser and Optoelectronics Progress, 2016, 53(10): 101002.
[16] Xu K, Ye H. Preparation and optimization of biomimetic materials simulating solar spectrum reflection characteristics of natural leaves[J]. Journal of Materials Science, 2020, 55(27): 12848-12863.
[17] 郭利, 徐国跃, 李澄, 等. 一种新型近红外伪装涂层的制备及光谱性能研究[J]. 红外技术, 2012, 34(10): 588-592.
Guo Li, Xu Guoyue, Li Cheng, et al. Research on preparation and spectral properties of a new near-infrared camouflage coating[J]. Infrared Technology, 2012, 34(10): 588-592.(in Chinese)
[18] 沈涛. 基于高光谱探测的仿植物叶片材料研究[D]. 成都: 电子科技大学, 2022.
[19] Jiang P L, Cui X Q, Zhu D D, et al. A superslippery biomimetic leaf with self-driven water absorption performance for robust spectral simulation[J]. ACS Applied Polymer Materials, 2026, 8(1): 262-274.
[20] 马世欣, 刘春桐, 李洪才, 等. 基于高光谱图像探测与感知的伪装效果评估方法[J]. 兵工学报, 2019, 40(7): 1485-1494.
Ma Shixin, Liu Chuntong, Li Hongcai, et al. Camouflage effect evaluation based on hyperspectral image detection and visual perception[J]. Acta Armamentarii, 2019, 40(7): 1485-1494.(in Chinese)
[21] He Z X, Gan Y Y, Ma S X, et al. Evaluation method for the hyperspectral image camouflage effect based on multifeature description and grayscale clustering[J]. EURASIP Journal on Advances in Signal Processing, 2023(1): 11.
[22] 刘志明, 吴文健, 胡碧茹. 基于被子植物叶类器官的仿生伪装材料设计[J]. 中国科学(E辑:技术科学), 2009(1): 174-180.
Liu Zhiming, Wu Wenjian, Hu Biru. Bionic camouflage materials design based on angiosperm leaf organs[J]. Sci China Ser E-Tech Sci, 2009(1): 174-180.(in Chinese)
[23] 杨玉杰, 胡碧茹, 吴文健. 植物叶片仿生伪装材料的设计与制备[J]. 国防科技大学学报, 2011, 33(5): 50-53.
Yang Yujie, Hu Biru, Wu Wenjian. Design and preparation of bionic camouflage materials by simulating plant leaves[J]. Journal of National University of Defense Technology, 2011, 33(5): 50-53.(in Chinese)
[24] Lu Q X, Li M, Tian A L, et al. Green plant leaf-inspired smart camouflage fabrics for visible light and near-infrared stealth[J]. Journal of Bionic Engineering, 2022, 19(3): 788-798.
[25] Lu Q X, Guan Y, Fu S H. Self-driven super water vapor-absorbing calcium alginate-based bionic leaf for Vis-NIR spectral simulation[J]. Carbohydrate Polymers, 2022, 296: 119932.
[26] 邢英鑫. 可见-近红外-中红外多波段隐身研究[D]. 杭州: 浙江大学, 2021.
[27] Gao Y, Tang B, Ji G J, et al. A camouflage coating with similar solar spectrum reflectance to leaves based on polymeric inorganic composite[J]. Materials Research Express, 2021, 8(6): 066404.
[28] Xu K, Wang S M, Wang L W, et al. Bionic coating imitating reflection characteristics of plant leaf in solar spectrum waveband for hyperspectral camouflage[J]. Infrared Physics and Technology, 2022, 127: 104477.
[29] Ye H, Gao Y, Li S M, et al. Bionic leaves imitating the transpiration and solar spectrum reflection characteristics of natural leaves[J]. Journal of Bionic Engineering, 2015, 12(1): 109-116.
[30] Gao Y, Ye H. Bionic membrane simulating solar spectrum reflection characteristics of natural leaf[J]. International Journal of Heat and Mass Transfer, 2017, 114: 115-124.
[31] 谢东津, 吕呈龙, 祖梅, 等. 绿色植被可见-近红外反射光谱模拟材料研究进展[J]. 光谱学与光谱分析, 2021, 41(4): 1032-1038.
Xie Dongjin, Lü Chenglong, Zu Mei, et al. Research progress of bionic materials simulating vegetation visible-near infrared reflectance spectra[J]. Spectroscopy and Spectral Analysis, 2021, 41(4): 1032-1038.(in Chinese)
[32] Yang Y J, Liu Z M, Hu B R, et al. Bionic composite material simulating the optical spectra of plant leaves[J]. Journal of Bionic Engineering, 2010, 7: 43- 49.
[33] Yang Y J, Liu Z M, Hu B R, et al. Design of plant leaf bionic camouflage materials based on spectral analysis[J]. Spectroscopy and Spectral Analysis, 2011, 31(6): 1668-1672.
[34] Qin R, Xu G Y, Guo L, et al. Preparation and characterization of a novel poly(urea-formaldehyde)microcapsules with similar reflectance spectrum to leaves in the UV-Vis-NIR region of 300~2 500 nm[J]. Materials Chemistry and Physics, 2012, 136(2/3): 737-743.
[35] Yuan L, Wang C, Qing X L, et al. Synthesis and fine spectros-copy tuning of the hyperspectral simulation material based on organic anions intercalated Mg-Al layered double hydroxide[J]. Infrared Physics and Technology, 2020, 107: 103328.
[36] Xiao Y, Tan S J, Qu L J, et al. Highly water-resistant coating for vegetation mimicry with sunlight spectrum and infrared compatibi-lity[J]. Applied Surface Science, 2025, 686: 162218.
[37] Xiao F F, Xu W D, Liu H, et al. Green camouflage coating for fabric screen printing[J]. The Journal of the Textile Institute, 2025, 116(9): 1965-1972.
[38] Zhuang S X, Chen W Q, Li B, et al. A leaf-mimic material based on polyurethane microcapsules and Cr2O3 for hyperspectral stealth[J]. Materials and Design, 2024, 243: 113051.
[39] 安镜澄, 娄鸿飞, 马剑平, 等. 原位界面聚合工艺制备超高水分含量微胶囊[J]. 涂料工业, 2024, 54(12): 34- 41.
An Jingcheng, Lou Hongfei, Ma Jianping, et al. Preparation of microcapsules with ultra-high water content by in-situ interfacial polymerization process[J]. Paint and Coatings Industry, 2024, 54(12): 34- 41.(in Chinese)
[40] Li Z R, Huang Z Z, Li W, et al. Leaf-inspired multifunctional paint for full-solar-spectrum hyperspectral camouflage with enhanced weather-resistance and adhesion[J]. Small, 2026: e12131.
[41] 郭利. 模拟绿色植被光谱特征的近红外伪装涂层研究[D]. 南京: 南京航空航天大学, 2013.
[42] 王晶. 绿色植被近红外光谱特征模拟材料设计、制备及应用研究[D]. 南京: 南京航空航天大学, 2017.
[43] Xie Z X, Yuan L, Qing X L, et al. Hygroscopic Mg-Al LDHs composite microspheres for highly efficient hyperspectral camouflage in the VIS and NIR wavebands[J]. Scientific Reports, 2024, 14: 15649.
[44] Qing X L, Weng X L, Yuan L, et al. Hyperspectral camouflage with an inorganic coating mimicking vegetation in the 1.5~1.8 μm spectral window[J]. Infrared Physics and Technology, 2026, 152: 106246.
[45] Zhou M, Sheng Z Z, Ji G B, et al. Aerogel-involved triple-state gels resemble natural living leaves in structure and multi-functions[J]. Advanced Materials, 2024, 36(32): 2406007.
[46] 邓子琛, 王明亮, 刘佳琪, 等. 光子晶体薄膜可见光-红外光谱设计及其辐射特性分析[J]. 导弹与航天运载技术(中英文), 2024(3): 73-78.
Deng Zichen, Wang Mingliang, Liu Jiaqi, et al. Visible-infrared spectrum design and radiation characteristics analysis of photonic crystal films[J]. Missiles and Space Vehicles, 2024(3): 73-78.(in Chinese)
[47] Deng Z C, Zhou P, Hu W Y, et al. Biomimetic multilayer film simulating solar spectrum reflection characteristics of natural vegetations for optical camouflage[J]. Optics Express, 2023, 31(22): 37082-37093.
[48] Huang L Q, Li M, Deng Z C, et al. All-in-one multispectral camouflage film: highly mimicking green vegetation hyperspectral features with low laser and infrared detectability[J]. ACS Applied Materials and Interfaces, 2025, 17(50): 68335-68344.
[49] Lu Q X, Liu R, Zhang D D, et al. Thermochromic pastes for reversible dynamic simulation of colors and visible reflection spectra of green leaf and soil[J]. Dyes and Pigments, 2024, 230: 112314.
[50] Jiang C Y, Wei P P, Yuan L, et al. An intelligent multi-band camouflage textile inspired by natural leaves[J]. Advanced Functional Materials, 2025, 35(35): 2424325.
[51] Tang S W, Zhang H Z, Liu Y L, et al. Breakthrough in anti-reconnaissance technology from a new perspective: a bio-inspired electrochromic device with hyperspectral characteristics of vegetation foliage[J]. Chemical Engineering Journal, 2024, 497: 154604.
[52] Huang Z Z, Long L S, Gao Y F, et al. A color-changing biomi-metic material closely resembling the spectral characteristics of vegetation foliage[J]. Small, 2024, 20(10): 2303966.
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更新日期/Last Update: 2026-02-28