Compatible Stealth Metasurface for Laser and Infrared with Radiative Thermal Engineering Enabled by Machine Learning

Liu, Xianghui; Wang, Pan; Xiao, Chengyu; Fu, Liucheng; Xu, Jun; Zhang, Di; Zhou, Han; Fan, Tongxiang

doi:10.1002/adfm.202212068

Cited by 16 publications

(3 citation statements)

References 58 publications

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“…Considerable efforts have been directed toward developing thermal camouflage using various techniques in the MWIR and LWIR bands, including metallic/dielectric structures 10 – 21 , electrochromic 22 – 29 and thermochromic 30 – 33 materials. Additionally, progress has been made in thermal camouflage through simultaneous radiative heat dissipation in the 5–8 μm non-atmospheric window using nano-structures (e.g., photonic crystals 34 , 35 , metal-insulator-metal metasurfaces 36 – 42 , Fabry-Perot cavities 43 , 44 , anti-reflection layers 43 – 45 , and porous nanostructures 46 ). Besides, some studies have combined thermal camouflage with visible camouflage (e.g., cheating coloration 35 , 39 , 46 , transparency 37 , 41 , 44 , and low reflection 47 ) or laser camouflage in the NIR band (by using metal-insulator-metal metasurfaces 38 , 39 , 42 , 48 or photonic crystals 35 to absorb or using coding metasurfaces 49 to scatter the incident lasers) to address multiband detectors.…”

Section: Introductionmentioning

confidence: 99%

“…Considerable efforts have been directed toward developing thermal camouflage using various techniques in the MWIR and LWIR bands, including metallic/dielectric structures [10][11][12][13][14][15][16][17][18][19][20][21] , electrochromic [22][23][24][25][26][27][28][29] and thermochromic [30][31][32][33] materials. Additionally, progress has been made in thermal camouflage through simultaneous radiative heat dissipation in the 5-8 μm non-atmospheric window using nano-structures (e.g., photonic crystals 34,35 , metal-insulator-metal metasurfaces [36][37][38][39][40][41][42] , Fabry-Perot cavities 43,44 , anti-reflection layers [43][44][45] , and porous nanostructures 46 ). Besides, some studies have combined thermal camouflage with visible camouflage (e.g., cheating coloration 35,39,46 , transparency 37,41,44 , and low reflection…”

Section: Introductionmentioning

confidence: 99%

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Whole-infrared-band camouflage with dual-band radiative heat dissipation

Qin,

Zhu,

Zhou

et al. 2023

Light Sci Appl

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Advanced multispectral detection technologies have emerged as a significant threat to objects, necessitating the use of multiband camouflage. However, achieving effective camouflage and thermal management across the entire infrared spectrum, especially the short-wave infrared (SWIR) band, remains challenging. This paper proposes a multilayer wavelength-selective emitter that achieves effective camouflage across the entire infrared spectrum, including the near-infrared (NIR), SWIR, mid-wave infrared (MWIR), and long-wave infrared (LWIR) bands, as well as the visible (VIS) band. Furthermore, the emitter enables radiative heat dissipation in two non-atmospheric windows (2.5–3 μm and 5–8 μm). The emitter’s properties are characterized by low emittance of 0.270/0.042/0.218 in the SWIR/MWIR/LWIR bands, and low reflectance of 0.129/0.281 in the VIS/NIR bands. Moreover, the high emittance of 0.742/0.473 in the two non-atmospheric windows ensures efficient radiative heat dissipation, which results in a temperature decrement of 14.4 °C compared to the Cr reference at 2000 W m−2 input power density. This work highlights the role of solar radiance in camouflage, and provides a comprehensive guideline for developing multiband camouflage compatible with radiative heat dissipation, from the visible to LWIR.

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Section: Introductionmentioning

confidence: 99%

“…Considerable efforts have been directed toward developing thermal camouflage using various techniques in the MWIR and LWIR bands, including metallic/dielectric structures [10][11][12][13][14][15][16][17][18][19][20][21] , electrochromic [22][23][24][25][26][27][28][29] and thermochromic [30][31][32][33] materials. Additionally, progress has been made in thermal camouflage through simultaneous radiative heat dissipation in the 5-8 μm non-atmospheric window using nano-structures (e.g., photonic crystals 34,35 , metal-insulator-metal metasurfaces [36][37][38][39][40][41][42] , Fabry-Perot cavities 43,44 , anti-reflection layers [43][44][45] , and porous nanostructures 46 ). Besides, some studies have combined thermal camouflage with visible camouflage (e.g., cheating coloration 35,39,46 , transparency 37,41,44 , and low reflection…”

Section: Introductionmentioning

confidence: 99%

Whole-infrared-band camouflage with dual-band radiative heat dissipation

Qin,

Zhu,

Zhou

et al. 2023

Light Sci Appl

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“…Machine Learning (ML) has recently become a powerful and innovative technique for complex computational problems and inverse design, i.e., to predict the complete optical response of photonic structures for given geometric parameters, as well as to retrieve the optimal design parameters for the desired optical response . The ML approach can be applied to strike the balance between excellent spectral characteristics and manufacture availability, which is beneficial to obtain easy-to-process artificial structures and hence to reduce the fabrication cost. − Additionally, ML is accurate and efficient in establishing correlations and sensitivities between numerous design variables, determining the optimal parameter interval and thus enhancing the robustness of the material preparation. − Therefore, by utilizing ML, we can incorporate it into the construction of biomimetic photonic structures to enhance spectral performance, clarify parametric mechanisms of action, and reduce the cost of preparation.…”

mentioning

confidence: 99%

Machine-Learning-Assisted Design of a Robust Biomimetic Radiative Cooling Metamaterial

Ding,

Li,

et al. 2024

ACS Materials Lett.

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Recently, biomimetic photonic structural materials have significantly improved their radiative cooling performance. However, most research has focused on understanding cooling mechanisms, with limited exploration of sensitive parameter variations. Traditional numerical methods are costly and time-consuming and often struggle to identify optimal solutions, limiting the scope of high-performance microstructure design. To address these challenges, we integrated machine learning into the design of Batocera LineolataHope bionic photonic structures, using SiO 2 as the substrate. Deep learning models provided insights into the complex relationship between bionic metamaterials and their spectral response, enabling us to identify the optimal performance parameter range for truncated cone arrays (height-to-diameter ratio (H/D bottom ) from 0.8 to 2.4), achieving a high average emissivity of 0.985. Experimentally, the noon temperature of fabricated samples decreased by about 8.3 °C. This data-driven approach accelerates the design and optimization of robust biomimetic radiative cooling metamaterials, promising significant advancements in standardized passive radiative cooling applications.

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Design and Development of Metasurface Materials for Enhancing Photodetector Properties

Guan,

Xu,

Lou

et al. 2024

Advanced Science

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Recently, metasurface‐based photodetectors (metaphotodetectors) have been developed and applied in various fields. Metasurfaces are artificial materials with unique properties that have emerged over the past decade, and photodetectors are powerful tools used to quantify incident electromagnetic wave information by measuring changes in the conductivity of irradiated materials. Through an efficient microstructural design, metasurfaces can effectively regulate numerous characteristics of electromagnetic waves and have demonstrated unique advantages in various fields, including holographic projection, stealth, biological image enhancement, biological sensing, and energy absorption applications. Photodetectors play a crucial role in military and civilian applications; therefore, efficient photodetectors are essential for optical communications, imaging technology, and spectral analysis. Metaphotodetectors have considerably improved sensitivity and noise‐equivalent power and miniaturization over conventional photodetectors. This review summarizes the advantages of metaphotodetectors based on five aspects. Furthermore, the applications of metaphotodetectors in various fields including military and civil applications, are systematically discussed. It highlights the potential future applications and developmental trends of metasurfaces in metaphotodetectors, provides systematic guidance for their development, and establishes metasurfaces as a promising technology.

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Compatible Stealth Metasurface for Laser and Infrared with Radiative Thermal Engineering Enabled by Machine Learning

Cited by 16 publications

References 58 publications

Whole-infrared-band camouflage with dual-band radiative heat dissipation

Whole-infrared-band camouflage with dual-band radiative heat dissipation

Machine-Learning-Assisted Design of a Robust Biomimetic Radiative Cooling Metamaterial

Design and Development of Metasurface Materials for Enhancing Photodetector Properties

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