Broadband spectrally selective infrared radiation and its applications of a superstructure film of combined circular patches

Selective infrared radiation is crucial for achieving infrared stealth and heat dissipation. Artificially designed superstructure film (SF) provides several advantages for controlling and modulating infrared radiation, making them a promising solution for these applications. The research described i...

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Bibliographic Details
Published in:Journal of applied physics 2023-06, Vol.133 (24)
Main Authors: An, Ze-Lin, Liu, Li, Liu, Li-Ying, Wang, Chao, Ai, Li-Hong, Zhang, Sheng-Jun, Wang, Ru-Zhi
Format: Article
Language:English
Subjects:
Applied physics
Broadband
Dissipation
Emissivity
Infrared radiation
Patches (structures)
Selectivity
Stealth technology
Superstructures
Thermal management
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Summary:Selective infrared radiation is crucial for achieving infrared stealth and heat dissipation. Artificially designed superstructure film (SF) provides several advantages for controlling and modulating infrared radiation, making them a promising solution for these applications. The research described in this work has successfully produced broadband selective infrared radiation by using a surface made up of circular patches that are combined. Numerical simulations show that this SF can achieve broadband selective radiation with 3–5 μm mid-wave infrared (MWIR) suppression and 8–14 μm long-wave infrared (LWIR) emission. The spectral selectivity can be easily switched to high emissivity in MWIR and low emissivity in LWIR by simply changing the basal layer. The resonance mechanism for achieving broadband spectral selectivity in the SF may be due to a combination of multimode plasmon resonances that are induced by the structural nonrotational symmetry of the circular patches. By applying the selective radiation SF on the tail nozzle or the vehicle, the effect of thermal management is very significant. Selective radiation SF can reduce radiant energy in the 3−5 μm band by a significant amount at 500 °C, resulting in a 46 °C cooler temperature than that at the body without the SF. At 80 °C, radiated energy in the 8–14 μm band is also considerably reduced and the temperature is 10 °C lower than that of the body without the SF. There will be obvious advantages in potential applications for infrared stealth and heat dissipation by the designed SF, a simple and convenient manufacturing process.
ISSN:0021-8979
1089-7550
DOI:10.1063/5.0152953