Multispectral camouflage faces growing urgency due to multimodal detection threats. To meet the spectral requirements for different bands, artificially designed selective spectral properties are needed. However, achieving a balance among simplicity of configuration, durability, spectral selectivity, and large-scale potential remains challenging, as well as achieving passive radiative cooling for effective thermal management. Here, we present a Ge (635 nm)/ZnS (1152 nm)/Ge (1260 nm)/ZnS (1141 nm)/Ge (656 nm) heterogeneous photonic crystal (HPC) selective thermal emitter for achieving low thermal emissivity camouflage ( =0.28, =0.24), low laser reflection at 10.6 μm (0.29), and radiative cooling within non-atmospheric window (0.70 at 5-7.5 μm). This emitter shows a 25 °C radiative cooling reduction than traditional low-emissivity Cu films at 350 °C. The emitter also has good angle and polarization independence, environmental durability, and can be manufactured on a large scale. This technology offers a cost-effective way for multispectral-compatible camouflage design and creates new opportunities for combining camouflage with thermal management. The HPC used for multispectral camouflage and its configuration.
Wang et al. (Tue,) studied this question.
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