Abstract
High-temperature infrared (IR) camouflage is crucial to the effective concealment of high-temperature objects but remains a challenging issue, as the thermal radiation of an object is proportional to the fourth power of temperature (T4). Here, we experimentally demonstrate high-temperature IR camouflage with efficient thermal management. By combining a silica aerogel for thermal insulation and a Ge/ZnS multilayer wavelength-selective emitter for simultaneous radiative cooling (high emittance in the 5–8 μm non-atmospheric window) and IR camouflage (low emittance in the 8–14 μm atmospheric window), the surface temperature of an object is reduced from 873 to 410 K. The IR camouflage is demonstrated by indoor/outdoor (with/without earthshine) radiation temperatures of 310/248 K for an object at 873/623 K and a 78% reduction in with-earthshine lock-on range. This scheme may introduce opportunities for high-temperature thermal management and infrared signal processing.
Similar content being viewed by others
Introduction
Infrared (IR) camouflage technology aims to conceal the IR signature of objects and render them invisible to potential threats with IR detectors, including thermal imaging systems, heat-seeking missiles, IR missile warning satellites, etc.1,2,3,4. According to Planck’s law, any object with a temperature above absolute zero emits thermal radiation, which is mainly located in the mid-infrared (MIR) range in most cases5. In particular, the thermal radiation of an object is proportional to the surface emittance (ε) and the fourth power of temperature (T). Therefore, IR camouflage for high-temperature objects (e.g., converging nozzles of aircrafts (~950 K)6 and funnels of naval ships (~680 K)7) is not only highly challenging but also urgently demanded.
IR camouflage can be achieved by controlling either the surface emittance or the surface temperature of an object. To control the surface emittance, nanostructure-based surfaces (e.g., metasurfaces3,8 and metallic-dielectric nanowires9) or films (metal10, semiconductor11,12, and multilayer films13,14,15,16,17) are demonstrated with low-surface emittance over the whole IR range, and yet the radiative heat transfer is blocked, causing severe heat instability18. Wavelength-selective emitters19,20,21,22,23,24,25 with radiative cooling26,27,28,29,30,31 in the non-atmospheric window (5–8 μm)18,20,32 are adopted to mitigate the heat instability without influencing the IR camouflage. However, they cannot operate at high temperature (<523 K)18,20,32. To control the surface temperature, thermal insulators33, phase-change materials33, and transformation thermotics34,35,36,37 have been proposed. Thermal insulators with low-thermal conductivity and low IR transparency can be applied to hide the IR radiation of objects, but the accompanying high absorption is contradictory to the requirement for low-surface emittance. IR camouflage with phase-change materials and transformation thermotics has been demonstrated at moderate (<573 K)33 and low (<373 K)35 temperatures, respectively. Moreover, the IR camouflage based on the phase-change material cannot be maintained after a complete phase change. Consequently, advanced technology for high-temperature IR camouflage still needs to be explored.
In this paper, we experimentally demonstrate high-temperature IR camouflage with efficient thermal management by combining wavelength-selective emitters and thermal insulators. The radiative cooling (ε~0.58) in the non-atmospheric window (5–8 μm) by the wavelength-selective emitter together with thermal insulation by the silica aerogel can effectively reduce the surface temperature of a high-temperature object (873 K) to 410 K. The indoor/outdoor (corresponding to with/without earthshine case) radiation temperatures are reduced to 310/248 K at object temperatures of 873/623 K, and the with-earthshine lock-on range is reduced by 76.9% compared with the case without camouflage.
Results
Scheme for high-temperature IR camouflage
The scheme for high-temperature IR camouflage, which combines a thermal insulator and a wavelength-selective emitter, is shown in Fig. 1a. The thermal insulator is directly fixed on the high-temperature object, and the selective emitter is placed on top of the thermal insulator. According to the requirement of IR opacity on the thermal insulator38, the thermal radiation from the high-temperature object is blocked, and the thermal radiation from the thermal insulator itself decreases with temperature. High broadband radiation covering the whole MIR range is desirable for radiative cooling of high-temperature objects27, while low radiation in the atmospheric window (3–5 and 8–14 μm) is required for IR camouflage. Therefore, for simultaneous IR camouflage and radiative cooling, the emittance of wavelength-selective emitters in the atmospheric window (3–5 and 8–14 μm) should be low, while that in the non-atmospheric window (5–8 μm) should be high (see the spectrum in Fig. 1a).
To demonstrate the IR camouflage effect of this scheme, two types of thermal boundary conditions (Case I and Case II) are considered in simulations with COMSOL Multiphysics (see the heat transfer simulation details in Section S1 in the Supporting information). In Case I, the lower surface of the high-temperature object is regarded as a convection surface, which is convectively heated by a variable high-temperature source Th with a constant heat transfer coefficient h = 500 W/(m2 K). In Case II, the surface of the high-temperature object is a boundary with variable surface temperature To. In both cases, the thermal insulation is modeled with a 1-cm-thick (experimental value) silica aerogel layer with ultralow thermal conductivity39,40 (0.017 W/(m K) at 400 K; see the temperature-dependent thermal conductivity of silica aerogel in Fig. S1 in the Supporting information). Under the conditions of Case I, the surface temperatures Ts of the object are compared for radiative cooling in the non-atmospheric window (5–8 μm), thermal insulation and their combined effect (Fig. 1b). The combination of thermal insulation and radiative cooling shows the maximum surface temperature reduction (orange line in Fig. 1b) with respect to the heating temperature. At the highest heating temperature of 2000 K, the surface temperature reductions with only radiative cooling, only thermal insulation and their combination are 142 K, 967 K, and 1232 K, respectively. As the heating temperature increases, the thermal radiation in the non-atmospheric window becomes more significant, leading to increased surface temperature reduction. When the heating temperature is higher than 800 K, the thermal radiation contributes more than 20% of the total heat flux. For only radiation in the non-atmospheric window (blue line), the surface temperature is close to the heating temperature (black dashed line), as the dissipation flux, including natural convection and thermal radiation, is small. For the same surface temperature (623 or 769 K, dotted lines in Fig. 1b), the corresponding heating temperature for the combination of radiation and insulation (1525 or 2000 K) is much higher than that for only insulation (1252 or 1543 K). Therefore, combining thermal insulation and radiation in the non-atmospheric window can significantly increase the applicable object temperature range for IR camouflage.
In Case II, the contributions of thermal insulation, low emittance in the atmospheric window (8–14 μm) and radiative cooling in the non-atmospheric window (5–8 μm) to IR camouflage are compared (Fig. 1c, and see corresponding surface temperature Ts in Fig. S2 in the Supporting information). The IR signal intensity of an object is estimated by integrating the IR radiant exitance in the atmospheric window (8–14 μm):
where Mbb(λ, T) is the blackbody spectral radiant exitance at a given temperature T and ε(λ) is the surface emittance. For comparison, the IR signal intensity for the high-temperature blackbody is regarded as the base (0 dB). In the case of only thermal insulation with unity surface emittance, the surface temperature is effectively reduced, and thus, the IR signal intensity is reduced by more than 5 dB (orange area) when the temperature is higher than 500 K. Assuming the surface emittance is reduced to ε = 0.05 in the atmospheric window (8–14 μm), the IR signal is further reduced by 13 dB (red area). With radiative cooling in the non-atmospheric window (5–8 μm), the surface temperature further decreases, and its contribution to IR camouflage is more significant when the object temperature is high (blue area). When the object temperature is 1000 K, the IR signal intensity can be reduced by 21 dB with simultaneous thermal insulation, low emittance in the atmospheric window and radiative cooling in the non-atmospheric window, demonstrating the applicability of high-temperature camouflage via effective thermal management.
Structure design and measurement
To achieve high-temperature IR camouflage, a wavelength-selective emitter composed of alternating Ge/ZnS multilayer films is designed, and a commercially available silica aerogel blanket with high emittance (see Section S6 in the Supporting information) is chosen as the thermal insulator (Fig. 2a; see the optical and IR images in Fig. S1). The thicknesses of the Ge/ZnS (blue/red blocks in Fig. 2a) multilayer films are optimized as 0.693/1.26/0.693/1.26/0.693/1.26/1.134/1.323/0.659 μm (from top to bottom). The refractive indexes of Ge and ZnS in the MIR wavelength range are ~4 and 2.2, respectively (Fig. S3 in the Supporting information). The corresponding normalized electric field distributions at wavelengths of 6 and 11 μm are shown in Fig. 2a. For λ = 11 μm in the atmospheric window (orange curve), high reflectance is achieved with the distributed Bragg reflector in the upper six alternating Ge/ZnS layers, and the reflectance further increases in the bottom three layers (see reflectance spectrum in Fig. S3 in the Supporting information). The thermal radiation from the silica substrate at λ = 11 μm is effectively blocked, as indicated by the decaying electric field intensity (Fig. 2a). For λ = 6 μm in the non-atmospheric window (red curve), the transmittance of the multilayers is high, and therefore, the thermal radiation from the substrate is not blocked, contributing to the high emittance. The reflectance spectra of the wavelength-selective emitter are also not sensitive to the angle (calculated and measured reflectance spectra in Figs. S4 and S5, respectively).
The wavelength-selective emitter is experimentally fabricated by depositing alternating multilayer films of Ge and ZnS on a thin silica substrate (inset in Fig. 2b). The emittance of the wavelength-selective emitter is compared with that of polished stainless steel, which shows low-surface emittance and is extensively applied in military objectives. For the atmospheric window (8–14 μm), the band emittance (ε8–14, see band emittance in Section S3 in the Supporting information) at 573 K and the absorptance are 0.078 and 0.022, respectively, similar to the simulated absorptance of 0.094. For the non-atmospheric window (5–8 μm), the measured band emittance (ε5–8) at 573 K, the measured absorptance and the simulated absorptance are 0.580, 0.545, and 0.575, respectively. The band emittances ε5–8 and ε8–14 of stainless steel are 0.087 and 0.060, respectively. The band emittance ε5–8 of the wavelength-selective emitter is much higher than that of stainless steel without wavelength-selective radiation, while their band emittances ε8–14 are similar.
High-temperature IR camouflage with earthshine
The IR detector positioned under the object collects both radiation and reflected earthshine from the object41, as shown in Fig. 3a. Indoor measurements are employed to imitate this situation, as both the radiation emitted from the sample and the ambient radiation reflected by the sample are collected (Fig. 3b). To demonstrate the surface temperature reduction and the IR camouflage performance for high-temperature objects, both the surface temperature and the radiation temperature of the wavelength-selective emitter on silica aerogel are measured (sample I). For comparison, polished stainless steel on silica aerogel (sample II), only silica aerogel (sample III), and selective emitter and stainless steel directly on the high-temperature object (samples IV and V) are used. The surface temperatures Ts of samples I–III are shown in Fig. 3c (the surface temperatures of samples IV and V are close to the object temperature To and therefore not provided). For these three samples, the surface temperatures are significantly lower than the object temperature due to the excellent thermal insulation of the silica aerogel layer. At the highest object temperature of 873 K, the surface temperature of sample I (409.8 K) is 16.9 K lower than that of sample II (426.7 K) due to radiative cooling in the non-atmospheric window for sample I.
The radiation temperature monitored by the IR camera, which indicates the collected total radiation intensity integrated in the 8–14 μm range, is employed to demonstrate the IR camouflage performance (Fig. 3d). At the highest object temperature of 873 K, the radiation temperature of sample I (310.4 K) is 11.7 K lower than that of sample II (322.1 K). The IR images of samples I and II (Fig. 3f) also show a radiation intensity reduction of sample I by approximately 15% (0.72 dB) compared with sample II in the atmospheric window (200 W/m2 and 236 W/m2 for sample I and sample II, respectively). The low-surface temperature and low band emittance (ε8–14) contribute to the lower radiation temperature of sample I. The maximum heating temperature for samples IV and V is 573 K, beyond which the samples are oxidized (Fig. S7 in Supporting information). At an object temperature of 573 K, the radiation temperature of sample I (299.6 K) is 54.1 K lower than that of sample V (353.7 K), corresponding to a 51% (3.14 dB) reduction in the band radiation intensity.
To quantitatively evaluate the IR camouflage performance, the IR lock-on range, which is an extensively employed indicator for aircraft, is assessed. The IR lock-on range is dependent on both the radiation intensity of the object and the reflected earthshine radiation42 (see the lock-on range calculation in Section S4 in the Supporting information). The object can only be detected when the distance between the object and the detector is within the lock-on range; a small lock-on range is therefore desirable for enhanced IR camouflage performance. The lock-on ranges considering the earthshine for all five samples are calculated with the measured surface temperature and emittance (Fig. 3e). At the highest object temperature of 873 K, the lock-on range of sample I (2.81 km) is shorter than those of sample II (2.94 km), sample V (5.72 km) and the sample without camouflage (12.73 km) by 4.5% (inset in Fig. 3e), 50.9% and 77.9%, respectively. The increase in the lock-on range with the object temperature for sample I is slower than that of the other samples and the samples without camouflage due to its lowest surface temperature and low-surface emittance. Sample I, combining a thermal insulator and a wavelength-selective emitter, shows much better high-temperature IR camouflage performance than the widely used stainless steel surface.
High-temperature IR camouflage without earthshine
For the IR detector positioned over the object, there is no reflected earthshine by the object, as shown in Fig. 4a. In this situation, only the radiation from the object is collected by the IR detector. The outdoor experiment on a clear night is performed to imitate this situation, and samples I–III are considered. For samples IV and V, the surface temperatures are close to the heating temperature and are therefore not considered here. At the highest object temperature of 623 K, the surface temperature of sample I is 353.2 K, which is only slightly lower than that of sample II (357.8 K), as shown in Fig. 4b. As the outdoor ambient temperature (11.9–13.1 °C) is lower than the indoor ambient temperature (~21 °C), the surface temperature in the outdoor measurement is lower than that in the indoor measurement at the same heating stage temperature (object temperature). At the highest object temperature of 623 K, the radiation temperature of sample I (248.2 K) is 7.7 K lower than that of sample II (255.9 K), corresponding to an 18% (0.86 dB) reduction in the integrated IR signal intensity, as shown in Fig. 4c. The IR image captured with the IR camera at the highest object temperature of 623 K (Fig. 4e) also indicates the lowest radiation temperature for sample I with simultaneous thermal insulation and wavelength-selective emission.
For the situation without earthshine, the lock-on ranges for samples I and II with low-surface emittance in the atmospheric window are significantly reduced (Fig. 4d). At the highest object temperature of 623 K, the lock-on range for sample I is only 1.28 km, which is approximately half that of the samples with earthshine (2.52 km). For sample III, the lock-on range is not significantly influenced by the earthshine, as its surface emittance is high. The lock-on ranges for sample III with and without earthshine at an object temperature of 623 K are 3.42 and 3.26 km, respectively. Consequently, the scheme combining thermal insulation and wavelength-selective emission presents excellent high-temperature IR camouflage performance in situations with and without earthshine. Due to the radiative cooling in the non-atmospheric window, both the indoor (with earthshine) and the outdoor (without earthshine) experiments demonstrate enhanced IR camouflage performance by combining thermal insulation and wavelength-selective emission in comparison with polished stainless steel as a common broadband low-emittance surface.
Discussion
A scheme combining a thermal insulator and a wavelength-selective emitter with radiative cooling in the non-atmospheric window is demonstrated for high-temperature IR camouflage. First, the introduction of wavelength-selective emissive surfaces offers compatibility for IR camouflage and thermal management, as the conventional high MIR emittance requirement of thermal management is in conflict with the low MIR emittance requirement of IR camouflage. Second, the combination of thermal insulation and wavelength-selective emission provides an approach for optimized thermal management, which is of vital importance not only for high-temperature camouflage but also for other thermal management applications43,44,45,46,47. Third, wavelength-selective emitters based on multilayer films and silica aerogels for thermal insulation are easy to fabricate and thus have potential for large-area applications. Last, the temperature endurance for the combination of thermal insulation and wavelength-selective emission promises an even higher applicable object temperature than that already demonstrated (873 K). The Ge/ZnS multilayer film can stand at 623 K for 1 h (Supporting information Fig. S6); therefore, the object temperature can be well above 623 K if the silica aerogel is properly chosen (as shown by the dotted line in Fig. 1b). It has been shown that the silica aerogel has long-term temperature endurance at 923 K48. Ultimately, our scheme may open opportunities for further developments of energy-efficient MIR optical materials and devices49,50.
Materials and methods
Selective emitter fabrication
The Ge/ZnS multilayer film was deposited with E-beam evaporation on a silica substrate, with deposition rates of 0.5 nm/s (Ge) and 1.5 nm/s (ZnS).
Emittance/absorptance spectrum measurements
The emittance/absorptance was measured with FTIR (Vertex 70, Brucker) with DTGS/MCT detectors.
Radiation/surface temperature measurements
The radiation temperature was measured with an IR camera (Blackbird precision sl, Jenoptik) with a detection wavelength range of 8–14 μm. The surface temperature was measured by thermocouples (5TC-TT-K-30-36, Omega) with a thermometer (THTZ408R, Tenghui, Ningbo). The thermocouples were attached to the upper surface of the samples (I. Selective emitter on aerogel, II. Stainless steel on aerogel, III. Bare aerogel). For object temperatures higher than 473 K, the surface of stainless steel became yellow due to possible oxidization (see Supporting information Fig. S7); therefore, the object temperature limit for sample IV/V was only 573 K.
Simulations
The heat transfer simulation was conducted with a heat transfer module and surface-to-surface radiation module in COMSOL Multiphysics. The electric field distribution was calculated with a radio frequency module (electromagnetic waves, frequency domain) in COMSOL Multiphysics.
References
Baranwal, N. & Mahulikar, S. P. Infrared signature of aircraft engine with choked converging nozzle. J. Thermophys. Heat Transf. 30, 854–862 (2016).
Phan, L. et al. Reconfigurable infrared camouflage coatings from a cephalopod protein. Adv. Mater. 25, 5621–5625 (2013).
Xie, X. et al. Plasmonic metasurfaces for simultaneous thermal infrared invisibility and holographic illusion. Adv. Funct. Mater. 28, 1706673 (2018).
Xu, C. Y., Stiubianu, G. T. & Gorodetsky, A. A. Adaptive infrared-reflecting systems inspired by cephalopods. Science 359, 1495–1500 (2018).
Baranov, D. G. et al. Nanophotonic engineering of far-field thermal emitters. Nat. Mater. 18, 920–930 (2019).
Mahulikar, S. P., Rao, G. A. & Kolhe, P. S. Infrared signatures of low-flying aircraft and their rear fuselage skin’s emissivity optimization. J. Aircr. 43, 226–232 (2006).
Thompson, J., Vaitekunas, D. & Birk, A. M. IR signature suppression of modern naval ships. Proceedings of ASNE 21st Century Combatant Technology Symposium (ASNE, Biloxi, MS, 1998).
Qu, Y. R. et al. Dynamic thermal emission control based on ultrathin plasmonic metamaterials including phase-changing material GST. Laser Photonics Rev. 11, 1700091 (2017).
Moghimi, M. J., Lin, G. Y. & Jiang, H. R. Broadband and ultrathin infrared stealth sheets. Adv. Eng. Mater. 20, 1800038 (2018).
Zhang, C. et al. An ultralight and thin metasurface for radar-infrared bi-stealth applications. J. Phys. D: Appl. Phys. 50, 444002 (2017).
Zhang, C. L. et al. Flexible and transparent microwave-infrared bistealth structure. Adv. Mater. Technol. 4, 1900063 (2019).
Chandra, S. et al. Adaptive multispectral infrared camouflage. ACS Photonics 5, 4513–4519 (2018).
Xiao, L. et al. Fast adaptive thermal camouflage based on flexible VO2/Graphene/CNT thin films. Nano Lett. 15, 8365–8370 (2015).
Salihoglu, O. et al. Graphene-based adaptive thermal camouflage. Nano Lett. 18, 4541–4548 (2018).
Xu, Z. Q. et al. Spatially resolved dynamically reconfigurable multilevel control of thermal emission. Laser Photonics Rev. 14, 1900162 (2020).
Qu, Y. R. et al. Thermal camouflage based on the phase-changing material GST. Light: Sci. Appl. 7, 26 (2018).
Du, K. K. et al. Control over emissivity of zero-static-power thermal emitters based on phase-changing material GST. Light: Sci. Appl. 6, e16194 (2017).
Kim, T. et al. Hierarchical metamaterials for multispectral camouflage of infrared and microwaves. Adv. Funct. Mater. 29, 1807319 (2019).
Dyachenko, P. N. et al. Controlling thermal emission with refractory epsilon-near-zero metamaterials via topological transitions. Nat. Commun. 7, 11809 (2016).
Pan, M. Y. et al. Multi-band middle-infrared-compatible camouflage with thermal management via simple photonic structures. Nano Energy 69, 104449 (2020).
Costantini, D. et al. Plasmonic metasurface for directional and frequency-selective thermal emission. Phys. Rev. Appl. 4, 014023 (2015).
Inoue, T. et al. Realization of dynamic thermal emission control. Nat. Mater. 13, 928–931 (2014).
Asano, T. et al. Near-infrared-to-visible highly selective thermal emitters based on an intrinsic semiconductor. Sci. Adv. 2, e1600499 (2016).
Yokoyama, T. et al. Spectrally selective mid-infrared thermal emission from molybdenum plasmonic metamaterial operated up to 1000 °C. Adv. Opt. Mater. 4, 1987–1992 (2016).
Park, J. H. et al. Observation of thermal beaming from tungsten and molybdenum bull’s eyes. ACS Photonics 3, 494–500 (2016).
Raman, A. P. et al. Passive radiative cooling below ambient air temperature under direct sunlight. Nature 515, 540–544 (2014).
Zhao, B. et al. Radiative cooling: A review of fundamentals, materials, applications, and prospects. Appl. Energy 236, 489–513 (2019).
Zhu, L. X. et al. Radiative cooling of solar cells. Optica 1, 32–48 (2014).
Shi, N. N. et al. Keeping cool: enhanced optical reflection and radiative heat dissipation in Saharan silver ants. Science 349, 298–301 (2015).
Zhou, L. et al. A polydimethylsiloxane-coated metal structure for all-day radiative cooling. Nat. Sustain. 2, 718–724 (2019).
Mandal, J. et al. Hierarchically porous polymer coatings for highly efficient passive daytime radiative cooling. Science 362, 315–319 (2018).
Peng, L. et al. A multilayer film based selective thermal emitter for infrared stealth technology. Adv. Opt. Mater. 6, 1801006 (2018).
Lyu, J. et al. Nanofibrous Kevlar aerogel films and their phase-change composites for highly efficient infrared stealth. ACS Nano 13, 2236–2245 (2019).
Li, Y. et al. Structured thermal surface for radiative camouflage. Nat. Commun. 9, 273 (2018).
Xu, H. Y. et al. Ultrathin three-dimensional thermal cloak. Phys. Rev. Lett. 115, 054301 (2014).
Fan, C. Z., Gao, Y. & Huang, J. P. Shaped graded materials with an apparent negative thermal conductivity. Appl. Phys. Lett. 92, 251907 (2008).
Xu, L. J. & Huang, J. P. Metamaterials for manipulating thermal radiation: transparency, cloak, and expander. Phys. Rev. Appl. 12, 044048 (2019).
Keppler, H. et al. Optical absorption and radiative thermal conductivity of silicate perovskite to 125 gigapascals. Science 322, 1529–1532 (2008).
Zhao, L. et al. Harnessing heat beyond 200 °C from unconcentrated sunlight with nonevacuated transparent aerogels. ACS Nano 13, 7508–7516 (2019).
Weinstein, L. A. et al. A hybrid electric and thermal solar receiver. Joule 2, 962–975 (2018).
Mahulikar, S. P., Potnuru, S. K. & Arvind Rao, G. Study of sunshine, skyshine, and earthshine for aircraft infrared detection. J. Opt. A: Pure Appl. Opt. 11, 045703 (2009).
Rao, G. A. & Mahulikar, S. P. Aircraft powerplant and plume infrared signature modelling and analysis. Proceedings of the 43rd AIAA Aerospace Sciences Meeting and Exhibit (AIAA, Reno, NV, 2005).
Wang, Y. L. et al. High temperature thermal management with boron nitride nanosheets. Nanoscale 10, 167–173 (2018).
Shang, B. F. et al. Passive thermal management system for downhole electronics in harsh thermal environments. Appl. Therm. Eng. 118, 593–599 (2017).
Hsu, P. C. et al. Radiative human body cooling by nanoporous polyethylene textile. Science 353, 1019–1024 (2016).
Luo, H. et al. An ultra-thin colored textile with simultaneous solar and passive heating abilities. Nano Energy 65, 103998 (2019).
Bierman, D. M. et al. Radiative thermal runaway due to negative-differential thermal emission across a solid-solid phase transition. Phys. Rev. Appl. 10, 021001 (2018).
Bheekhun, N., Talib, A. R. A. & Hassan, M. R. Aerogels in aerospace: an overview. Adv. Mater. Sci. Eng. 2013, 406065 (2013).
Ziolkowski, P., Zabrocki, K. & Müller, E. TEG design for waste heat recovery at an aviation jet engine nozzle. Appl. Sci. 8, 2637 (2018).
Zhang, X. et al. Controlling thermal emission by parity-symmetric fano resonance of optical absorbers in metasurfaces. ACS Photonics 6, 2671–2676 (2019).
Acknowledgements
This work was supported by the National Key Research and Development Program of China (2017YFA0205700 and 2017YFE0100200) and the National Natural Science Foundation of China (Grant Nos. 61975181, 61775194, and 61950410608).
Author information
Authors and Affiliations
Contributions
Q.L. conceived the idea and supervised the project together with M.Q. H.Z., C.Z. and H.W. performed the experiments. H.Z. and Z.X. performed the calculations. H.Z., W.S. and Y.H. fabricated the devices. Q.L., H.Z. and M.Q. analysed the data. Q.L., H.Z., S.K., P.G. and M.Q. wrote the paper. All authors contributed to the final version of the paper.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Zhu, H., Li, Q., Zheng, C. et al. High-temperature infrared camouflage with efficient thermal management. Light Sci Appl 9, 60 (2020). https://doi.org/10.1038/s41377-020-0300-5
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41377-020-0300-5
This article is cited by
-
General deep learning framework for emissivity engineering
Light: Science & Applications (2023)
-
Ultrahigh-efficient material informatics inverse design of thermal metamaterials for visible-infrared-compatible camouflage
Nature Communications (2023)
-
Whole-infrared-band camouflage with dual-band radiative heat dissipation
Light: Science & Applications (2023)
-
Low emissivity and thermal insulating infrared stealth composite of silver plating TPU fibers@WPU/CNF aerogel with all-in-one structure
Cellulose (2023)
-
Sustainable wearable infrared shielding bamboo fiber fabrics loaded with antimony doped tin oxide/silver binary nanoparticles
Advanced Composites and Hybrid Materials (2023)