Performance and electromagnetic mechanism of radar- and infrared-compatible stealth materials based on photonic crystals

Yanming Liu; Xuan Yang; Lixin Xuan; Weiwei Men; Xiao Wu; Yuping Duan

doi:10.1007/s12613-024-2986-5

International Journal of Minerals, Metallurgy, and Materials ›› 2025, Vol. 32 ›› Issue (3) : 710 -717. DOI: 10.1007/s12613-024-2986-5

Research Article

Performance and electromagnetic mechanism of radar- and infrared-compatible stealth materials based on photonic crystals

Yanming Liu ¹^,²
, Xuan Yang ¹^,²
, Lixin Xuan ¹^,²
, Weiwei Men ¹^,²
, Xiao Wu ¹^,²
, Yuping Duan ³^,^a

Author information +

History +

PDF

Abstract

Traditional stealth materials do not fulfill the requirements of high absorption for radar waves and low emissivity for infrared waves. Furthermore, they can be detected by various technologies, considerably threatening weapon safety. Therefore, a stealth material compatible with radar and infrared was designed based on the photonic bandgap characteristics of photonic crystals. The radar stealth layer (bottom layer) is a composite of carbonyl iron/silicon dioxide/epoxy resin, and the infrared stealth layer (top layer) is a 1D photonic crystal with alternately and periodically stacked germanium and silicon nitride. Through composition optimization and structural adjustment, the effective absorption bandwidth of the compatible stealth material with a reflection loss of less than −10 dB has reached 4.95 GHz. The average infrared emissivity of the proposed design is 0.1063, indicating good stealth performance. The theoretical analysis proves that photonic crystals with this structural design can produce infrared waves within the photonic bandgap, achieving high radar wave transmittance and low infrared emissivity. Infrared stealth is achieved without affecting the absorption performance of the radar stealth layer, and the conflict between radar and infrared stealth performance is resolved. This work aims to promote the application of photonic crystals in compatible stealth materials and the development of stealth technology and to provide a design and theoretical foundation for related experiments and research.

Cite this article

Download citation ▾

Yanming Liu, Xuan Yang, Lixin Xuan, Weiwei Men, Xiao Wu, Yuping Duan. Performance and electromagnetic mechanism of radar- and infrared-compatible stealth materials based on photonic crystals. International Journal of Minerals, Metallurgy, and Materials, 2025, 32(3): 710-717 DOI:10.1007/s12613-024-2986-5

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	L.L. Liang, X.Y. Yang, C. Li, et al., MXene-enabled pneumatic multiscale shape morphing for adaptive, programmable and multimodal radar–infrared compatible camouflage, Adv. Mater., 36(2024), No. 24, art. No. 2313939.

[2]	Luo H, Ma BB, Chen F, et al.. Bimetallic oxalate rod-derived NiFe/Fe₃O₄@C composites with tunable magneto–dielectric properties for high-performance microwave absorption. J. Phys. Chem. C, 2021, 125(44): 24540.

[3]	W.H. Gu, S.J.H. Ong, Y.H. Shen, et al., A lightweight, elastic, and thermally insulating stealth foam with high infrared–radar compatibility, Adv. Sci., 9(2022), No. 35, art. No. 2204165.

[4]	Z.Y. Zhou and J. Huang, Mixed design of radar/infrared stealth for advanced fighter intake and exhaust system, Aerosp. Sci. Technol., 110(2021), art. No. 106490.

[5]	Z.Y. Zhou, J. Huang, and J.J. Wang, Radar/infrared integrated stealth optimization design of helicopter engine intake and exhaust system, Aerosp. Sci. Technol., 95(2019), art. No. 105483.

[6]	Y. Wu, S.J. Tan, Y. Zhao, L.L. Liang, M. Zhou, and G.B. Ji, Broadband multispectral compatible absorbers for radar, infrared and visible stealth application, Prog. Mater. Sci., 135(2023), art. No. 101088.

[7]	Chen XL, Tian CH, Che ZX, Chen TP. Selective metamaterial perfect absorber for infrared and 1.54 µm laser compatible stealth technology. Optik, 2018, 172: 840.

[8]	Z.G. Cheng, F. Zhao, X.K. Wang, X.D. Cai, X.J. Tang, and K. Han, Coaxial electrospinning fabrication and radar–infrared compatible stealth properties of Zn_0.96Co_0.04O nanotubes, J. Alloys Compd., 835(2020), art. No. 155368.

[9]	C.L. Xu, B.K. Wang, M.B. Yan, et al., An optically transparent sandwich structure for radar–infrared bi-stealth, Infrared Phys. Technol., 105(2020), art. No. 103108.

[10]	L.P. Chen, Z.Y. Ren, X.M. Liu, K. Wang, and Q. Wang, Infrared–visible compatible stealth based on Al–SiO₂ nanoparticle composite film, Opt. Commun., 482(2021), art. No. 126608.

[11]	Q. Yuan, J.M. Jiang, Y.F. Li, et al., The compatible method of designing the transparent ultra-broadband radar absorber with low infrared emissivity, Infrared Phys. Technol., 123(2022), art. No. 104114.

[12]	Y. Zhu, L. Zhang, J. Wang, et al., Microwave–infrared compatible stealth via high-temperature frequency selective surface upon Al₂O₃–TiC coating, J. Alloys Compd., 920(2022), art. No. 165977.

[13]	Z.Q. Gao, Q. Fan, X.X. Tian, et al., An optically transparent broadband metamaterial absorber for radar–infrared bi-stealth, Opt. Mater., 112(2021), art. No. 110793.

[14]	Shi MY, Xu C, Yang ZH, et al.. Achieving good infrared–radar compatible stealth property on metamaterial-based absorber by controlling the floating rate of Al type infrared coating. J. Alloys Compd., 2018, 764: 314.

[15]	Lv HL, Ji GB, Li XG, et al.. Microwave absorbing properties and enhanced infrared reflectance of FeAl mixture synthesized by two-step ball-milling method. J. Magn. Magn. Mater., 2015, 374: 225.

[16]	Lu SB, Meng Y, Wang HB, et al.. Tailoring conductive network Zn@NPC@MWCNTs nanocomposites derived from ZIF-8 as high-performance electromagnetic absorber for the whole X-band. Def. Technol., 2023, 23: 189.

[17]	Pan WL, He M, Bu XH, et al.. Microwave absorption and infrared emissivity of helical polyacetylene@multiwalled carbon nanotubes composites. J. Mater. Sci. Mater. Electron., 2017, 28(12): 8601.

[18]	Zhang ZY, Xu MZ, Ruan XF, et al.. Enhanced radar and infrared compatible stealth properties in hierarchical SnO₂@ZnO nanostructures. Ceram. Int., 2017, 43(3): 3443.

[19]	Z.M. Zhang, X.H. Wu, and C.J. Fu, Validity of Kirchhoff’s law for semitransparent films made of anisotropic materials, J. Quant. Spectrosc. Radiat. Transfer, 245(2020), art. No. 106904.

[20]	Z.C. Deng, Y.R. Su, W. Gong, X. Wang, and R.Z. Gong, Temperature characteristics of Ge/ZnS one-dimension photonic crystal for infrared camouflage, Opt. Mater., 121(2021), art. No. 111564.

[21]	Chen S, Guo LY, Ji MH, et al.. Photonic crystal enhanced laser desorption and ionization substrate for detection of stress biomarkers under atmospheric pressure. J. Mater. Chem. B, 2019, 7(6): 908.

[22]	A. Biswal, R. Kumar, C. Nayak, and S. Dhanalakshmi, Photonic bandgap characteristics of GaAs/AlAs-based one-dimensional quasi-periodic photonic crystal, Optik, 234(2021), art. No. 166597.

[23]	S. Razi, F. Sepahi, and A.A. Saray, Graphene based photonic crystals including anisotropic defect layers with highly tunable optical responses in infrared frequency range, Phys. B: Condens. Matter, 597(2020), art. No. 412380.

[24]	Heshmat M, Li PCH. Construction of an array of photonic crystal films for visual differentiation of water/ethanol mixtures. ACS Omega, 2019, 4(22): 19991. 6882101

[25]	W.G. Zhang and D.D. Lv, Preparation and characterization of Ge/TiO₂ one-dimensional photonic crystal with low infrared-emissivity in the 8–14 µm band, Mater. Res. Bull., 124(2020), art. No. 110747.

[26]	L.C. Zhang, L.L. Qiu, W. Lu, et al., Preparation of opal photonic crystal infrared stealth materials, Acta Phys. Sin., 66(2017), No. 8, art. No. 084208.

[27]	T. Nagano, R. Hara, K. Moto, K. Yamamoto, and T. Sadoh, Improved carrier mobility of Sn-doped Ge thin films (≤20 nm) on insulator by interface-modulated solid-phase crystallization combined with surface passivation, Mater. Sci. Semicond. Process., 165(2023), art. No. 107692.

[28]	He J, Ke YC. Plasma-enhanced chemical vapor-deposited SiN and liquid-phase-deposited SiO₂ stack double-layer anti-reflection films for multi-crystalline solar cells. Superlattices Microstruct., 2018, 122: 296.

[29]	M. Bouzidi, A.S. Alshammari, S. Soltani, et al., Correlation of structural and optical properties of AlGaN films grown on SiN-treated sapphire by MOVPE, Mater. Sci. Eng. B, 263(2021), art. No. 114866.

[30]	Li L, Fang Y, Xiao Q, Wu YJ, Wang N, Chen XM. Microwave dielectric properties of fused silica prepared by different approaches. Int. J. Appl. Ceram. Technol., 2014, 11(1): 193.

[31]	Szwagierczak D, Synkiewicz B, Kulawik J. Low dielectric constant composites based on B₂O₃ and SiO₂ rich glasses, cordierite and mullite. Ceram. Int., 2018, 44(12): 14495.

[32]	Y. Yang, Y. Yang, W. Xiao, C.P. Neo, and J. Ding, Shape-dependent microwave permeability of Fe₃O₄ nanoparticles: A combined experimental and theoretical study, Nanotechnology, 26(2015), No. 26, art. No. 265704.

[33]	Guo C, Yang ZH, Shen SL, Liang J, Xu GY. High microwave attenuation performance of planar carbonyl iron particles with orientation of shape anisotropy field. J. Magn. Magn. Mater., 2018, 454: 32.

[34]	Zhang N, Wang Y, Chen PZ, Chen WX. A rational route towards dual wave-transparent type of carbonyl iron@SiO₂@heterogeneous state polypyrrole@paraffin composites for electromagnetic wave absorption application. J. Colloid Interface Sci., 2021, 581: 84.

[35]	Wang BC, Wei JQ, Yang Y, Wang T, Li FS. Investigation on peak frequency of the microwave absorption for carbonyl iron/epoxy resin composite. J. Magn. Magn. Mater., 2011, 323(8): 1101.

[36]	Duan YP, Liu Y, Cui YL, Ma GJ, Wang TM. Graphene to tune microwave absorption frequencies and enhance absorption properties of carbonyl iron/polyurethane coating. Prog. Org. Coat., 2018, 125: 89.

[37]	Wang BC, Zhang LY, Zhao X, et al.. Unique dielectric dispersion induced ultra-broadband microwave absorption of tellurium doped black phosphorus nanoflakes/aramid nanofibers/carbonyl iron nanopowders ultra-lightweight aerogel. Ceram. Int., 2023, 49(18): 30837.

[38]	Pourmahmoud V, Rezaei B. Manipulation of Bragg and graphene photonic band gaps in one-dimensional photonic crystal containing graphene. Optik, 2019, 185: 875.