Synthesis and high frequency structure simulator electromagnetic simulation of hollow NC@CeO2 nanospheres for broad absorption bandwidth

Shuhao Yang; Peiyan Zhao; Xianyong Lu; Xiaoyuan Hao; Yufan Wu; Huiya Wang; Tao Zhou; Guangsheng Wang

doi:10.1007/s12613-024-3056-8

International Journal of Minerals, Metallurgy, and Materials ›› 2025, Vol. 32 ›› Issue (3) : 678 -688. DOI: 10.1007/s12613-024-3056-8

Research Article

Synthesis and high frequency structure simulator electromagnetic simulation of hollow NC@CeO₂ nanospheres for broad absorption bandwidth

Author information +

History +

PDF

Abstract

Recent progress in microwave absorption materials stimulates the extensive exploration of rare earth oxide materials. Herein, we report the synthesis of a hollow sphere-based carbon material compounded with rare earth oxides. Hollow N-doped carbon nanospheres loaded ceria composites (H-NC@CeO₂) were designed and prepared by the template method, combined with in-situ coating, pyrolysis and chemical etching. By controlling the loading content of H-NC@CeO₂ and adjusting the impedance matching of the material, the H-NC@CeO₂/PS (polystyrene) composite exhibited a minimum reflection loss (RL) of −50.8 dB and an effective absorption bandwidth (EAB) of 4.64 GHz at a filler ratio of 20wt% and a thickness of 2 mm. In accordance with measured electromagnetic parameters, simulations using the high frequency structure simulator (HFSS) software were conducted to investigate the impact of the honeycomb structure on the electromagnetic wave performance of H-NC@CeO₂/PS. By calculating the surface electric field and the material’s bulk loss density, the mechanism of electromagnetic loss for the honeycomb structure was elaborated. A method for structural design and manufacturing of broadband absorbing devices was proposed and a broadband absorber with an EAB of 11.9 GHz was prepared. This study presents an innovative approach to designing advanced electromagnetic (EM) wave absorbing materials with broad absorption bandwidths.

Cite this article

Download citation ▾

Shuhao Yang, Peiyan Zhao, Xianyong Lu, Xiaoyuan Hao, Yufan Wu, Huiya Wang, Tao Zhou, Guangsheng Wang. Synthesis and high frequency structure simulator electromagnetic simulation of hollow NC@CeO₂ nanospheres for broad absorption bandwidth. International Journal of Minerals, Metallurgy, and Materials, 2025, 32(3): 678-688 DOI:10.1007/s12613-024-3056-8

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]	X.F. Xu, S.H. Shi, Y.L. Tang, et al., Growth of NiAl-layered double hydroxide on graphene toward excellent anticorrosive microwave absorption application, Adv. Sci., 8(2021), No. 5, art. No. 2002658.

[2]	Di XC, Wang Y, Fu YQ, Wu XM, Wang P. Wheat flour-derived nanoporous carbon@ZnFe₂O₄ hierarchical composite as an outstanding microwave absorber. Carbon, 2021, 173: 174.

[3]	Liu ZH, Cui YH, Li Q, Zhang QY, Zhang BL. Fabrication of folded MXene/MoS₂ composite microspheres with optimal composition and their microwave absorbing properties. J. Colloid Interface Sci., 2022, 607: 633.

[4]	P. Song, Z.L. Ma, H. Qiu, Y.F. Ru, and J.W. Gu, High-efficiency electromagnetic interference shielding of rGO@FeNi/epoxy composites with regular honeycomb structures, Nano Micro Lett., 14(2022), No. 1, art. No. 51.

[5]	Li B, Wang FL, Wang KJ, et al.. Metal sulfides based composites as promising efficient microwave absorption materials: A review. J. Mater. Sci. Technol., 2022, 104: 244.

[6]	Sambyal P, Iqbal A, Hong J, et al.. Ultralight and mechanically robust Ti₃C₂T_x hybrid aerogel reinforced by carbon nanotubes for electromagnetic interference shielding. ACS Appl. Mater. Interfaces, 2019, 11(41): 38046.

[7]	Han YX, He MK, Hu JW, et al.. Hierarchical design of FeCo-based microchains for enhanced microwave absorption in C band. Nano Res., 2023, 16(1): 1773.

[8]	L.J. Rao, L. Wang, C.D. Yang, et al., Confined diffusion strategy for customizing magnetic coupling spaces to enhance low-frequency electromagnetic wave absorption, Adv. Funct. Mater., 33(2023), No. 16, art. No. 2213258.

[9]	Li C, Qi XS, Gong X, et al.. Magnetic-dielectric synergy and interfacial engineering to design yolk-shell structured CoNi@void@C and CoNi@void@C@MoS₂ nanocomposites with tunable and strong wideband microwave absorption. Nano Res., 2022, 15(7): 6761.

[10]	C.L. Lei and Y.W. Du, Tunable dielectric loss to enhance microwave absorption properties of flakey FeSiAl/ferrite composites, J. Alloys Compd., 822(2020), art. No. 153674.

[11]	R.W. Shu, J.B. Zhang, C.L. Guo, et al., Facile synthesis of nitrogen-doped reduced graphene oxide/nickel–zinc ferrite composites as high-performance microwave absorbers in the X-band, Chem. Eng. J., 384(2020), art. No. 123266.

[12]	Wang LX, Guan YK, Qiu X, et al.. Efficient ferrite/Co/porous carbon microwave absorbing material based on ferrite@metal–organic framework. Chem. Eng. J., 2017, 326: 945.

[13]	Chen XT, Wu Y, Gu WH, et al.. Research progress on nanostructure design and composition regulation of carbon spheres for the microwave absorption. Carbon, 2022, 189: 617.

[14]	Qiu X, Wang LX, Zhu HL, Guan YK, Zhang QT. Lightweight and efficient microwave absorbing materials based on walnut shell-derived nano-porous carbon. Nanoscale, 2017, 9(22): 7408.

[15]	X. Li, L.M. Yu, W.K. Zhao, et al., Prism-shaped hollow carbon decorated with polyaniline for microwave absorption, Chem. Eng. J., 379(2020), art. No. 122393.

[16]	L. Wang, X.F. Yu, X. Li, J. Zhang, M. Wang, and R.C. Che, MOF-derived yolk–shell Ni@C@ZnO Schottky contact structure for enhanced microwave absorption, Chem. Eng. J., 383(2020), art. No. 123099.

[17]	Wang MM, Wang RM, Dai HY, et al.. The effects of hot isostatic pressing temperature on the structure and properties in GdMnO₃ ceramics. Ceram. Int., 2022, 48(3): 3685.

[18]	J.E. Wang, W. Ming, L.F. Chen, et al., MoS₂ lubricate-toughened MXene/ANF composites for multifunctional electromagnetic interference shielding, Nano Micro Lett., 17(2025), No. 1, art. No. 36.

[19]	H.Y. Dai, H.Z. Liu, K. Peng, et al., Correlation between vacancy defects and magnetic properties of the GdMn_1−xZn_xO₃ multiferroic ceramics studied by positron annihilation, Mater. Res. Bull., 119(2019), art. No. 110565.

[20]	Yan FF, Liu ZY, Chen J, et al.. Modulating the structure, vacancy defects, magnetic and dielectric properties in multiferroic GdMnO₃ ceramics by alkaline earth ion substitution. Ceram. Int., 2022, 48(22): 33135.

[21]	D.L. Tan, Q. Wang, M.R. Li, et al., Magnetic media synergistic carbon fiber@Ni/NiO composites for high-efficiency electromagnetic wave absorption, Chem. Eng. J., 492(2024), art. No. 152245.

[22]	J.Q. Wang, L. Liu, S.L. Jiao, K.J. Ma, J. Lv, and J.J. Yang, Hierarchical carbon fiber@MXene@MoS₂ core-sheath synergistic microstructure for tunable and efficient microwave absorption, Adv. Funct. Mater., 30(2020), No. 45, art. No. 2002595.

[23]	J.Q. Wang, Z. Wu, Y.Q. Xing, B.J. Li, P. Huang, and L. Liu, Multi-scale design of ultra-broadband microwave metamaterial absorber based on hollow carbon/MXene/Mo₂C microtube, Small, 19(2023), No. 14, art. No. 2207051.

[24]	Zou Z, Ning MQ, Lei ZK, et al.. 0D/1D/2D architectural Co@C/MXene composite for boosting microwave attenuation performance in 2–18 GHz. Carbon, 2022, 193: 182.

[25]	Wang JE, Song TL, Ming W, et al.. High MXene loading, nacre-inspired MXene/ANF electromagnetic interference shielding composite films with ultralong strain-to-failure and excellent Joule heating performance. Nano Res., 2024, 17(3): 2061.

[26]	Y.F. He, Q. Su, D.D. Liu, et al., Surface engineering strategy for MXene to tailor electromagnetic wave absorption performance, Chem. Eng. J., 491(2024), art. No. 152041.

[27]	Gao S, Zhang GZ, Wang Y, Han XP, Huang Y, Liu PB. MOFs derived magnetic porous carbon microspheres constructed by core-shell Ni@C with high-performance microwave absorption. J. Mater. Sci. Technol., 2021, 88: 56.

[28]	P.B. Liu, S. Gao, G.Z. Zhang, Y. Huang, W.B. You, and R.C. Che, Hollow engineering to Co@N-doped carbon nanocages via synergistic protecting-etching strategy for ultrahigh microwave absorption, Adv. Funct. Mater., 31(2021), No. 27, art. No. 2102812.

[29]	Lei L, Yao ZJ, Zhou JT, et al.. Hydrangea-like Ni/NiO/C composites derived from metal–organic frameworks with superior microwave absorption. Carbon, 2021, 173: 69.

[30]	Xue W, Yang G, Bi S, Zhang JY, Hou ZL. Construction of caterpillar-like hierarchically structured Co/MnO/CNTs derived from MnO₂/ZIF-8@ZIF-67 for electromagnetic wave absorption. Carbon, 2021, 173: 521.

[31]	C.H. Sun, D. Lan, Z.R. Jia, Z.G. Gao, and G.L. Wu, Kirkendall effect-induced ternary heterointerfaces engineering for high polarization loss MOF–LDH–MXene absorbers, Small, 20(2024), No. 48, art. No. e2405874.

[32]	Wang MM, Wang RM, Dai HY, et al.. A comparative study of the structure, defects, optical, dielectric, and magnetic properties of GdMnO₃ multiferroic ceramics synthesized by solid-state reaction and sol–gel methods. Ceram. Int., 2022, 48(15): 21622.

[33]	Dai HY, Ye FJ, Chen ZP, Li T, Liu DW. The effect of ion doping at different sites on the structure, defects and multi-ferroic properties of BiFeO₃ ceramics. J. Alloys Compd., 2018, 734: 60.

[34]	Dai HY, Chen ZP, Li T, Li Y. Microstructure and properties of Sm-substituted BiFeO₃ ceramics. J. Rare Earths, 2012, 30(11): 1123.

[35]	X.M. Zhang, Y. Fan, J.Y. Wang, et al., Enhanced microwave absorption performance of nitrogen-doped porous carbon dodecahedrons composite embedded with ceric dioxide, Adv. Powder Technol., 33(2022), No. 4, art. No. 103527.

[36]	W.H. Huang, W. Wang, C.Y. Su, M. Song, Y.F. Kang, and G.Q. Fei, Hetero-interface engineering on 9.0wt% CoO_x–doped CeO₂ nanorods as electromagnetic wave absorber and integrated into multifunctional aerogel, Small, 20 (2024), No. 32, art. No. 2311389.

[37]	Sun CH, Jia ZR, Xu S, Hu DQ, Zhang CH, Wu GL. Synergistic regulation of dielectric-magnetic dual-loss and triple heterointerface polarization via magnetic MXene for high-performance electromagnetic wave absorption. J. Mater. Sci. Technol., 2022, 113: 128.

[38]	Shen ZY, Xing HL, Wang H, et al.. Synthesis and enhanced electromagnetic absorption properties of Co-doped CeO₂/RGO nanocomposites. J. Alloys Compd., 2018, 753: 28.

[39]	W.T. Qi, W. Jiang, F. Xu, J.B. Jia, C. Yang, and B.Q. Cao, Improving confinement and redox kinetics of polysufides through hollow NC@CeO₂ nanospheres for high-performance lithium-sulfur batteries, Chem. Eng. J., 382(2020), art. No. 122852.

[40]	Wu ZC, Yang ZQ, Jin C, Zhao YH, Che RC. Accurately engineering 2D/2D/0D heterojunction in hierarchical Ti₃C₂T_x MXene nanoarchitectures for electromagnetic wave absorption and shielding. ACS Appl. Mater. Interfaces, 2021, 13(4): 5866.

[41]	H.Y. Wang, X.B. Sun, S.H. Yang, et al., 3D ultralight hollow NiCo compound@MXene composites for tunable and high-efficient microwave absorption, Nano Micro Lett., 13(2021), No. 1, art. No. 206.

[42]	M.Q. Huang, L. Wang, K. Pei, et al., Multidimension-controllable synthesis of MOF-derived Co@N-doped carbon composite with magnetic-dielectric synergy toward strong microwave absorption, Small, 16(2020), No. 14, art. No. 2000158.

[43]	Z. Su, S. Yi, W.Y. Zhang, et al., Ultrafine vacancy-rich Nb₂O₅ semiconductors confined in carbon nanosheets boost dielectric polarization for high-attenuation microwave absorption, Nano Micro Lett., 15(2023), No. 1, art. No. 183.

[44]	Liu Y, Ren XY, Zhou XF, et al.. Defect design and vacancy engineering of NiCo₂Se₄ spinel composite for excellent electromagnetic wave absorption. Ceram. Int., 2024, 50(22): 46643.

[45]	R.W. Shu, X.H. Yang, and Z.W. Zhao, Fabrication of core-shell structure NiFe₂O₄@SiO₂ decorated nitrogen-doped graphene composite aerogels towards excellent electromagnetic absorption in the Ku band, Carbon, 210(2023), art. No. 118047.

[46]	Pang HF, Duan YP, Dai XH, et al.. The electromagnetic response of composition-regulated honeycomb structural materials used for broadband microwave absorption. J. Mater. Sci. Technol., 2021, 88: 203.

[47]	Y.H. Zou, L.Y. Jiang, S.C. Wen, et al., Enhancing and tuning absorption properties of microwave absorbing materials using metamaterials, Appl. Phys. Lett., 93(2008), No. 26, art. No. 261115.

[48]	Huang YX, Song WL, Wang CX, et al.. Multi-scale design of electromagnetic composite metamaterials for broadband microwave absorption. Compos. Sci. Technol., 2018, 162: 206.

[49]	D.W. Hu, J. Cao, W. Li, et al., Optically transparent broadband microwave absorption metamaterial by standing-up closed-ring resonators, Adv. Opt. Mater., 5(2017), No. 13, art. No. 1700109.