[1] Y XIA, W GAO, C GAO. A review on graphene-based electromagnetic functional materials: electromagnetic wave shielding and absorption. Advanced Functional Materials, 32, 2204591(2022).
[2] R ZHOU, Y WANG, Z LIU et al. Digital light processing 3D-printed ceramic metamaterials for electromagnetic wave absorption. Nano-Micro Letters, 14: 122(2022).
[3] Z ZOU, M NING, Z LEI et al. 0D/1D/2D architectural Co@C/MXene composite for boosting microwave attenuation performance in 2-18 GHz. Carbon(2022).
[4] M QIAO, J QI, J WANG et al. Recent progress on 3D graphene aerogel based microwave absorbing materials. Acta Materiae Compositae Sinica, 41, 550(2024).
[5] Y SONG, P LIU, R ZHOU et al. SiBNC
[6] Y SONG, S JIN, K HU et al. Adjustable iron-containing SiBCN ceramics with high temperature microwave absorption and anti-oxidation properties. Journal of the American Ceramic Society, 104: 5244(2021).
[7] P CHEN, J CHEN, C WANG et al. The heterointerface of graphene
[8] R ANAND, K LU, B B NAYAK et al. Structural evolution and oxidation resistance of polysilazane-derived SiCN-HfO2 ceramics. Journal of the American Ceramic Society, 107, 1657(2024).
[9] Q XIA, Z HAN, Z ZHANG et al. High temperature microwave absorbing materials. Journal of Materials Chemistry C, 11, 4552(2023).
[10] X JIAO, Q HE, M QING et al. Ablation behavior of C/C-Zr1-
[11] B REN, Y DENG, Y JIA et al. Achieving broadband electromagnetic absorption at a wide temperature range up to 1273 K by metamaterial design on polymer-derived SiC-BN@CNT ceramic composites. Chemical Engineering Journal, 478: 147251(2023).
[12] J SHEN, Z TANG, R TUSIIME et al. Effects of hafnium sources and hafnium content on the structures and properties of SiBNC-Hf ceramic precursors. Journal of the American Ceramic Society, 106, 3239(2023).
[13] Y SONG, Z LIU, X ZHANG et al. Single source precursor derived SiBCNHf ceramic with enhanced high-temperature microwave absorption and antioxidation. Journal of Materials Science & Technology, 126: 215(2022).
[14] C SUN, H WANG, X ZHOU. Research progress on ultra-high temperature ceramics powder prepared by precursor-derived method. Bulletin of the Chinese Ceramic Society, 42, 2865(2023).
[15] Z ZHAO, C HAN, X WANG et al. Synthesis and pyrolysis of Hf-N-B backbone polymer precursor for HfC/HfB2 composite ceramics. Journal of the American Ceramic Society, 107, 3424(2024).
[16] X ZHANG, J SUN, Y ZHANG et al. Microstructure and phase evolution of polymer-derived SiHfOC ceramic microspheres. Journal of the American Ceramic Society, 105, 7726(2022).
[17] M ZHANG, X FAN, F YE et al. Synthesis, microstructure and electromagnetic properties of Hf-based SiBCN ceramics. Ceramics International, 49, 19664(2023).
[18] L SONG, C WU, Q ZHI et al. Multifunctional SiC aerogel reinforced with nanofibers and nanowires for high-efficiency electromagnetic wave absorption. Chemical Engineering Journal, 467: 143518(2023).
[19] X LIU, Z YU, R ISHIKAWA et al. Single-source-precursor synthesis and electromagnetic properties of novel RGO-SiCN ceramic nanocomposites. Journal of Materials Chemistry C, 5, 7950(2017).
[20] Q CHEN, D LI, Z YANG et al. SiBCN-reduced graphene oxide (rGO) ceramic composites derived from single-source-precursor with enhanced and tunable microwave absorption performance. Carbon, 179: 180(2021).
[21] Y HOU, B XIAO, G YANG et al. Enhanced electromagnetic wave absorption performance of novel carbon-coated Fe3Si nanoparticles in an amorphous SiCO ceramic matrix. Journal of Materials Chemistry C, 6, 7661(2018).
[22] Y ZHANG, J SUN, Y WANG et al. SiCN ceramics with controllable carbon nanomaterials for electromagnetic absorption performance. Journal of the American Ceramic Society, 106, 4220(2023).
[23] G ZENG, P XU, C ZENG et al. Preparation of HfC
[24] J SUN, Q WEN, T LI et al. Phase evolution of SiOC-based ceramic nanocomposites derived from a polymethylsiloxane modified by Hf- and Ti-alkoxides. Journal of the American Ceramic Society, 103, 1436(2020).
[25] S S NADAR, V K RATHOD. One pot synthesis of
[26] M NOROUZI, D ELHAMIFAR, R MIRBAGHERI. Phenylene- based periodic mesoporous organosilica supported melamine: an efficient, durable and reusable organocatalyst. Microporous and Mesoporous Materials, 278: 251(2019).
[27] H WANG, W ZHU, X SUN et al. Preparation of aerogel-like SiOC ceramic with honeycomb structure and its high-temperature performance. Journal of Alloys and Compounds, 937: 168438(2023).
[28] C WU, B WANG, N WU et al. Molecular-scale understanding on the structure evolution from melamine diborate supramolecule to boron nitride fibers. Ceramics International, 46, 1083(2020).
[29] A H TAVAKOLI, P GERSTEL, J A GOLCZEWSKI et al. Kinetic effect of boron on the thermal stability of Si-(B-)C-N polymer- derived ceramics. Acta Materialia, 58, 6002(2010).
[30] Y CHENG, L HU, K ZHANG et al. Facile synthesis of hollow SiC/C nanospheres for high-performance electromagnetic wave absorption. Carbon, 215: 118391(2023).
[31] A C FERRARI, J ROBERTSON. Interpretation of Raman spectra of disordered and amorphous carbon. Physical Review B, 61, 14095(2000).
[33] C ZHONG, Y HOU, W YANG et al. Carbon rich SiOC fibres derived from ceramic precursor for microwave absorption. Journal of Ceramics, 44, 703(2023).
[34] L PANG, H LUO, X FAN et al. Electromagnetic wave absorbing performance of multiphase (SiC/HfC/C)/SiO2 nanocomposites with an unique microstructure. Journal of the European Ceramic Society, 41, 2425(2021).
[35] C LUO, P MIAO, Y TANG et al. Excellent electromagnetic wave absorption of MOF/SiBCN nanomaterials at high temperature. Chinese Journal of Aeronautics, 34, 277(2020).
[36] R PAN, G CHEN, X YU et al. Densification, microstructure and mechanical properties of Ta4HfC5-based ceramics obtained from synthesized nanoscale powder. Journal of the European Ceramic Society, 41, 2247(2021).
[37] Y JIA, T D AJAYI, K R RAMAKRISHNAN et al. A skin layer made of cured polysilazane and yttria stabilized zirconia for enhanced thermal protection of carbon fiber reinforced polymers (CFRPs). Surface and Coatings Technology, 404: 126481(2020).
[38] G ZENG, X LI, Y WEI et al. Significantly toughened SiC foams with enhanced microwave absorption
[39] C WANG, P CHEN, X LI et al. Enhanced electromagnetic wave absorption for Y2O3-doped SiBCN ceramics. ACS Applied Materials & Interfaces, 13: 55440(2021).
[40] X ZHOU, H HAN, Y WANG et al. Silicon-coated fibrous network of carbon nanotube/iron towards stable and wideband electromagnetic wave absorption. Journal of Materials Science & Technology, 121: 199(2022).
[41] D ZHI, T LI, Z QI et al. Core-shell heterogeneous graphene-based aerogel microspheres for high-performance broadband microwave absorption
[42] L YAO, W YANG, S ZHOU et al. Design paradigm for strong-lightweight perfect microwave absorbers: the case of 3D printed gyroid shellular SiOC-based metamaterials. Carbon, 196: 961(2022).
[43] H YU, X KOU, X ZUO et al. Optimization of multiple attenuation mechanisms by cation substitution in imidazolic MOFs-derived porous composites for superior broadband electromagnetic wave absorption. Journal of Materials Science & Technology, 176: 176(2024).
[44] S YANG, L TANG, H WEI et al. In-situ construction of volcanic rock-like structures in Yb2O3 modified reduced graphene oxide and their boosted electromagnetic wave absorbing properties. Carbon, 215: 118445(2023).
