References(59)
[1]
Z Chen, ZF Chen, ZG Yang, et al. Preparation and characterization of vacuum insulation panels with super-stratified glass fiber core material. Energy 2015, 93: 945-954.
[2]
J Tang, HM Meng, LL Huang. Energy-saving and environmentally friendly electrodeposition of γ-MnO2. RSC Adv 2014, 4: 16512-16516.
[3]
S Chu, A Majumdar. Opportunities and challenges for a sustainable energy future. Nature 2012, 488: 294-303.
[4]
ZP Chen, C Xu, CQ Ma, et al. Lightweight and flexible graphene foam composites for high-performance electromagnetic interference shielding. Adv Mater 2013, 25: 1296-1300.
[5]
WY Duan, XW Yin, Q Li, et al. A review of absorption properties in silicon-based polymer derived ceramics. J Eur Ceram Soc 2016, 36: 3681-3689.
[6]
Q Li, XW Yin, WY Duan, et al. Electrical, dielectric and microwave-absorption properties of polymer derived SiC ceramics in X band. J Alloys Compd 2013, 565: 66-72.
[7]
WY Duan, XW Yin, CJ Luo, et al. Microwave-absorption properties of SiOC ceramics derived from novel hyperbranched ferrocene-containing polysiloxane. J Eur Ceram Soc 2017, 37: 2021-2030.
[8]
P Wang, LF Cheng, LT Zhang. One-dimensional carbon/ SiC nanocomposites with tunable dielectric and broadband electromagnetic wave absorption properties. Carbon 2017, 125: 207-220.
[9]
B Wen, MS Cao, ZL Hou, et al. Temperature dependent microwave attenuation behavior for carbon-nanotube/silica composites. Carbon 2013, 65: 124-139.
[10]
B Zhong, TQ Sai, L Xia, et al. High-efficient production of SiC/SiO2 core-shell nanowires for effective microwave absorption. Mater Des 2017, 121: 185-193.
[11]
XH Liang, B Quan, GB Ji, et al. Novel nanoporous carbon derived from metal-organic frameworks with tunable electromagnetic wave absorption capabilities. Inorg Chem Front 2016, 3: 1516-1526.
[12]
S He, GS Wang, C Lu, et al. Controllable fabrication of CuS hierarchical nanostructures and their optical, photocatalytic, and wave absorption properties. ChemPlusChem 2013, 78: 250-258.
[13]
XY Yuan, LF Cheng, SW Guo, et al. High-temperature microwave absorbing properties of ordered mesoporous inter-filled SiC/SiO2 composites. Ceram Int 2017, 43: 282-288.
[14]
P Wang, LF Cheng, YN Zhang, et al. Flexible, hydrophobic SiC ceramic nanofibers used as high frequency electromagnetic wave absorbers. Ceram Int 2017, 43: 7424-7435.
[15]
GM Li, LC Wang, WX Li, et al. CoFe2O4 and/or Co3Fe7 loaded porous activated carbon balls as a lightweight microwave absorbent. Phys Chem Chem Phys 2014, 16: 12385-12392.
[16]
B Zhao, G Shao, BB Fan, et al. Fabrication and enhanced microwave absorption properties of Al2O3 nanoflake-coated Ni core-shell composite microspheres. RSC Adv 2014, 4: 57424-57429.
[17]
Y Cheng, YH Guo, ZY Zhang, et al. Facile synthesis of NixCo3-xS4 hollow nanoprism with broader electromagnetic absorption properties: Effect of Ni/Co atomic ratios. J Alloys Compd 2018, 767: 323-329.
[18]
F Moglie, D Micheli, S Laurenzi, et al. Electromagnetic shielding performance of carbon foams. Carbon 2012, 50: 1972-1980.
[19]
Y Zhang, Y Huang, TF Zhang, et al. Broadband and tunable high-performance microwave absorption of an ultralight and highly compressible graphene foam. Adv Mater 2015, 27: 2049-2053.
[20]
R Kumar, SR Dhakate, T Gupta, et al. Effective improvement of the properties of light weight carbon foam by decoration with multi-wall carbon nanotubes. J Mater Chem A 2013, 1: 5727-5735.
[21]
ZG Fang, XM Cao, CS Li, et al. Investigation of carbon foams as microwave absorber: Numerical prediction and experimental validation. Carbon 2006, 44: 3368-3370.
[22]
M Crespo, M González, AL Elías, et al. Ultra-light carbon nanotube sponge as an efficient electromagnetic shielding material in the GHz range. Phys Status Solidi RRL 2014, 8: 698-704.
[23]
Y Li, B Shen, XL Pei, et al. Ultrathin carbon foams for effective electromagnetic interference shielding. Carbon 2016, 100: 375-385.
[24]
J Yang, ZM Shen, ZB Hao. Microwave characteristics of sandwich composites with mesophase pitch carbon foams as core. Carbon 2004, 42: 1882-1885.
[25]
XW Zhu, DL Jiang, SH Tan. Microwave absorbing property of SiC reticulated porous ceramics. J Inorg Mater 2002, 17: 1152-1156. (in Chinese)
[26]
HT Zhang, JS Zhang, HY Zhang. Computation of radar absorbing silicon carbide foams and their silica matrix composites. Comput Mater Sci 2007, 38: 857-864.
[27]
HD Huang, CY Liu, D Zhou, et al. Cellulose composite aerogel for highly efficient electromagnetic interference shielding. J Mater Chem A 2015, 3: 4983-4991.
[28]
AM Xie, F Wu, MX Sun, et al. Self-assembled ultralight three-dimensional polypyrrole aerogel for effective electromagnetic absorption. Appl Phys Lett 2015, 106: 222902.
[29]
K Chen, XH Li, DS Lv, et al. Study on microwave absorption properties of metal-containing foam glass. Mater Sci Eng B 2011, 176: 1239-1242.
[30]
YF He, RZ Gong. Preparation and microwave absorption properties of foam-based honeycomb sandwich structures. Europhys Lett 2009, 85: 58003.
[31]
S Wang, N Xiao, Y Zhou, et al. Lightweight carbon foam from coal liquefaction residue with broad-band microwave absorbing capability. Carbon 2016, 105: 224-226.
[32]
CQ Song, XW Yin, MK Han, et al. Three-dimensional reduced graphene oxide foam modified with ZnO nanowires for enhanced microwave absorption properties. Carbon 2017, 116: 50-58.
[33]
SC Chiu, HC Yu, YY Li. High electromagnetic wave absorption performance of silicon carbide nanowires in the gigahertz range. J Phys Chem C 2010, 114: 1947-1952.
[34]
HT Liu, HF Cheng, J Wang, et al. Dielectric properties of the SiC fiber-reinforced SiC matrix composites with the CVD SiC interphases. J Alloys Compd 2010, 491: 248-251.
[35]
WY Duan, XW Yin, FX Cao, et al. Absorption properties of twinned SiC nanowires reinforced Si3N4 composites fabricated by 3D-prining. Mater Lett 2015, 159: 257-260.
[36]
RB Wu, Y Pan, GY Yang, et al. Twinned SiC zigzag nanoneedles. J Phys Chem C 2007, 111: 6233-6237.
[37]
WY Duan, XW Yin, Q Li, et al. Synthesis and microwave absorption properties of SiC nanowires reinforced SiOC ceramic. J Eur Ceram Soc 2014, 34: 257-266.
[38]
LX Wen, YJ Ma, B Dai, et al. Preparation and dielectric properties of SiC nanowires self-sacrificially templated by carbonated bacterial cellulose. Mater Res Bull 2013, 48: 687-690.
[39]
ZM Li, WC Zhou, XL Su, et al. Effect of boron doping on microwave dielectric properties of SiC powder synthesized by combustion synthesis. J Alloys Compd 2011, 509: 973-976.
[40]
Y Mu, WC Zhou, Y Hu, et al. Enhanced microwave absorbing properties of 2.5D SiCf/SiC composites fabricated by a modified precursor infiltration and pyrolysis process. J Alloys Compd 2015, 637: 261-266.
[41]
XL Su, WC Zhou, J Xu, et al. Preparation and dielectric property of B and N-codoped SiC powder by combustion synthesis. J Alloys Compd 2013, 551: 343-347.
[42]
SS Xiao, H Mei, DY Han, et al. Ultralight lamellar amorphous carbon foam nanostructured by SiC nanowires for tunable electromagnetic wave absorption. Carbon 2017, 122: 718-725.
[43]
Q Li, XW Yin, WY Duan, et al. Improved dielectric and electromagnetic interference shielding properties of ferrocene-modified polycarbosilane derived SiC/C composite ceramics. J Eur Ceram Soc 2014, 34: 2187-2201.
[44]
S Dong, WZ Zhang, XH Zhang, et al. Designable synthesis of core-shell SiCw@C heterostructures with thickness-dependent electromagnetic wave absorption between the whole X-band and Ku-band. Chem Eng J 2018, 354: 767-776.
[45]
XL Ye, ZF Chen, SF Ai, et al. Effect of thickness of SiC films on compression and thermal properties of SiC/CF composites. Ceramic Int 2019, 45: 4674-4679.
[46]
XL Ye, ZF Chen, SF Ai, et al. Synthesis and microwave absorption properties of novel reticulation SiC/Porous melamine-derived carbon foam. J Alloys Compd 2019, 791: 883-891.
[47]
M Inagaki, JS Qiu, QG Guo. Carbon foam: Preparation and application. Carbon 2015, 87: 128-152.
[48]
ZG Fang, CS Li, JY Sun, et al. The electromagnetic characteristics of carbon foams. Carbon 2007, 45: 2873-2879.
[49]
YC Ge, YQ Liu, S Wu, et al. Characterization of SiC nanowires prepared on C/C composite without catalyst by CVD. Trans Nonferrous Met Soc China 2015, 25: 3258-3264.
[50]
B Zhao, G Shao, BB Fan, et al. Facile synthesis and enhanced microwave absorption properties of novel hierarchical heterostructures based on a Ni microsphere-CuO nano-rice core-shell composite. Phys Chem Chem Phys 2015, 17: 6044-6052.
[51]
P Wang, LF Cheng, YN Zhang, et al. Electrospinning of graphite/SiC hybrid nanowires with tunable dielectric and microwave absorption characteristics. Compos Part Appl Sci Manuf 2018, 104: 68-80.
[52]
S Dong, P Hu, XH Zhang, et al. Carbon foams modified with in situ formation of Si3N4 and SiC for enhanced electromagnetic microwave absorption property and thermostability. Ceram Int 2018, 44: 7141-7150.
[53]
W Liu, SJ Tan, ZH Yang, et al. Hollow graphite spheres embedded in porous amorphous carbon matrices as lightweight and low-frequency microwave absorbing material through modulating dielectric loss. Carbon 2018, 138: 143-153.
[54]
WH Gu, B Quan, XH Liang, et al. Composition and structure design of Co3O4 nanowires network by nickel foam with effective electromagnetic performance in C and X band. ACS Sustain Chem Eng 2019, 7: 5543-5552.
[55]
XH Liang, B Quan, GB Ji, et al. Novel nanoporous carbon derived from metal-organic frameworks with tunable electromagnetic wave absorption capabilities. Inorg Chem Front 2016, 3: 1516-1526.
[56]
XH Liang, XM Zhang, W Liu, et al. A simple hydrothermal process to grow MoS2 nanosheets with excellent dielectric loss and microwave absorption performance. J Mater Chem C 2016, 4: 6816-6821.
[57]
H Lv, XH Liang, GB Ji, et al. Porous three-dimensional flower-like Co/CoO and its excellent electromagnetic absorption properties. ACS Appl Mater Interfaces 2015, 7: 9776-9783.
[58]
XH Liang, B Quan, YS Sun, et al. Multiple interfaces structure derived from metal-organic frameworks for excellent electromagnetic wave absorption. Part Part Syst Charact 2017, 34: 1700006.
[59]
JY Fang, T Liu, Z Chen, et al. A wormhole-like porous carbon/magnetic particles composite as an efficient broadband electromagnetic wave absorber. Nanoscale 2016, 8: 8899-8909.