Electromagnetic wave (EMW)-absorbing materials can effectively mitigate the issues arising from the development of electromagnetic technology, such as electromagnetic radiation, communication interference and information leakage. Fiber materials, with the advantages of lightweight, high aspect ratio and pronounced mechanical properties, can enhance the scattering effect and transmission path of EMWs at reduced working thicknesses. Significant research efforts have been dedicated to fiber component modulation and microstructure design toward enhancing the effective absorption bandwidth and the dissipation of EMWs. This review summarizes the recent developments in EMW-absorbing fibers, including their absorption mechanisms, preparation methods, performance optimization and structural design. For inorganic EMW-absorbing fibers, their inherent dielectric properties allow the matrix to absorb EMWs, while doping with additional components further enhances impedance matching. In contrast, organic fibers, which generally lack intrinsic EMW-absorbing capabilities, require hybridization with various organic or inorganic functional materials and structural modifications to optimize EMW-absorbing performance. Finally, emerging trends and ongoing challenges in the development of EMW-absorbing fibers are discussed, with the goal of promoting their practical applications. This review gives new insights into the research of EMW-absorbing fibers and fabrics, which will significantly relieve the imminent concerns regarding electromagnetic radiation.
| [1] |
ZhaoZ, ZhangL, WuH. Hydro/organo/ionogels: “controllable” electromagnetic wave absorbers. Adv Mater, 2022, 34: 2205376.
|
| [2] |
HuZ, JiX, LiB, LuoY. A self-assembled graphene/polyurethane sponge for excellent electromagnetic interference shielding performance. RSC Adv, 2019, 9: 25829-25835.
|
| [3] |
IqbalA, ShahzadF, HantanasirisakulK, KimMK, KwonJ, HongJ, KimH, KimD, GogotsiY, KooCM. Anomalous absorption of electromagnetic waves by 2D transition metal carbonitride Ti3CNTx (MXene). Science, 2020, 369: 446-450.
|
| [4] |
CaoM, HanC, WangX, ZhangM, ZhangY, ShuJ, YangH, FangX, YuanJ. Graphene nanohybrids: excellent electromagnetic properties for the absorbing and shielding of electromagnetic waves. J Mater Chem C, 2018, 6: 4586-4602.
|
| [5] |
ZhangXC, ZhangM, WangMQ, ChangL, LiL, CaoMS. Metal single-atoms toward electromagnetic wave-absorbing materials: insights and perspective. Adv Funct Mater, 2024.
|
| [6] |
HuaJ, LiY, LiuX, LiX, LinS, GuJ, CuiZ-K, ZhuangQ. Graphene/MWNT/poly(p-phenylenebenzobisoxazole) multiphase nanocomposite via solution prepolymerization with superior microwave absorption properties and thermal stability. J Phys Chem C, 2017, 121: 1072-1081.
|
| [7] |
ZhouC, GengS, XuX, WangT, ZhangL, TianX, YangF, YangH, LiY. Lightweight hollow carbon nanospheres with tunable sizes towards enhancement in microwave absorption. Carbon, 2016, 108: 234-241.
|
| [8] |
ShahzadF, AlhabebM, HatterCB, AnasoriB, Man HongS, KooCM, GogotsiY. Electromagnetic interference shielding with 2D transition metal carbides (MXenes). Science, 2016, 353: 1137-1140.
|
| [9] |
QuanL, QinFX, EstevezD, WangH, PengHX. Magnetic graphene for microwave absorbing application: towards the lightest graphene-based absorber. Carbon, 2017, 125: 630-639.
|
| [10] |
WuZ, ChengH, JinC, YangB, XuC, PeiK, ZhangH, YangZ, CheR. Dimensional design and core-shell engineering of nanomaterials for electromagnetic wave absorption. Adv Mater, 2022, 34: 2107538.
|
| [11] |
LiQ, ZhangZ, QiL, LiaoQ, KangZ, ZhangY. Toward the application of high frequency electromagnetic wave absorption by carbon nanostructures. Adv Sci, 2019, 6: 1801057.
|
| [12] |
QinM, ZhangL, ZhaoX, WuH. Lightweight Ni foam-based ultra-broadband electromagnetic wave absorber. Adv Funct Mater, 2021, 31: 2103436.
|
| [13] |
ChengJ, ZhangH, NingM, RazaH, ZhangD, ZhengG, ZhengQ, CheR. Emerging materials and designs for low- and multi-band electromagnetic wave absorbers: The search for dielectric and magnetic synergy?. Adv Funct Mater, 2022, 32: 2200123.
|
| [14] |
QiangR, DuY, ZhaoH, WangY, TianC, LiZ, HanX, XuP. Metal organic framework-derived Fe/C nanocubes toward efficient microwave absorption. J Mater Chem A, 2015, 3: 13426-13434.
|
| [15] |
WangY, XiuZ, MengN, YangL, LuW, YeC, LiaoY. Conjugated microporous polymer-derived nitrogen-doped carbon nanocomposites with multiple magnetic components for broadband microwave absorption. ACS Appl Nano Mater, 2024.
|
| [16] |
DingD, WangY, LiX, QiangR, XuP, ChuW, HanX, DuY. Rational design of core-shell Co@C microspheres for high-performance microwave absorption. Carbon, 2017, 111: 722-732.
|
| [17] |
GaoS, YangS-H, WangH-Y, WangG-S, YinP-G, ZhangX-J. CoNi alloy with tunable magnetism encapsulated by N-doped carbon nanosheets toward high-performance microwave attenuation. Compos B Eng, 2021, 215. 108781
|
| [18] |
BhattacharjeeY, AriefI, BoseS. Recent trends in multi-layered architectures towards screening electromagnetic radiation: challenges and perspectives. J Mater Chem C, 2017, 5: 7390-7403.
|
| [19] |
DuanW, LiX, WangY, QiangR, TianC, WangN, HanX, DuY. Surface functionalization of carbonyl iron with aluminum phosphate coating toward enhanced anti-oxidative ability and microwave absorption properties. Appl Surf Sci, 2018, 427: 594-602.
|
| [20] |
LiuQ, CaoQ, BiH, LiangC, YuanK, SheW, YangY, CheR. CoNi@SiO2@TiO2 and CoNi@Air@TiO2 microspheres with strong wideband microwave absorption. Adv Mater, 2015, 28: 486-490.
|
| [21] |
YanF, GuoD, ZhangS, LiC, ZhuC, ZhangX, ChenY. An ultra-small NiFe2O4 hollow particle/graphene hybrid: fabrication and electromagnetic wave absorption property. Nanoscale, 2018, 10: 2697-2703.
|
| [22] |
XieW, ZhuX, YiS, KuangJ, ChengH, TangW, DengY. Electromagnetic absorption properties of natural microcrystalline graphite. Mater Des, 2016, 90: 38-46.
|
| [23] |
ShiY, LiD, WeiY, GongC, ZhangJ. Magnetic TiN composites for efficient microwave absorption: Nanoribbons vs nanoparticles. Compos Commun, 2021, 28. 100919
|
| [24] |
ZhaoS, RefaaiMRA, SalmanS, AkhtarMN, DuK. Investigations of physicochemical and microwave absorption performance of NiCo2S4/AgBr nanocomposite in X-band frequency. Surf Interfaces, 2023, 37. 102684
|
| [25] |
Hashira NarudinN, AbdullahH, Nasir TaibM, Abdul HadiB, Mohd KasimL, Mohd NoorN, IsmailA, AhmadA, MohdKN. The study of innovative anti-microwave brick walls by using POFA as partial cement replacement. Mater Today Proc, 2022, 48: 1947-1952.
|
| [26] |
SongX, LuY, SongD, LiuS, LuX. Electromagnetic absorption and corresponding mechanism of graphene oxide/γ-Fe2O3-UHPC composite sheet. J Mater Sci Mater Electron, 2022, 33: 5924-5937.
|
| [27] |
ZhengY, WangY. Electromagnetic-wave absorption properties of 3D-printed thermoplastic polyurethane/carbonyl iron powder composites. Polymers, 2022, 14: 4960.
|
| [28] |
BhattacharjeeY, ChatterjeeD, BoseS. Core-multishell heterostructure with excellent heat dissipation for electromagnetic interference shielding. ACS Appl Mater Interfaces, 2018, 10: 30762-30773.
|
| [29] |
QiaoM, LeiX, MaY, TianL, HeX, SuK, ZhangQ. Application of yolk–shell Fe3O4@N-doped carbon nanochains as highly effective microwave-absorption material. Nano Res, 2018, 11: 1500-1519.
|
| [30] |
XieX, ZhangB, WangQ, ZhaoX, WuD, WuH, SunX, HouC, YangX, YuR, ZhangS, MurugadossV, DuW. Efficient microwave absorber and supercapacitors derived from puffed-rice-based biomass carbon: effects of activating temperature. J Colloid Interface Sci, 2021, 594: 290-303.
|
| [31] |
SongS, ZhangA, ChenL, JiaQ, ZhouC, LiuJ, WangX. A novel multi-cavity structured MOF derivative/porous graphene hybrid for high performance microwave absorption. Carbon, 2021, 176: 279-289.
|
| [32] |
QiuX, WangL, ZhuH, GuanY, ZhangQ. Lightweight and efficient microwave absorbing materials based on walnut shell-derived nano-porous carbon. Nanoscale, 2017, 9: 7408-7418.
|
| [33] |
WuZ, TianK, HuangT, HuW, XieF, WangJ, SuM, LiL. Hierarchically porous carbons derived from biomasses with excellent microwave absorption performance. ACS Appl Mater Interfaces, 2018, 10: 11108-11115.
|
| [34] |
FengS, DengJ, YuL, DongY, ZhuY, FuY. Development of lightweight polypyrrole/cellulose aerogel composite with adjustable dielectric properties for controllable microwave absorption performance. Cellulose, 2020, 27: 10213-10224.
|
| [35] |
TingTH, YuRP, JauYN. Synthesis and microwave absorption characteristics of polyaniline/NiZn ferrite composites in 2–40GHz. Mater Chem Phys, 2011, 126: 364-368.
|
| [36] |
JiB, FanS, KouS, XiaX, DengJ, ChengL, ZhangL. Microwave absorption properties of multilayer impedance gradient absorber consisting of Ti3C2TX MXene/polymer films. Carbon, 2021, 181: 130-142.
|
| [37] |
YinX, LongC, LiJ, ZhuH, ChenL, GuanJ, LiX. Ultra-wideband microwave absorber by connecting multiple absorption bands of two different-sized hyperbolic metamaterial waveguide arrays. Sci Rep, 2015, 5: 15367.
|
| [38] |
WangL, LiX, ShiX, HuangM, LiX, ZengQ, CheR. Recent progress of microwave absorption microspheres by magnetic–dielectric synergy. Nanoscale, 2021, 13: 2136-2156.
|
| [39] |
MaM, LiaoZ, SuX, ZhengQ, LiuY, WangY, MaY, WanF. Magnetic CoNi alloy particles embedded N-doped carbon fibers with polypyrrole for excellent electromagnetic wave absorption. J Colloid Interface Sci, 2022, 608: 2203-2212.
|
| [40] |
DaiX, DuY, YangJ, WangD, GuJ, LiY, WangS, XuBB, KongJ. Recoverable and self-healing electromagnetic wave absorbing nanocomposites. Compos Sci Technol, 2019, 174: 27-32.
|
| [41] |
XiaY, GaoW, GaoC. A review on graphene-based electromagnetic functional materials: electromagnetic wave shielding and absorption. Adv Funct Mater, 2022, 32: 2204591.
|
| [42] |
LiangL, LiQ, YanX, FengY, WangY, ZhangHB, ZhouX, LiuC, ShenC, XieX. Multifunctional magnetic Ti(3)C(2)T(x) MXene/graphene aerogel with superior electromagnetic wave absorption performance. ACS Nano, 2021, 15: 6622-6632.
|
| [43] |
LiuJ, ZhangHB, XieX, YangR, LiuZ, LiuY, YuZZ. Multifunctional, superelastic, and lightweight MXene/polyimide aerogels. Small, 2018, 14. e1802479
|
| [44] |
DaiY, WuX, LiuZ, ZhangH-B, YuZ-Z. Highly sensitive, robust and anisotropic MXene aerogels for efficient broadband microwave absorption. Compos B Eng, 2020, 200. 108263
|
| [45] |
SongZ, LiuX, SunX, LiY, NieX, TangW, YuR, ShuiJ. Alginate-templated synthesis of CoFe/carbon fiber composite and the effect of hierarchically porous structure on electromagnetic wave absorption performance. Carbon, 2019, 151: 36-45.
|
| [46] |
MaM, LiW, TongZ, MaY, BiY, LiaoZ, ZhouJ, WuG, LiM, YueJ, SongX, ZhangX. NiCo2O4 nanosheets decorated on one-dimensional ZnFe2O4@SiO2@C nanochains with high-performance microwave absorption. J Colloid Interface Sci, 2020, 578: 58-68.
|
| [47] |
BhattacharjeeY, BoseS. Core-shell nanomaterials for microwave absorption and electromagnetic interference shielding: a review. ACS Appl Nano Mater, 2021, 4: 949-972.
|
| [48] |
DaiB, LiJ, WangW, LiuX, QiY, QiY. Carbon fibers with eddy current loss characteristics exhibit different microwave absorption properties in different graphitization states. Mater Lett, 2020, 281. 128667
|
| [49] |
MishraRK, MishraP, VermaK, MondalA, ChaudharyRG, AbolhasaniMM, LoganathanS. Electrospinning production of nanofibrous membranes. Environ Chem Lett, 2018, 17: 767-800.
|
| [50] |
WangXX, YuGF, ZhangJ, YuM, RamakrishnaS, LongYZ. Conductive polymer ultrafine fibers via electrospinning: Preparation, physical properties and applications. Prog Mater Sci, 2021, 115. 100704
|
| [51] |
XueJ, WuT, DaiY, XiaY. Electrospinning and electrospun nanofibers: methods, materials, and applications. Chem Rev, 2019, 119: 5298-5415.
|
| [52] |
QiuP, JinR, SonY, JuA, JiangW, WangL, LuoW. Mesoporous nanofibers from extended electrospinning technique. Adv Fiber Mater, 2024, 6: 658-685.
|
| [53] |
WangYF, ZhouXH, HanL, ShanXY, CuiWQ, ZhuL, GaoY, ZhaiSR, LyuLH, LiaoYP. In-situ growth of magnetic nanoparticles on honeycomb-like porous carbon nanofibers as lightweight and efficient microwave absorbers. Ceram Int, 2023, 49: 35476-35487.
|
| [54] |
JiaoZ, HuJ, MaM, LiuY, ZhaoJ, WangX, LuanS, ZhangL. One-dimensional core–shell CoC@CoFe/C@PPy composites for high-efficiency microwave absorption. J Colloid Interface Sci, 2023, 650: 2014-2023.
|
| [55] |
ChenF, ZhangS, GuoR, MaB, XiongY, LuoH, ChengY, WangX, GongR. 1D magnetic nitrogen doped carbon-based fibers derived from NiFe Prussian blue analogues embedded polyacrylonitrile via electrospinning with tunable microwave absorption. Compos B Eng, 2021, 224. 109161
|
| [56] |
LiL, ChenZ, PanF, GuoH, WangX, ChengJ, CaiL, XiuZ, ChenL, BataluD, LuW. Electrospinning technology on one dimensional microwave absorbers: fundamentals, current progress, and perspectives. Chem Eng J, 2023, 470. 144236
|
| [57] |
MercanteLA, AndreRS, FacureMHM, CorreaDS, MattosoLHC. Recent progress in conductive electrospun materials for flexible electronics: energy, sensing, and electromagnetic shielding applications. Chem Eng J, 2023, 465. 142847
|
| [58] |
WangY, YokotaT, SomeyaT. Electrospun nanofiber-based soft electronics. NPG Asia Mater, 2021, 13: 22.
|
| [59] |
PangL, XiaoP, LiZ, LuoH, ZhengJ, JiangS, TongJ, LiY. Long-range uniform SiCxOy beaded carbon fibers for efficient microwave absorption. ACS Appl Mater Interfaces, 2023, 15: 30815-30825.
|
| [60] |
ZhaoX, ZhangJ, LvK, KongN, ShaoY, TaoJ. Carbon nanotubes boosts the toughness and conductivity of wet-spun MXene fibers for fiber-shaped super capacitors. Carbon, 2022, 200: 38-46.
|
| [61] |
DengX, GaoS, QiX, DaiH, FuS, NiQ, FuY. Scalable 3D textile with hierarchically functionalized pyramidal units using nanostructured polyamide@carbon/Fe3O4 fibers for tunable microwave absorption. Chem Eng J, 2023, 473. 145040
|
| [62] |
VasiljevićJ, ČolovićM, JermanI, SimončičB, DemšarA, SamakiY, ŠobakM, ŠestE, GoljaB, LeskovšekM, BukošekV, MedvedJ, BarbaliniM, MalucelliG, BolkaS. In situ prepared polyamide 6/DOPO-derivative nanocomposite for melt-spinning of flame retardant textile filaments. Polym Degrad Stab, 2019, 166: 50-59.
|
| [63] |
GuoX, ZhangY, LiJ, HaoY, KeH, LvP, WeiQ. Wet spinning technology for aerogel fiber: pioneering the frontier of high-performance and multifunctional materials. Adv Fiber Mater, 2024.
|
| [64] |
RenN, QiaoA, CuiM, HuangR, QiW, SuR. Design and fabrication of nanocellulose-based microfibers by wet spinning. Chem Eng Sci, 2023, 282. 119320
|
| [65] |
WenN, GuanX, ZuoX, GuoY, ChenZ, LiC, XuH, PanL, FanZ. Investigations of morphology and carrier transport characteristics in high-performance PEDOT:PSS/tellurium binary composite fibers produced via continuous wet-spinning. Adv Funct Mater, 2024, 34: 2315677.
|
| [66] |
DangC, WangZ, Hughes-RileyT, DiasT, QianS, WangZ, WangX, LiuM, YuS, LiuR, XuD, WeiL, YanW, ZhuM. Fibres-threads of intelligence-enable a new generation of wearable systems. Chem Soc Rev, 2024, 53: 8790-8846.
|
| [67] |
Rohani ShirvanA, NouriA, SuttiA. A perspective on the wet spinning process and its advancements in biomedical sciences. Eur Polym J, 2022, 181. 111681
|
| [68] |
YangZ, YangY, HuangY, ShaoY, HaoH, YaoS, XiQ, GuoY, TongL, JianM, ShaoY, ZhangJ. Wet-spinning of carbon nanotube fibers: dispersion, processing and properties. Natl Sci Rev, 2024, 11: nwae203.
|
| [69] |
GaoT, YanG, YangX, YanQ, TianY, SongJ, LiF, WangX, YuJ, LiY, GuoS. Wet spinning of fiber-shaped flexible Zn-ion batteries toward wearable energy storage. J Energy Chem, 2022, 71: 192-200.
|
| [70] |
KimSW, KwonSN, NaSI. Stretchable and electrically conductive polyurethane- silver/graphene composite fibers prepared by wet-spinning process. Compos B Eng, 2019, 167: 573-581.
|
| [71] |
JeongHD, KimSG, ChoiGM, ParkM, KuB-C, LeeHS. Theoretical and experimental investigation of the wet-spinning process for mechanically strong carbon nanotube fibers. Chem Eng J, 2021, 412. 128650
|
| [72] |
HeM, LvX, PengH, ZhouY, LiH, LiZ, WangY, BuX. Biomimetic artificial nacre-like microfiber of Co/C modified cellulose nanofiber/Ti3C2Tx MXene with efficient microwave absorption. Chem Eng J, 2024, 491. 151726
|
| [73] |
TangJ, LiT, LiuQ, DuJ, LiJ, QiQ, MengF. Flexible microwave absorbing fabrics woven by high-strength graphene-based hybrid fibers with broadband electromagnetic response. J Mater Sci Technol, 2024, 200: 93-103.
|
| [74] |
TanH, SunL, HuangH, ZhangL, NeisianyRE, MaX, YouZ. Continuous melt spinning of adaptable covalently cross-linked self-healing ionogel fibers for multi-functional ionotronics. Adv Mater, 2023, 36: 2310020.
|
| [75] |
PintoTV, FernandesDM, GuedesA, CardosoN, DurãesNF, SilvaC, PereiraC, FreireC. Photochromic polypropylene fibers based on UV-responsive silica@phosphomolybdate nanoparticles through melt spinning technology. Chem Eng J, 2018, 350: 856-866.
|
| [76] |
PanW, ZhouJ, XiangH, InnocentMT, ZhaiG, ZhuM. Melt-spun industrial super-strong polycaprolactam fiber: effects of tie-molecules and crystal transformation. Compos B Eng, 2020, 185. 107772
|
| [77] |
NaeimiradM, KrinsB, GruterGJM. A review on melt-spun biodegradable fibers. Sustainability, 2023, 15: 14474.
|
| [78] |
ZengS, PianS, SuM, WangZ, WuM, LiuX, ChenM, XiangY, WuJ, ZhangM, CenQ. Hierarchical-morphology metafabric for scalable passive daytime radiative cooling. Science, 2021, 373: 692-696.
|
| [79] |
LeeJ, Llerena ZambranoB, WooJ, YoonK, LeeT. Recent advances in 1D stretchable electrodes and devices for textile and wearable electronics: materials, fabrications, and applications. Adv Mater, 2019, 32: 1902532.
|
| [80] |
KwonS, KimW, KimH, ChoiS, ParkBC, KangSH, ChoiKC. High luminance fiber-based polymer light-emitting devices by a dip-coating method. Adv Electron Mater, 2015, 1: 1500103.
|
| [81] |
GalinskiH, LeuteneggerD, AmbergM, KroghF, SchnabelV, HeubergerM, SpolenakR, HegemannD. Functional coatings on high-performance polymer fibers for smart sensing. Adv Funct Mater, 2020, 30: 1910555.
|
| [82] |
SunT, ZhouB, ZhengQ, WangL, JiangW, SnyderGJ. Stretchable fabric generates electric power from woven thermoelectric fibers. Nat Commun, 2020, 11: 572.
|
| [83] |
YangZ, LiuH, ZhaoJ, WangC, LiH, WangX, YangY, WuH, GuZ, LiY. UV absorption enhanced polydopamine coating. Mater Horizons, 2024, 11: 2438-2448.
|
| [84] |
LiY, LiuX, WangS, LiW, WangQ, GuoL, WangF, WangL, MaoJ. Dopamine-induced high fiber wetness for improved conductive fiber bundles with striated polypyrrole coating toward wearable healthcare electronics. Chem Eng J, 2024, 485. 149888
|
| [85] |
MaK, IslamogluT, ChenZ, LiP, WassonMC, ChenY, WangY, PetersonGW, XinJH, FarhaOK. Scalable and template-free aqueous synthesis of zirconium-based metal-organic framework coating on textile fiber. J Am Chem Soc, 2019, 141: 15626-15633.
|
| [86] |
WangL, LiX, LiQ, YuX, ZhaoY, ZhangJ, WangM, CheR. Oriented polarization tuning broadband absorption from flexible hierarchical ZnO arrays vertically supported on carbon cloth. Small, 2019, 15: 1900900.
|
| [87] |
FengY, LiT, GeK, WangX, WenG, YeJ, XiaL. Impedance matching strategy boost excellent wave absorption performance of zinc-aluminosilicate cladded short carbon fiber core-sheath structure. Mater Res Bull, 2022, 153. 111872
|
| [88] |
YangM, YuanY, LiY, SunX, WangS, LiangL, NingY, LiJ, YinW, CheR, LiY. Dramatically enhanced electromagnetic wave absorption of hierarchical CNT/Co/C fiber derived from cotton and metal-organic-framework. Carbon, 2020, 161: 517-527.
|
| [89] |
HanY, XuY, ZhangS, LiT, RamakrishnaS, LiuY. Progress of improving mechanical strength of electrospun nanofibrous membranes. Macromol Mater Eng, 2020, 305: 2000230.
|
| [90] |
LiC, ZhangL, ZhangS, YuQ, LiD, ZhangL, GongC, ZhangJ. Flexible regulation engineering of titanium nitride nanofibrous membranes for efficient electromagnetic microwave absorption in wide temperature spectrum. Nano Res, 2023, 17: 1666-1675.
|
| [91] |
MaoX, HongJ, WuYX, ZhangQ, LiuJ, ZhaoL, LiHH, WangYY, ZhangK. An efficient strategy for reinforcing flexible ceramic membranes. Nano Lett, 2021, 21: 9419-9425.
|
| [92] |
ZhangY, LiuS, YanJ, ZhangX, XiaS, ZhaoY, YuJ, DingB. Superior flexibility in oxide ceramic crystal nanofibers. Adv Mater, 2021, 33: 2105011.
|
| [93] |
LiuQ, YanK, ChenJ, XiaM, LiM, LiuK, WangD, WuC, XieY. Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation. Aggregate, 2021, 2: 100-126.
|
| [94] |
AbdallaI, CaiJ, LuW, YuJ, LiZ, DingB. Recent progress on electromagnetic wave absorption materials enabled by electrospun carbon nanofibers. Carbon, 2023, 213. 118300
|
| [95] |
AbdallaI, ElhassanA, YuJ, LiZ, DingB. A hybrid comprised of porous carbon nanofibers and rGO for efficient electromagnetic wave absorption. Carbon, 2020, 157: 703-713.
|
| [96] |
BhattacharjeeY, BhingardiveV, BiswasS, BoseS. Construction of a carbon fiber based layer-by-layer (LbL) assembly – a smart approach towards effective EMI shielding. RSC Adv, 2016, 6: 112614-112619.
|
| [97] |
ChenJ, ZhengJ, WangF, HuangQ, JiG. Carbon fibers embedded with FeIII-MOF-5-derived composites for enhanced microwave absorption. Carbon, 2021, 174: 509-517.
|
| [98] |
GunwantD, VedrtnamA. Microwave absorbing properties of carbon fiber based materials: a review and prospective. J Alloys Compd, 2021, 881. 160572
|
| [99] |
LiC, DengL, HeJ, PengS, HuangS, QiuL. Multi-interfacial TiO2/carbon fibers encapsulated with needle-like FeCo2O4 for excellent microwave absorption. Appl Surf Sci, 2023, 629. 157417
|
| [100] |
ChenQ, LiD, LiaoX, YangZ, JiaD, ZhouY, RiedelR. Polymer-derived lightweight SiBCN ceramic nanofibers with high microwave absorption performance. ACS Appl Mater Interfaces, 2021, 13: 34889-34898.
|
| [101] |
LiZ, YeF, ChengL, WangP, GuoC, LiM, ZhangL. Synthesis of Si–C–N aligned nanofibers with preeminent electromagnetic wave absorption in ultra-broad band. J Mater Chem C, 2021, 9: 16966-16977.
|
| [102] |
WangS, GongH, AshfaqMZ, QiD, YueX. Strengthened microwave absorption properties of polymer-derived carbon-rich SiCN (Ni3Si) ceramic fibers pyrolyzed at low temperature. Ceram Int, 2023, 49: 30719-30731.
|
| [103] |
MinD, JiangJ, QingY, GaoX, HuG, ZhouM. Attapulgite coated polycrystalline iron fibers composites with light weight feature and enhanced microwave absorption properties. J Alloys Compd, 2023, 948. 169817
|
| [104] |
WeiZ, YangS, JiaoP, LiJ, LuH, LiY, HeX, YuanY. Novel and effective strategy for producing NiFe alloy fibers with tunable microwave absorption performance. Materialia, 2019, 8. 100495
|
| [105] |
WangZJ, LiKZ, WangC. Freezing–thawing effects on electromagnetic wave reflectivity of carbon fiber cement based composites. Constr Build Mater, 2014, 64: 288-292.
|
| [106] |
WangH, HuangX, LiW, GaoJ, XueH, LiRKY, MaiY-W. TiO2 nanoparticle decorated carbon nanofibers for removal of organic dyes. Colloids Surf A Physicochem Eng Asp, 2018, 549: 205-211.
|
| [107] |
LiuW, LiH, ZengQ, DuanH, GuoY, LiuX, SunC, LiuH. Fabrication of ultralight three-dimensional graphene networks with strong electromagnetic wave absorption properties. J Mater Chem A, 2015, 3: 3739-3747.
|
| [108] |
ZhangY, HuangY, ChenH, HuangZ, YangY, XiaoP, ZhouY, ChenY. Composition and structure control of ultralight graphene foam for high-performance microwave absorption. Carbon, 2016, 105: 438-447.
|
| [109] |
WuN, ZhaoB, LiuJ, LiY, ChenY, ChenL, WangM, GuoZ. MOF-derived porous hollow Ni/C composites with optimized impedance matching as lightweight microwave absorption materials. Adv Compos Hybrid Mater, 2021, 4: 707-715.
|
| [110] |
ZhuJ, MuS. Defect engineering in carbon-based electrocatalysts: insight into intrinsic carbon defects. Adv Funct Mater, 2020, 30: 2001097.
|
| [111] |
DaiB, LiJ, LiuX, WangN, DaiY, QiY. Multiple synergistic losses in the absorption of electromagnetic waves by three-dimensional cross-linked carbon fiber. Carbon, 2022, 195: 308-318.
|
| [112] |
ZhanY, XiaL, YangH, ZhouN, MaG, ZhangT, HuangX, XiongL, QinC, GuangwuW. Tunable electromagnetic wave absorbing properties of carbon nanotubes/carbon fiber composites synthesized directly and rapidly via an innovative induction heating technique. Carbon, 2021, 175: 101-111.
|
| [113] |
ZhengS, ZengZ, QiaoJ, LiuY, LiuJ. Facile preparation of C/MnO/Co nanocomposite fibers for High-Performance microwave absorption. Compos Part A Appl Sci Manuf, 2022, 155. 106814
|
| [114] |
WangB, DingM, ShaoC, YuJ, KongH, ZhaoD, LiC. Facile synthesis of CoxFey@C nanocomposite fibers derived from pyrolysis of cobalt/iron chelate nanowires for strong broadband electromagnetic wave absorption. Chem Eng J, 2023, 465. 142803
|
| [115] |
BiY, MaM, JiaoZ, MaY, HouD, GengG, FengW, MaA, QiaoM, LiuY. Enhancing electromagnetic wave absorption performance of one-dimensional C@Co/N-doped C@PPy composite fibers. Carbon, 2022, 197: 152-162.
|
| [116] |
CaoM, WangX, CaoW, FangX, WenB, YuanJ. Thermally driven transport and relaxation switching self-powered electromagnetic energy conversion. Small, 2018, 14: 1800987.
|
| [117] |
HouY, ShengZ, FuC, KongJ, ZhangX. Hygroscopic holey graphene aerogel fibers enable highly efficient moisture capture, heat allocation and microwave absorption. Nat Commun, 2022, 13: 1227.
|
| [118] |
FuS, ZhuM, ZhuY. Organosilicon polymer-derived ceramics: an overview. J Adv Ceram, 2019, 8: 457-478.
|
| [119] |
WenQ, QuF, YuZ, Graczyk-ZajacM, XiongX, RiedelR. Si-based polymer-derived ceramics for energy conversion and storage. J Adv Ceram, 2022, 11: 197-246.
|
| [120] |
XiaoF, SunH, LiJ, GuoX, ZhangH, LuJ, PanZ, XuJ. Electrospinning preparation and electromagnetic wave absorption properties of SiCN fibers. Ceram Int, 2020, 46: 12773-12781.
|
| [121] |
ZhuB, CuiY, LvD, LiuP, WeiH, BuJ. Synthesis and electromagnetic wave absorption properties of peanut shell-like SiC fibers. Mater Lett, 2020, 263. 127288
|
| [122] |
WangP, ChengL, ZhangY, ZhangL. Flexible SiC/Si3N4 composite nanofibers with in situ embedded graphite for highly efficient electromagnetic wave absorption. ACS Appl Mater Interfaces, 2017, 9: 28844-28858.
|
| [123] |
HuangB, WangZ, HuH, XiuZ, HuangX, YueJ, WangY. Enhancement of the microwave absorption properties of PyC-SiCf/SiC composites by electrophoretic deposition of SiC nanowires on SiC fibers. Ceram Int, 2020, 46: 9303-9310.
|
| [124] |
YuanX, WangR, HuangW, KongL, GuoS, ChengL. Morphology design of co-electrospinning MnO-VN/C nanofibers for enhancing the microwave absorption performances. ACS Appl Mater Interfaces, 2020, 12: 13208-13216.
|
| [125] |
LiuR, LunN, QiY-X, BaiY-J, ZhuH-L, HanF-D, MengX-L, BiJ-Q, FanR-H. Microwave absorption properties of TiN nanoparticles. J Alloys Compd, 2011, 509: 10032-10035.
|
| [126] |
LiC, LiD, ZhangS, MaL, ZhangL, ZhangJ, GongC. Interface engineering of titanium nitride nanotube composites for excellent microwave absorption at elevated temperature. Nano-Micro Lett, 2024, 16: 168.
|
| [127] |
LiC, LiD, ZhangL, ZhangY, ZhangL, GongC, ZhangJ. Boosted microwave absorption performance of transition metal doped TiN fibers at elevated temperature. Nano Res, 2022, 16: 3570-3579
|
| [128] |
LiR, LuJ, LiC, CuiY, LvD, ChenY, WeiY, WeiH, LiangB, BuJ. Mesoporous vanadium nitride nanofiber@N-doped carbon with excellent microwave absorption and anti-corrosion. Colloids Surf A Physicochem Eng Asp, 2024, 686. 133420
|
| [129] |
CuiY, XuK, ZhuB, HuS, ChenY, LvD, YuY, BuJ, WeiH, LiangB. Synthesis of niobium nitride porous nanofibers with excellent microwave absorption properties via reduction nitridation of electrospinning precursor nanofibers with ammonia gas. J Alloys Compd, 2022, 907. 164453
|
| [130] |
LuJ, LiR, CuiY, WangR, LvD, WeiY, ChenY, WeiH, BuJ. Synthesis and microwave absorption properties of zirconium nitride nanofibers by electrospinning combined with carbon thermal reduction nitriding method. J Mater Sci Mater Electron, 2023, 34: 1586.
|
| [131] |
HuangX, ZhangJ, LaiM, SangT. Preparation and microwave absorption mechanisms of the NiZn ferrite nanofibers. J Alloys Compd, 2015, 627: 367-373.
|
| [132] |
XiangJ, HouZ, ZhangX, GongL, WuZ, MiJ. Facile synthesis and enhanced microwave absorption properties of multiferroic Ni0.4Co0.2Zn0.4Fe2O4/BaTiO3 composite fibers. J Alloys Compd, 2018, 737: 412-420.
|
| [133] |
ZhuB, CuiY, LvDF, XuKZ, ChenYJ, WeiYN, WeiHY, BuJL. Synthesis of setaria viridis-like TiN fibers for efficient broadband electromagnetic wave absorption in the whole X and Ku bands. Appl Surf Sci, 2020, 533. 147439
|
| [134] |
WangX, ZhaoC, LiC, LiuY, SunS, YuQ, YuB, CaiM, ZhouF. Progress in MXene-based materials for microwave absorption. J Mater Sci Technol, 2024, 180: 207-225.
|
| [135] |
LanX, WangR, LiuW, HuangZ, DengP, WangZ. Multicomponent synergistic flower-like FeS/hollow C fiber for tunable and efficient microwave absorption. Chem Eng J, 2024, 485. 149238
|
| [136] |
QinM, ZhangL, WuH. Dielectric loss mechanism in electromagnetic wave absorbing materials. Adv Sci, 2022, 9: 2105553.
|
| [137] |
WangY, LiJ, LiW, MaL, LinJ, YeS, ZhaoQ, LiuY, ZhaoS. Flexible polypyrrole-coated polyamide based mats for broadband microwave absorption and electromagnetic interference shielding with low reflection. ACS Appl Polym Mater, 2023, 5: 2995-3004.
|
| [138] |
GaoS, DengX, QiX, DaiH, FuSY, FuY. Nanometer-sized carbon black and Fe3O4 nanoparticles incorporated into polyamide-66 composite fibers and woven into three-dimensional fabrics for electromagnetic absorption. ACS Appl Nano Mater, 2024, 7: 6525-6535.
|
| [139] |
HeM, TangJ, WangY, HuangL, WangX, YuJ. Controlled growth of polyaniline nanofibers on the surface of alkali pre-treated PI fabric as electromagnetic wave-absorbing fabrics. Surf Interfaces, 2024, 48. 104367
|
| [140] |
SunH, YangB, ZhangM. Functional-structural integrated aramid nanofiber-based honeycomb materials with ultrahigh strength and multi-functionalities. Adv Fiber Mater, 2024.
|
| [141] |
LiaoZ, MaM, TongZ, WangR, BiY, ChenY, ChungKL, MaY. Fabrication of ZnFe2O4/C@PPy composites with efficient electromagnetic wave absorption properties. J Colloid Interface Sci, 2021, 602: 602-611.
|
| [142] |
RenH, LiT, WangH, GuoZ, ChenT, MengF. Two birds with one stone: Superhelical chiral polypyrrole towards high-performance electromagnetic wave absorption and corrosion protection. Chem Eng J, 2022, 427. 131582
|
| [143] |
MengN, RenX, SantagiulianaG, VenturaL, ZhangH, WuJ, YanH, ReeceMJ, BilottiE. Ultrahigh β-phase content poly(vinylidene fluoride) with relaxor-like ferroelectricity for high energy density capacitors. Nat Commun, 2019, 10: 4535.
|
| [144] |
MaW, RenW, BaiX, PanJ, HuangL, HuangQ, GuoZ, WangX. Facile fabrication of PVDF-CTFE microporous membranes with optimized surface and sublayer structure via non-solvent induced phase separation. J Water Process Eng, 2022, 45. 102504
|
| [145] |
MengN, ZhangY, LiuY, ShiY, JiangR, WuJ, LiaoY. Boosting photocatalytic removal of organic pollutants through enhanced piezoelectricity in free-standing nanofibril pyridyl-functionalized conjugated microporous polymer/poly(vinylidene fluoride–trifluoroethylene) hybrids. J Mater Chem C, 2022, 10: 15367-15376.
|
| [146] |
MaW, PanJ, RenW, ChenL, HuangL, XuS, JiangZ. Fabrication of antibacterial and self-cleaning CuxP@g-C3N4/PVDF-CTFE mixed matrix membranes with enhanced properties for efficient ultrafiltration. J Membr Sci, 2022, 659. 120792
|
| [147] |
LiuX, ZhangM, JiangB, ZhangQ, ChenH, ShenY, WangZ, YinX. Process investigation on robust electrospinning of non-aligned and aligned polyvinylidene fluoride nanofiber mats for flexible piezoelectric sensors. Polymers, 2024, 16: 816.
|
| [148] |
LiY, ZhaoY, LuX, ZhuY, JiangL. Self-healing superhydrophobic polyvinylidene fluoride/Fe3O4@polypyrrole fiber with core–sheath structures for superior microwave absorption. Nano Res, 2016, 9: 2034-2045.
|
| [149] |
WangX, ZhangW, DingE, FangY, BiS, SunL, LiuW, ZhangL. Heterointerface effects in electrospun carbon nanotube/poly(vinylidene difluoride) nanofibrous mats for microwave absorption. ACS Appl Nano Mater, 2022, 5: 14609-14621.
|
| [150] |
HanH, LouZ, WangQ, XuL, LiY. Introducing rich heterojunction surfaces to enhance the high-frequency electromagnetic attenuation response of flexible fiber-based wearable absorbers. Adv Fiber Mater, 2024, 6: 739-757.
|
| [151] |
LvH, GuoY, YangZ, GuoT, WuH, LiuG, WangL, WuR. Doping strategy to boost the electromagnetic wave attenuation ability of hollow carbon spheres at elevated temperatures. ACS Sustain Chem Eng, 2017, 6: 1539-1544.
|
| [152] |
ZhaoB, YanZ, DuY, RaoL, ChenG, WuY, YangL, ZhangJ, WuL, ZhangDW, CheR. High-entropy enhanced microwave attenuation in titanate perovskites. Adv Mater, 2023, 35: 2210243.
|
| [153] |
ZhangT, ZhouP, XiaoB, ZhangJ, WenG, ZhongB, XiaL. Controllable synthesis of porous CxNy nanofibers with enhanced electromagnetic wave absorption property. Ceram Int, 2017, 43: 8603-8610.
|
| [154] |
WangJ, HuyanY, YangZ, ZhangA, ZhangQ, ZhangB. Tubular carbon nanofibers: synthesis, characterization and applications in microwave absorption. Carbon, 2019, 152: 255-266.
|
| [155] |
CuiY, YangK, LyuY, LiuP, ZhangQ, ZhangB. Hollow nitrogen-doped carbon nanofibers filled with MnO2 nanoparticles/nanosheets as high-performance microwave absorbing materials. Carbon, 2022, 196: 49-58.
|
| [156] |
ZhangZ, ZhaoY, LiZ, ZhangL, LiuZ, LongZ, LiY, LiuY, FanR, SunK, ZhangZ. Synthesis of carbon/SiO2 core-sheath nanofibers with Co-Fe nanoparticles embedded in via electrospinning for high-performance microwave absorption. Adv Compos Hybrid Mater, 2021, 5: 513-524.
|
| [157] |
LuZ, WangY, DiX, WangN, ChengR, YangL. Heterostructure design of carbon fiber@graphene@layered double hydroxides synergistic microstructure for lightweight and flexible microwave absorption. Carbon, 2022, 197: 466-475.
|
| [158] |
ZhangF, LiN, ShiJF, WangYY, YanDX, LiZM. Cation bimetallic MOF anchored carbon fiber for highly efficient microwave absorption. Small, 2024.
|
| [159] |
WangC, JiangH, CuiB, XuX, LiM, XuZ, TanH, YangD, FengY, WangY, WangC. ZIF-67@carbon fiber derived magnetic-dielectric synergistic heterostructure for excellent microwave absorption under ultrathin thickness. Chem Eng J, 2023, 475. 146298
|
| [160] |
ZhaoS, GaoZ, ChenC, WangG, ZhangB, ChenY, ZhangJ, LiX, QinY. Alternate nonmagnetic and magnetic multilayer nanofilms deposited on carbon nanocoils by atomic layer deposition to tune microwave absorption property. Carbon, 2016, 98: 196-203.
|
| [161] |
HuangL, DuanY, ShiY, MaX, PangH, ZengQ, CheR. Chiral asymmetric polarizations generated by bioinspired helical carbon fibers to induce broadband microwave absorption and multispectral photonic manipulation. Adv Opt Mater, 2022, 10: 2200249.
|
| [162] |
ZhaoY, ZhangY, YangC, ChengL. Ultralight and flexible SiC nanoparticle-decorated carbon nanofiber mats for broad-band microwave absorption. Carbon, 2021, 171: 474-483.
|
| [163] |
HouY, ChengL, ZhangY, YangY, DengC, YangZ, ChenQ, DuX, ZhaoC, ZhengL. Enhanced flexibility and microwave absorption properties of HfC/SiC nanofiber mats. ACS Appl Mater Interfaces, 2018, 10: 29876-29883.
|
| [164] |
HouS, WangY, GaoF, WangF, YangH, JinF, BaiG, CaoZ, DuY. In situ growing fusiform SnO2 nanocrystals film on carbon fiber cloth as an efficient and flexible microwave absorber. Mater Des, 2023, 225. 111576
|
| [165] |
QuanB, LiangX, ZhangX, XuG, JiG, DuY. Functionalized carbon nanofibers enabling stable and flexible absorbers with effective microwave response at low thickness. ACS Appl Mater Interfaces, 2018, 10: 41535-41543.
|
| [166] |
WeiY, YueJ, TangX, HuangX. Enhanced microwave-absorbing properties of FeCo magnetic film-functionalized silicon carbide fibers fabricated by a radio frequency magnetron method. Ceram Int, 2017, 43: 16371-16375.
|
| [167] |
SinghSK, AkhtarMJ, KarKK. Hierarchical carbon nanotube-coated carbon fiber: ultra lightweight, thin, and highly efficient microwave absorber. ACS Appl Mater Interfaces, 2018, 10: 24816-24828.
|
| [168] |
ZhangX, XiangJ, WuZ, GongL, ChenX, GuanG, WangY, ZhangK. Enhanced absorbing properties and structural design of microwave absorbers based on Ni0.8Co0.2Fe2O4 nanofibers and Ni-C hybrid nanofibers. J Alloys Compd, 2018, 764: 691-700.
|
| [169] |
LiD, GuoK, WangF, WuZ, ZhongB, ZuoS, TangJ, FengJ, ZhuoR, YanD, YanP. Enhanced microwave absorption properties in C band of Ni/C porous nanofibers prepared by electrospinning. J Alloys Compd, 2019, 800: 294-304.
|
| [170] |
LiW, QiH, GuoF, DuY, SongN, LiuY, ChenY. Co nanoparticles supported on cotton-based carbon fibers: a novel broadband microwave absorbent. J Alloys Compd, 2019, 772: 760-769.
|
| [171] |
LiuY, ChenZ, XieW, SongS, ZhangY, DongL. In-situ growth and graphitization synthesis of porous Fe3O4/Carbon fiber composites derived from biomass as lightweight microwave absorber. ACS Sustain Chem Eng, 2019, 7: 5318-5328.
|
| [172] |
GuW, LvJ, QuanB, LiangX, ZhangB, JiG. Achieving MOF-derived one-dimensional porous ZnO/C nanofiber with lightweight and enhanced microwave response by an electrospinning method. J Alloys Compd, 2019, 806: 983-991.
|
| [173] |
ZhouW, LongL, XiaoP, JiaC-k, LiY. Comparison in dielectric and microwave absorption properties of SiC coated carbon fibers with PyC and BN interphases. Surf Coat Technol, 2019, 359272277
|
| [174] |
LiX, CuiE, XiangZ, YuL, XiongJ, PanF, LuW. Fe@NPC@CF nanocomposites derived from Fe-MOFs/biomass cotton for lightweight and high-performance electromagnetic wave absorption applications. J Alloys Compd, 2020, 819. 152952
|
| [175] |
ZhaoZ, KouK, WuH. 2-Methylimidazole-mediated hierarchical Co3O4/N-doped carbon/short-carbon-fiber composite as high-performance electromagnetic wave absorber. J Colloid Interface Sci, 2020, 574: 1-10.
|
| [176] |
GuanG, GaoG, XiangJ, YangJ, GongL, ChenX, ZhangY, ZhangK, MengX. CoFe2/BaTiO3 hybrid nanofibers for microwave absorption. ACS Appl Nano Mater, 2020, 3: 8424-8437.
|
| [177] |
WeiY, ZhongK, JiangT, ZhangJ, BiK, LiL, PengY. Gumdrop-cake-like CuNi/C nanofibers with tunable microstructure for microwave absorbing application. Ceram Int, 2020, 46: 11406-11415.
|
| [178] |
XuJ, XiaL, LuoJ, LuS, HuangX, ZhongB, ZhangT, WenG, WuX, XiongL, WangG. High-performance electromagnetic wave absorbing CNT/SiCf composites: synthesis, tuning, and mechanism. ACS Appl Mater Interfaces, 2020, 12: 20775-20784.
|
| [179] |
WuF, LiuZ, XiuT, ZhuB, KhanI, LiuP, ZhangQ, ZhangB. Fabrication of ultralight helical porous carbon fibers with CNTs-confined Ni nanoparticles for enhanced microwave absorption. Compos B Eng, 2021, 215. 108814
|
| [180] |
HanC, ZhangM, CaoW-Q, CaoM-S. Electrospinning and in-situ hierarchical thermal treatment to tailor C-NiCo 2 O 4 nanofibers for tunable microwave absorption. Carbon, 2021, 171: 953-962.
|
| [181] |
ZhangM, LingH, DingS, XieY, ChengT, ZhaoL, WangT, BianH, LinH, LiZ, MengA. Synthesis of CF@PANI hybrid nanocomposites decorated with Fe3O4 nanoparticles towards excellent lightweight microwave absorber. Carbon, 2021, 174: 248-259.
|
| [182] |
HanX, HuangY, GaoS, ZhangG, LiT, LiuP. A hierarchical carbon Fiber@MXene@ZnO core-sheath synergistic microstructure for efficient microwave absorption and photothermal conversion. Carbon, 2021, 183: 872-883.
|
| [183] |
GuoY, WangD, WangJ, TianY, LiuH, LiuC, ShenC. Hierarchical HCF@NC/Co Derived from hollow loofah fiber anchored with metal-organic frameworks for highly efficient microwave absorption. ACS Appl Mater Interfaces, 2021, 14: 2038-2050.
|
| [184] |
ChenJ, ZhengJ, HuangQ, WangF, JiG. Enhanced microwave absorbing ability of carbon fibers with embedded FeCo/CoFe2O4 nanoparticles. ACS Appl Mater Interfaces, 2021, 13: 36182-36189.
|
| [185] |
BandaruS, MurthyN, KulkarniR, EnglishNJ. Magnetic ferrite/carbonized cotton fiber composites for improving electromagnetic absorption properties at gigahertz frequencies. J Mater Sci Technol, 2021, 86: 127-138.
|
| [186] |
GuoT, HuangB, LiC, LouY, TangX-Z, HuangX, YueJ. Magnetic sputtering of FeNi/C bilayer film on SiC fibers for effective microwave absorption in the low-frequency region. Ceram Int, 2021, 47: 5221-5226.
|
| [187] |
ZhangY, ShenY, DangM, ZhangF, DuX. In situ synthesis hydrophobic Co/CoO/C nanofibers with enhanced microwave absorption. Ceram Int, 2021, 47: 9178-9187.
|
| [188] |
GuoS, ZhangY, ChenJ, WuY, CaoJ, TangS, JiG. The excellent electromagnetic wave absorbing properties of carbon fiber composites: the effect of metal content. Inorg Chem Front, 2022, 9: 3244-3250.
|
| [189] |
LiaoZ, MaM, BiY, TongZ, ChungKL, LiZ, MaY, GaoB, CaoZ, SunR, ZhongX. MoS2 decorated on one-dimensional MgFe2O4/MgO/C composites for high-performance microwave absorption. J Colloid Interface Sci, 2022, 606: 709-718.
|
| [190] |
WuT, HuanX, JiaX, SuiG, WuL, CaiQ, YangX. 3D printing nanocomposites with enhanced mechanical property and excellent electromagnetic wave absorption capability via the introduction of ZIF-derivative modified carbon fibers. Compos B Eng, 2022, 233. 109658
|
| [191] |
GuoY, LiuH, WangD, El-BahyZM, AlthakafyJT, Abo-DiefHM, GuoZ, XuBB, LiuC, ShenC. Engineering hierarchical heterostructure material based on metal-organic frameworks and cotton fiber for high-efficient microwave absorber. Nano Res, 2022, 15: 6841-6850.
|
| [192] |
LiuL, WuM, WuQ, LiuJ, YangJ, ZhangJ. Conductive, superhydrophobic, and microwave-absorbing cotton fabric by dip-coating of aqueous silk nanofibers stabilized MWCNTs and octadecanoyl chain bonding. Cellulose, 2022, 29: 4687-4701.
|
| [193] |
SuX, HanM, WangJ, WuQ, DuanH, LiangC, ZhangS, PuZ, LiuY. Regulated dielectric loss based on core-sheath carbon–carbon hierarchical nanofibers toward the high-performance microwave absorption. J Colloid Interface Sci, 2022, 624: 619-628.
|
| [194] |
JinH, WenH-M, HongQ, LinJ, LiJ, HuJ. NiCo@NPC@CF nanocomposites derived from NiCo-MOF/cotton for high-performance electromagnetic wave absorption. J Mater Chem C, 2022, 10: 8310-8320.
|
| [195] |
GuoR, SuD, ChenF, ChengY, WangX, GongR, LuoH. Hollow beaded Fe3C/N-doped carbon fibers toward broadband microwave absorption. ACS Appl Mater Interfaces, 2022, 14: 3084-3094.
|
| [196] |
HuangB, HuH, LimS, TangX-Z, HuangX, LiuY, YueJ. Gradient FeNi-SiO 2 films on SiC fiber for enhanced microwave absorption performance. J Alloys Compd, 2022, 897. 163204
|
| [197] |
LiL, ZhaoH, LiP, MengL, YangJ, BaiJ, WangG, YanJ. Rough porous N-doped graphene fibers modified with Fe-based Prussian blue analog derivative for wide-band electromagnetic wave absorption. Compos B Eng, 2022, 243. 110121
|
| [198] |
RanjkeshZ, NasouriK. Facile synthesis of novel porous nickel/carbon fibers obtained from cigarette butts for high-frequency microwave absorption. J Environ Chem Eng, 2022, 10. 106969
|
| [199] |
ShenY, ZhangF, ZhangY, DangM, LiB, MaJ, DuX. Ni/NiO/SiO2/C nanofibers with strong wideband microwave absorption and robust hydrophobicity. Appl Surf Sci, 2022, 588. 152964
|
| [200] |
ChengJ-B, ZhaoH-B, ZhangA-N, WangY-Q, WangY-Z. Porous carbon/Fe composites from waste fabric for high-efficiency electromagnetic wave absorption. J Mater Sci Technol, 2022, 126: 266-274.
|
| [201] |
WangX, LvX, LiuZ, ZhangH, LiuM, XuC, ZhouX, YuanM, YangL, YouW, WuL, LiangC, LvH, ZhangJ, CheR. Multi-interfacial 1D magnetic ferrite@C fibers for broadband microwave absorption. Mater Today Phys, 2023, 35. 101140
|
| [202] |
ZhaoX, HuangY, LiuX, YuM, ZongM, LiT. Magnetic nanorods/carbon fibers heterostructures coated with flower-like MoS2 layers for superior microwave absorption. Carbon, 2023, 213. 118265
|
| [203] |
LiuC, TongY, LiuC, LiuJ, SunH, HuQ, WuS, ZhaoY, LiJ, GuoX, FengY. Novel and efficient electromagnetic wave absorption of SiBCN(Fe) nanofibers. Colloids Surf A Physicochem Eng Asp, 2023, 679. 132605
|
| [204] |
ChenN, WeiS, FengY, HuS, TangY, HeW, ZhangY, CaoD, FuZ. Double-loss Co-Ti3C2Tx/Fe2O3/PAN hollow fiber composite material for high-efficiency electromagnetic absorption. ACS Appl Nano Mater, 2023, 6: 11013-11022.
|
| [205] |
TahalyaniJ, AkhtarMJ, KarKK. Flexible, stretchable, and lightweight hierarchical carbon-nanotube-decorated carbon fiber structures for microwave absorption. ACS Appl Nano Mater, 2023, 6: 11888-11901.
|
| [206] |
WangJ, WangC, HouK, SuX, Tendo InnocentM, HuZ, YuS, XiangH, ZhuM. Electrospinning of bitter gourd shape CoNiSe2@N carbon nanofibers as absorbers for electromagnetic wave attenuation. Compos Part A Appl Sci Manuf, 2023, 175. 107770
|
| [207] |
KongL, ZhangS, LiuY, WuH, FanX, CaoY, HuangJ. Hierarchical architecture bioinspired CNTs/CNF electromagnetic wave absorbing materials. Carbon, 2023, 207: 198-206.
|
| [208] |
ZhaoZ, DuZ, HuangX, JiangC. 1D–2D heterostructured silicon carbide fibers@WS2 with high efficiency and broad bandwidth for microwave absorption performance. Ceram Int, 2023, 49: 9916-9923.
|
| [209] |
SunJ, HuangX, LiuY, ZhangK, YanY, LiuY, YanX. Enhanced microwave absorption performance originated from interface and unrivaled impedance matching of SiO2/carbon fiber. Appl Surf Sci, 2023, 623. 157029
|
| [210] |
MaM, HuJ, HanX, LiuJ, JiangJ, FengC, HouY, MaY. Design and synthesis of one-dimensional magnetic composites with Co nanoparticles encapsulated in carbon nanofibers for enhanced microwave absorption. J Colloid Interface Sci, 2023, 652: 680-691.
|
| [211] |
TianK, HuangY, WangJ, ZhangC, ShuR, ChenZ, LiuX, LiY, XuL. Carbon cloth based flexible electromagnetic wave absorbing materials loaded with Co3O4 array and tunable electromagnetic wave absorption performance. J Colloid Interface Sci, 2023, 649: 675-684.
|
| [212] |
YuanR, LyuJ, FuC, FengH, ZhangX. Carbonized kevlar nanofiber/carbon nanotube/magnetic nanoparticle hybrid aerogel fibers for microwave absorption. ACS Appl Nano Mater, 2023, 6: 10944-10952.
|
| [213] |
GuanZJ, YangBA, SunXY, LiY, JiangJT, SongB, GongYX, ZhenL. SiC/Co composite fibers with enhanced conductivity and magnetic coupling developed for reinforcing and high-efficiency electromagnetic absorbing (EMA) materials. Compos B Eng, 2023, 266. 111010
|
| [214] |
WangX, ZhangL, DingE, CaoX, LuoC, HuangL. Seed-assisted in situ ZIF-8 growth on carbon nanofibers for enhanced microwave absorption. Carbon, 2023, 214. 118316
|
| [215] |
LiuC, TongY, LiuC, SunH, HuQ, WuS, ZhaoY, LiJ, GuoX, FengY. Impedance matching optimization mechanism of SiBCN(Ni) absorbing fibers with Ni as catalyst. Ceram Int, 2024.
|
| [216] |
HanX, CaiH, WangG, ZhangS, LiuX, HuangY. Synthesis of hierarchical CF@Fe3O4 fibers decorated with MoS2 layers forming core-sheath microstructure toward tunable and efficient electromagnetic wave absorption. ACS Appl Mater Interfaces, 2024, 16: 4886-4895.
|
| [217] |
JiaH, HeL, SunQ, YeW, LongX, ZhangP. Surface modification of carbon fibers for enhanced electromagnetic absorption. J Alloys Compd, 2024, 976. 173168
|
| [218] |
LiW, LiB, ZhaoY, WangY, LiangH, lv B,. Facile preparation of CoFe alloy/carbonized bamboo fibers for broadband microwave absorption. J Alloys Compd, 2024, 970: 172545.
|
| [219] |
HuJ, JiaoZ, HanX, LiuJ, MaM, JiangJ, HouY, WangX, FengC, MaY. Facile synthesis of FeNi nanoparticle-loaded carbon nanocomposite fibers for enhanced microwave absorption performance. J Mater Sci Technol, 2024, 175: 141-152.
|
| [220] |
DingC, MaS, SuD, MaY, RenX, ZhangH, WuS, WeiC, WenG, HuangX. Pomegranate plasma heterostructure regulated 1D biomass derived microtube networks for lightweight broadband microwave absorber. J Colloid Interface Sci, 2024, 657: 54-62.
|
| [221] |
WuD, DengS, WangY, WenJ, RenL, HeQ. Hierarchical porous carbon fibers for broadband and tunable high-performance microwave absorption. Mater Res Bull, 2024, 172. 112653
|
| [222] |
DengY, YangM, LiuQ, LiuC, JianX, ChenY. Biologically inspired nanoporous PAN/PMMA/β-CD carbon fibers for efficient microwave absorption. ACS Appl Nano Mater, 2024, 7: 3199-3209.
|
| [223] |
LiT, LiJ, XuZ, TianY, LiJ, DuJ, MengF. Electromagnetic response of multistage-helical nano-micro conducting polymer structures and their enhanced attenuation mechanism of multiscale-chiral synergistic effect. Small, 2023, 19: 2300233.
|
Funding
National Key Research and Development Program of China(2022YFB3807100)
National Natural Science Foundation of China(52103024)
Young Elite Scientists Sponsorship Program by China Association for Science and Technology(2023QNRC001)
Changjiang Scholar Program, Ministry of Education(Q2019152)
Science and Technology Commission of Shanghai Municipality(23ZR1401100)
Chenguang Program of Shanghai Education Development Foundation and Shanghai Municipal Education Commission(21CGA40)
Donghua University 2024 Cultivation Project of Discipline Innovation(xkcx-202413)
RIGHTS & PERMISSIONS
Donghua University, Shanghai, China
Just Accepted
This article has successfully passed peer review and final editorial review, and will soon enter typesetting, proofreading and other publishing processes. The currently displayed version is the accepted final manuscript. The officially published version will be updated with format, DOI and citation information upon launch. We recommend that you pay attention to subsequent journal notifications and preferentially cite the officially published version. Thank you for your support and cooperation.
PDF
