With the rapid advancement of the information age, electromagnetic waves have brought convenience to people while also posing numerous problems and challenges. Developing absorptive materials that combine strong absorption, wide bandwidth, low density, and high stability has become a core research direction in the field of materials science. Using the hydrothermal method, a flower-like zinc oxide/multi-walled carbon nanotube nanocomposite was synthesized with hydroxylated multi-walled carbon nanotubes as the carrier. This was achieved by selecting different solvents and varying concentrations of zinc precursor solutions. The composite was then blended with 50 wt% paraffin wax to investigate its electromagnetic parameters and absorptive properties. Results indicate optimal absorption performance occurs in a mixed solvent of deionized water: anhydrous ethanol = 1:1, with a zinc oxide precursor concentration of 0.2 mol/L. At a sample thickness of 2.5 mm, the minimum reflection loss reaches −40.15 dB, and the effective absorption bandwidth spans 2.88 GHz (8.00–10.88 GHz). The synergistic design strategy of “hydroxylated carrier-flower-like structure-mixed solvent” provides an innovative and practical new pathway for preparing high-performance zinc oxide/multi-walled carbon nanotube absorber materials.
WangKFChuWSLiH, et al.Ferromagnetic Ti3CNCl2-decorated RGO aerogel: from 3D interconnecting conductive network construction to ultra-broadband microwave absorber with thermal insulation property. J Colloid Interface Sci2021; 604: 402–414.
2.
ZhangXLiuZCDengBW, et al.Honeycomb-like NiCo2O4@MnO2 nanosheets array/3D porous expanded graphite hybrids for high-performance microwave absorber with hydrophobic and flame-retardant functions. Chem Eng J2021; 419: 129547.
3.
ZhouJZhangGPLuoJL, et al.A MOFs-derived 3D superstructure nanocomposite as excellent microwave absorber. Chem Eng J2021; 426: 130725.
4.
ChenZCZhouJTFuXY, et al.Effect of different morphologies induced by in situ semi-conversion strategy on MOF-derived microwave absorbers. Chem Eng J2023; 474: 145917.
5.
SharmaSParneSRPandaSSS, et al.Progress in microwave absorbing materials: a critical review. Adv Colloid Interface Sci2024; 327: 103143.
JiaJLiangHChenG, et al.A review on one-dimensional carbon-based composites as electromagnetic wave absorbers . J Mater Sci: Mater Electron2022; 33: 567–584.
8.
LvHLYangZHPanH, et al.Electromagnetic absorption materials: current progress and new frontiers. Prog Mater Sci2022; 127: 100946.
9.
ChenNKXiaoYYWangC, et al.Dual resonance behavior and enhanced microwave absorption performance of Fe3O4@C@MoS2 composites with shape magnetic anisotropy. ACS Appl Mater Interfaces2023; 15: 48529–48542.
10.
WangNNanKZhengH, et al.Two-phase magnetic nanospheres with magnetic coupling effect encapsulated in porous carbon to achieve lightweight and efficient microwave absorbers. J Colloid Interface Sci2024; 671: 56–66.
11.
YanTMYeXCHeEY, et al.Preparation of a double-layer bionic bamboo structure absorber based on CB/PLA-TPU composites and its broadband microwave absorption characteristics. J Alloys Compd2024; 990: 174461.
12.
WangGSWuYYZhangXJ, et al.Controllable synthesis of uniform ZnO nanorods and their enhanced dielectric and absorption properties. J Mater Chem A2014; 2: 8644–8651.
13.
ZhangHPangHFDuanYP, et al.Facile morphology controllable synthesis of zinc oxide decorated carbon nanotubes with enhanced microwave absorption. J Mater Sci: Mater Electron2021; 32: 12208–12222.
14.
SaeedMUl HaqRSAhmedS, et al.Recent advances in carbon nanotubes, graphene and carbon fibers-based microwave absorbers. J Alloys Compd2024; 970: 172625.
15.
NieLJWanZLShuRW. Synthesis of magnesium ferrite decorated MXene composites with broadband and high-efficiency microwave dissipation performance. Compos Sci Technol2024; 256: 110764.
16.
ZhangYFZhangLZhouBQ, et al.Hierarchical 2H/1T-MoSe2@ graphene on cotton fabric for multifunctional and flexible microwave absorption. Carbon N Y2023; 205: 562–572.
17.
KaramiMRJalehBNasriA, et al.Development of CuS/C composite for microwave absorption using lignin biopolymer. J Mater Res Technol2024; 32: 1368–1381.
18.
CaiRYangPARuanHB, et al.Directional control of electromagnetic parameters of Fe@Ni nanowires for ultrathin and low-frequency microwave absorbing. Appl Surf Sci2024; 668: 160434.
19.
NaqviSTASinghCGodaraSK. Functionalization and synthesis of biomass and its composites as renewable, lightweight and eco-efficient microwave-absorbing materials: a review. J Alloys Compd2023; 968: 171991.
20.
ChenNKWangCXiaoYY, et al.Tunable microwave absorption properties of anisotropic Nd2Co17 micro-flakes. J Alloys Compd2023; 947: 169554.
21.
YangXYWangCHeJH, et al.Enhanced microwave absorption properties of solid waste fly ash with varying loading concentrations of Co. J Mater Sci: Mater Electron2023; 34: 2035.
22.
ChennaPPandaSSSSharmaS, et al.Optical, dielectric, and electromagnetic microwave absorption properties of hexagonal Ba3(VO4)2. ECS J Solid State Sci Technol2024; 13: 013010.
23.
ZhaoBDuYQLvHL, et al.Liquid-metal-assisted programmed galvanic engineering of core-shell nanohybrids for microwave absorption. Adv Funct Mater2023; 33: 2302172.
24.
JiangBQiCLYangH, et al.Recent advances of carbon-based electromagnetic wave absorption materials facing the actual situations. Carbon N Y2023; 208: 390–409.
25.
WangJYZhongSCLiuMY, et al.Multi-component attached carbon matrix composites with superior electromagnetic wave absorption performance and multifunctional applications. Carbon N Y2024; 229: 119508.
26.
WangYFZhouXHHanL, et al.In-situ growth of magnetic nanoparticles on honeycomb-like porous carbon nanofibers as lightweight and efficient microwave absorbers. Ceram Int2023; 49: 35476–35487.
27.
LiuZFYuanJTJinSW. Preparation of ZIF-8-derived ZnO/RGO composites and their electromagnetic wave absorption properties. J Anhui Univ (Natural Science Edition)2018; 42: 66–70.
28.
ZhengXLLiuCHZhuZH, et al.Preparation of broadband microwave absorbing material by blending zinc oxide and FeNiMo. J Nanchang Univ (Science Edition)2015; 3: 266–269.
29.
LiuYZhangHYLiuYX. Preparation and properties of thermally conductive and microwave-absorbing silicone rubber based on ZnO/FeSiAl. Basic Sci J Textile Univ2025; 38: 45–52.
30.
PanWQZhouWLiY. Preparation and microwave absorption properties of FeSiAl/ZnO@YCo composites. Mater Sci Eng Powder Metall2025; 30: 233–244.
