Low-frequency Microwave Absorption of CIPs@Mn0.8Zn0.2Fe2O4-CNTs Composites

Haiyan CHEN; Zhipeng TANG; Liangjun YIN; Linbo ZHANG; Xin XU

doi:10.15541/jim20230333

[1] C L WANG. Harm of electromagnetic radiation pollution and its protection measures. Construction & Design for Engineering, 4: 131(2017).

[2] K NASRI, D DAGHFOUS, A LANDOULSI. Effects of microwave (2.45 GHz) irradiation on some biological characters of Salmonella typhimurium. Comptes Rendus Biologies, 194(2013).

[3] Z ZHANG, F WANG, X Q ZHANG et al. Recent advance of broadband and thin microwave absorbing material for low frequency. Journal of Functional Materials, 6038(2019).

[4] Y T TANG, P F YIN, L M ZHANG et al. Novel carbon encapsulated zinc ferrite/MWCNTs composite: preparation and low- frequency microwave absorption investigation. Ceramics International, 28250(2020).

[5] S SONG, A ZHANG, L CHEN et al. A novel multi-cavity structured MOF derivative/porous graphene hybrid for high performance microwave absorption. Carbon, 176: 279(2021).

[6] 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).

[7] R DOSOUDIL, K LISY, J KRUZELAK. Permeability, permittivity and EM-wave absorption properties of polymer composites filled with MnZn ferrite and carbon black. Acta Physica Polonica A, 827(2020).

[8] Y LEI, Z YAO, S LI et al. Broadband high-performance electromagnetic wave absorption of Co-doped NiZn ferrite/polyaniline on MXenes. Ceramics International, 10006(2020).

[9] R DOSOUDIL, M USAKOVA. High-frequency absorbing performances of carbonyl iron/MnZn ferrite/PVC polymer composites. Acta Physica Polonica A, 687(2017).

[10] Y MU, Z H MA, H S LIANG et al. Ferrite-based composites and morphology-controlled absorbers. Rare Metals, 2943(2022).

[11] X YE, Z CHEN, S AI et al. Porous SiC/melamine-derived carbon foam frameworks with excellent electromagnetic wave absorbing capacity. Journal of Advanced Ceramics, 479(2019).

[12] B X MAO, X S XIA, R R QIN et al. Microstructure evolution and microwave absorbing properties of novel double-layered SiC reinforced SiO₂aerogel. Journal of Alloys and Compounds, 936: 168314(2023).

[13] N L BURHANNUDDIN, N A NORDIN, S A MAZLAN et al. Physicochemical characterization and rheological properties of magnetic elastomers containing different shapes of corroded carbonyl iron particles. Scientific Reports, 11: 868(2021).

[14] M Y HAN, M ZHOU, Y WU et al. Constructing angular conical FeSiAl/SiO₂ composites with corrosion resistance for ultra-broadband microwave absorption. Journal of Alloys and Compounds, 902: 163792(2022).

[15] D JIN, Y G DU, X L YANG et al. Facile synthesis of Ti₃C₂T_x- MXene composite with polyhedron Fe₃O₄/carbonyl iron toward microwave absorption. Journal of Materials Science: Materials in Electronics, 32: 23762(2021).

[16] T MA, Y CUI, Y L SHA et al. Facile synthesis of hierarchically porous rGO/MnZn ferrite composites for enhanced microwave absorption performance. Synthetic Metals, 265: 116407(2020).

[17] D D MIN, W C ZHOU, F LUO et al. Facile preparation and enhanced microwave absorption properties of flake carbonyl iron/ Fe₃O₄ composite. Journal of Magnetism and Magnetic Materials, 435: 26(2017).

[18] L CHEN, Z Z GU, M X ZHANG. Microwave absorbing property of thin coating in the broadband low-frequency range. Materials Science Forum, 916: 33(2018).

[19] S W LIU, C Z YUAN, K M MA et al. Preparation and low- frequency microwave-absorbing properties of MWCNTs/Co-Ni/ Fe₃O₄ hybrid material. Functional Materials Letters, 9: 1650035(2016).

[20] X G SU, J WANG, X X ZHANG et al. One-step preparation of CoFe₂O₄/FeCo/graphite nano-sheets hybrid composites with tunable microwave absorption performance. Ceramics International, 12353(2020).

[21] W LI, C LE, J LV et al. Electromagnetic and oxidation resistance properties of core-shell structure flaked carbonyl iron powder@SiO₂ nanocomposite. Physica Status Solidi(a), 1600747(2017).

[22] P SONG, B LIU, H QIU et al. MXenes for polymer matrix electromagnetic interference shielding composites: a review. Composites Communications, 24: 100653(2021).

[23] P YIN, L ZHANG, H WU et al. Two-step solvothermal synthesis of (Zn_0.5Co_0.5Fe₂O₄/Mn_0.5Ni_0.5Fe₂O₄)@C-MWCNTs hybrid with enhanced low frequency microwave absorbing performance. Nanomaterials, 1601(2019).

[24] J SNOEK. Dispersion and absorption in magnetic ferrites at frequencies above one Mc/s. Physica, 207(1948).

[25] O ACHER, S DUBOURG. Generalization of Snoek's law to ferromagnetic films and composites. Physical Review B, 77: 104440(2008).

[26] R HAN, X H HAN, L QIAO et al. Enhanced microwave absorption of ZnO-coated planar anisotropy carbonyl-iron particles in quasimicrowave frequency band. Materials Chemistry and Physics, 317(2011).

[27] J W OH, Y W YOON, J HEO et al. Electrochemical detection of nanomolar dopamine in the presence of neurophysiological concentration of ascorbic acid and uric acid using charge-coated carbon nanotubes via facile and green preparation. Talanta, 147: 453(2016).

[28] P YIN, L ZHANG, Y TANG et al. Earthworm-like (Co/CoO)@C composite derived from MOF for solving the problem of low- frequency microwave radiation. Journal of Alloys and Compounds, 881: 160556(2021).

[29] L LAN, Y P ZHENG, A B ZHANG et al. Study of ionic solvent- free carbon nanotube nanofluids and its composites with epoxy matrix. Journal of Nanoparticle Research, 14: 735(2012).

[30] Z NICHOLAS, R R VICTOR, S NAVADEEP et al. Heat generation in magnetic hyperthermia by manganese ferrite-based nanoparticles arises from Néel collective magnetic relaxation. ACS Applied Nano Materials, 7521(2022).

[31] F WANG, X LI, Z CHEN et al. Efficient low-frequency microwave absorption and solar evaporation properties of γ-Fe₂O₃ nanocubes/graphene composites. Chemical Engineering Journal, 405: 126676(2021).

[32] T PRODROMAKIS, C PAPAVASSILIOU. Engineering the Maxwell-Wagner polarization effect. Applied Surface Science, 6989(2009).

[33] P YIN, L ZHANG, Y JIANG et al. Recycling of waste straw in sorghum for preparation of biochar/(Fe,Ni) hybrid aimed at significant electromagnetic absorbing of low-frequency band. Journal of Materials Research and Technology, 14212(2020).

[34] H PENG, X MA, C LIU et al. Facile fabrication of indium tin oxide/nanoporous carbon composites with excellent low-frequency microwave absorption. Journal of Alloys and Compounds, 889: 161636(2021).

[35] Z MA, Y ZHANG, C CAO et al. Attractive microwave absorption and the impedance match effect in zinc oxide and carbonyl iron composite. Physica B-Condensed Matter, 406: 4620(2011).