.554. 工程科学学报，第41卷，第5期 水热法 水热法 Fe.O/RGO % 38 GO Fe,0 @BaTiO/RGO 图7Fe0,@BaT0,/RG0合成路线[6] Fig.7 Schematic illustration of the synthesis process of Fe@BaTiO/RCO nanocomposites(] 参考文献 an iron microplate with excellent microwave absorption performance [1]Xu J S,Zhou W C,Luo F,et al.Research progress on radar and its direct micromagnetic analysis by electron holography and stealth technique and radar absorbing materials.Mater Rer,2014, Lorentz microscopy.J Mater Chem C,2017,5(24):6047 28(5):46 [10]Duan WY,Yin X W,Li Q.et al.A review of absorption prop- (徐剑盛，周万城，罗发，等.雷达波隐身技术及雷达吸波材 erties in silicon-based polymer derived ceramics.J Eur Ceram 料研究进展.材料导报，2014,28(5)：46) Sc,2016,36(15):3681 [2]Liu Z H,Ban G D.Jiang Z Q,et al.Absorbing properties of [11]Qin F,Brosseau C.A review and analysis of microwave absorp- nickalloy/iron package mica powder composite absorbing materi- tion in polymer composites filled with carbonaceous particles.J als.J Comput Theor Nanosci,2017,14(4):1794 Appl Phys,2012,111(6):061301 [3]Wang H B,Liu S X,Huo JC,et al.Progress on inorganic wave- [12]Ding D.Wang Y,Li X D,et al.Rational design of core-shell Co absorbing materials.Bull Chin Ceram Soc,2008,27(4):754 C microspheres for high-performance microwave absorption. (王海滨，刘树信，霍冀川，等.无机吸波材料研究进展.硅 Carbon,2017,111:722 酸盐通报，2008,27(4)：754) [13]Zhou C.Geng S,Xu X W,et al.Lightweight hollow carbon [4]Hu X S,Shen Y,Wang L M,et al.Research progress of novel nanospheres with tunable sizes towards enhancement in microwave microwave absorbing materials.Carbon Tech,2016,35(2):11 absorption.Carbon,2016,108:234 (胡小赛，沈勇，王黎明，等.吸波材料研究新进展.炭素技 [14]Song W L,Zhang K L,Chen M J,et al.A universal permittivi- 术，2016,35(2)：11) ty-attenuation evaluation diagram for accelerating design of dielec- [5]Tian C H,Du Y C,Xu P,et al.Constructing uniform core-shell tric-based microwave absorption materials:A case of graphene- PPy@PANI composites with tunable shell thickness toward en- based composites.Carbon,2017,118:86 hancement in microwave absorption.ACS Appl Mater Interfaces, [15]Chylekt P.Light scattering by small particles in an absorbing me- 2015,7(36):20090 dium.J0 ot Soc Am,1977,67(4):561 [6]Zhou M,Zhang X.Wang L,et al.Enhanced microwave absorp- [16]Jnossy L.Classical and wave mechanical theory of Rayleigh tion performance of hollow a-MnO2 nanourchins.J Nanosci Nano- scattering.Acta Phys Academiae Scientiarum Hungaricae,1976, technol,2013,13(2):904 41(1):41 [7]Liu Q H,Xu X H,Xia W X,et al.Dependency of magnetic mi- [17]Wagner P E.A constant-angle Mie scattering method (CAMS) crowave absorption on surface architecture of Co Niso hierarchical for investigation of particle formation processes.Colloid Inter structures studied by electron holography.Nanoscale,2015,7 face Sci,1985,105(2):456 (5):1736 [18] Duan T,Yang Y S.PengTJ,et al.Review of progress in core- [8] Yuan K P.Che R C.Cao Q,et al.Designed fabrication and shell structural nanocomposite material.Mater Rer,2009.23 characterization of three-dimensionally ordered arrays of core-shell (2):19 magnetic mesoporous carbon microspheres.ACS Appl Mater Inter- (段涛，杨玉山，彭同江，等.核壳型纳米复合材料的研究进 faces,2015,7(9):5312 展.材料导报，2009,23(2)：19) [9]You W B,She W,Liu Z W,et al.High-temperature annealing of [19]Liu Y,Li Z Y,Yu X,et al.Design of metamaterial electromag-工程科学学报,第 41 卷,第 5 期 图 7 Fe3O4@ BaTiO3 / RGO 合成路线[56] Fig. 7 Schematic illustration of the synthesis process of Fe3O4@ BaTiO3 / RGO nanocomposites [56] 参 考 文 献 [1] Xu J S, Zhou W C, Luo F, et al. Research progress on radar stealth technique and radar absorbing materials. Mater Rev, 2014, 28(5): 46 (徐剑盛, 周万城, 罗发, 等. 雷达波隐身技术及雷达吸波材 料研究进展. 材料导报, 2014, 28(5): 46) [2] Liu Z H, Ban G D, Jiang Z Q, et al. Absorbing properties of nickalloy / iron package mica powder composite absorbing materi鄄 als. J Comput Theor Nanosci, 2017, 14(4): 1794 [3] Wang H B, Liu S X, Huo J C, et al. Progress on inorganic wave鄄 absorbing materials. Bull Chin Ceram Soc, 2008, 27(4): 754 (王海滨, 刘树信, 霍冀川, 等. 无机吸波材料研究进展. 硅 酸盐通报, 2008, 27(4): 754) [4] Hu X S, Shen Y, Wang L M, et al. Research progress of novel microwave absorbing materials. Carbon Tech, 2016, 35(2): 11 (胡小赛, 沈勇, 王黎明, 等. 吸波材料研究新进展. 炭素技 术, 2016, 35(2): 11) [5] Tian C H, Du Y C, Xu P, et al. Constructing uniform core鄄鄄shell PPy@ PANI composites with tunable shell thickness toward en鄄 hancement in microwave absorption. ACS Appl Mater Interfaces, 2015, 7(36): 20090 [6] Zhou M, Zhang X, Wang L, et al. Enhanced microwave absorp鄄 tion performance of hollow 琢鄄MnO2 nanourchins. J Nanosci Nano鄄 technol, 2013, 13(2): 904 [7] Liu Q H, Xu X H, Xia W X, et al. Dependency of magnetic mi鄄 crowave absorption on surface architecture of Co20Ni80 hierarchical structures studied by electron holography. Nanoscale, 2015, 7 (5): 1736 [8] Yuan K P, Che R C, Cao Q, et al. Designed fabrication and characterization of three鄄dimensionally ordered arrays of core鄄鄄shell magnetic mesoporous carbon microspheres. ACS Appl Mater Inter鄄 faces, 2015, 7(9): 5312 [9] You W B, She W, Liu Z W, et al. High鄄temperature annealing of an iron microplate with excellent microwave absorption performance and its direct micromagnetic analysis by electron holography and Lorentz microscopy. J Mater Chem C, 2017, 5(24): 6047 [10] Duan W Y, Yin X W, Li Q, et al. A review of absorption prop鄄 erties in silicon鄄based polymer derived ceramics. J Eur Ceram Soc, 2016, 36(15): 3681 [11] Qin F, Brosseau C. A review and analysis of microwave absorp鄄 tion in polymer composites filled with carbonaceous particles. J Appl Phys, 2012, 111(6): 061301 [12] Ding D, Wang Y, Li X D, et al. Rational design of core鄄shell Co @ C microspheres for high鄄performance microwave absorption. Carbon, 2017, 111: 722 [13] Zhou C, Geng S, Xu X W, et al. Lightweight hollow carbon nanospheres with tunable sizes towards enhancement in microwave absorption. Carbon, 2016, 108: 234 [14] Song W L, Zhang K L, Chen M J, et al. A universal permittivi鄄 ty鄄attenuation evaluation diagram for accelerating design of dielec鄄 tric鄄based microwave absorption materials: A case of graphene鄄 based composites. Carbon, 2017, 118: 86 [15] Ch伥lekt P. Light scattering by small particles in an absorbing me鄄 dium. J Opt Soc Am, 1977, 67(4): 561 [16] J觃nossy L. Classical and wave mechanical theory of Rayleigh scattering. Acta Phys Academiae Scientiarum Hungaricae, 1976, 41(1): 41 [17] Wagner P E. A constant鄄angle Mie scattering method ( CAMS) for investigation of particle formation processes. J Colloid Inter鄄 face Sci, 1985, 105(2): 456 [18] Duan T, Yang Y S, Peng T J, et al. Review of progress in core鄄 shell structural nanocomposite material. Mater Rev, 2009, 23 (2): 19 (段涛, 杨玉山, 彭同江, 等. 核壳型纳米复合材料的研究进 展. 材料导报, 2009, 23(2): 19) [19] Liu Y, Li Z Y, Yu X, et al. Design of metamaterial electromag鄄 ·554·