张猛   

张猛,副教授,硕士生导师,“泰山学者”团队核心成员。江苏省“科技副总”、青岛市十二届青年科技奖、青岛科技大学“科研新秀”、中国晶体学会会员、材料研究学会专业会员、中国化工学会高级会员、全国材料与器件科学家智库磁性材料与器件专家委员会常务委员、中国仪器仪表学会仪表功能材料分会电子元器件关键材料与技术专业委员会委员、国家自然科学基金/山东省自然科学基金/青岛市高新技术企业评审专家、SCI期刊《Frontiers ...Detials

Synthesis and enhanced electromagnetic wave absorption performances of Fe3O4@C decorated walnut shell-derived porous carbon

Release time:2021-03-15  Hits:

  • Key Words:EFFICIENT MICROWAVE-ABSORPTION; FACILE PREPARATION; COMPOSITES; LIGHTWEIGHT; MICROSPHERES; NANOTUBES; NANOCOMPOSITES; PERMITTIVITY; PERMEABILITY; MORPHOLOGY
  • Abstract:Bio-derived carbon is considered to be an ideal lightweight dielectric-type electromagnetic wave absorbing material (absorber). However, the vast majority of them cannot achieve satisfactory absorption performances just depending on dielectric loss. Herein, to obtain a superior electromagnetic wave absorber, Fe3O4@C nanospheres have been successfully decorated on the surface of the biomass (walnut shell)-derived porous carbon (BC) via a hydrothermal-calcination process. It is worth noting that the dielectric constant and permeability matching as well as corresponding electromagnetic wave absorption properties of the absorber can be effectively enhanced by adjusting the content of Fe3O4@C nano spheres. The as-synthesized optimal sample (BC/Fe3O4@C-2#) exhibits superior electromagnetic wave absorption performances with the minimum reflection loss (RL) value of -56.61 dB and wide effective absorbing bandwidth (EAB) of 2.72 GHz at 2.46 mm matching thickness, meanwhile, the widest EAB with the value of 5.68 GHz can be achieved at 1.46 mm thin matching thickness. Starting from the respective advantages of dielectric, magnetic and material components, a reasonable synergistic mechanism, including multiple reflection, Debye relaxation, interface polarization and other mechanisms are demonstrated to transmission and loss processes. This low cost, simple preparation process and excellent absorbing performance promise BC/Fe3O4@C nanocomposites being an excellent lightweight electromagnetic wave absorber. (C) 2020 Elsevier Ltd. All rights reserved.
  • Volume:167
  • Translation or Not:no