Superfluous electromagnetic(EM)waves as a new type of pollution have severely imperiled our life and working environment.Microwave absorption materials(MAMs)are reliable absorbers owing to their efficient EM energy di...Superfluous electromagnetic(EM)waves as a new type of pollution have severely imperiled our life and working environment.Microwave absorption materials(MAMs)are reliable absorbers owing to their efficient EM energy dissipation ability.The challenge to develop high-performance MAMs is to find magnetic and dielectric composites.In this work,a facile in situ carbothermal reduction method was carried out to design Co nanoparticles encapsulated in N and O dual-doped carbon(Co@NOC)composites.The Co@NOC exhibited a high reflective loss value of−48.9 dB and an effective absorption bandwidth of 14.96 GHz in the range of 3.04–18.00 GHz.The enhanced MA properties could be attributed to magnetic loss(eddy current effect and natural resonance),diversified dielectric loss(conductivity loss,and dipole and interfacial polarizations),and favorable impedance matching performance.In addition,N and O substitutions as dipolar sites were greatly beneficial to enhancing the dipole polarization,leading to enhanced MA properties.展开更多
基金supported by the National Natural Science Foundation of China(Grant No.91326102)the Science and Technology Development Foundation of China Academy of Engineering Physics(Grant No.2013A0301012)the Science and Technology Innovation Research Foundation of Institute of Nuclear Physics and Chemistry.
文摘Superfluous electromagnetic(EM)waves as a new type of pollution have severely imperiled our life and working environment.Microwave absorption materials(MAMs)are reliable absorbers owing to their efficient EM energy dissipation ability.The challenge to develop high-performance MAMs is to find magnetic and dielectric composites.In this work,a facile in situ carbothermal reduction method was carried out to design Co nanoparticles encapsulated in N and O dual-doped carbon(Co@NOC)composites.The Co@NOC exhibited a high reflective loss value of−48.9 dB and an effective absorption bandwidth of 14.96 GHz in the range of 3.04–18.00 GHz.The enhanced MA properties could be attributed to magnetic loss(eddy current effect and natural resonance),diversified dielectric loss(conductivity loss,and dipole and interfacial polarizations),and favorable impedance matching performance.In addition,N and O substitutions as dipolar sites were greatly beneficial to enhancing the dipole polarization,leading to enhanced MA properties.
