High-frequency magnetic materials are crucial for realizing anti-electromagnetic interference in GHz communication devices and electronic equipment.Current mainstream strategy to enhance highfrequency magnetic losses ...High-frequency magnetic materials are crucial for realizing anti-electromagnetic interference in GHz communication devices and electronic equipment.Current mainstream strategy to enhance highfrequency magnetic losses is shape anisotropy,and it is still difficult to obtain an improvement in intrinsic magnetic loss through electronic structure design.In this paper,the effects of 4f-3d interaction between Er and Fe/Co on magnetic moment,charge migration,and spin polarization were investigated based on density functional theory(DFT).The results show that Er 4f-Fe 3d orbitals undergo significant hybridization at around-4 eV,which increase the electronic locality of Fe and enhance the spin of Fe from 2.86 h/2 to 2.91 h/2.The Fe_(0.5-x)Co_(0.5)Er_(x)(0≤x≤0.05)alloys were further prepared by vacuum induction melting and mechanical alloying methods.The saturation magnetization intensity(Ms)increases from 0.141 to 0.182 A·m^(2)/g with increasing Er content.The μ"of Fe_(0.47)Co_(0.5)Er_(0.03)at 16.7 GHz increases from 0.55 to 0.93,and the frequency range over which tanδ_μvalues are greater than 0.5covers 8.0-18.0 GHz,with the maximum value being 0.83 at 17.0 GHz.These results indicate that the Fe_(0.5-x)Co_(0.5)Er_(x)/paraffin composite materials have excellent high-frequency magnetic losses and are promising candidates in the field of microwave-absorbing materials.展开更多
基金Project supported by the Nation Natural Science Foundation of China(52304410,51972242)Major Project of Hubei Province(2023BAA003)。
文摘High-frequency magnetic materials are crucial for realizing anti-electromagnetic interference in GHz communication devices and electronic equipment.Current mainstream strategy to enhance highfrequency magnetic losses is shape anisotropy,and it is still difficult to obtain an improvement in intrinsic magnetic loss through electronic structure design.In this paper,the effects of 4f-3d interaction between Er and Fe/Co on magnetic moment,charge migration,and spin polarization were investigated based on density functional theory(DFT).The results show that Er 4f-Fe 3d orbitals undergo significant hybridization at around-4 eV,which increase the electronic locality of Fe and enhance the spin of Fe from 2.86 h/2 to 2.91 h/2.The Fe_(0.5-x)Co_(0.5)Er_(x)(0≤x≤0.05)alloys were further prepared by vacuum induction melting and mechanical alloying methods.The saturation magnetization intensity(Ms)increases from 0.141 to 0.182 A·m^(2)/g with increasing Er content.The μ"of Fe_(0.47)Co_(0.5)Er_(0.03)at 16.7 GHz increases from 0.55 to 0.93,and the frequency range over which tanδ_μvalues are greater than 0.5covers 8.0-18.0 GHz,with the maximum value being 0.83 at 17.0 GHz.These results indicate that the Fe_(0.5-x)Co_(0.5)Er_(x)/paraffin composite materials have excellent high-frequency magnetic losses and are promising candidates in the field of microwave-absorbing materials.
