Title :
Giant tunneling magnetoresistance in polycrystalline nanostructured ZnxFe3-xO4-α-Fe2O3
Author :
Du, You-Wei ; Chen, Peng ; Ni, Gang ; Zhu, Jian-min ; Xing, Ding-yu
Author_Institution :
Lab. of Solid State Microstructures, Nanjing Univ., China
fDate :
9/1/2002 12:00:00 AM
Abstract :
Giant tunneling magnetoresistance effect (TMR) as large as 1280% at 4.2 K and 158% at 300 K was observed in Zn0.41Fe2.59O4-α-Fe2O3 polycrystalline sample. The Zn0.41Fe2.59O4 grains are separated by insulating α-Fe2O3 thin layer boundaries, The pattern of nanostructure has been verified by transmission electron microscopy and a high-resolution electron microscope, and the thickness of α-Fe2O3 boundary is about 6-7 nm. The huge TMR is attributed to the high spin-polarization of Zn0.41Fe2.59O4 grains and insulating antiferromagnetic α-Fe2O3 thin layer. The conductivity is found to depend exponentially on reciprocal temperature, which means the electronic transfer is dominated by thermally activated tunneling from grain to grain. The ZnxFe3-xO4 ferrite is a new type half-metallic material and has a huge TMR at room temperature.
Keywords :
electron spin polarisation; ferrites; giant magnetoresistance; magnetic hysteresis; nanostructured materials; transmission electron microscopy; tunnelling; zinc compounds; 300 K; 4.2 K; Zn0.41Fe2.59O4-Fe2O3; ferrimagnetic materials; giant tunneling magnetoresistance; half-metallic material; high spin polarization; hysteresis loops; insulating antiferromagnetic layer; insulating thin layer boundaries; nonhomogeneous media; polycrystalline nanostructured materials; reciprocal temperature; sol-gel method; spintronics; thermally activated tunneling; transmission electron microscopy; two-phase sample; Antiferromagnetic materials; Conducting materials; Ferrites; Insulation; Iron; Temperature dependence; Thermal conductivity; Transmission electron microscopy; Tunneling magnetoresistance; Zinc;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2002.803164
