[CITATION][C] Anisotropic magnetoresistance involves metal-insulator transition in single crystal La0. 77Ca0. 23MnO3
W Jiang, XZ Zhou, HP Kunkel, G Williams… - arXiv preprint arXiv …, 2007 - arxiv.org
W Jiang, XZ Zhou, HP Kunkel, G Williams, Y Mukovskii, K Glazyrin
arXiv preprint arXiv:0710.5537, 2007•arxiv.orgWe report anisotropic magnetoresistance (AMR) behaviors related to the metal-insulator
transition (MIT) in a colossal-magnetoresistance (CMR) single crystal of composition La 0.77
Ca 0.23 MnO 3, ie, as MIT temperature (T mi) driven by the applied magnetic field, the
associated AMR exhibits completely different characteristics. At 180 K< Curie temperature
Tc= 185 K, it presents a pure ferromagnetic (FM) behavior related to the crystalline
anisotropy. While system evolves into temperatures between T
transition (MIT) in a colossal-magnetoresistance (CMR) single crystal of composition La 0.77
Ca 0.23 MnO 3, ie, as MIT temperature (T mi) driven by the applied magnetic field, the
associated AMR exhibits completely different characteristics. At 180 K< Curie temperature
Tc= 185 K, it presents a pure ferromagnetic (FM) behavior related to the crystalline
anisotropy. While system evolves into temperatures between T
We report anisotropic magnetoresistance (AMR) behaviors related to the metal-insulator transition (MIT) in a colossal-magnetoresistance (CMR) single crystal of composition La 0.77 Ca 0.23 MnO 3, ie, as MIT temperature (T mi) driven by the applied magnetic field, the associated AMR exhibits completely different characteristics. At 180 K< Curie temperature Tc= 185 K, it presents a pure ferromagnetic (FM) behavior related to the crystalline anisotropy. While system evolves into temperatures between T
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