Manganese-Zinc-Ferrites with Improved Magnetic and Mechanical Properties

Baumgärtner, H.; Dreikorn, J.; Dreyer, Robert Marx; Michalowsky, L.; Pippel, Eckhard; Woltersdorfr, J.

doi:10.1051/jp4:1997114

Cited by 6 publications

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“…10 This degradation of microstructure by thermal shock is dependent on multiple factors such as the grain sizes, the size and distribution of pores and cracks, and types and distribution of grain boundaries. 11 It appears that in this study, a temperature sweep rate of 20 deg/min resulted in thermal shocks causing the microstructural contribution to coercivity to dominate the magnetocrystalline anisotropy contribution at 100 K and 50 K, hence the observed increase in coercivity. Therefore, the temperature dependence of coercivity is dominated by magnetocrystalline anisotropy while the compositional dependence of coercivity is dominated by microstructure.…”

Section: -mentioning

confidence: 90%

Thermal effects on the magnetic properties of titanium modified cobalt ferrite

Nlebedim

Jiles

2015

Journal of Applied Physics

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The temperature dependence of the magnetic properties of titanium modified cobalt ferrite is presented. The change of maximum magnetization obtained at H ≈ 2.4 MA/m between any two temperatures increases systematically with composition, which is desirable for applications in devices. Variation in magnetocrystalline anisotropy and coercivity were different from previous studies on cation substituted cobalt ferrite. At lower concentrations, the effect of lower thermal energy dominated the effect of non-magnetic cation substitutions in controlling the anisotropy.The reverse was the case at higher concentrations. The temperature dependence of coercivity is dominated by the contribution of magnetocrystalline anisotropy to coercivity, while the compositional dependence of coercivity is dominated by microstructural contribution through the pinning of domain walls. The temperature dependence of the magnetic properties of titanium modified cobalt ferrite is presented. The change of maximum magnetization obtained at H % 2.4 MA/m between any two temperatures increases systematically with composition, which is desirable for applications in devices. Variation in magnetocrystalline anisotropy and coercivity were different from previous studies on cation substituted cobalt ferrite. At lower concentrations, the effect of lower thermal energy dominated the effect of nonmagnetic cation substitutions in controlling the anisotropy. The reverse was the case at higher concentrations. The temperature dependence of coercivity is dominated by the contribution of magnetocrystalline anisotropy to coercivity, while the compositional dependence of coercivity is dominated by microstructural contribution through the pinning of domain walls. V C 2015 AIP Publishing LLC.

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