Nanophase Separation and Magnetic Spin Glass in Nd2/3Ca1/3MnO3

Marcela Kajňaková; Alexander Feher; Elena Fertman; Vladimir Desnenko; Anatoly Beznosov; Sergiy Dolya

doi:10.4028/www.scientific.net/SSP.190.675

Paper Titles

Non-Equilibrium Magnetization of a Dilute Suspension of Brownian Magnetic Particles
p.657

Effect of Electron Irradiation on the Non-Stoichiometric and Doped Lanthanum Manganites
p.663

Effect of Partial Oxygen Isotope Substitution on the Phase Diagram of (Pr_1-yEu_y)_0.7Ca_0.3CoO₃ Cobaltites
p.667

Effects of Non-Magnetic Doping upon Orbital and Magnetic Structures of Lanthanum Manganite
p.671

Nanophase Separation and Magnetic Spin Glass in Nd_2/3Ca_1/3MnO₃
p.675

Nucleation and Development of Clustered State in La_1-xSr_xCoO₃ and La_1-xCa_xCoO₃ Single Crystals at x=0.15
p.679

Infrared and X-Ray Absorption Spectra of Cu₂O and CuO Nanoceramics
p.683

Investigation of Phase Transitions in the Site-Diluted Three-Dimensional Potts Model
p.687

Structure and Properties of Ca_1-xEu_xMnO₃ Single Crystals
p.691

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Nanophase Separation and Magnetic Spin Glass in Nd_2/3Ca_1/3MnO₃

Abstract:

A study of the low temperature magnetic state of polycrystalline colossal magnetoresistance perovskite Nd_2/3Ca_1/3MnO₃ has been carried out. The data obtained, such as strongly divergent ZFC and FC static magnetizations and frequency dependent ac susceptibility, are evident of the glassy magnetic state of the system. Well defined maxima Tmax in the in-phase linear ac susceptibility χ curves were observed, indicating a spin-glass transition. Clear frequency dependence of the cusp temperature Tmax was found. The frequency dependence of Tmax was successfully analyzed by the dynamical scaling theory of a three-dimensional spin glass. Slow relaxation process and variety of relaxation times found imply a cluster glass magnetic state of the compound at low temperatures rather than a canonical spin glass state. The cluster glass state, accompanied by the multiple magnetic transitions of Nd_2/3Ca_1/3MnO₃, might exist due to the competing interaction between the FM clusters and the AFM matrix induced by the complex nanophase segregated state of the compound.