Role of structure imperfection in the formation of the magnetotransport properties of rare-earth manganites with a perov
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DISORDER, AND PHASE TRANSITION IN CONDENSED SYSTEM
Role of Structure Imperfection in the Formation of the Magnetotransport Properties of Rare-Earth Manganites with a Perovskite Structure A. V. Pashchenkoa, b*, V. P. Pashchenkoa†, V. K. Prokopenkoa, V. A. Turchenkoc, Yu. F. Revenkoa, A. S. Mazura, V. Ya. Sychevaa, N. A. Liedienova, V. G. Pitsyugad, and G. G. Levchenkoa a Galkin
Donetsk Institute for Physics and Engineering, National Academy of Sciences of Ukraine, Kiev, 03680 Ukraine Tugan-Baranovsky Donetsk National University of Economy and Trade, Kryvoy Rog, 50005 Ukraine c Joint Institute for Nuclear Research, Dubna, Moscow oblast, 141980 Russia d Donetsk National University, Vinnitsa, 21021 Ukraine *e-mail: [email protected]
b
Received April 2, 2016
Abstract—The structure, the structure imperfection, and the magnetoresistance, magnetotransport, and microstructure properties of rare-earth perovskite La0.3Ln0.3Sr0.3Mn1.1O3 – δ manganites are studied by X-ray diffraction, thermogravimetry, electrical resistivity measurement, magnetic, 55Mn NMR, magnetoresistance measurement, and scanning electron microscopy. It is found that the structure imperfection increases, and the symmetry of a rhombohedrally distorted R 3 c perovskite structure changes into its pseudocubic type during isovalent substitution for Ln = La3+, Pr3+, Nd3+, Sm3+, or Eu3+ when the ionic radius of an A cation decreases. Defect molar formulas are determined for a real perovskite structure, which contains anion and cation vacancies. The decrease in the temperatures of the metal–semiconductor (Tms) and ferromagnet– paramagnet (TC) phase transitions and the increase in electrical resistivity ρ and activation energy Ea with increasing serial number of Ln are caused by an increase in the concentration of vacancy point defects, which weaken the double exchange 3d4(Mn3+)–2p6(O2–)–3d3(Mn4+)–V(a)–3d4(Mn3+). The crystal structure of the compositions with Ln = La contains nanostructured planar clusters, which induce an anomalous magnetic hysteresis at T = 77 K. Broad and asymmetric 55Mn NMR spectra support the high-frequency electronic double exchange Mn3+(3d4) ↔ O2–(2p6) ↔ Mn4+(3d3) and indicate a heterogeneous surrounding of manganese by other ions and vacancies. A correlation is revealed between the tunneling magnetoresistance effect and the crystallite size. A composition–structure imperfection–property experimental phase diagram is plotted. This diagram supports the conclusion about a strong influence of structure imperfection on the formation of the magnetic, magnetotransport, and magnetoresistance properties of rare-earth perovskite manganites. DOI: 10.1134/S1063776116150127
1. INTRODUCTION Rare-earth (RE) manganites with a perovskite structure exhibit the magnetoresistance (MR) effect and belong to strongly correlated systems, the investigation of which is related to finding the mechanisms of changing their spin and electron states [1]. Such systems are characterized by the coexistence and mutual influence of different types of competing interactions,
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