Spontaneous Rotation of Ferrimagnetism Driven by Antiferromagnetic Spin Canting

Spin-reorientation phase transitions that involve the rotation of a crystal's magnetization have been well characterized in distorted-perovskite oxides such as orthoferrites. In these systems spin reorientation occurs due to competing rare-earth and transition metal anisotropies coupled via f-d...

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Veröffentlicht in:	Physical review letters 2020-03, Vol.124 (12), p.127201-127201, Article 127201
Hauptverfasser:	Vibhakar, A M, Khalyavin, D D, Manuel, P, Liu, J, Belik, A A, Johnson, R D
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Sprache:	eng
Schlagworte:	Antiferromagnetism Distortion Exchanging Ferrimagnetism Filing Magnetism Perovskites Phase transitions Rare earth elements Rotation Transition metals
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creator	Vibhakar, A M Khalyavin, D D Manuel, P Liu, J Belik, A A Johnson, R D
description	Spin-reorientation phase transitions that involve the rotation of a crystal's magnetization have been well characterized in distorted-perovskite oxides such as orthoferrites. In these systems spin reorientation occurs due to competing rare-earth and transition metal anisotropies coupled via f-d exchange. Here, we demonstrate an alternative paradigm for spin reorientation in distorted perovskites. We show that the R_{2}CuMnMn_{4}O_{12} (R=Y or Dy) triple A-site columnar-ordered quadruple perovskites have three ordered magnetic phases and up to two spin-reorientation phase transitions. Unlike the spin-reorientation phenomena in other distorted perovskites, these transitions are independent of rare-earth magnetism, but are instead driven by an instability towards antiferromagnetic spin canting likely originating in frustrated Heisenberg exchange interactions, and the competition between Dzyaloshinskii-Moriya and single-ion anisotropies.
doi_str_mv	10.1103/PhysRevLett.124.127201
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subjects	Antiferromagnetism Distortion Exchanging Ferrimagnetism Filing Magnetism Perovskites Phase transitions Rare earth elements Rotation Transition metals
title	Spontaneous Rotation of Ferrimagnetism Driven by Antiferromagnetic Spin Canting
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