Magnetic phase transition and continuous spin switching in a high-entropy orthoferrite single crystal

Rare-earth orthoferrite REFeO 3 (where RE is a rare-earth ion) is gaining interest. We created a high-entropy orthoferrite (Tm 0.2Nd 0.2Dy 0.2Y 0.2Yb 0.2)FeO 3 (HEOR) by doping five RE ions in equimolar ratios and grew the single crystal by optical floating zone method. It strongly tends to form a s...

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Published in:Frontiers of physics 2024-04, Vol.19 (2), p.23203, Article 23203
Main Authors: Yang, Wanting, Zhu, Shuang, Luo, Xiong, Ma, Xiaoxuan, Shi, Chenfei, Song, Huan, Sun, Zhiqiang, Guo, Yefei, Dedkov, Yuriy, Kang, Baojuan, Bao, Jin-Ke, Cao, Shixun
Format: Article
Language:English
Subjects:
Anisotropy
Astronomy
Astrophysics and Cosmology
Atomic
Condensed Matter Physics
Crystallography
Entropy
Ferromagnetism
high-entropy oxide
Low temperature
Magnetic fields
magnetocaloric effect
Molecular
Optical and Plasma Physics
Particle and Nuclear Physics
Phase transitions
Physics
Physics and Astronomy
Rare earth elements
rare-earth orthoferrite
Refrigeration
Research Article
Single crystals
Solid phases
spin reorientation transition
spin switching
Switching
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Summary:Rare-earth orthoferrite REFeO 3 (where RE is a rare-earth ion) is gaining interest. We created a high-entropy orthoferrite (Tm 0.2Nd 0.2Dy 0.2Y 0.2Yb 0.2)FeO 3 (HEOR) by doping five RE ions in equimolar ratios and grew the single crystal by optical floating zone method. It strongly tends to form a single-phase structure stabilized by high configurational entropy. In the low-temperature region (11.6‒ 14.4 K), the spin reorientation transition (SRT) of Γ 2 ( F x , C y , G z )‒Γ 24‒Γ 4 ( G x , A y , F z ) occurs. The weak ferromagnetic (FM) moment, which comes from the Fe sublattices distortion, rotates from the a- to c-axis. The two-step dynamic processes (Γ 2‒Γ 24‒Γ 4) are identified by AC susceptibility measurements. SRT in HEOR can be tuned in the range of 50‒60000 Oe, which is an order of magnitude larger than that of orthoferrites in the peer system, making it a candidate for high-field spin sensing. Typical spin-switching (SSW) and continuous spin-switching (CSSW) effects occur under low magnetic fields due to the strong interactions between RE‒Fe sublattices. The CSSW effect is tunable between 20‒50 Oe, and hence, HEOR potentially can be applied to spin modulation devices. Furthermore, because of the strong anisotropy of magnetic entropy change ( − Δ S m ) and refrigeration capacity ( RC) based on its high configurational entropy, HEOR is expected to provide a novel approach for refrigeration by altering the orientations of the crystallographic axes (anisotropic configurational entropy).
ISSN:2095-0462
2095-0470
DOI:10.1007/s11467-023-1343-x