U2 N i2Sn and the origin of magnetic anisotropy in uranium compounds

S. Mašková; A. V. Andreev; Y. Skourski; S. Yasin; D. I. Gorbunov; S. Zherlitsyn; H. Nakotte; K. Kothapalli; F. Nasreen; C. Cupp; H. B. Cao; A. Kolomiets; L. Havela

doi:10.1103/PhysRevB.99.064415

U2 N i2Sn and the origin of magnetic anisotropy in uranium compounds

S. Mašková, A. V. Andreev, Y. Skourski, S. Yasin, D. I. Gorbunov, S. Zherlitsyn, H. Nakotte, K. Kothapalli, F. Nasreen, C. Cupp, H. B. Cao, A. Kolomiets, L. Havela

Single Crystal Diffraction

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Abstract

U2Ni2Sn is a member of a large family of intermetallic compounds with the tetragonal Mo2FeB2 crystal structure. It orders antiferromagnetically at 25 K with propagation vector q=(0,0,12). Magnetization, magnetoacoustic, and neutron-diffraction experiments on a single crystal provide evidence that the uranium moments align parallel to the c axis with the anisotropy energy of ≈170 K, indicating that U2Ni2Sn can be classified as an Ising system. The results are at variance with previous studies on polycrystals, which indicated different magnetic structure, and which were incompatible with the 5f-5f two-ion anisotropy model dominant in most U band systems. High-field magnetization studies exhibit a weak linear response for fields along the basal plane up to the highest field applied (60 T), while the c-axis magnetization curve exhibits three metamagnetic transitions at approximately 30, 39, and 50 T. The U magnetic moments of 0.87μB, the low magnetic entropy, and the enhanced Sommerfeld coefficient γ=187mJ/molf.u.K2 suggest that U2Ni2Sn can be classified as an itinerant antiferromagnet with strong electron-electron correlations.

Original language	English
Article number	064415
Journal	Physical Review B
Volume	99
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevB.99.064415
State	Published - Feb 15 2019

Funding

This work was supported by the Czech Science Foundation under Grants No. 18-02344S and No. 16-03593S. Neutron scattering studies were performed at the Los Alamos Neutron Science Center (LANSCE) and Oak Ridge High Flux Isotope Reactor (HFIR), both DOE Office of Science User Facilities. We acknowledge the support of the High Magnetic Field Laboratory (HLD) at Helmholtz-Zentrum Dresden-Rossendorf (HZDR), a member of the European Magnetic Field Laboratory (EMFL). The authors are indebted to Frank de Boer for careful reading of the manuscript.

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title = "U2 N i2Sn and the origin of magnetic anisotropy in uranium compounds",

abstract = "U2Ni2Sn is a member of a large family of intermetallic compounds with the tetragonal Mo2FeB2 crystal structure. It orders antiferromagnetically at 25 K with propagation vector q=(0,0,12). Magnetization, magnetoacoustic, and neutron-diffraction experiments on a single crystal provide evidence that the uranium moments align parallel to the c axis with the anisotropy energy of ≈170 K, indicating that U2Ni2Sn can be classified as an Ising system. The results are at variance with previous studies on polycrystals, which indicated different magnetic structure, and which were incompatible with the 5f-5f two-ion anisotropy model dominant in most U band systems. High-field magnetization studies exhibit a weak linear response for fields along the basal plane up to the highest field applied (60 T), while the c-axis magnetization curve exhibits three metamagnetic transitions at approximately 30, 39, and 50 T. The U magnetic moments of 0.87μB, the low magnetic entropy, and the enhanced Sommerfeld coefficient γ=187mJ/molf.u.K2 suggest that U2Ni2Sn can be classified as an itinerant antiferromagnet with strong electron-electron correlations.",

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AU - Gorbunov, D. I.

AU - Zherlitsyn, S.

AU - Nakotte, H.

AU - Kothapalli, K.

AU - Nasreen, F.

AU - Cupp, C.

AU - Cao, H. B.

AU - Kolomiets, A.

AU - Havela, L.

PY - 2019/2/15

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N2 - U2Ni2Sn is a member of a large family of intermetallic compounds with the tetragonal Mo2FeB2 crystal structure. It orders antiferromagnetically at 25 K with propagation vector q=(0,0,12). Magnetization, magnetoacoustic, and neutron-diffraction experiments on a single crystal provide evidence that the uranium moments align parallel to the c axis with the anisotropy energy of ≈170 K, indicating that U2Ni2Sn can be classified as an Ising system. The results are at variance with previous studies on polycrystals, which indicated different magnetic structure, and which were incompatible with the 5f-5f two-ion anisotropy model dominant in most U band systems. High-field magnetization studies exhibit a weak linear response for fields along the basal plane up to the highest field applied (60 T), while the c-axis magnetization curve exhibits three metamagnetic transitions at approximately 30, 39, and 50 T. The U magnetic moments of 0.87μB, the low magnetic entropy, and the enhanced Sommerfeld coefficient γ=187mJ/molf.u.K2 suggest that U2Ni2Sn can be classified as an itinerant antiferromagnet with strong electron-electron correlations.

AB - U2Ni2Sn is a member of a large family of intermetallic compounds with the tetragonal Mo2FeB2 crystal structure. It orders antiferromagnetically at 25 K with propagation vector q=(0,0,12). Magnetization, magnetoacoustic, and neutron-diffraction experiments on a single crystal provide evidence that the uranium moments align parallel to the c axis with the anisotropy energy of ≈170 K, indicating that U2Ni2Sn can be classified as an Ising system. The results are at variance with previous studies on polycrystals, which indicated different magnetic structure, and which were incompatible with the 5f-5f two-ion anisotropy model dominant in most U band systems. High-field magnetization studies exhibit a weak linear response for fields along the basal plane up to the highest field applied (60 T), while the c-axis magnetization curve exhibits three metamagnetic transitions at approximately 30, 39, and 50 T. The U magnetic moments of 0.87μB, the low magnetic entropy, and the enhanced Sommerfeld coefficient γ=187mJ/molf.u.K2 suggest that U2Ni2Sn can be classified as an itinerant antiferromagnet with strong electron-electron correlations.

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U2 N i2Sn and the origin of magnetic anisotropy in uranium compounds

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