Half-metallicity in uranium intermetallics: Crystal structure prediction of a high-pressure phase of UCo
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A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
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Date
2019-01-16
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en
Pages
17
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Journal of Physics Condensed Matter, Volume 31, issue 2
Abstract
Evolutionary crystal structure prediction methods combined with density functional theory (DFT) calculations reveal a high-pressure (hp) phase of the intermetallic compound UCo crystalizing in the NaTl structure type (Fd3m, cF16). We predict this compound to be formed at pressures below 9 GPa. Hp-UCo shows the same structural trends as the two experimentally known pseudo-binary compounds UCo0.2Rh0.8 and UNi0.8Pt0.2. We classify them as ordered solid solutions of a bcc lattice following Vegards law. We predict hp-UCo and its adjacent phases UFe and UNi to be itinerant magnets. In the limit of vanishing spinorbit interactions UFe and hp-UCo are half-metallic ferrimagnets. Spinorbit coupling generally reduces the spin-polarization at the Fermi level. In case of hp-UCo the decrease depends on the applied DFT functional making the prediction of actual occurrence of half-metallicity problematic. In case of UFe the results are less dependent on the DFT functional. We demonstrate with these calulations that against common sense also materials with heavy elements can be interesting candidates for half-metallicity. We highlight that the NaTl structure type should be an interesting candidate for further investigations of half-metallicity.Description
Keywords
crystal structure prediction, DFT, half-metallic ferromagnetism, high pressure, spinorbit interactions, uranium intermetallics, SUPERCONDUCTIVITY, COMPOUND, U6FE, STATE, COHP, spin-orbit interactions, MAGNETISM, BILBAO CRYSTALLOGRAPHIC SERVER, X-RAY, CHARGE-DENSITY-WAVE, PLANE-WAVE
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Citation
Sachs, M, Karttunen, A J & Kraus, F 2019, ' Half-metallicity in uranium intermetallics : Crystal structure prediction of a high-pressure phase of UCo ', Journal of Physics Condensed Matter, vol. 31, no. 2, 025501 . https://doi.org/10.1088/1361-648X/aaeeca