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Influence of Dy<sup>3+</sup> environment on magnetic anisotropy and magnetocaloric effect in Dy<sub>3</sub><em>B</em><sub>2</sub><em>C</em><sub>3</sub>O<sub>12</sub> (<em>B </em>= In, Sc, Te; C = Ga, Al, Li) garnets
Damay, F., Petit, S., Sheptyakov, D., Colin, C. V., Suard, E., Rols, S., … Decorse, C. (2024). Influence of Dy3+ environment on magnetic anisotropy and magnetocaloric effect in Dy3B2C3O12 (B = In, Sc, Te; C = Ga, Al, Li) garnets. Physical Review B, 109(1), 014419 (12 pp.). https://doi.org/10.1103/PhysRevB.109.014419
Er-driven incommensurate to commensurate magnetic phase transition of Fe in the spin-chain compound BaErFeO<sub>4</sub>
Dönni, A., Pomjakushin, V. Y., & Belik, A. A. (2024). Er-driven incommensurate to commensurate magnetic phase transition of Fe in the spin-chain compound BaErFeO4. Physical Review B, 109(6), 064403 (12 pp.). https://doi.org/10.1103/PhysRevB.109.064403
Cobalt-free layered perovskites RBaCuFeO<sub>5+δ</sub> (R = 4f lanthanide) as electrocatalysts for the oxygen evolution reaction
Marelli, E., Lyu, J., Morin, M., Leménager, M., Shang, T., Yüzbasi, N. S., … Medarde, M. (2024). Cobalt-free layered perovskites RBaCuFeO5+δ (R = 4f lanthanide) as electrocatalysts for the oxygen evolution reaction. EES Catalysis, 1(2), 335-350. https://doi.org/10.1039/D3EY00142C
High-temperature transport properties of entropy-stabilized pyrochlores
Miruszewski, T., Vayer, F., Jaworski, D., Bérardan, D., Decorse, C., Bochentyn, B., … Dragoe, N. (2024). High-temperature transport properties of entropy-stabilized pyrochlores. Journal of Applied Physics, 135(8), 085112 (11 pp.). https://doi.org/10.1063/5.0180991
Emergence of the isotropic Kitaev honeycomb lattice α − RuCl<sub>3</sub> and its magnetic properties
Park, S. Y., Do, S. H., Choi, K. Y., Jang, D., Jang, T. H., Schefer, J., … Ji, S. (2024). Emergence of the isotropic Kitaev honeycomb lattice α − RuCl3 and its magnetic properties. Journal of Physics: Condensed Matter, 36(21), 215803 (11 pp.). https://doi.org/10.1088/1361-648X/ad294f
Observation by SANS and PNR of pure Néel-type domain wall profiles and skyrmion suppression below room temperature in magnetic [Pt/CoFeB/Ru]<sub>10</sub> multilayers
Ukleev, V., Ajejas, F., Devishvili, A., Vorobiev, A., Steinke, N. J., Cubitt, R., … White, J. S. (2024). Observation by SANS and PNR of pure Néel-type domain wall profiles and skyrmion suppression below room temperature in magnetic [Pt/CoFeB/Ru]10 multilayers. Science and Technology of Advanced Materials, 25(1), 2315015 (13 pp.). https://doi.org/10.1080/14686996.2024.2315015
Reflective, polarizing, and magnetically soft amorphous neutron optics with <sup>11</sup>B-enriched B<sub>4</sub>C
Zubayer, A., Ghafoor, N., Thórarinsdóttir, K. A., Stendahl, S., Glavic, A., Stahn, J., … Eriksson, F. (2024). Reflective, polarizing, and magnetically soft amorphous neutron optics with 11B-enriched B4C. Science Advances, 10(7), eadl0402 (7 pp.). https://doi.org/10.1126/sciadv.adl0402
The magnetic properties of MAl<sub>4</sub>(OH)<sub>12</sub>SO<sub>4</sub>·3H<sub>2</sub>O with M = Co<sup>2+</sup>, Ni<sup>2+</sup>, and Cu<sup>2+</sup> determined by a combined experimental and computational approach
Andersen, A. B. A., Christiansen, R. T., Holm-Janas, S., Manvell, A. S., Pedersen, K. S., Sheptyakov, D., … Nielsen, U. G. (2023). The magnetic properties of MAl4(OH)12SO4·3H2O with M = Co2+, Ni2+, and Cu2+ determined by a combined experimental and computational approach. Physical Chemistry Chemical Physics, 25(4), 3309-3322. https://doi.org/10.1039/d2cp05362d
Rich magnetic phase diagram of putative helimagnet Sr<sub>3</sub>Fe<sub>2</sub>O<sub>7</sub>
Andriushin, N. D., Grumbach, J., Kim, J. H., Reehuis, M., Tymoshenko, Y. V., Onykiienko, Y. A., … Peets, D. C. (2023). Rich magnetic phase diagram of putative helimagnet Sr3Fe2O7. Physical Review B, 108(17), 174420 (13 pp.). https://doi.org/10.1103/PhysRevB.108.174420
Crystal structure of and chemical bonding in MoNi<sub>4</sub>
Armbrüster, M., Rößner, L., Prots, Y., Akselrud, L., König, M., Sheptyakov, D., & Grin, Y. (2023). Crystal structure of and chemical bonding in MoNi4. Zeitschrift für Anorganische und Allgemeine Chemie, 649(23), e202300145 (8 pp.). https://doi.org/10.1002/zaac.202300145
Direct observation of exchange anisotropy in the helimagnetic insulator Cu<sub>2</sub>OSeO<sub>3</sub>
Baral, P. R., Utesov, O. I., Luo, C., Radu, F., Magrez, A., White, J. S., & Ukleev, V. (2023). Direct observation of exchange anisotropy in the helimagnetic insulator Cu2OSeO3. Physical Review Research, 5(3), L032019 (6 pp.). https://doi.org/10.1103/PhysRevResearch.5.L032019
Structural evolution of air-exposed layered oxide cathodes for sodium-ion batteries: an example of Ni-doped Na<sub>x</sub>MnO<sub>2</sub>
Brugnetti, G., Triolo, C., Massaro, A., Ostroman, I., Pianta, N., Ferrara, C., … Ruffo, R. (2023). Structural evolution of air-exposed layered oxide cathodes for sodium-ion batteries: an example of Ni-doped NaxMnO2. Chemistry of Materials, 35(20), 8440-8454. https://doi.org/10.1021/acs.chemmater.3c01196
Probing superconducting order in overdoped Ca<sub><em>x</em></sub>Y<sub>1-<em>x</em></sub>Ba<sub>2</sub>Cu<sub>3</sub>O<sub>7</sub> by neutron diffraction measurements of the vortex lattice
Cameron, A. S., Campillo, E., Alshemi, A., Bartkowiak, M., Shen, L., Kawano-Furukawa, H., … Blackburn, E. (2023). Probing superconducting order in overdoped CaxY1-xBa2Cu3O7 by neutron diffraction measurements of the vortex lattice. Physical Review B, 108(14), 144511 (10 PP.). https://doi.org/10.1103/PhysRevB.108.144511
Disorder-driven cluster glass state in a geometrically frustrated hexagonal perovskite
Chakravarty, S., Fjellvåg, Ø. S., Bhattacharyya, A., Keller, L., & Nair, S. (2023). Disorder-driven cluster glass state in a geometrically frustrated hexagonal perovskite. Physical Review B, 107(13), 134414 (12 pp.). https://doi.org/10.1103/PhysRevB.107.134414
Cycloidal spiral magnetic structures in the spin-chain compounds Ba<em>R</em>FeO<sub>4</sub> (<em>R</em> = Yb and Tm): ordered Yb versus partly ordered Tm
Dönni, A., Pomjakushin, V. Y., Yamaura, K., & Belik, A. A. (2023). Cycloidal spiral magnetic structures in the spin-chain compounds BaRFeO4 (R = Yb and Tm): ordered Yb versus partly ordered Tm. Physical Review B, 107(13), 134412 (12 pp.). https://doi.org/10.1103/PhysRevB.107.134412
Incommensurate magnetic structure of CrAs at low temperatures and high pressures
Eich, A., Grzechnik, A., Su, Y., Ouladdiaf, B., Sheptyakov, D., Wolf, T., … Friese, K. (2023). Incommensurate magnetic structure of CrAs at low temperatures and high pressures. Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials, 79, 473-481. https://doi.org/10.1107/S205252062300817X
Pressure-induced Yb valence transition and magnetism in YbMn<sub>6</sub>Ge<sub>6-<em>x</em></sub>Sn<em><sub>x</sub></em>
Eichenberger, L., François, M., Malterre, D., Sibille, R., Casati, N. P. M., Nataf, L., … Mazet, T. (2023). Pressure-induced Yb valence transition and magnetism in YbMn6Ge6-xSnx. Physical Review B, 107(20), 205146 (8 pp.). https://doi.org/10.1103/PhysRevB.107.205146
Magnetic phase diagram of the breathing-kagome antiferromagnet Nd<sub>3</sub>BWO<sub>9</sub>
Flavián, D., Nagl, J., Hayashida, S., Yan, M., Zaharko, O., Fennell, T., … Zheludev, A. (2023). Magnetic phase diagram of the breathing-kagome antiferromagnet Nd3BWO9. Physical Review B, 107(17), 174406 (12 pp.). https://doi.org/10.1103/PhysRevB.107.174406
Tuning magnetoelectricity in a mixed-anisotropy antiferromagnet
Fogh, E., Klemke, B., Reehuis, M., Bourges, P., Niedermayer, C., Holm-Dahlin, S., … Toft-Petersen, R. (2023). Tuning magnetoelectricity in a mixed-anisotropy antiferromagnet. Nature Communications, 14(1), 3408 (9 pp.). https://doi.org/10.1038/s41467-023-39128-7
In situ neutron diffraction of Zn-MOF-74 reveals nanoconfinement-induced effects on adsorbed propene
Gäumann, P., Ferri, D., Sheptyakov, D., van Bokhoven, J. A., Rzepka, P., & Ranocchiari, M. (2023). In situ neutron diffraction of Zn-MOF-74 reveals nanoconfinement-induced effects on adsorbed propene. Journal of Physical Chemistry C, 127(33), 16636-16644. https://doi.org/10.1021/acs.jpcc.3c03225
 

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