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Fidelity and variability in the interlayer electronic structure of the kagome superconductor ${CsV}_{3} {Sb}_{5}$

https://doi.org/10.1103/PhysRevMaterials.8.054204

Watkins, Aurland_K; Johrendt, Dirk; Vlcek, Vojtech; Wilson, Stephen_D; Seshadri, Ram (May 2024, Physical Review Materials)
Absence of a bulk thermodynamic phase transition to a density wave phase in ${UTe}_{2}$

https://doi.org/10.1103/PhysRevB.110.144507

Theuss, Florian; Shragai, Avi; Grissonnanche, Gael; Peralta, Luciano; Simarro, Gregorio_de_la_Fuente; Hayes, Ian_M; Saha, Shanta_R; Eo, Yun_Suk; Suarez, Alonso; Salinas, Andrea_Capa; et al (October 2024, Physical Review B)
Dynamical decoding of the competition between charge density waves in a kagome superconductor

https://doi.org/10.1038/s41467-024-51485-5

Ning, Honglie; Oh, Kyoung_Hun; Su, Yifan; von_Hoegen, Alexander; Porter, Zach; Capa_Salinas, Andrea; Nguyen, Quynh_L; Chollet, Matthieu; Sato, Takahiro; Esposito, Vincent; et al (August 2024, Nature Communications)
Structural coupling and magnetic tuning in Mn2− x Co x P magnetocalorics for thermomagnetic power generation

https://doi.org/10.1063/1.5142000

Levin, Emily_E; Bocarsly, Joshua_D; Grebenkemper, Jason_H; Issa, Ramsey; Wilson, Stephen_D; Pollock, Tresa_M; Seshadri, Ram (April 2020, APL Materials)

Promising materials for magnetic refrigeration and thermomagnetic power generation often display strong coupling between magnetism and structure. It has been previously proposed that MnCoP exhibits this strong coupling, contributing to its substantial magnetocaloric effect near TC = 578K. Here, we show from temperature-dependent synchrotron x-ray diffraction that MnCoP displays a discontinuity in the thermal expansion at TC, with spontaneous magnetostriction that is positive in the a direction and negative in the b direction, highlighting the anisotropic nature of the magnetostructural coupling. Varying the Mn:Co ratio of Mn2−xCoxP within the range of 0.6 ≤ x ≤ 1.4 allows the magnetic properties to be tuned. TC decreases as the composition deviates from stoichiometric MnCoP, as does the saturation magnetization. The magnitude of the magnetocaloric effect, |ΔSM|, decreases as well, due to broadening of the magnetic transition. The large reversible change in magnetization ΔM accessible over a small temperature range under moderate magnetic fields makes these materials promising for thermomagnetic power generation from waste heat.
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Carrier density control of magnetism and Berry phases in doped EuTiO3

https://doi.org/10.1063/1.5025317

Ahadi, Kaveh; Gui, Zhigang; Porter, Zach; Lynn, Jeffrey_W; Xu, Zhijun; Wilson, Stephen_D; Janotti, Anderson; Stemmer, Susanne (May 2018, APL Materials)

In materials with broken time-reversal symmetry, the Berry curvature acts as a reciprocal space magnetic field on the conduction electrons and is a significant contribution to the magnetotransport properties, including the intrinsic anomalous Hall effect. Here, we report neutron diffraction, transport, and magnetization measurements of thin films of doped EuTiO3, an itinerant magnetic material, as a function of carrier density and magnetic field. These films are itinerant antiferromagnets at all doping concentrations. At low carrier densities, the magnetoresistance indicates a metamagnetic transition, which is absent at high carrier densities (>6 × 1020 cm−3). Strikingly, the crossover coincides with a sign change in the spontaneous Hall effects, indicating a sign change in the Berry curvature. We discuss the results in the context of the band structure topology and its coupling to the magnetic texture.
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