DeepPolaron ML-MD simulations show rutile electrons form Ti-localized polarons hopping along [001] with 39 meV barrier and 4.4e-2 cm2/Vs mobility, while anatase holes form O-localized polarons hopping to second neighbors with 139 meV barrier and 1.4e-3 cm2/Vs mobility.
and Zaanen, Jan and Andersen, Ole K
3 Pith papers cite this work. Polarity classification is still indexing.
citation-role summary
citation-polarity summary
fields
cond-mat.mtrl-sci 3years
2026 3verdicts
UNVERDICTED 3roles
background 1polarities
unclear 1representative citing papers
Strain engineering drives altermagnetic-to-ferrimagnetic transitions and activates anomalous transport responses in RuO2 and MnF2 via symmetry breaking.
DFT and atomistic spin dynamics calculations predict that 1T-CrSI, 1H-CrSeI, and 1H-CrSI Janus monolayers are ferromagnets with perpendicular magnetic anisotropy and Curie temperatures of 210-410 K.
citing papers explorer
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Polaron Transport in TiO$_{2}$ from Machine Learning Molecular Dynamics
DeepPolaron ML-MD simulations show rutile electrons form Ti-localized polarons hopping along [001] with 39 meV barrier and 4.4e-2 cm2/Vs mobility, while anatase holes form O-localized polarons hopping to second neighbors with 139 meV barrier and 1.4e-3 cm2/Vs mobility.
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Strain induced magnetic phase transition and anomalous transport phenomena in RuO$_2$ and MnF$_2$
Strain engineering drives altermagnetic-to-ferrimagnetic transitions and activates anomalous transport responses in RuO2 and MnF2 via symmetry breaking.
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Chromium chalcohalide Janus monolayer ferromagnets with perpendicular magnetic anisotropy and high Curie temperature
DFT and atomistic spin dynamics calculations predict that 1T-CrSI, 1H-CrSeI, and 1H-CrSI Janus monolayers are ferromagnets with perpendicular magnetic anisotropy and Curie temperatures of 210-410 K.