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Main Authors: Braun, Adrian, Dick, Henrik, Sieweke, Timon, Kunzmann, Alexander, Lünser, Klara, Schierning, Gabi, Dahm, Thomas
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.14772
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author Braun, Adrian
Dick, Henrik
Sieweke, Timon
Kunzmann, Alexander
Lünser, Klara
Schierning, Gabi
Dahm, Thomas
author_facet Braun, Adrian
Dick, Henrik
Sieweke, Timon
Kunzmann, Alexander
Lünser, Klara
Schierning, Gabi
Dahm, Thomas
contents We present a mean-field charge density wave theory for NiTi using density functional theory bandstructure as a starting point. We calculate the Hall coefficient as a function of temperature and compare with recent experimental results. We analyze the contributions to the Hall coefficient from different parts of the Fermi surface and find that the Hall coefficient is dominated by certain ``hot spots''. The analysis shows that these hot spots are mostly dominated by Ni d-orbitals. We demonstrate that the Hall coefficient is not well reproduced by Boltzmann transport theory within the constant relaxation time approximation without charge density waves. We consider both uniaxial and biaxial charge density waves and show that biaxial charge density waves can account well for the Hall coefficient, while uniaxial cannot. We also investigate the temperature dependence of the resistivity and the specific heat.
format Preprint
id arxiv_https___arxiv_org_abs_2601_14772
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Influence of Charge Density Waves on the Hall coefficient in NiTi
Braun, Adrian
Dick, Henrik
Sieweke, Timon
Kunzmann, Alexander
Lünser, Klara
Schierning, Gabi
Dahm, Thomas
Materials Science
We present a mean-field charge density wave theory for NiTi using density functional theory bandstructure as a starting point. We calculate the Hall coefficient as a function of temperature and compare with recent experimental results. We analyze the contributions to the Hall coefficient from different parts of the Fermi surface and find that the Hall coefficient is dominated by certain ``hot spots''. The analysis shows that these hot spots are mostly dominated by Ni d-orbitals. We demonstrate that the Hall coefficient is not well reproduced by Boltzmann transport theory within the constant relaxation time approximation without charge density waves. We consider both uniaxial and biaxial charge density waves and show that biaxial charge density waves can account well for the Hall coefficient, while uniaxial cannot. We also investigate the temperature dependence of the resistivity and the specific heat.
title Influence of Charge Density Waves on the Hall coefficient in NiTi
topic Materials Science
url https://arxiv.org/abs/2601.14772