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Main Authors: Wu, Hao, Shishidou, Tatsuya, Weinert, Michael, Agterberg, Daniel F.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.09793
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_version_ 1866912120314003456
author Wu, Hao
Shishidou, Tatsuya
Weinert, Michael
Agterberg, Daniel F.
author_facet Wu, Hao
Shishidou, Tatsuya
Weinert, Michael
Agterberg, Daniel F.
contents The recently synthesized $η$-carbide-type superconductors exhibit large critical fields. A notable example is Ti$_4$Ir$_2$O, for which the upper critical field strongly violates the Pauli paramagnetic limit, behavior that is unusual for cubic materials that preserve inversion symmetry. Here, by combining density functional theory (DFT) and analytic modeling, we provide an explanation for this enhanced Pauli limiting field. We show that the nonsymmorphic Fd$\overline{3}$m symmetry implies that the electronic states near the X points exhibit strong spin-orbit coupling (SOC), which leads to a vanishing effective $g$-factor and enables the enhanced Pauli limiting field. Furthermore, our DFT results reveal a Van Hove singularity (VHS) peak near the X points, accounting for $\sim$65\% of the total density of states (DOS), occurring near the chemical potential. We propose that the strong SOC and enhanced DOS in the vicinity of the X points provide the origin of the observed enhanced critical field. This leads to a prediction that the magnetic field will lead to a strongly momentum-dependent gap suppression. The gap due to electronic states away from (near to) the X points will be rapidly (slowly) suppressed by fields.
format Preprint
id arxiv_https___arxiv_org_abs_2411_09793
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Large critical fields in superconducting Ti$_{4}$Ir$_2$O from spin-orbit coupling
Wu, Hao
Shishidou, Tatsuya
Weinert, Michael
Agterberg, Daniel F.
Superconductivity
The recently synthesized $η$-carbide-type superconductors exhibit large critical fields. A notable example is Ti$_4$Ir$_2$O, for which the upper critical field strongly violates the Pauli paramagnetic limit, behavior that is unusual for cubic materials that preserve inversion symmetry. Here, by combining density functional theory (DFT) and analytic modeling, we provide an explanation for this enhanced Pauli limiting field. We show that the nonsymmorphic Fd$\overline{3}$m symmetry implies that the electronic states near the X points exhibit strong spin-orbit coupling (SOC), which leads to a vanishing effective $g$-factor and enables the enhanced Pauli limiting field. Furthermore, our DFT results reveal a Van Hove singularity (VHS) peak near the X points, accounting for $\sim$65\% of the total density of states (DOS), occurring near the chemical potential. We propose that the strong SOC and enhanced DOS in the vicinity of the X points provide the origin of the observed enhanced critical field. This leads to a prediction that the magnetic field will lead to a strongly momentum-dependent gap suppression. The gap due to electronic states away from (near to) the X points will be rapidly (slowly) suppressed by fields.
title Large critical fields in superconducting Ti$_{4}$Ir$_2$O from spin-orbit coupling
topic Superconductivity
url https://arxiv.org/abs/2411.09793