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Main Authors: Hosoi, S., Imamura, K., Bordelon, M. M., Bauer, E. D., Thomas, S. M., Ronning, F., Rosa, P. F. S., Movshovich, R., Vekhter, I., Matsuda, Y.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.11278
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author Hosoi, S.
Imamura, K.
Bordelon, M. M.
Bauer, E. D.
Thomas, S. M.
Ronning, F.
Rosa, P. F. S.
Movshovich, R.
Vekhter, I.
Matsuda, Y.
author_facet Hosoi, S.
Imamura, K.
Bordelon, M. M.
Bauer, E. D.
Thomas, S. M.
Ronning, F.
Rosa, P. F. S.
Movshovich, R.
Vekhter, I.
Matsuda, Y.
contents The unconventional superconductor UTe$_2$ represents a rare example of spin-triplet pairing with potentially topologically protected quantum states. However, conflicting reports on its gap structure, particularly regarding point nodes, have hindered understanding of the order parameter symmetry and topological properties. Here we report high-resolution thermal conductivity measurements on high-quality UTe$_2$ single crystals down to ~50 mK that resolve the gap anisotropy through bulk directional transport. The $b$-axis thermal conductivity $κ_b/T$ exhibits negligible residual conductivity as $T \to 0$, and its temperature dependence is consistent with a small superconducting energy gap along the $b$-axis. Under magnetic fields, the residual $κ_b/T$ shows only weak field-induced enhancement. Remarkably, a threshold field emerges at low fields for $H \parallel a$, characterized by a kink that signals a change in quasiparticle transport normal to the field. Below the threshold, $κ_b/T$ remains isotropic for all field orientations, whereas strong anisotropy between transport along and normal to the field develops above it. These signatures strongly suggest that UTe$_2$ exhibits a fully gapped state with a pseudo point-nodal structure, where gap minima approach but never reach zero. We estimate the minimal gap $Δ_{min}/Δ_0 \sim 0.1$ along the $b$-axis, where $Δ_0$ is the characteristic superconducting gap. This unusual gap structure provides crucial insights into the pairing mechanism and topology of this spin-triplet superconductor and excludes non-unitary mixing of pairing symmetries.
format Preprint
id arxiv_https___arxiv_org_abs_2603_11278
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Pseudo Point Nodal Superconducting Gap in Spin-Triplet UTe$_2$
Hosoi, S.
Imamura, K.
Bordelon, M. M.
Bauer, E. D.
Thomas, S. M.
Ronning, F.
Rosa, P. F. S.
Movshovich, R.
Vekhter, I.
Matsuda, Y.
Superconductivity
Materials Science
The unconventional superconductor UTe$_2$ represents a rare example of spin-triplet pairing with potentially topologically protected quantum states. However, conflicting reports on its gap structure, particularly regarding point nodes, have hindered understanding of the order parameter symmetry and topological properties. Here we report high-resolution thermal conductivity measurements on high-quality UTe$_2$ single crystals down to ~50 mK that resolve the gap anisotropy through bulk directional transport. The $b$-axis thermal conductivity $κ_b/T$ exhibits negligible residual conductivity as $T \to 0$, and its temperature dependence is consistent with a small superconducting energy gap along the $b$-axis. Under magnetic fields, the residual $κ_b/T$ shows only weak field-induced enhancement. Remarkably, a threshold field emerges at low fields for $H \parallel a$, characterized by a kink that signals a change in quasiparticle transport normal to the field. Below the threshold, $κ_b/T$ remains isotropic for all field orientations, whereas strong anisotropy between transport along and normal to the field develops above it. These signatures strongly suggest that UTe$_2$ exhibits a fully gapped state with a pseudo point-nodal structure, where gap minima approach but never reach zero. We estimate the minimal gap $Δ_{min}/Δ_0 \sim 0.1$ along the $b$-axis, where $Δ_0$ is the characteristic superconducting gap. This unusual gap structure provides crucial insights into the pairing mechanism and topology of this spin-triplet superconductor and excludes non-unitary mixing of pairing symmetries.
title Pseudo Point Nodal Superconducting Gap in Spin-Triplet UTe$_2$
topic Superconductivity
Materials Science
url https://arxiv.org/abs/2603.11278