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Main Authors: Wang, Xusheng, He, Lianyi, Ji, Shuai-hua
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.19030
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author Wang, Xusheng
He, Lianyi
Ji, Shuai-hua
author_facet Wang, Xusheng
He, Lianyi
Ji, Shuai-hua
contents Through a comprehensive free energy analysis, we demonstrate that finite temperature can simultaneously weaken superconductivity and mitigate spin polarization induced depairing, leading to potential non-monotonic temperature-dependent behaviors in superconductors subjected to large exchange fields. Remarkably, superconductivity can be counterintuitively enhanced by temperature when the Zeeman energy exceeds the superconducting order parameter, owing to the competition between thermal and magnetic effects. We propose that multiband effect offers one possible microscopic route for this temperature-induced enhancement and demonstrate it explicitly within a two-band superconducting model. A detailed parameter analysis identifies the conditions under which this phenomenon emerges, suggesting that temperature-enhanced superconductivity may be observable in materials such as MgB2 and FeSe through transport and tunneling measurements.
format Preprint
id arxiv_https___arxiv_org_abs_2511_19030
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Temperature-Induced Superconductivity Enhancement under Large Exchange Field
Wang, Xusheng
He, Lianyi
Ji, Shuai-hua
Superconductivity
Through a comprehensive free energy analysis, we demonstrate that finite temperature can simultaneously weaken superconductivity and mitigate spin polarization induced depairing, leading to potential non-monotonic temperature-dependent behaviors in superconductors subjected to large exchange fields. Remarkably, superconductivity can be counterintuitively enhanced by temperature when the Zeeman energy exceeds the superconducting order parameter, owing to the competition between thermal and magnetic effects. We propose that multiband effect offers one possible microscopic route for this temperature-induced enhancement and demonstrate it explicitly within a two-band superconducting model. A detailed parameter analysis identifies the conditions under which this phenomenon emerges, suggesting that temperature-enhanced superconductivity may be observable in materials such as MgB2 and FeSe through transport and tunneling measurements.
title Temperature-Induced Superconductivity Enhancement under Large Exchange Field
topic Superconductivity
url https://arxiv.org/abs/2511.19030