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Autori principali: Vasques, Gustavo Gomes, Sundar, Shyam, Aristizábal-Giraldo, Deisy, Castello-Arango, Juan F., de Freitas, Rafael Sá, Benvenho, Adriano Reinaldo Viçoto, Onimaru, Takahiro, Osorio-Guillén, Jorge M., Avila, Marcos A.
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.03408
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author Vasques, Gustavo Gomes
Sundar, Shyam
Aristizábal-Giraldo, Deisy
Castello-Arango, Juan F.
de Freitas, Rafael Sá
Benvenho, Adriano Reinaldo Viçoto
Onimaru, Takahiro
Osorio-Guillén, Jorge M.
Avila, Marcos A.
author_facet Vasques, Gustavo Gomes
Sundar, Shyam
Aristizábal-Giraldo, Deisy
Castello-Arango, Juan F.
de Freitas, Rafael Sá
Benvenho, Adriano Reinaldo Viçoto
Onimaru, Takahiro
Osorio-Guillén, Jorge M.
Avila, Marcos A.
contents Superconductivity in noncentrosymmetric RPt2Si2 (R = rare earth) compounds exhibit a rich playground to explore the competition between different ground states, such as unconventional superconductivity, antiferromagnetism and charge density wave. Here, we report the successful single crystal synthesis of noncentrosymmetric YPt2Si2 superconductor, with a transition temperature Tc = 1.67 K, via Sn flux method. The high quality of the prepared single crystals was confirmed using powder and Laue XRD measurements. The superconducting and normal state properties are investigated using electrical transport and heat capacity measurements down to 0.5 K. In the normal state, unlike LaPt2Si2, no charge density wave transition is observed in YPt2Si2, as evidenced by electrical transport and specific heat measurements. A relatively large Kadowaki-Woods ratio and a linear temperature variation of the electrical resistivity in an extended temperature range of 50-300 K suggest an unconventional normal-state in YPt2Si2. The estimated superconducting parameters indicate that YPt2Si2 is a type-II superconductor with weak electron-phonon coupling. The temperature dependence of specific heat in the superconducting state can be explained reasonably well using an isotropic two-gap model. A positive curvature near Tc in the temperature variation of upper critical field also supports the two-gap superconductivity. First-principles DFT calculations suggest a BCS-like superconducting state driven primarily by d-electron contributions. The calculated electron-phonon coupling constant identifies the material as a weak-coupling superconductor, with the McMillan-Allen-Dynes formula yielding a Tc of 1.8 K. Additionally, we provide a comparative analysis of the superconducting and normal-state properties of YPt2Si2 and compositionally similar LaPt2Si2.
format Preprint
id arxiv_https___arxiv_org_abs_2604_03408
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Enhanced Kadowaki-Woods Ratio and Weak-Coupling Superconductivity in Noncentrosymmetric YPt$_2$Si$_2$ Single Crystals
Vasques, Gustavo Gomes
Sundar, Shyam
Aristizábal-Giraldo, Deisy
Castello-Arango, Juan F.
de Freitas, Rafael Sá
Benvenho, Adriano Reinaldo Viçoto
Onimaru, Takahiro
Osorio-Guillén, Jorge M.
Avila, Marcos A.
Superconductivity
Materials Science
Strongly Correlated Electrons
Superconductivity in noncentrosymmetric RPt2Si2 (R = rare earth) compounds exhibit a rich playground to explore the competition between different ground states, such as unconventional superconductivity, antiferromagnetism and charge density wave. Here, we report the successful single crystal synthesis of noncentrosymmetric YPt2Si2 superconductor, with a transition temperature Tc = 1.67 K, via Sn flux method. The high quality of the prepared single crystals was confirmed using powder and Laue XRD measurements. The superconducting and normal state properties are investigated using electrical transport and heat capacity measurements down to 0.5 K. In the normal state, unlike LaPt2Si2, no charge density wave transition is observed in YPt2Si2, as evidenced by electrical transport and specific heat measurements. A relatively large Kadowaki-Woods ratio and a linear temperature variation of the electrical resistivity in an extended temperature range of 50-300 K suggest an unconventional normal-state in YPt2Si2. The estimated superconducting parameters indicate that YPt2Si2 is a type-II superconductor with weak electron-phonon coupling. The temperature dependence of specific heat in the superconducting state can be explained reasonably well using an isotropic two-gap model. A positive curvature near Tc in the temperature variation of upper critical field also supports the two-gap superconductivity. First-principles DFT calculations suggest a BCS-like superconducting state driven primarily by d-electron contributions. The calculated electron-phonon coupling constant identifies the material as a weak-coupling superconductor, with the McMillan-Allen-Dynes formula yielding a Tc of 1.8 K. Additionally, we provide a comparative analysis of the superconducting and normal-state properties of YPt2Si2 and compositionally similar LaPt2Si2.
title Enhanced Kadowaki-Woods Ratio and Weak-Coupling Superconductivity in Noncentrosymmetric YPt$_2$Si$_2$ Single Crystals
topic Superconductivity
Materials Science
Strongly Correlated Electrons
url https://arxiv.org/abs/2604.03408