Maximizing Tc by tuning nematicity and magnetism in FeSe1−xSx superconductors

Maximizing Tc by tuning nematicity and magnetism in FeSe1−xSx superconductors

A fundamental issue concerning iron-based superconductivity is the roles of electronic nematicity and magnetism in realising high transition temperature ( T c ). To address this issue, FeSe is a key material, as it exhibits a unique pressure phase diagram involving non-magnetic nematic and pressure-...

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Veröffentlicht in:Nature communications 2017-10, Vol.8 (1)
Hauptverfasser: Matsuura, K., Mizukami, Y., Arai, Y., Sugimura, Y., Maejima, N., Machida, A., Watanuki, T., Fukuda, T., Yajima, T., Hiroi, Z., Yip, K. Y., Chan, Y. C., Niu, Q., Hosoi, S., Ishida, K., Mukasa, K., Kasahara, S., Cheng, J.-G., Goh, S. K., Matsuda, Y., Uwatoko, Y., Shibauchi, T.
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container_issue 1
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container_title Nature communications
container_volume 8
creator Matsuura, K.
Mizukami, Y.
Arai, Y.
Sugimura, Y.
Maejima, N.
Machida, A.
Watanuki, T.
Fukuda, T.
Yajima, T.
Hiroi, Z.
Yip, K. Y.
Chan, Y. C.
Niu, Q.
Hosoi, S.
Ishida, K.
Mukasa, K.
Kasahara, S.
Cheng, J.-G.
Goh, S. K.
Matsuda, Y.
Uwatoko, Y.
Shibauchi, T.
description A fundamental issue concerning iron-based superconductivity is the roles of electronic nematicity and magnetism in realising high transition temperature ( T c ). To address this issue, FeSe is a key material, as it exhibits a unique pressure phase diagram involving non-magnetic nematic and pressure-induced antiferromagnetic ordered phases. However, as these two phases in FeSe have considerable overlap, how each order affects superconductivity remains perplexing. Here we construct the three-dimensional electronic phase diagram, temperature ( T ) against pressure ( P ) and isovalent S-substitution ( x ), for FeSe 1− x S x . By simultaneously tuning chemical and physical pressures, against which the chalcogen height shows a contrasting variation, we achieve a complete separation of nematic and antiferromagnetic phases. In between, an extended non-magnetic tetragonal phase emerges, where T c shows a striking enhancement. The completed phase diagram uncovers that high- T c superconductivity lies near both ends of the dome-shaped antiferromagnetic phase, whereas T c remains low near the nematic critical point. The overlap between different phases has hindered the understanding of how each phase affects superconductivity in FeSe. Here, Matsuura et al. achieve a complete separation of non-magnetic nematic and antiferromagnetic phases for FeSe 1- x S x , observing a tetragonal phase in between with a strikingly enhanced T c .
doi_str_mv 10.1038/s41467-017-01277-x
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Y. ; Chan, Y. C. ; Niu, Q. ; Hosoi, S. ; Ishida, K. ; Mukasa, K. ; Kasahara, S. ; Cheng, J.-G. ; Goh, S. K. ; Matsuda, Y. ; Uwatoko, Y. ; Shibauchi, T.</creator><creatorcontrib>Matsuura, K. ; Mizukami, Y. ; Arai, Y. ; Sugimura, Y. ; Maejima, N. ; Machida, A. ; Watanuki, T. ; Fukuda, T. ; Yajima, T. ; Hiroi, Z. ; Yip, K. Y. ; Chan, Y. C. ; Niu, Q. ; Hosoi, S. ; Ishida, K. ; Mukasa, K. ; Kasahara, S. ; Cheng, J.-G. ; Goh, S. K. ; Matsuda, Y. ; Uwatoko, Y. ; Shibauchi, T.</creatorcontrib><description>A fundamental issue concerning iron-based superconductivity is the roles of electronic nematicity and magnetism in realising high transition temperature ( T c ). To address this issue, FeSe is a key material, as it exhibits a unique pressure phase diagram involving non-magnetic nematic and pressure-induced antiferromagnetic ordered phases. However, as these two phases in FeSe have considerable overlap, how each order affects superconductivity remains perplexing. 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To address this issue, FeSe is a key material, as it exhibits a unique pressure phase diagram involving non-magnetic nematic and pressure-induced antiferromagnetic ordered phases. However, as these two phases in FeSe have considerable overlap, how each order affects superconductivity remains perplexing. Here we construct the three-dimensional electronic phase diagram, temperature ( T ) against pressure ( P ) and isovalent S-substitution ( x ), for FeSe 1− x S x . By simultaneously tuning chemical and physical pressures, against which the chalcogen height shows a contrasting variation, we achieve a complete separation of nematic and antiferromagnetic phases. In between, an extended non-magnetic tetragonal phase emerges, where T c shows a striking enhancement. The completed phase diagram uncovers that high- T c superconductivity lies near both ends of the dome-shaped antiferromagnetic phase, whereas T c remains low near the nematic critical point. The overlap between different phases has hindered the understanding of how each phase affects superconductivity in FeSe. 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Y.</au><au>Chan, Y. C.</au><au>Niu, Q.</au><au>Hosoi, S.</au><au>Ishida, K.</au><au>Mukasa, K.</au><au>Kasahara, S.</au><au>Cheng, J.-G.</au><au>Goh, S. K.</au><au>Matsuda, Y.</au><au>Uwatoko, Y.</au><au>Shibauchi, T.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Maximizing Tc by tuning nematicity and magnetism in FeSe1−xSx superconductors</atitle><jtitle>Nature communications</jtitle><stitle>Nat Commun</stitle><date>2017-10-26</date><risdate>2017</risdate><volume>8</volume><issue>1</issue><eissn>2041-1723</eissn><abstract>A fundamental issue concerning iron-based superconductivity is the roles of electronic nematicity and magnetism in realising high transition temperature ( T c ). To address this issue, FeSe is a key material, as it exhibits a unique pressure phase diagram involving non-magnetic nematic and pressure-induced antiferromagnetic ordered phases. However, as these two phases in FeSe have considerable overlap, how each order affects superconductivity remains perplexing. Here we construct the three-dimensional electronic phase diagram, temperature ( T ) against pressure ( P ) and isovalent S-substitution ( x ), for FeSe 1− x S x . By simultaneously tuning chemical and physical pressures, against which the chalcogen height shows a contrasting variation, we achieve a complete separation of nematic and antiferromagnetic phases. In between, an extended non-magnetic tetragonal phase emerges, where T c shows a striking enhancement. The completed phase diagram uncovers that high- T c superconductivity lies near both ends of the dome-shaped antiferromagnetic phase, whereas T c remains low near the nematic critical point. The overlap between different phases has hindered the understanding of how each phase affects superconductivity in FeSe. 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subjects 639/301/119/1003
639/766/119/2795
639/766/119/995
Humanities and Social Sciences
multidisciplinary
Science
Science (multidisciplinary)
title Maximizing Tc by tuning nematicity and magnetism in FeSe1−xSx superconductors
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