Nematic State in CeAuSb2

S. Seo; Xiaoyu Wang; S. M. Thomas; M. C. Rahn; D. Carmo; F. Ronning; E. D. Bauer; R. D. Dos Reis; M. Janoschek; J. D. Thompson; R. M. Fernandes; P. F.S. Rosa

doi:10.1103/PhysRevX.10.011035

Nematic State in CeAuSb2

S. Seo, Xiaoyu Wang, S. M. Thomas, M. C. Rahn, D. Carmo, F. Ronning, E. D. Bauer, R. D. Dos Reis, M. Janoschek, J. D. Thompson, R. M. Fernandes, P. F.S. Rosa

Research output: Contribution to journal › Article › peer-review

Abstract

At ambient pressure and zero field, tetragonal CeAuSb2 hosts stripe antiferromagnetic order at TN=6.3 K. Here, we first show via bulk thermodynamic probes and x-ray diffraction measurements that this magnetic order is connected with a structural phase transition to a superstructure that likely breaks C4 symmetry, thus signaling nematic order. The temperature-field-pressure phase diagram of CeAuSb2 subsequently reveals the emergence of additional ordered states under applied pressure at a multicritical point. Our phenomenological model supports the presence of a vestigial nematic phase in CeAuSb2 akin to iron-based high-temperature superconductors; however, superconductivity, if present, remains to be discovered.

Original language	English (US)
Article number	011035
Journal	Physical Review X
Volume	10
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevX.10.011035
State	Published - Mar 2020
Externally published	Yes

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General Physics and Astronomy

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10.1103/PhysRevX.10.011035

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abstract = "At ambient pressure and zero field, tetragonal CeAuSb2 hosts stripe antiferromagnetic order at TN=6.3 K. Here, we first show via bulk thermodynamic probes and x-ray diffraction measurements that this magnetic order is connected with a structural phase transition to a superstructure that likely breaks C4 symmetry, thus signaling nematic order. The temperature-field-pressure phase diagram of CeAuSb2 subsequently reveals the emergence of additional ordered states under applied pressure at a multicritical point. Our phenomenological model supports the presence of a vestigial nematic phase in CeAuSb2 akin to iron-based high-temperature superconductors; however, superconductivity, if present, remains to be discovered.",

author = "S. Seo and Xiaoyu Wang and Thomas, {S. M.} and Rahn, {M. C.} and D. Carmo and F. Ronning and Bauer, {E. D.} and {Dos Reis}, {R. D.} and M. Janoschek and Thompson, {J. D.} and Fernandes, {R. M.} and Rosa, {P. F.S.}",

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year = "2020",

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doi = "10.1103/PhysRevX.10.011035",

language = "English (US)",

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AU - Seo, S.

AU - Wang, Xiaoyu

AU - Thomas, S. M.

AU - Rahn, M. C.

AU - Carmo, D.

AU - Ronning, F.

AU - Bauer, E. D.

AU - Dos Reis, R. D.

AU - Janoschek, M.

AU - Thompson, J. D.

AU - Fernandes, R. M.

AU - Rosa, P. F.S.

PY - 2020/3

Y1 - 2020/3

N2 - At ambient pressure and zero field, tetragonal CeAuSb2 hosts stripe antiferromagnetic order at TN=6.3 K. Here, we first show via bulk thermodynamic probes and x-ray diffraction measurements that this magnetic order is connected with a structural phase transition to a superstructure that likely breaks C4 symmetry, thus signaling nematic order. The temperature-field-pressure phase diagram of CeAuSb2 subsequently reveals the emergence of additional ordered states under applied pressure at a multicritical point. Our phenomenological model supports the presence of a vestigial nematic phase in CeAuSb2 akin to iron-based high-temperature superconductors; however, superconductivity, if present, remains to be discovered.

AB - At ambient pressure and zero field, tetragonal CeAuSb2 hosts stripe antiferromagnetic order at TN=6.3 K. Here, we first show via bulk thermodynamic probes and x-ray diffraction measurements that this magnetic order is connected with a structural phase transition to a superstructure that likely breaks C4 symmetry, thus signaling nematic order. The temperature-field-pressure phase diagram of CeAuSb2 subsequently reveals the emergence of additional ordered states under applied pressure at a multicritical point. Our phenomenological model supports the presence of a vestigial nematic phase in CeAuSb2 akin to iron-based high-temperature superconductors; however, superconductivity, if present, remains to be discovered.

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Nematic State in CeAuSb2

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