Persistent insulating state at megabar pressures in strongly spin-orbit coupled S r2Ir O4

Chunhua Chen; Yonghui Zhou; Xuliang Chen; Tao Han; Chao An; Ying Zhou; Yifang Yuan; Bowen Zhang; Shuyang Wang; Ranran Zhang; Lili Zhang; Changjin Zhang; Zhaorong Yang; Lance E. Delong; Gang Cao

doi:10.1103/PhysRevB.101.144102

Persistent insulating state at megabar pressures in strongly spin-orbit coupled S r2Ir O4

Chunhua Chen
, Yonghui Zhou
, Xuliang Chen
, Tao Han
, Chao An
, Ying Zhou
, Yifang Yuan
, Bowen Zhang
, Shuyang Wang
, Ranran Zhang
, Lili Zhang
, Changjin Zhang
, Zhaorong Yang
, Lance E. Delong
, Gang Cao

Producción científica: Article › revisión exhaustiva

32 Citas (Scopus)

Resumen

It is commonly anticipated that an insulating state will collapse in favor of an emergent metallic state at high pressures: The average electron density must increase with pressure, while the electronic bandwidth is expected to broaden and fill the insulating energy band gap. Here we report an unusually stable insulating state that persists up to at least 185 GPa in Sr2IrO4, the archetypical spin-orbit-driven Jeff=1/2 insulator. This study shows that the electrical resistance R of single-crystal Sr2IrO4 initially decreases with applied pressure P, reaches a minimum in the range 32-38 GPa, then abruptly rises to recover the insulating state with increasing P up to 185 GPa. However, evidence of a saturation of R below 80 K for P≥124GPa GPa raises the possibility of a low-temperature exotic state. Our synchrotron X-ray diffraction and Raman scattering data show the emergence of the rapid increase in R is accompanied by a structural phase transition from the native tetragonal I41/acd phase to an orthorhombic Pbca phase (with much reduced symmetry) at 40.6 GPa. The clear correspondence of the onset pressures of these two anomalies is key to understanding the stability of the insulating state at megabar pressures: Pressure-induced, structural distortions prevent the expected onset of metallization, despite the sizable volume compression attained at the highest pressure accessed in this study.

Idioma original	English
Número de artículo	144102
Publicación	Physical Review B
Volumen	101
N.º	14
DOI	https://doi.org/10.1103/PhysRevB.101.144102
Estado	Published - abr 1 2020

Nota bibliográfica

Publisher Copyright:
© 2020 American Physical Society.

Financiación

We are grateful for the financial support from the National Key Research and Development Program of China (Grants No. 2018YFA0305700 and No. 2016YFA0401804), the National Natural Science Foundation of China (NSFC) (Grants No. 11574323, No. U1632275, No. 11874362, No. 11804344, No. U1832209, and No. 11704387), the Users with Excellence Project of Hefei Science Center CAS (Grant No. 2018HSCUE012) and the Major Program of Development Foundation of Hefei Center for Physical Science and Technology (Grant No. 2018ZYFX002). Y.Z. was supported by the Youth Innovation Promotion Association CAS (Grant No. 2020443). The x-ray diffraction experiment was performed at the beamline BL15U1, Shanghai Synchrotron Radiation Facility (SSRF). G.C. acknowledges support from the US National Science Foundation via Grants No. DMR 1712101 and No. 1903888. G.C. is thankful to Dr. Feng Ye, Dr. Bing Hu, and Mr. Hengdi Zhao for useful discussions. LED research is supported by U.S. National Science Foundation Grant No. DMR-1506979.

Financiadores	Número del financiador
Innovative Program of Development Foundation of Hefei Center for Physical Science and Technology	2018ZYFX002
National Science Foundation Arctic Social Science Program	DMR 1712101, DMR-1506979, 1903888
National Key Basic Research and Development Program of China	2018YFA0305700, 2016YFA0401804
Hefei Science Center, Chinese Academy of Sciences	2018HSCUE012
National Natural Science Foundation of China (NSFC)	11804344, 11874362, 11704387, U1632275, 11574323, U1832209
Youth Innovation Promotion Association of the Chinese Academy of Sciences	2020443

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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title = "Persistent insulating state at megabar pressures in strongly spin-orbit coupled S r2Ir O4",

abstract = "It is commonly anticipated that an insulating state will collapse in favor of an emergent metallic state at high pressures: The average electron density must increase with pressure, while the electronic bandwidth is expected to broaden and fill the insulating energy band gap. Here we report an unusually stable insulating state that persists up to at least 185 GPa in Sr2IrO4, the archetypical spin-orbit-driven Jeff=1/2 insulator. This study shows that the electrical resistance R of single-crystal Sr2IrO4 initially decreases with applied pressure P, reaches a minimum in the range 32-38 GPa, then abruptly rises to recover the insulating state with increasing P up to 185 GPa. However, evidence of a saturation of R below 80 K for P≥124GPa GPa raises the possibility of a low-temperature exotic state. Our synchrotron X-ray diffraction and Raman scattering data show the emergence of the rapid increase in R is accompanied by a structural phase transition from the native tetragonal I41/acd phase to an orthorhombic Pbca phase (with much reduced symmetry) at 40.6 GPa. The clear correspondence of the onset pressures of these two anomalies is key to understanding the stability of the insulating state at megabar pressures: Pressure-induced, structural distortions prevent the expected onset of metallization, despite the sizable volume compression attained at the highest pressure accessed in this study.",

author = "Chunhua Chen and Yonghui Zhou and Xuliang Chen and Tao Han and Chao An and Ying Zhou and Yifang Yuan and Bowen Zhang and Shuyang Wang and Ranran Zhang and Lili Zhang and Changjin Zhang and Zhaorong Yang and Delong, \{Lance E.\} and Gang Cao",

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AU - Zhou, Ying

AU - Yuan, Yifang

AU - Zhang, Bowen

AU - Wang, Shuyang

AU - Zhang, Ranran

AU - Zhang, Lili

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AU - Yang, Zhaorong

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AU - Cao, Gang

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AB - It is commonly anticipated that an insulating state will collapse in favor of an emergent metallic state at high pressures: The average electron density must increase with pressure, while the electronic bandwidth is expected to broaden and fill the insulating energy band gap. Here we report an unusually stable insulating state that persists up to at least 185 GPa in Sr2IrO4, the archetypical spin-orbit-driven Jeff=1/2 insulator. This study shows that the electrical resistance R of single-crystal Sr2IrO4 initially decreases with applied pressure P, reaches a minimum in the range 32-38 GPa, then abruptly rises to recover the insulating state with increasing P up to 185 GPa. However, evidence of a saturation of R below 80 K for P≥124GPa GPa raises the possibility of a low-temperature exotic state. Our synchrotron X-ray diffraction and Raman scattering data show the emergence of the rapid increase in R is accompanied by a structural phase transition from the native tetragonal I41/acd phase to an orthorhombic Pbca phase (with much reduced symmetry) at 40.6 GPa. The clear correspondence of the onset pressures of these two anomalies is key to understanding the stability of the insulating state at megabar pressures: Pressure-induced, structural distortions prevent the expected onset of metallization, despite the sizable volume compression attained at the highest pressure accessed in this study.

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Persistent insulating state at megabar pressures in strongly spin-orbit coupled S r2Ir O4

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ASJC Scopus subject areas

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