Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure

L. Nataf; F. Aguado; I. Hernández; R. Valiente; J. González; M. N. Sanz-Ortiz; H. Wilhelm; A. P. Jephcoat; F. Baudelet; F. Rodríguez

doi:10.1103/PhysRevB.95.014110

Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure

L. Nataf, F. Aguado, I. Hernández, R. Valiente, J. González, M. N. Sanz-Ortiz, H. Wilhelm, A. P. Jephcoat, F. Baudelet, F. Rodríguez

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Abstract

This work investigates the high-pressure structure of Cs2CoCl4 and how it affects the electronic and vibrational properties using optical absorption, Raman spectroscopy, x-ray diffraction, and x-ray absorption in the 0-15 GPa range. In particular, we focus on the electronic and local structures of Co2+, since compression of Cs2CoCl4 yields structural transformations associated with change of coordination around Co2+, which are eventually responsible for the intense piezochromism at 7 GPa. This study provides a complete characterization of the electronic and vibrational structures of Cs2CoCl4 in the Pnma phase as a function of the cell volume and the local CoCl4 bond length, RCo-Cl, as well as its corresponding equation of state. In addition, our interest is to elucidate whether the phase transition undergone by Cs2CoCl4 at 7 GPa leads to a perovskite-layer-type structure where Co2+ is sixfold coordinated, decomposes into CsCl+CsCoCl3, or it involves an unknown phase with different coordination sites for Co2+. We show that Co2+ is sixfold coordinated in the high-pressure phase. The analysis of optical spectra and x-ray diffraction data suggests the formation of an interconnected structure of exchange-coupled Co2+ through edge-sharing octahedra at high pressure.

Original language	English
Article number	014110
Journal	Physical Review B
Volume	95
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevB.95.014110
Publication status	Published - Jan 24 2017

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.95.014110

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Nataf, L., Aguado, F., Hernández, I., Valiente, R., González, J., Sanz-Ortiz, M. N., Wilhelm, H., Jephcoat, A. P., Baudelet, F., & Rodríguez, F. (2017). Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure. Physical Review B, 95(1), Article 014110. https://doi.org/10.1103/PhysRevB.95.014110

Nataf, L, Aguado, F, Hernández, I, Valiente, R, González, J, Sanz-Ortiz, MN, Wilhelm, H, Jephcoat, AP, Baudelet, F & Rodríguez, F 2017, 'Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure', Physical Review B, vol. 95, no. 1, 014110. https://doi.org/10.1103/PhysRevB.95.014110

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title = "Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure",

abstract = "This work investigates the high-pressure structure of Cs2CoCl4 and how it affects the electronic and vibrational properties using optical absorption, Raman spectroscopy, x-ray diffraction, and x-ray absorption in the 0-15 GPa range. In particular, we focus on the electronic and local structures of Co2+, since compression of Cs2CoCl4 yields structural transformations associated with change of coordination around Co2+, which are eventually responsible for the intense piezochromism at 7 GPa. This study provides a complete characterization of the electronic and vibrational structures of Cs2CoCl4 in the Pnma phase as a function of the cell volume and the local CoCl4 bond length, RCo-Cl, as well as its corresponding equation of state. In addition, our interest is to elucidate whether the phase transition undergone by Cs2CoCl4 at 7 GPa leads to a perovskite-layer-type structure where Co2+ is sixfold coordinated, decomposes into CsCl+CsCoCl3, or it involves an unknown phase with different coordination sites for Co2+. We show that Co2+ is sixfold coordinated in the high-pressure phase. The analysis of optical spectra and x-ray diffraction data suggests the formation of an interconnected structure of exchange-coupled Co2+ through edge-sharing octahedra at high pressure.",

author = "L. Nataf and F. Aguado and I. Hern{\'a}ndez and R. Valiente and J. Gonz{\'a}lez and Sanz-Ortiz, {M. N.} and H. Wilhelm and Jephcoat, {A. P.} and F. Baudelet and F. Rodr{\'i}guez",

note = "Funding Information: Financial support from the Spanish Ministerio de Economia y Competitividad (Project No. MAT2015-69508-P) and MALTA-CONSOLIDER (Ref. No. MAT2015-71070-REDC) is acknowledged. We also acknowledge financial support and facilities from the Synchrotron SOLEIL (Proposal Ref. No. 20100989) and Synchrotron DIAMOND (Project Ref. No. EE1655). I.H. thanks the EU FP7 for his Marie Curie CIG grant (Grant No. MC-CIG 303535). Publisher Copyright: {\textcopyright} 2017 American Physical Society.",

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doi = "10.1103/PhysRevB.95.014110",

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T2 - Identification of a pressure-induced piezochromic phase at high pressure

AU - Nataf, L.

AU - Aguado, F.

AU - Hernández, I.

AU - Valiente, R.

AU - González, J.

AU - Sanz-Ortiz, M. N.

AU - Wilhelm, H.

AU - Jephcoat, A. P.

AU - Baudelet, F.

AU - Rodríguez, F.

N1 - Funding Information: Financial support from the Spanish Ministerio de Economia y Competitividad (Project No. MAT2015-69508-P) and MALTA-CONSOLIDER (Ref. No. MAT2015-71070-REDC) is acknowledged. We also acknowledge financial support and facilities from the Synchrotron SOLEIL (Proposal Ref. No. 20100989) and Synchrotron DIAMOND (Project Ref. No. EE1655). I.H. thanks the EU FP7 for his Marie Curie CIG grant (Grant No. MC-CIG 303535). Publisher Copyright: © 2017 American Physical Society.

PY - 2017/1/24

Y1 - 2017/1/24

N2 - This work investigates the high-pressure structure of Cs2CoCl4 and how it affects the electronic and vibrational properties using optical absorption, Raman spectroscopy, x-ray diffraction, and x-ray absorption in the 0-15 GPa range. In particular, we focus on the electronic and local structures of Co2+, since compression of Cs2CoCl4 yields structural transformations associated with change of coordination around Co2+, which are eventually responsible for the intense piezochromism at 7 GPa. This study provides a complete characterization of the electronic and vibrational structures of Cs2CoCl4 in the Pnma phase as a function of the cell volume and the local CoCl4 bond length, RCo-Cl, as well as its corresponding equation of state. In addition, our interest is to elucidate whether the phase transition undergone by Cs2CoCl4 at 7 GPa leads to a perovskite-layer-type structure where Co2+ is sixfold coordinated, decomposes into CsCl+CsCoCl3, or it involves an unknown phase with different coordination sites for Co2+. We show that Co2+ is sixfold coordinated in the high-pressure phase. The analysis of optical spectra and x-ray diffraction data suggests the formation of an interconnected structure of exchange-coupled Co2+ through edge-sharing octahedra at high pressure.

AB - This work investigates the high-pressure structure of Cs2CoCl4 and how it affects the electronic and vibrational properties using optical absorption, Raman spectroscopy, x-ray diffraction, and x-ray absorption in the 0-15 GPa range. In particular, we focus on the electronic and local structures of Co2+, since compression of Cs2CoCl4 yields structural transformations associated with change of coordination around Co2+, which are eventually responsible for the intense piezochromism at 7 GPa. This study provides a complete characterization of the electronic and vibrational structures of Cs2CoCl4 in the Pnma phase as a function of the cell volume and the local CoCl4 bond length, RCo-Cl, as well as its corresponding equation of state. In addition, our interest is to elucidate whether the phase transition undergone by Cs2CoCl4 at 7 GPa leads to a perovskite-layer-type structure where Co2+ is sixfold coordinated, decomposes into CsCl+CsCoCl3, or it involves an unknown phase with different coordination sites for Co2+. We show that Co2+ is sixfold coordinated in the high-pressure phase. The analysis of optical spectra and x-ray diffraction data suggests the formation of an interconnected structure of exchange-coupled Co2+ through edge-sharing octahedra at high pressure.

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Volume and pressure dependences of the electronic, vibrational, and crystal structures of C s2CoC l4: Identification of a pressure-induced piezochromic phase at high pressure

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