Characterization and Decomposition of the Natural van der Waals SnSb2Te4 under Compression

High pressure X-ray diffraction, Raman scattering, and electrical measurements, together with theoretical calculations, which include the analysis of the topological electron density and electronic localization function, evidence the presence of an isostructural phase transition around 2 GPa, a Ferm...

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Veröffentlicht in:	Inorganic chemistry 2020-07, Vol.59 (14), p.9900-9918
Hauptverfasser:	Sans, Juan A, Vilaplana, Rosario, da Silva, E. Lora, Popescu, Catalin, Cuenca-Gotor, Vanesa P, Andrada-Chacón, Adrián, Sánchez-Benitez, Javier, Gomis, Oscar, Pereira, André L. J, Rodríguez-Hernández, Plácida, Muñoz, Alfonso, Daisenberger, Dominik, García-Domene, Braulio, Segura, Alfredo, Errandonea, Daniel, Kumar, Ravhi S, Oeckler, Oliver, Urban, Philipp, Contreras-García, Julia, Manjón, Francisco J
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Schlagworte:	Chemical Sciences Condensed Matter Inorganic chemistry Materials Science Physics
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creator	Sans, Juan A Vilaplana, Rosario da Silva, E. Lora Popescu, Catalin Cuenca-Gotor, Vanesa P Andrada-Chacón, Adrián Sánchez-Benitez, Javier Gomis, Oscar Pereira, André L. J Rodríguez-Hernández, Plácida Muñoz, Alfonso Daisenberger, Dominik García-Domene, Braulio Segura, Alfredo Errandonea, Daniel Kumar, Ravhi S Oeckler, Oliver Urban, Philipp Contreras-García, Julia Manjón, Francisco J
description	High pressure X-ray diffraction, Raman scattering, and electrical measurements, together with theoretical calculations, which include the analysis of the topological electron density and electronic localization function, evidence the presence of an isostructural phase transition around 2 GPa, a Fermi resonance around 3.5 GPa, and a pressure-induced decomposition of SnSb2Te4 into the high-pressure phases of its parent binary compounds (α-Sb2Te3 and SnTe) above 7 GPa. The internal polyhedral compressibility, the behavior of the Raman-active modes, the electrical behavior, and the nature of its different bonds under compression have been discussed and compared with their parent binary compounds and with related ternary materials. In this context, the Raman spectrum of SnSb2Te4 exhibits vibrational modes that are associated but forbidden in rocksalt-type SnTe; thus showing a novel way to experimentally observe the forbidden vibrational modes of some compounds. Here, some of the bonds are identified with metavalent bonding, which were already observed in their parent binary compounds. The behavior of SnSb2Te4 is framed within the extended orbital radii map of BA2Te4 compounds, so our results pave the way to understand the pressure behavior and stability ranges of other “natural van der Waals” compounds with similar stoichiometry.
doi_str_mv	10.1021/acs.inorgchem.0c01086
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Chem</addtitle><description>High pressure X-ray diffraction, Raman scattering, and electrical measurements, together with theoretical calculations, which include the analysis of the topological electron density and electronic localization function, evidence the presence of an isostructural phase transition around 2 GPa, a Fermi resonance around 3.5 GPa, and a pressure-induced decomposition of SnSb2Te4 into the high-pressure phases of its parent binary compounds (α-Sb2Te3 and SnTe) above 7 GPa. The internal polyhedral compressibility, the behavior of the Raman-active modes, the electrical behavior, and the nature of its different bonds under compression have been discussed and compared with their parent binary compounds and with related ternary materials. In this context, the Raman spectrum of SnSb2Te4 exhibits vibrational modes that are associated but forbidden in rocksalt-type SnTe; thus showing a novel way to experimentally observe the forbidden vibrational modes of some compounds. Here, some of the bonds are identified with metavalent bonding, which were already observed in their parent binary compounds. 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Chem</addtitle><date>2020-07-20</date><risdate>2020</risdate><volume>59</volume><issue>14</issue><spage>9900</spage><epage>9918</epage><pages>9900-9918</pages><issn>0020-1669</issn><eissn>1520-510X</eissn><abstract>High pressure X-ray diffraction, Raman scattering, and electrical measurements, together with theoretical calculations, which include the analysis of the topological electron density and electronic localization function, evidence the presence of an isostructural phase transition around 2 GPa, a Fermi resonance around 3.5 GPa, and a pressure-induced decomposition of SnSb2Te4 into the high-pressure phases of its parent binary compounds (α-Sb2Te3 and SnTe) above 7 GPa. The internal polyhedral compressibility, the behavior of the Raman-active modes, the electrical behavior, and the nature of its different bonds under compression have been discussed and compared with their parent binary compounds and with related ternary materials. In this context, the Raman spectrum of SnSb2Te4 exhibits vibrational modes that are associated but forbidden in rocksalt-type SnTe; thus showing a novel way to experimentally observe the forbidden vibrational modes of some compounds. Here, some of the bonds are identified with metavalent bonding, which were already observed in their parent binary compounds. 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title	Characterization and Decomposition of the Natural van der Waals SnSb2Te4 under Compression
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