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Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials. / Tverjanovich, Andrey; Khomenko, Maxim; Benmore, Chris J.; Bokova, Maria; Sokolov, Anton; Fontanari, Daniele; Kassem, Mohammad; Usuki, Takeshi; Bychkov, Eugene.

In: Chemistry of Materials, Vol. 33, No. 3, 09.02.2021, p. 1031-1045.

Research output: Contribution to journalArticlepeer-review

Harvard

Tverjanovich, A, Khomenko, M, Benmore, CJ, Bokova, M, Sokolov, A, Fontanari, D, Kassem, M, Usuki, T & Bychkov, E 2021, 'Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials', Chemistry of Materials, vol. 33, no. 3, pp. 1031-1045. https://doi.org/10.1021/acs.chemmater.0c04409

APA

Tverjanovich, A., Khomenko, M., Benmore, C. J., Bokova, M., Sokolov, A., Fontanari, D., Kassem, M., Usuki, T., & Bychkov, E. (2021). Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials. Chemistry of Materials, 33(3), 1031-1045. https://doi.org/10.1021/acs.chemmater.0c04409

Vancouver

Tverjanovich A, Khomenko M, Benmore CJ, Bokova M, Sokolov A, Fontanari D et al. Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials. Chemistry of Materials. 2021 Feb 9;33(3):1031-1045. https://doi.org/10.1021/acs.chemmater.0c04409

Author

Tverjanovich, Andrey ; Khomenko, Maxim ; Benmore, Chris J. ; Bokova, Maria ; Sokolov, Anton ; Fontanari, Daniele ; Kassem, Mohammad ; Usuki, Takeshi ; Bychkov, Eugene. / Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials. In: Chemistry of Materials. 2021 ; Vol. 33, No. 3. pp. 1031-1045.

BibTeX

@article{331af7747ffa4383ba3c49b4df8c0cc2,
title = "Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials",
abstract = "Vitreous germanium disulfide GeS2 and diselenide GeSe2 belong to canonical chalcogenide glasses extensively studied over the past half century. Their high-temperature orthorhombic polymorphs are congruently melting compounds, and the tetrahedral crystal and glass structure is largely preserved in the melt. In contrast, the ditelluride counterpart is absent in the Ge-Te phase diagram, which shows only a single compound, monotelluride GeTe. Phase-change materials based on GeTe have become a technologically important class of solids, and their structure and properties are also widely studied. Surprisingly, very scarce information is available for alloys having GeTe2 stoichiometry. Using a fast quenching procedure in silica capillaries, high-energy X-ray diffraction, and Raman spectroscopy supported by first-principles simulations, we show that bulk glassy GeTe2 differs substantially from the lighter GeX2 members, revealing 46% of trigonal germanium, 31% of three-fold coordinated tellurium, and only 20% of edge-sharing tetrahedra or pyramids. The fraction of homopolar Ge-Ge bonds is low; however, the population of dominant Te-Te dimers and Ten oligomers, n ≤ 10, appears to be significant. The complex structural and chemical topology of g-GeTe2 is directly related to the thermodynamic metastability of germanium ditelluride, schematically represented by the following reaction: GeTe2 ⇄ GeTe + Te. Disproportionation is complete above liquidus in the temperature range of semiconductor-metal transition, and the dense metallic GeTe2 liquid, mostly consisting of five-fold coordinated Ge species, exhibits high fluidity, strong fragility (m = 99 ± 5), and presumably a fast structural transformation rate combined with low atomic mobility in the vicinity of the glass transition temperature, favorable for reliable long-term data retention in nonvolatile memories. The observed and predicted characteristic features make GeTe2 a promising precursor for the next generation of phase-change materials, especially coupled with additional metal doping, depolymerizing the tetrahedral interconnected glass network and accelerating (sub)nanosecond crystallization. ",
author = "Andrey Tverjanovich and Maxim Khomenko and Benmore, {Chris J.} and Maria Bokova and Anton Sokolov and Daniele Fontanari and Mohammad Kassem and Takeshi Usuki and Eugene Bychkov",
note = "Publisher Copyright: {\textcopyright} 2021 American Chemical Society. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.",
year = "2021",
month = feb,
day = "9",
doi = "10.1021/acs.chemmater.0c04409",
language = "English",
volume = "33",
pages = "1031--1045",
journal = "Chemistry of Materials",
issn = "0897-4756",
publisher = "American Chemical Society",
number = "3",

}

RIS

TY - JOUR

T1 - Bulk Glassy GeTe2: A Missing Member of the Tetrahedral GeX2Family and a Precursor for the Next Generation of Phase-Change Materials

AU - Tverjanovich, Andrey

AU - Khomenko, Maxim

AU - Benmore, Chris J.

AU - Bokova, Maria

AU - Sokolov, Anton

AU - Fontanari, Daniele

AU - Kassem, Mohammad

AU - Usuki, Takeshi

AU - Bychkov, Eugene

N1 - Publisher Copyright: © 2021 American Chemical Society. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.

PY - 2021/2/9

Y1 - 2021/2/9

N2 - Vitreous germanium disulfide GeS2 and diselenide GeSe2 belong to canonical chalcogenide glasses extensively studied over the past half century. Their high-temperature orthorhombic polymorphs are congruently melting compounds, and the tetrahedral crystal and glass structure is largely preserved in the melt. In contrast, the ditelluride counterpart is absent in the Ge-Te phase diagram, which shows only a single compound, monotelluride GeTe. Phase-change materials based on GeTe have become a technologically important class of solids, and their structure and properties are also widely studied. Surprisingly, very scarce information is available for alloys having GeTe2 stoichiometry. Using a fast quenching procedure in silica capillaries, high-energy X-ray diffraction, and Raman spectroscopy supported by first-principles simulations, we show that bulk glassy GeTe2 differs substantially from the lighter GeX2 members, revealing 46% of trigonal germanium, 31% of three-fold coordinated tellurium, and only 20% of edge-sharing tetrahedra or pyramids. The fraction of homopolar Ge-Ge bonds is low; however, the population of dominant Te-Te dimers and Ten oligomers, n ≤ 10, appears to be significant. The complex structural and chemical topology of g-GeTe2 is directly related to the thermodynamic metastability of germanium ditelluride, schematically represented by the following reaction: GeTe2 ⇄ GeTe + Te. Disproportionation is complete above liquidus in the temperature range of semiconductor-metal transition, and the dense metallic GeTe2 liquid, mostly consisting of five-fold coordinated Ge species, exhibits high fluidity, strong fragility (m = 99 ± 5), and presumably a fast structural transformation rate combined with low atomic mobility in the vicinity of the glass transition temperature, favorable for reliable long-term data retention in nonvolatile memories. The observed and predicted characteristic features make GeTe2 a promising precursor for the next generation of phase-change materials, especially coupled with additional metal doping, depolymerizing the tetrahedral interconnected glass network and accelerating (sub)nanosecond crystallization.

AB - Vitreous germanium disulfide GeS2 and diselenide GeSe2 belong to canonical chalcogenide glasses extensively studied over the past half century. Their high-temperature orthorhombic polymorphs are congruently melting compounds, and the tetrahedral crystal and glass structure is largely preserved in the melt. In contrast, the ditelluride counterpart is absent in the Ge-Te phase diagram, which shows only a single compound, monotelluride GeTe. Phase-change materials based on GeTe have become a technologically important class of solids, and their structure and properties are also widely studied. Surprisingly, very scarce information is available for alloys having GeTe2 stoichiometry. Using a fast quenching procedure in silica capillaries, high-energy X-ray diffraction, and Raman spectroscopy supported by first-principles simulations, we show that bulk glassy GeTe2 differs substantially from the lighter GeX2 members, revealing 46% of trigonal germanium, 31% of three-fold coordinated tellurium, and only 20% of edge-sharing tetrahedra or pyramids. The fraction of homopolar Ge-Ge bonds is low; however, the population of dominant Te-Te dimers and Ten oligomers, n ≤ 10, appears to be significant. The complex structural and chemical topology of g-GeTe2 is directly related to the thermodynamic metastability of germanium ditelluride, schematically represented by the following reaction: GeTe2 ⇄ GeTe + Te. Disproportionation is complete above liquidus in the temperature range of semiconductor-metal transition, and the dense metallic GeTe2 liquid, mostly consisting of five-fold coordinated Ge species, exhibits high fluidity, strong fragility (m = 99 ± 5), and presumably a fast structural transformation rate combined with low atomic mobility in the vicinity of the glass transition temperature, favorable for reliable long-term data retention in nonvolatile memories. The observed and predicted characteristic features make GeTe2 a promising precursor for the next generation of phase-change materials, especially coupled with additional metal doping, depolymerizing the tetrahedral interconnected glass network and accelerating (sub)nanosecond crystallization.

UR - http://www.scopus.com/inward/record.url?scp=85099908876&partnerID=8YFLogxK

U2 - 10.1021/acs.chemmater.0c04409

DO - 10.1021/acs.chemmater.0c04409

M3 - Article

AN - SCOPUS:85099908876

VL - 33

SP - 1031

EP - 1045

JO - Chemistry of Materials

JF - Chemistry of Materials

SN - 0897-4756

IS - 3

ER -

ID: 78063556