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Alkali Metal (Li, Na, and K) Orthocarbonates: Stabilization of sp3-Bonded Carbon at Pressures above 20 GPa. / Sagatova, Dinara N.; Sagatov, Nursultan E.; Gavryushkin, Pavel N. и др.

в: Crystal Growth and Design, Том 21, № 12, 01.12.2021, стр. 6744-6751.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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APA

Vancouver

Sagatova DN, Sagatov NE, Gavryushkin PN, Banaev MV, Litasov KD. Alkali Metal (Li, Na, and K) Orthocarbonates: Stabilization of sp3-Bonded Carbon at Pressures above 20 GPa. Crystal Growth and Design. 2021 дек. 1;21(12):6744-6751. Epub 2021 нояб. 16. doi: 10.1021/acs.cgd.1c00652

Author

Sagatova, Dinara N. ; Sagatov, Nursultan E. ; Gavryushkin, Pavel N. и др. / Alkali Metal (Li, Na, and K) Orthocarbonates: Stabilization of sp3-Bonded Carbon at Pressures above 20 GPa. в: Crystal Growth and Design. 2021 ; Том 21, № 12. стр. 6744-6751.

BibTeX

@article{65038512463e43b8b8bb0814a73f6816,
title = "Alkali Metal (Li, Na, and K) Orthocarbonates: Stabilization of sp3-Bonded Carbon at Pressures above 20 GPa",
abstract = "In the present work, based on the density functional theory and crystal structure prediction algorithms, we found novel structures of alkali metal orthocarbonates Li4CO4-C2/c, Na4CO4-C2/c, and K4CO4-P21/c. The pressure of thermodynamic stabilization of the obtained orthocarbonates with respect to decomposition into the corresponding carbonate and oxide ranges from 21 GPa (for K4CO4) to 25 GPa (for Li4CO4). All obtained structures contain isolated groups of [CO4]tetrahedra. The structures of lithium and sodium orthocarbonates were found to be isotypic. As well as alkaline earth orthocarbonates, orthocarbonates of alkali metals are structurally similar to orthosilicates of the same metal. Na4CO4-C2/c was found to be dynamically stable at ambient pressure, while all other structures are destabilized on decompression. In addition, the P-T phase diagrams of lithium, sodium, and potassium oxides have been calculated for the first time. All oxides have a high-pressure phase transition from the Fm3¯ m (anti-fluorite) structure to the Pnma (anti-cotunnite) structure at 34 GPa for Li2O, at 10 GPa for Na2O, and at 5 GPa for K2O at low temperatures. In the Na2O and K2O systems, high-temperature phase transition to the P6¯ 2m (barringerite) structure was revealed at temperatures above 1300 and 650 K, respectively. ",
author = "Sagatova, {Dinara N.} and Sagatov, {Nursultan E.} and Gavryushkin, {Pavel N.} and Banaev, {Maksim V.} and Litasov, {Konstantin D.}",
note = "Funding Information: This study was funded by the RFBR under research project No. 20-03-00774 and the state assignment of the IGM SB RAS. The computations were performed using resources provided by the Novosibirsk State University Supercomputer Center. Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",
year = "2021",
month = dec,
day = "1",
doi = "10.1021/acs.cgd.1c00652",
language = "English",
volume = "21",
pages = "6744--6751",
journal = "Crystal Growth and Design",
issn = "1528-7483",
publisher = "American Chemical Society",
number = "12",

}

RIS

TY - JOUR

T1 - Alkali Metal (Li, Na, and K) Orthocarbonates: Stabilization of sp3-Bonded Carbon at Pressures above 20 GPa

AU - Sagatova, Dinara N.

AU - Sagatov, Nursultan E.

AU - Gavryushkin, Pavel N.

AU - Banaev, Maksim V.

AU - Litasov, Konstantin D.

N1 - Funding Information: This study was funded by the RFBR under research project No. 20-03-00774 and the state assignment of the IGM SB RAS. The computations were performed using resources provided by the Novosibirsk State University Supercomputer Center. Publisher Copyright: © 2021 American Chemical Society.

PY - 2021/12/1

Y1 - 2021/12/1

N2 - In the present work, based on the density functional theory and crystal structure prediction algorithms, we found novel structures of alkali metal orthocarbonates Li4CO4-C2/c, Na4CO4-C2/c, and K4CO4-P21/c. The pressure of thermodynamic stabilization of the obtained orthocarbonates with respect to decomposition into the corresponding carbonate and oxide ranges from 21 GPa (for K4CO4) to 25 GPa (for Li4CO4). All obtained structures contain isolated groups of [CO4]tetrahedra. The structures of lithium and sodium orthocarbonates were found to be isotypic. As well as alkaline earth orthocarbonates, orthocarbonates of alkali metals are structurally similar to orthosilicates of the same metal. Na4CO4-C2/c was found to be dynamically stable at ambient pressure, while all other structures are destabilized on decompression. In addition, the P-T phase diagrams of lithium, sodium, and potassium oxides have been calculated for the first time. All oxides have a high-pressure phase transition from the Fm3¯ m (anti-fluorite) structure to the Pnma (anti-cotunnite) structure at 34 GPa for Li2O, at 10 GPa for Na2O, and at 5 GPa for K2O at low temperatures. In the Na2O and K2O systems, high-temperature phase transition to the P6¯ 2m (barringerite) structure was revealed at temperatures above 1300 and 650 K, respectively.

AB - In the present work, based on the density functional theory and crystal structure prediction algorithms, we found novel structures of alkali metal orthocarbonates Li4CO4-C2/c, Na4CO4-C2/c, and K4CO4-P21/c. The pressure of thermodynamic stabilization of the obtained orthocarbonates with respect to decomposition into the corresponding carbonate and oxide ranges from 21 GPa (for K4CO4) to 25 GPa (for Li4CO4). All obtained structures contain isolated groups of [CO4]tetrahedra. The structures of lithium and sodium orthocarbonates were found to be isotypic. As well as alkaline earth orthocarbonates, orthocarbonates of alkali metals are structurally similar to orthosilicates of the same metal. Na4CO4-C2/c was found to be dynamically stable at ambient pressure, while all other structures are destabilized on decompression. In addition, the P-T phase diagrams of lithium, sodium, and potassium oxides have been calculated for the first time. All oxides have a high-pressure phase transition from the Fm3¯ m (anti-fluorite) structure to the Pnma (anti-cotunnite) structure at 34 GPa for Li2O, at 10 GPa for Na2O, and at 5 GPa for K2O at low temperatures. In the Na2O and K2O systems, high-temperature phase transition to the P6¯ 2m (barringerite) structure was revealed at temperatures above 1300 and 650 K, respectively.

UR - http://www.scopus.com/inward/record.url?scp=85119923272&partnerID=8YFLogxK

U2 - 10.1021/acs.cgd.1c00652

DO - 10.1021/acs.cgd.1c00652

M3 - Article

AN - SCOPUS:85119923272

VL - 21

SP - 6744

EP - 6751

JO - Crystal Growth and Design

JF - Crystal Growth and Design

SN - 1528-7483

IS - 12

ER -

ID: 34840361