Noriko Saito
(Research Center for Functional Materials/Electric and Electronic Materials Field/Ceramics Surface and Interface Group)
;
Yoshitaka Matsushita
(Research Network and Facility Services Division/Materials Analysis Station)
;
Takeo Ohsawa
(Research Center for Functional Materials/Electric and Electronic Materials Field/Electroceramics Group)
;
Hiroyo Segawa
(Research Center for Functional Materials/Electric and Electronic Materials Field/Electroceramics Group)
;
Naoki Ohashi
(Research Center for Functional Materials/Electric and Electronic Materials Field/Electroceramics Group)
Collection
Citation
Description:
(abstract)The dataset provides the calculated crystal structures of Formamidinium–lead–chloride–dimethyl sulfoxide solvate, FAPbCl3–DMSO, and related compounds (CsPbCl3-DMSO, CsPbCl3, CsCl, DMSO-lattice, FAPbCl3, FACl, PbCl2) listed in Table 3 of https://doi.org/10.1039/D2CE00889K.
Description:
(abstract)The reproduction of the refined crystal structures was examined by total-energy calculations using DFT method. The total energy calculations were performed using a plane-wave-based pseudo-potential method implemented in the CASTEP code, which is included in the Materials Studio Package (Dassault Systèmes, Tokyo, Japan). Norm-conserved pseudopotentials were generated using the CASTEP code, and a generalized gradient approximation optimized for solids, referred to as PBESol, was adopted as the exchange-correlation functional for self-consistent total energy calculations. The plane-wave cut-off energy was set to 1050 eV, and two sampling points on a Monkhorst–Pack grid were used for k-point sampling. In order to achieve efficient conversion of self-consistent field calculations, ensemble DFT was applied. Structural optimization was performed with the Broyden–Fletcher–Goldfarb–Shanno scheme. Convergence of the energy minimization and structural relaxation was judged with following tolerances: tolerance for electronic energy mineralization was set to 5.0×10-7 eV per atom, energy tolerance for structural optimization to 5.0×10-6 eV per atom, force tolerance to 0.01 eV/Å, stress tolerance to 0.02 GPa, and atomic displacement tolerance to 5.0×10-4 Å.
Data origin type: simulation
Rights:
Keyword: hybrid halide, formamidinium, dimethyl sulfoxide (DMSO), lead halide
Date published: 2022-11-03
Publisher: Royal Society of Chemistry
Journal:
- CRYSTENGCOMM (ISSN: 14668033) vol. 24 issue. 45 p. 7996-8004
Funding:
- MEXT JPMXP0112101001 (Elements Strategy Initiative to Form Core Research Center for Electronic Materials: Tokodai Institute of Elements Strategy)
- JSPS 21K04646 (結晶構造の対称性に着目した有機ー無機ハイブリッドハライド結晶の合成と機能探索)
Manuscript type: Not a journal article
MDR DOI: https://doi.org/10.48505/nims.3849
First published URL: https://doi.org/10.1039/D2CE00889K
Related item:
Other identifier(s):
Contact agent:
Updated at: 2024-01-05 22:13:14 +0900
Published on MDR: 2023-02-01 09:42:52 +0900
Name / 名称 : CASTEP
Version / バージョン :
Description / 説明 :
Software ID / ソフトウェアID :
Description / 説明 :
Category /
カテゴリ
:
density functional theory or electronic structure
Category description / カテゴリの説明 :
Calculated at / 計算時刻 :
| Filename | Size | |||
|---|---|---|---|---|
| Filename |
FAPbCl3-DMSO.cif
chemical/x-cif |
Size | 1.72 KB | Detail |
| Filename |
FAPbCl3.cif
chemical/x-cif |
Size | 1.46 KB | Detail |
| Filename |
CsPbCl3-DMSO.cif
chemical/x-cif |
Size | 3.47 KB | Detail |
| Filename |
CsPbCl3.cif
chemical/x-cif |
Size | 999 Bytes | Detail |
| Filename |
FACl.cif
chemical/x-cif |
Size | 1.13 KB | Detail |
| Filename |
CsCl.cif
(Thumbnail)
chemical/x-cif |
Size | 1.22 KB | Detail |
| Filename |
PbCl2.cif
chemical/x-cif |
Size | 939 Bytes | Detail |
| Filename |
DIMSO-lattice.cif
chemical/x-cif |
Size | 1.18 KB | Detail |