Mechanical Properties of Formamidinium Halide Perovskites FABX3 (FA=CH(NH2)2; B=Pb, Sn; X=Br, I) by First-Principles Calculations

Lei Guo; Gang Tang; Jiawang Hong

doi:10.1088/0256-307X/36/5/056201

Mechanical Properties of Formamidinium Halide Perovskites FABX₃ (FA=CH(NH₂)₂; B=Pb, Sn; X=Br, I) by First-Principles Calculations

Lei Guo, Gang Tang, Jiawang Hong^*

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

47 Citations (Scopus)

Abstract

The mechanical properties of formamidinium halide perovskites FABX3 (FA=CH(NH₂)2; B=Pb, Sn; X=Br, I) are systematically investigated using first-principles calculations. Our results reveal that FABX₃ perovskites possess excellent mechanical flexibility, ductility and strong anisotropy. We shows that the planar organic cation FA⁺ has an important effect on the mechanical properties of FABX₃ perovskites. In addition, our results indicate that (i) the moduli (bulk modulus B, Young's modulus E, and shear modulus G) of FABBr3 are larger than those of FABI³ for the same B atom, and (ii) the moduli of FAPbX3 are larger than those of FASnX₃ for the same halide atom. The reason for the two trends is demonstrated by carefully analyzing the bond strength between B and X atoms based on the projected crystal orbital Hamilton population method.

Original language	English
Article number	056201
Journal	Chinese Physics Letters
Volume	36
Issue number	5
DOIs	https://doi.org/10.1088/0256-307X/36/5/056201
Publication status	Published - 2019

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title = "Mechanical Properties of Formamidinium Halide Perovskites FABX3 (FA=CH(NH2)2; B=Pb, Sn; X=Br, I) by First-Principles Calculations",

abstract = "The mechanical properties of formamidinium halide perovskites FABX3 (FA=CH(NH2)2; B=Pb, Sn; X=Br, I) are systematically investigated using first-principles calculations. Our results reveal that FABX3 perovskites possess excellent mechanical flexibility, ductility and strong anisotropy. We shows that the planar organic cation FA+ has an important effect on the mechanical properties of FABX3 perovskites. In addition, our results indicate that (i) the moduli (bulk modulus B, Young's modulus E, and shear modulus G) of FABBr3 are larger than those of FABI3 for the same B atom, and (ii) the moduli of FAPbX3 are larger than those of FASnX3 for the same halide atom. The reason for the two trends is demonstrated by carefully analyzing the bond strength between B and X atoms based on the projected crystal orbital Hamilton population method.",

author = "Lei Guo and Gang Tang and Jiawang Hong",

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doi = "10.1088/0256-307X/36/5/056201",

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journal = "Chinese Physics Letters",

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AU - Guo, Lei

AU - Tang, Gang

AU - Hong, Jiawang

PY - 2019

Y1 - 2019

N2 - The mechanical properties of formamidinium halide perovskites FABX3 (FA=CH(NH2)2; B=Pb, Sn; X=Br, I) are systematically investigated using first-principles calculations. Our results reveal that FABX3 perovskites possess excellent mechanical flexibility, ductility and strong anisotropy. We shows that the planar organic cation FA+ has an important effect on the mechanical properties of FABX3 perovskites. In addition, our results indicate that (i) the moduli (bulk modulus B, Young's modulus E, and shear modulus G) of FABBr3 are larger than those of FABI3 for the same B atom, and (ii) the moduli of FAPbX3 are larger than those of FASnX3 for the same halide atom. The reason for the two trends is demonstrated by carefully analyzing the bond strength between B and X atoms based on the projected crystal orbital Hamilton population method.

AB - The mechanical properties of formamidinium halide perovskites FABX3 (FA=CH(NH2)2; B=Pb, Sn; X=Br, I) are systematically investigated using first-principles calculations. Our results reveal that FABX3 perovskites possess excellent mechanical flexibility, ductility and strong anisotropy. We shows that the planar organic cation FA+ has an important effect on the mechanical properties of FABX3 perovskites. In addition, our results indicate that (i) the moduli (bulk modulus B, Young's modulus E, and shear modulus G) of FABBr3 are larger than those of FABI3 for the same B atom, and (ii) the moduli of FAPbX3 are larger than those of FASnX3 for the same halide atom. The reason for the two trends is demonstrated by carefully analyzing the bond strength between B and X atoms based on the projected crystal orbital Hamilton population method.

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Mechanical Properties of Formamidinium Halide Perovskites FABX₃ (FA=CH(NH₂)₂; B=Pb, Sn; X=Br, I) by First-Principles Calculations

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