PbI2 band gap engineering by gel incorporation

Chong Hu; Tao Ye; Yujing Liu; Jie Ren; Xinyi Jin; Hongzheng Chen; Hanying Li

doi:10.1039/c7qm00509a

PbI₂ band gap engineering by gel incorporation

Chong Hu, Tao Ye, Yujing Liu, Jie Ren, Xinyi Jin, Hongzheng Chen, Hanying Li

Zhejiang University

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

14 Scopus citations

Abstract

Incorporation of guest materials into semiconducting single crystalline hosts leads to the formation of semiconducting single-crystal composites. However, limited efforts have been made to comprehensively investigate the property of these potential functionalized single-crystal composites. Herein, PbI₂/gel single-crystal composites have been successfully prepared. Diffuse reflectance spectra show a clear increase in the band gap of PbI₂ after gel incorporation. The band gap is further increased through expanding the area of host/guest interfaces or enhancing the interatomic forces at the interfaces. The interatomic forces (electrostatic interaction) at the host/guest interfaces are attributed to this band gap shift. As such, this study provides a novel and facile way for band gap engineering by gel incorporation.

Original language	English
Pages (from-to)	362-368
Number of pages	7
Journal	Materials Chemistry Frontiers
Volume	2
Issue number	2
DOIs	https://doi.org/10.1039/c7qm00509a
State	Published - 2018
Externally published	Yes

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title = "PbI2 band gap engineering by gel incorporation",

abstract = "Incorporation of guest materials into semiconducting single crystalline hosts leads to the formation of semiconducting single-crystal composites. However, limited efforts have been made to comprehensively investigate the property of these potential functionalized single-crystal composites. Herein, PbI2/gel single-crystal composites have been successfully prepared. Diffuse reflectance spectra show a clear increase in the band gap of PbI2 after gel incorporation. The band gap is further increased through expanding the area of host/guest interfaces or enhancing the interatomic forces at the interfaces. The interatomic forces (electrostatic interaction) at the host/guest interfaces are attributed to this band gap shift. As such, this study provides a novel and facile way for band gap engineering by gel incorporation.",

author = "Chong Hu and Tao Ye and Yujing Liu and Jie Ren and Xinyi Jin and Hongzheng Chen and Hanying Li",

year = "2018",

doi = "10.1039/c7qm00509a",

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T1 - PbI2 band gap engineering by gel incorporation

AU - Hu, Chong

AU - Ye, Tao

AU - Liu, Yujing

AU - Ren, Jie

AU - Jin, Xinyi

AU - Chen, Hongzheng

AU - Li, Hanying

PY - 2018

Y1 - 2018

N2 - Incorporation of guest materials into semiconducting single crystalline hosts leads to the formation of semiconducting single-crystal composites. However, limited efforts have been made to comprehensively investigate the property of these potential functionalized single-crystal composites. Herein, PbI2/gel single-crystal composites have been successfully prepared. Diffuse reflectance spectra show a clear increase in the band gap of PbI2 after gel incorporation. The band gap is further increased through expanding the area of host/guest interfaces or enhancing the interatomic forces at the interfaces. The interatomic forces (electrostatic interaction) at the host/guest interfaces are attributed to this band gap shift. As such, this study provides a novel and facile way for band gap engineering by gel incorporation.

AB - Incorporation of guest materials into semiconducting single crystalline hosts leads to the formation of semiconducting single-crystal composites. However, limited efforts have been made to comprehensively investigate the property of these potential functionalized single-crystal composites. Herein, PbI2/gel single-crystal composites have been successfully prepared. Diffuse reflectance spectra show a clear increase in the band gap of PbI2 after gel incorporation. The band gap is further increased through expanding the area of host/guest interfaces or enhancing the interatomic forces at the interfaces. The interatomic forces (electrostatic interaction) at the host/guest interfaces are attributed to this band gap shift. As such, this study provides a novel and facile way for band gap engineering by gel incorporation.

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JO - Materials Chemistry Frontiers

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PbI₂ band gap engineering by gel incorporation

Abstract

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