High Selectivity Gas Sensing and Charge Transfer of SnSe2

Óscar Leonardo Camargo Moreira; Wei Ying Cheng; Huei Ru Fuh; Wei Chen Chien; Wenjie Yan; Haifeng Fei; Hongjun Xu; Duan Zhang; Yanhui Chen; Yanfeng Zhao; Yanhui Lv; Gang Wu; Chengzhai Lv; Sunil K. Arora; Cormac Ó Coileáin; Chenglin Heng; Ching Ray Chang; Han Chun Wu

doi:10.1021/acssensors.9b01461

High Selectivity Gas Sensing and Charge Transfer of SnSe₂

Óscar Leonardo Camargo Moreira, Wei Ying Cheng, Huei Ru Fuh^*, Wei Chen Chien, Wenjie Yan, Haifeng Fei, Hongjun Xu, Duan Zhang, Yanhui Chen, Yanfeng Zhao, Yanhui Lv, Gang Wu, Chengzhai Lv, Sunil K. Arora, Cormac Ó Coileáin, Chenglin Heng, Ching Ray Chang, Han Chun Wu

^*Corresponding author for this work

School of Physics

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

80 Citations (Scopus)

Abstract

SnSe₂ is an anisotropic binary-layered material with rich physics, which could see it used for a variety of potential applications. Here, we investigate the gas-sensing properties of SnSe₂ using first-principles calculations and verify predictions using a gas sensor made of few-layer SnSe₂ grown by chemical vapor deposition. Theoretical simulations indicate that electrons transfer from SnSe₂ to NO₂, whereas the direction of charge transfer is the opposite for NH₃. Notably, a flat molecular band appears around the Fermi energy after NO₂ adsorption and the induced molecular band is close to the conduction band minimum. Moreover, compared with NH₃, NO₂ molecules adsorbed on SnSe₂ have a lower adsorption energy and a higher charge transfer value. The dynamic-sensing responses of SnSe₂ sensors confirm the theoretical predictions. The good match between the theoretical prediction and experimental demonstration suggests that the underlying sensing mechanism is related to the charge transfer and induced flat band. Our results provide a guideline for designing high-performance gas sensors based on SnSe₂.

Original language	English
Pages (from-to)	2546-2552
Number of pages	7
Journal	ACS Sensors
Volume	4
Issue number	9
DOIs	https://doi.org/10.1021/acssensors.9b01461
Publication status	Published - 27 Sept 2019

Keywords

NH gas sensor
NO gas sensor
SnSe
charge transfer
first-principles calculations
gas sensing
selective gas sensing

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10.1021/acssensors.9b01461

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Moreira, Ó. L. C., Cheng, W. Y., Fuh, H. R., Chien, W. C., Yan, W., Fei, H., Xu, H., Zhang, D., Chen, Y., Zhao, Y., Lv, Y., Wu, G., Lv, C., Arora, S. K., Ó Coileáin, C., Heng, C., Chang, C. R., & Wu, H. C. (2019). High Selectivity Gas Sensing and Charge Transfer of SnSe₂ ACS Sensors, 4(9), 2546-2552. https://doi.org/10.1021/acssensors.9b01461

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title = "High Selectivity Gas Sensing and Charge Transfer of SnSe2 ",

abstract = "SnSe2 is an anisotropic binary-layered material with rich physics, which could see it used for a variety of potential applications. Here, we investigate the gas-sensing properties of SnSe2 using first-principles calculations and verify predictions using a gas sensor made of few-layer SnSe2 grown by chemical vapor deposition. Theoretical simulations indicate that electrons transfer from SnSe2 to NO2, whereas the direction of charge transfer is the opposite for NH3. Notably, a flat molecular band appears around the Fermi energy after NO2 adsorption and the induced molecular band is close to the conduction band minimum. Moreover, compared with NH3, NO2 molecules adsorbed on SnSe2 have a lower adsorption energy and a higher charge transfer value. The dynamic-sensing responses of SnSe2 sensors confirm the theoretical predictions. The good match between the theoretical prediction and experimental demonstration suggests that the underlying sensing mechanism is related to the charge transfer and induced flat band. Our results provide a guideline for designing high-performance gas sensors based on SnSe2.",

keywords = "NH gas sensor, NO gas sensor, SnSe, charge transfer, first-principles calculations, gas sensing, selective gas sensing",

author = "Moreira, {{\'O}scar Leonardo Camargo} and Cheng, {Wei Ying} and Fuh, {Huei Ru} and Chien, {Wei Chen} and Wenjie Yan and Haifeng Fei and Hongjun Xu and Duan Zhang and Yanhui Chen and Yanfeng Zhao and Yanhui Lv and Gang Wu and Chengzhai Lv and Arora, {Sunil K.} and {{\'O} Coile{\'a}in}, Cormac and Chenglin Heng and Chang, {Ching Ray} and Wu, {Han Chun}",

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AU - Moreira, Óscar Leonardo Camargo

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AU - Yan, Wenjie

AU - Fei, Haifeng

AU - Xu, Hongjun

AU - Zhang, Duan

AU - Chen, Yanhui

AU - Zhao, Yanfeng

AU - Lv, Yanhui

AU - Wu, Gang

AU - Lv, Chengzhai

AU - Arora, Sunil K.

AU - Ó Coileáin, Cormac

AU - Heng, Chenglin

AU - Chang, Ching Ray

AU - Wu, Han Chun

PY - 2019/9/27

Y1 - 2019/9/27

N2 - SnSe2 is an anisotropic binary-layered material with rich physics, which could see it used for a variety of potential applications. Here, we investigate the gas-sensing properties of SnSe2 using first-principles calculations and verify predictions using a gas sensor made of few-layer SnSe2 grown by chemical vapor deposition. Theoretical simulations indicate that electrons transfer from SnSe2 to NO2, whereas the direction of charge transfer is the opposite for NH3. Notably, a flat molecular band appears around the Fermi energy after NO2 adsorption and the induced molecular band is close to the conduction band minimum. Moreover, compared with NH3, NO2 molecules adsorbed on SnSe2 have a lower adsorption energy and a higher charge transfer value. The dynamic-sensing responses of SnSe2 sensors confirm the theoretical predictions. The good match between the theoretical prediction and experimental demonstration suggests that the underlying sensing mechanism is related to the charge transfer and induced flat band. Our results provide a guideline for designing high-performance gas sensors based on SnSe2.

AB - SnSe2 is an anisotropic binary-layered material with rich physics, which could see it used for a variety of potential applications. Here, we investigate the gas-sensing properties of SnSe2 using first-principles calculations and verify predictions using a gas sensor made of few-layer SnSe2 grown by chemical vapor deposition. Theoretical simulations indicate that electrons transfer from SnSe2 to NO2, whereas the direction of charge transfer is the opposite for NH3. Notably, a flat molecular band appears around the Fermi energy after NO2 adsorption and the induced molecular band is close to the conduction band minimum. Moreover, compared with NH3, NO2 molecules adsorbed on SnSe2 have a lower adsorption energy and a higher charge transfer value. The dynamic-sensing responses of SnSe2 sensors confirm the theoretical predictions. The good match between the theoretical prediction and experimental demonstration suggests that the underlying sensing mechanism is related to the charge transfer and induced flat band. Our results provide a guideline for designing high-performance gas sensors based on SnSe2.

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High Selectivity Gas Sensing and Charge Transfer of SnSe₂

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Keywords

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