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Density functional theory study of NO_2 -sensing mechanisms of pure and Ti-doped WO_3 (002) surfaces 被引量:3

Density functional theory study of NO_2 -sensing mechanisms of pure and Ti-doped WO_3 (002) surfaces
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摘要 Density functional theory (DFT) calculations are employed to explore the NO2-sensing mechanisms of pure and Ti-doped WO3 (002) surfaces. When Ti is doped into the WO3 surface, two substitution models are considered: substitution of Ti for W6c and substitution of Ti for Wsc. The results reveal that substitution of Ti for 5-fold W forms a stable doping structure, and doping induces some new electronic states in the band gap, which may lead to changes in the surface properties. Four top adsorption models of NO2 on pure and Ti-doped WO3 (002) surfaces are investigated: adsorptions on 5-fold W (Ti), on 6-fold W, on bridging oxygen, and on plane oxygen. The most stable and likely NO2 adsorption structures are both N-end oriented to the surface bridge oxygen Olc site. By comparing the adsorption energy and the electronic population, it is found that Ti doping can enhance the adsorption of NO2, which theoretically proves the experimental observation that Ti doping can greatly increase the WO3 gas sensor sensitivity to NO2 gas. Density functional theory (DFT) calculations are employed to explore the NO2-sensing mechanisms of pure and Ti-doped WO3 (002) surfaces. When Ti is doped into the WO3 surface, two substitution models are considered: substitution of Ti for W6c and substitution of Ti for Wsc. The results reveal that substitution of Ti for 5-fold W forms a stable doping structure, and doping induces some new electronic states in the band gap, which may lead to changes in the surface properties. Four top adsorption models of NO2 on pure and Ti-doped WO3 (002) surfaces are investigated: adsorptions on 5-fold W (Ti), on 6-fold W, on bridging oxygen, and on plane oxygen. The most stable and likely NO2 adsorption structures are both N-end oriented to the surface bridge oxygen Olc site. By comparing the adsorption energy and the electronic population, it is found that Ti doping can enhance the adsorption of NO2, which theoretically proves the experimental observation that Ti doping can greatly increase the WO3 gas sensor sensitivity to NO2 gas.
作者 胡明 王巍丹 曾晶 秦玉香
机构地区 School of Electronics and Information Engineering
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2011年第10期177-184,共8页 中国物理B(英文版)
基金 supported by the National Natural Science Foundation of China (Grant Nos. 60771019 and 60801018) Tianjin Key Research Program of Application Foundation and Advanced Technology, China (Grant No. 11JCZDJC15300) Tianjin Natural Science Foundation, China (Grant No. 09JCYBJC01100) the New Teacher Foundation of the Ministry of Education, China(Grant No. 200800561109)
关键词 adsorption Ti doping NO2-sensing density functional theory adsorption, Ti doping, NO2-sensing, density functional theory
分类号 TP212 [自动化与计算机技术—检测技术与自动化装置]
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参考文献28

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同被引文献15

  • 1张富春,邓周虎,阎军锋,张志勇.ZnO电子结构与光学性质的第一性原理计算[J].光学学报,2006,26(8):1203-1209. 被引量:40
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  • 3曾文,刘天模.SnO2/TiO2体系气敏性能及其机理研究[D].重庆:重庆大学,2011.
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  • 6BENJAWAN K, WARANYU P, BANCHOB W, et al. Density Functional Studies of Small Gases Adsorbed on the ZnO Sodalite-like Cage and Its Adsorption Abilities [J].Computational and Theoretical Chemistry, 2013,1020 : 100.
  • 7MICHELLE J S S. Gas Sensing Applications of 1D- Nanostructured Zinc Oxide: Insights from Density Functional Theory Calculations [J]. Progress in Materials Science, 2012,57 : 437.
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Chinese Physics B
2011年 第10期

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