Your search keyword '"Ye, Liqun"' showing total 7 results

1. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019

2. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019

3. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019

4. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019

5. Correction: Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2 (vol. 6, no 19, article-id 1901032, 2019)

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu W., Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu W.

Published

2019

6. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019

7. Enhancing Photocatalytic Activity of NO Removal through an In Situ Control of Oxygen Vacancies in Growth of TiO2

Author

Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, Sun, Jianwu, Shen, Xiaoling, Dong, Guohui, Wang, Lan, Ye, Liqun, and Sun, Jianwu

Abstract

Although defects play an important role in the photocatalytic activity of TiO2, the mechanism of the photocatalytic activity related to different defects remains disputable. Moreover, the reported methods to introduce defects raise the preparation cost. In this work, different types of defects including O-vacancy cluster, surface O-vacancy, and bulk O-vacancy defects are in situ introduced in TiO2 by controlling the crystallization temperature. The medium-degree crystallinity TiO2 sample mainly containing surface O-vacancies exhibits the best NO removal activity. The systematic study of photocatalytic mechanism demonstrates that the surface O-vacancies significantly promote the adsorption of H2O molecules and improve charge transfer to the adsorbed H2O forming center dot OH, thus dramatically enhancing the photocatalytic NO removal activity. On the contrary, bulk O-vacancies neither help the adsorption of H2O molecules, nor improve the charge transfer to H2O., Funding Agencies|National Nature Science Foundation of China [21876104, 21603271, U1703129]; Swedish Research Council (Vetenskapsradet) [621-2014-5461, 2018-04670]; Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning (FORMAS) [2016-00559]; Swedish Foundation for International Cooperation in Research and Higher Education (STINT) [CH2016-6722]

Published

2019