Chuanyi Wang is a Chinese American, environmental chemistry scientist, academic, and an author. He is a Distinguished Professor and Academic Dean at the School of Environmental Science and Engineering at the Shaanxi University of Science & Technology.[1] He is recognized for his research in environmental photocatalysis, environmental materials, surface/interface chemistry, nanomaterials, and pollution controlling.[2]
Chuanyi Wang | |
---|---|
Born | Jiangsu, China | July 25, 1966
Nationality | Chinese American |
Occupation(s) | Environmental chemistry scientist, academic |
Awards | IAAM Scientist Award, Tianshan Award of China, Science and Technology Award, China's Overseas Chinese Community Contribution Award (Innovative Talents) |
Academic background | |
Education | Undergraduate diplomas in Chemistry (1986,1991), PhD in Physical Chemistry |
Alma mater | Institute of Photographic Chemistry (now Technical Institute of Physics and Chemistry), Chinese Academy of Sciences |
Thesis | Surface/Interfacial Microscopic Events at TiO2 and its Metal Composites (1998) |
Academic work | |
Institutions | Shaanxi University of Science & Technology |
Wang is the author and editor of two books, Recent Research Developments in Physical Chemistry: Surfaces And Interfaces of Nanostructured Systems and Encyclopedia of Surface and Colloid Science.
Wang is a Fellow of Royal Society of Chemistry, and International Association of Advanced Materials (IAAM).[3]
Education
editBorn in China on July 25, 1966, Wang graduated with Undergraduate Diplomas in Chemistry from Yancheng Teachers University in 1986 and Soochow University in 1991. He completed his PhD in 1998 from Technical Institute of Physics and Chemistry, Chinese Academy of Sciences.[3]
Career
editAfter completing his PhD in 1998, Wang held the Alexander von Humboldt Research Fellowship at the Free University Berlin and Institute for Solar Energy Research in Germany from 1999 to 2000.[4] Between 2001 and 2006, he held the appointment of Research Associate and post-doctoral Research Associate at Tufts University.[5] Following this appointment, he occupied the position of Research Assistant Professor at University of Missouri-Kansas City for two years. Starting from 2008 till 2009, he joined the University of Missouri-Kansas City as an Adjunct PhD Faculty. From 2010 to 2017, he served as a Distinguished Professor of Chinese Academy of Sciences (CAS). Currently, he holds the appointment of Honorary Professor at Wuhan University since 2014 and a Visiting Scientist at Tufts from 2019.[6] He holds an appointment as a Distinguished Professor in the department of Environmental Science and Engineering at Shaanxi University of Science & Technology.
As of 2021, Wang is serving as an Academic Dean at School of Environmental Science and Engineering in Shaanxi University of Science & Technology. He served as a Director of Laboratory of Environmental Sciences and Technology, XJIPC and Vice-Director of Key Laboratory of Functional Materials & Devices for Special Environments of CAS.[7]
Research
editWang has authored more than 270 publications.[8] Wang's research work spans on environmental remediation, eco-materials, and surface/interface chemistry, and catalysis focused on nanosized metals and semiconductors.[9]
Photocatalysis
editWang's research on photocatalysis is significant in reducing contaminants. He studied the selective photocatalytic N2 fixation induced by the nitrogen vacancies and indicated that Photocatalytic N2 fixation supported by nitrogen vacancies (NVs) leads to improved graphitic carbon nitride (g-C3N4).[10]
Wang's research work focuses on the performance of nanostructured TiO2 particles. He conducted a comparative study that aimed to characterize the performance of TiO2 particles created in three different ways. The results from the study concluded that TiO2 nanoparticles prepared from organic precursors demonstrated an increased photocatalytic activity. Based on this method, Wang developed a method to uniformly distribute doped species like metal ions in semiconductor photocatalyst matrix.[11]
Wang presented an in-depth view into the effectiveness of photocatalytic production under carbon vacancies. The findings suggested that Photocatalytic H2O2 production at Graphitic carbon nitrides (g-C3N4) carries the possibility to increase by 14 times with the carbon vacancies.[12] He also studied the role of oxygen vacancies in the photocatalytic removal of NO under visible light. The study demonstrated that oxygen vacancies carry the potential to support selective photoreduction of NO to N2 and hinder the production of more toxic nitrogen dioxide.[13]
Pollution Controlling
editWang's research characterized the importance of heavy metal adsorption by clay minerals. In a study conducted in 2019, he highlighted the primary adsorption mechanisms of the clay minerals like halloysite, bentonite, and attapulgite. This study reveals how wastewater contamination can be tackled with the utilization of clay mineral adsorbents.[14]
Wang also focused his research on the removal of microplastics from the environment. In a recent study, he reviewed the removal methods, mechanisms, advantages of the efficient methods as well as the disadvantages of many microplastics removal methods.[15]
Nanoparticles
editWang has extensively carried out research on nanoparticles and its implications for the environment. He formulated and characterized chitosan–poly(vinyl alcohol)/bentonite nanocomposites. The study of adsorption of Hg(II) ions by nanocomposites revealed that they carry high adsorption capacity for mercury ions, and can promote the adsorption selectivity of the nanocomposites.[16]
Wang reviewed the interaction between silver nanoparticles and other nanoparticles. Discarded into the aquatic environment via waste or intentional release, the silver nanoparticles can lead to adverse effects on the aquatic life. With his study, it was revealed that Titanium oxide nanoparticles help in reducing the toxicity and dissolution of silver nanoparticles.[17]
Surface/interface chemistry
editWang conducted a surface chemistry study on typical photocatalytic material TiO2 by means of second-order nonlinear laser spectroscopy, clarifying the distribution characteristics of hydroxyl groups on the surface of TiO2, and the properties of probe molecules methanol and acetic acid, as well as their adsorption modes and competitive adsorption with water molecules.[18][19]
Awards and honors
edit- 1998 - Humboldt Research Fellowship, Alexander von Humboldt Foundation
- 1998 – Excellent Prize, President Scholarship of Chinese Academy of Sciences
- 2011 – Science and Technology Award, Chinese Materials Research Society
- 2014 – Tianshan Award of China, Government of Xinjiang Uygur Autonomous Region
- 2016 – China's Overseas Chinese Community Contribution Award (Innovative Talents), China Association for Science and Technology (CAST)
- 2018- Fellow of Royal Society of Chemistry (FRSC)
- 2020 – Named in the top 2 % of the most influential scientists in the world in their scientific career, 2021 (Physical Chemistry, #169 in 2020). Stanford University[20]
- 2020 – IAAM Scientist Award, International Association of Advanced Materials
- 2022 - Fellow of International Association of Advanced Materials
- 2022 - Named in the top 2 % of the most influential scientists in the world in their scientific career, 2022 (Physical Chemistry, #87 in 2021). Stanford University[21]
Bibliography
editBooks/chapters
edit- Encyclopedia of Surface and Colloid Science, Third Edition (2002) ISBN 9781466590458
- Recent Research Developments in Physical Chemistry: Surfaces And Interfaces of Nanostructured Systems (2017) ISBN 9788178952840
Selected articles
edit- Wang, C. Y., Bahnemann, D. W., & Dohrmann, J. K. (2000). A novel preparation of iron-doped TiO2 nanoparticles with enhanced photocatalytic activity. Chemical Communications, (16), 1539–1540.
- Wang, C. Y., Böttcher, C., Bahnemann, D. W., & Dohrmann, J. K. (2003). A comparative study of nanometer sized Fe (III)-doped TiO2 photocatalysts: synthesis, characterization and activity. Journal of Materials Chemistry, 13(9), 2322–2329.
- Chen, S., Slattum, P., Wang, C., & Zang, L. (2015). Self-assembly of perylene imide molecules into 1D nanostructures: methods, morphologies, and applications. Chemical reviews, 115(21), 11967-11998.
- Dong, G., Ho, W., & Wang, C. (2015). Selective photocatalytic N2 fixation dependent on gC3N4 induced by nitrogen vacancies. Journal of Materials Chemistry A, 3(46), 23435-23441.
- Li, S., Dong, G., Hailili, R., Yang, L., Li, Y., Wang, F., ... & Wang, C. (2016). Effective photocatalytic H2O2 production under visible light irradiation at g-C3N4 modulated by carbon vacancies. Applied Catalysis B: Environmental, 190, 26–35.
References
edit- ^ "Loop | Chuanyi Wang". loop.frontiersin.org.
- ^ "Chuanyi Wang – Research Gate Profile".
- ^ a b "ORCID". orcid.org.
- ^ "Prof. WANG Chuanyi Invited as an Editor of JASMI----The Xinjing Technical Institute of Physics & Chemistry.CAS". english.xjipc.cas.cn.
- ^ "People – Shultz Research Group".
- ^ Croucher, Gwilym; Wang, Chuanyi; Yang, Jiale (July 28, 2022). The Performance of Asian Higher Education: Understanding Productivity Across Institutions and Systems. Taylor & Francis. ISBN 9781000602098 – via Google Books.
- ^ Li, Nan; Wang, Chuanyi; Zhang, Ke; Lv, Haiqin; Yuan, Mingzhe; Bahnemann, Detlef W. (2022). "Progress and prospects of photocatalytic conversion of low-concentration NOx". Chinese Journal of Catalysis. 43 (9): 2363–2387. doi:10.1016/S1872-2067(22)64139-1. S2CID 251303962.
- ^ "Chuanyi Wang". scholar.google.com.
- ^ "Current Chinese Science". Bentham Science Publishers.
- ^ Dong, Guohui; Ho, Wingkei; Wang, Chuanyi (November 18, 2015). "Selective photocatalytic N2 fixation dependent on g-C3N4 induced by nitrogen vacancies". Journal of Materials Chemistry A. 3 (46): 23435–23441. doi:10.1039/C5TA06540B – via pubs.rsc.org.
- ^ Wang, Chuan-yi; Böttcher, Christoph; Bahnemann, Detlef W.; Dohrmann, Jürgen K. (August 20, 2003). "A comparative study of nanometer sized Fe(III)-doped TiO2 photocatalysts: synthesis, characterization and activity". Journal of Materials Chemistry. 13 (9): 2322–2329. doi:10.1039/B303716A – via pubs.rsc.org.
- ^ Li, Shuna; Dong, Guohui; Hailili, Reshalaiti; Yang, Liping; Li, Yingxuan; Wang, Fu; Zeng, Yubin; Wang, Chuanyi (August 5, 2016). "Effective photocatalytic H2O2 production under visible light irradiation at g-C3N4 modulated by carbon vacancies". Applied Catalysis B: Environmental. 190: 26–35. doi:10.1016/j.apcatb.2016.03.004.
- ^ Duan, Yanyan; Zhang, Mei; Wang, Lan; Wang, Fu; Yang, Liping; Li, Xiyou; Wang, Chuanyi (May 5, 2017). "Plasmonic Ag-TiO2−x nanocomposites for the photocatalytic removal of NO under visible light with high selectivity: The role of oxygen vacancies". Applied Catalysis B: Environmental. 204: 67–77. doi:10.1016/j.apcatb.2016.11.023 – via ScienceDirect.
- ^ Gu, Shiqing; Kang, Xiaonan; Wang, Lan; Lichtfouse, Eric; Wang, Chuanyi (2019). "Clay mineral adsorbents for heavy metal removal from wastewater: a review". Environmental Chemistry Letters. 17 (2): 629–654. Bibcode:2019EnvCL..17..629G. doi:10.1007/s10311-018-0813-9.
- ^ Padervand, Mohsen; Lichtfouse, Eric; Robert, Didier; Wang, Chuanyi (May 1, 2020). "Removal of microplastics from the environment. A review" (PDF). Environmental Chemistry Letters. 18 (3): 807–828. Bibcode:2020EnvCL..18..807P. doi:10.1007/s10311-020-00983-1. S2CID 212732078 – via Springer Link.
- ^ Wang, Xiaohuan; Yang, Li; Zhang, Junping; Wang, Chuanyi; Li, Qiuye (September 1, 2014). "Preparation and characterization of chitosan–poly(vinyl alcohol)/bentonite nanocomposites for adsorption of Hg(II) ions". Chemical Engineering Journal. 251: 404–412. Bibcode:2014ChEnJ.251..404W. doi:10.1016/j.cej.2014.04.089 – via ScienceDirect.
- ^ Sharma, Virender K.; Sayes, Christie M.; Guo, Binglin; Pillai, Suresh; Parsons, Jason G.; Wang, Chuanyi; Yan, Bing; Ma, Xingmao (2019). "Interactions between silver nanoparticles and other metal nanoparticles under environmentally relevant conditions: A review". scholar.google.com. pp. 1042–1051.
- ^ Wang, Chuan-yi; Groenzin, Henning; Shultz, Mary Jane (July 13, 2005). "Comparative Study of Acetic Acid, Methanol, and Water Adsorbed on Anatase TiO 2 Probed by Sum Frequency Generation Spectroscopy". Journal of the American Chemical Society. 127 (27): 9736–9744. doi:10.1021/ja051996m. PMID 15998078.
- ^ Wang, Chuan-yi; Groenzin, Henning; Shultz, Mary Jane (July 1, 2004). "Direct Observation of Competitive Adsorption between Methanol and Water on TiO 2 : An in Situ Sum-Frequency Generation Study". Journal of the American Chemical Society. 126 (26): 8094–8095. doi:10.1021/ja048165l. PMID 15225032.
- ^ Baas, Jeroen; Boyack, Kevin; Ioannidis, John P. A. (October 19, 2021). "August 2021 data-update for "Updated science-wide author databases of standardized citation indicators"". Elsevier digital commons data. Version 3. 3. doi:10.17632/btchxktzyw.3.
- ^ Jeroen Baas (2022). "September 2022 data-update for "Updated science-wide author databases of standardized citation indicators"". Elsevier BV. doi:10.17632/btchxktzyw.4.