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王雪璐

青年研究员

物理与电子科学学院      

个人资料

  • 部门: 物理与电子科学学院
  • 毕业院校:
  • 学位:
  • 学历:
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  • 联系电话:
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  • 电子邮箱: xlwang@phy.ecnu.edu.cn
  • 办公地址: 闵行校区光学大楼B513
  • 通讯地址: 东川路500号

教育经历

工作经历

个人简介

社会兼职

研究方向

1、太阳能光催化水分解制氢、太阳能电池和光还原二氧化碳制备有机燃料等新型清洁能源和环境净化领域的关键材料制备和应用研究;

 

2、磁共振原位探测:

        基于核磁共振检测技术特点,设计和建立可用于原位实时监测真实固液气反应过程的检测系统和评价方法,并主攻清洁能源和环境净化领域关键反应过程机理解析方面的基础理论研究。包括:

1)/固(气/固)表界面光化学反应的原位检测

2)钙钛矿材料光电响应的原位探测

 

3、低场磁共振方法的应用

 

开授课程

科研项目

²  国家自然科学基金面上项目CO2光还原过程中金属助催化剂的设计及对产物选择性影响的原位核磁共振研究,202001-202412在研,主持

²  华东师范大学物理与电子科学学院科研创新基金青年科研能力项目,原位核磁共振方法与清洁能源材料,201901-201912在研,主持

²  苏州市科技计划项目,核磁共振指纹谱在食用油掺伪检测中的技术应用研究,201907-202206在研,主持

²  国家自然科学基金青年科学基金项目基于核磁共振检测方法的光催化制氢模型体系中含氢化合物轨迹追踪及作用机制研究,201701-201912结题,主持

²  中国博士后科学基金特别资助项目2017T100276,光还原CO2水体系中碳氢轨迹的原位追踪及作用机理研究,201706-201807结题,主持

²  中国博士后科学基金面上项目2016M591615TiO2光分解水制氢体系中金属助催化剂逆催化过程研究,201607-201707结题,主持

²  中央高校基本科研业务费专项基金222201514303,基于原位核磁共振技术的光解水固液催化体系关键问题研究,201511-201710结题,主持



学术成果

B. B. Xu, M. Zhou, M. Ye, L. Yang, H. F. Wang*,  X. L. Wang*, Y.-F. Yao*, Cooperative motion in water-methanol clusters controls the reaction rates of heterogeneous photocatalytic reactions, Journal of the American Chemical Society, 2021, 143 (29), 10940-10947.


W.-C. Qiao, J. Liang, W. Dong, K. Ma, Wen-Cheng Qiao, Jiaqi Liang, Wei Dong, Kaiyang Ma,  X. L. Wang*, Y.-F. Yao*, Illumination-induced changed in methylammonium lead bromine perovskites. An In situ 2H MR study, The Journal of Physical Chemistry C, 2021, 125 (18), 9908-9915.


H. Y. Yuan, J. Y. Bai, B. Xu, X. Y. Li, S. Y. Xiao, P. F. Liu, X. L. Wang*, H. G. Yang*, Graphite carbon nitride doped with benzene ring for enhanced photocatalytic H2 evolution, Chemical Communications, 2021, 57, 3042-3045.


W. Dong, S. Xiong, J. Yang, W. Qiao, X. L. Wang*Y.-F. Yao, Q. Bao*, Black phosphorus doped poly(triarylamine) as hole transport layer for highly efficient perovskite solar cells, Organic Electronics, 2021, 89, 106052


R. Wang, B.-B. Xu, J. Wang*, X. L. Wang*, Y.-F. Yao*, Selective hydrogen-deuterium exchange in graphitic carbon nitrides: probing the active sites for photocatalytic water splitting by solid-state NMR, Journal of Materials Chemistry A, 2021, 9, 3985-3994.


W.-C. Qiao, J. Wu, R. Zhang, W. O.-Yang, X. Chen, G. Yang, Q. Chen, X. L. Wang*, H. F. Wang*, Y.-F. Yao*, In situ NMR investigation of the photoresponse of perovskite crystal, Matter, 2020, 3(6), 2042-2054.


W.-C. Qiao, J. Yang, W. Dong, G. Yang, Q., R. Huang, X. L. Wang*Y.-F. Yao*, Metastable alloying structures in MAPbI3-xClx crystals, NPG Asia Materials, 2020, 12, 68.


X. Niu, J. Dong, X. L. Wang*Y.-F. Yao*, Enhanced photocatalytic reduction of Cr(vi) to Cr(iii) over g-C3N4 catalysts with Ag nanoclusters in conjunction with Cr(iii) quantification based on operando low-field NMR relaxometry, Environmental Science: Nano, 2020, 7(9), 2823-2832.


G. Gao, X. Niu, B. Xu, X. L. Wang*, Y.-F. Yao*, Shape and size effects on photocatalytic hydrogen production via Pd/C3N4 photocatalysts under visible light, Catalysis Science & Technology, 2020, 10, 5438-5442.


B.-B. Xu, M. Zhou, R. Zhang, M. Ye, L.-Y. Yang, R. Huang, H. F. Wang*, X. L. Wang*, Y.-F. Yao*, Solvent water controls photocatalytic methanol reforming, The Journal of Physical Chemistry Letters, 2020, 11, 3738-3744. 


R. Zhang, M. Ye, Y. Ning, R. Huang, X. L. Wang*, Y.-F. Yao*, Operando NMR study on the effect of photon flux and wavelength on photocatalytic reforming of methanol, Journal of Catalysis, 2020, 382, 173-180.


J. Y. Bai, L. J. Wang, Y. J. Zhang, C. F. Wen, X. L. Wang*, H. G. Yang*, Carboxyl functionalized graphite carbon nitride for remarkably enhanced photocatalytic hydrogen evolution, Applied Catalysis B: Environmental, 2020, 266, 118590.


M. Ye, B.-B. Xu, R. Zhang, Y.-N. Yang, L.-Y. Yang, X. L. Wang*, Y.-F. Yao*, Probing the methanol heterogeneous photochemistry processes by operando NMR-The role of bulk water, Journal of Catalysis, 2019, 378, 36-41.


X. L. Wang, W. Liu, Y.-Y. Yu, Y. Song, W. Q. Fang, D. Wei, X.-Q. Gong*, Y.-F. Yao*, H. G. Yang*, Operando NMR spectroscopic analysis of proton transfer in heterogeneous photocatalytic reactions, Nature Communications, 2016, 7, 11918.


Y. L. Wang, J. M. Jin, Y. H. Li, X. L. Wang, B. Zhang, X. Gong, H. F. Wang, A. P. Chen, L. R. Zheng, P. Hu, H. G. Yang*, Ce0.3 Zr0.7O1.88N0.12solid solution as a stable photocatalyst for visible light driven water splittng, Applied Catalysis B: Environmental, 2018, 224, 733-739.


J. J. Zhao, Y. H. Li, P. F. Liu, Y. L. Wang, X. L. Du, X. L. Wang, H. D. Zeng, L. R. Zheng, H. G. Yang*, Local coulomb attraction for enhanced H2evolution stability of metal sulfide photocatalysts, Applied Catalysis B: Environmental, 2018, 221, 152-157.


X. L. Wang, W. Q. Fang, W. Liu, Y. Jia, D. Jing, Y. Wang, L.-Y. Yang, X.-Q. Gong, Y.-F. Yao*, H. G. Yang*, X. Yao*, Brönsted base sites engineering of graphitic carbon nitride for enhanced photocatalytic activity, Journal of Materials Chemistry A, 2017, 5, 19227-19236.


X. L. Wang, H. G. Yang*, Facile fabrication of high-yield graphitic carbon nitride with a large surface area using bifunctional urea for enhanced photocatalytic performance, Applied Catalysis B: Environmental, 2017, 205, 624-630.


L. J. Fang, X. L. Wang †, Y. H. Li, P. F. Liu, Y. L. Wang, H. D. Zeng, H. G. Yang*, Nickel nanoparticles coated with graphene layers as efficient co-catalyst for photocatalytic hydrogen evolution, Applied Catalysis B: Environmental, 2017, 200, 578-584.


X. L. Du, X. L. Wang, Y. H. Li, Y. L. Wang, J. J. Zhao, L. J. Fang, L. R. Zheng, H. Tong, H. G. Yang, Isolation of single Pt atom in silver cluster: Forming highly efficient silver-based cocatalysts for photocatalytic hydrogen evolution, Chemical Communications, 2017, 53, 9402-9405.


L. J. Fang, Y. H. Li, P. Liu, D. P. Wang, H. D. Zeng*, X. L. Wang*, H. G. Yang, Facile fabrication of large-aspect-ratio g-C3N4 nanosheets for enhanced photocatalytic hydrogen evolution, ACS Sustainable Chemistry & Engineering, 2017, 5(3): 2039-2043.


Y. L. Wang, X. L. Wang, Y. H. Li, L. J. Fang, J. J. Zhao, X. L. Du, A. P. Chen*, H. G. Yang*, Controllable synthesis of hexagonal WO3 nanoplates for efficient visible-light-driven photocatalytic oxygen production, Chemistry - An Asian Journal, 2017, 12, 387-391.


Y. L. Wang, Y. H. Li, X. L. Wang, Y. Hou, A. P. Chen, H. G. Yang*, Effects of redox mediators on α-Fe2O3 exposed by {012} and {104} facets for photocatalytic water oxidation, Applied Catalysis B: Environmental, 2017, 206, 216-220.


Y. L. Wang, Y. H. Li, X. L. Wang, A. P. Chen*, H. G. Yang*, Rhodium dopants on Zn2GeO4 surface as active sites for photocatalytic water splitting, Chempluschem, 2017, 82, 199-203.


Y. L. Wang, T. Nie, Y. H. Li, X. L. Wang, L. R. Zheng, A. P. Chen, X. Q. Gong, H. G. Yang*, Black Tungsten Nitride as Metallic Photocatalyst for Overall Water Splitting Operable at up to 765 nm, Angewandte International Edition Chemie, 2017, 56, 1-6.


J. J. Zhao, P. F. Liu, Y. L. Wang, M. Y. Zu, C. W. Wang, X. L. Wang, L. J. Fang, H. D. Zeng, H. G. Yang*, Metallic Ni3P/Ni cocatalyst to enhance photocatalytic hydrogen evolution, Chemistry-A European Journal, 2017, 23, 16734-16737.


L. J. Fang, X. L. Wang †, J. J. Zhao, Y. H. Li, Y. L. Wang, X. L. Du, Z. F. He, H. D. Zeng, H. G. Yang*, One-step fabrication of porous oxygen-doped g-C3N4 with feeble nitrogen vacancies for enhanced photocatalytic performance, Chemical Communications, 2016, 52, 14408-14411.

X. L. Wang, W. Q. Fang, Y.-F. Yao, P. Liu, Y. Wang, H. Zhang, H. Zhao*, H. G. Yang*, Switching the photocatalytic activity of g-C3N4 by homogenous surface chemical modification with nitrogen residues and vacancies, RSC Advances, 2015, 5(27), 21430-21433.


X. L. Wang, W. Q. Fang, Y. H. Li, P.Liu, H. Zhang, Y. Wang, P. Liu, Y.-F. Yao, H. Zhao, H. G. Yang*, Bottom-up enhancement of g-C3N4 photocatalytic H2 evolution utilizing disordering intermolecular interactions of precursor, International Journal of Photoenergy, 2014, 2014(2014), 1-8.


X. L. Wang, W. Q. Fang, S. Yang, P. Liu, H. Zhao*, H. G. Yang*, Structure disorder of graphitic carbon nitride induced by liquid-assisted grinding for enhanced photocatalytic conversion, RSC Advances, 2014, 4(21), 10676-10679.


W. Q. Fang, Z. Huo, P. Liu, X. L. Wang, M. Zhang, Y. Jia, H. Zhang, H. Zhao, H. G. Yang*, X. Yao*, Fluorine-doped porous single-crystal rutile TiO2 nanorods for enhancing photoelectrochemical water splitting, Chemistry-A European Journal, 2014, 20(36), 11439-11444.


X. L. Wang, W. Q. Fang, H. F. Wang, H. Zhang, H. Zhao, Y. Yao*, H. G. Yang*, Surface hydrogen bonding can enhance photocatalytic H2 evolution efficiency, Journal of Materials Chemistry A, 2013, 1(45), 14089-14096.


W. Q. Fang, X. L. Wang, H. Zhang, Y. Jia, Z. Huo, Z. Li, H. Zhao, H. G. Yang*, X. Yao*, Manipulating solar absorption and electron transport properties of rutile TiO2 photocatalysts via highly n-type F-doping, Journal of Materials Chemistry A, 2013, 2(10), 3513-3520.

F. Y. Xiao, J. Xing, L. Wu, Z. P. Chen, X. L. Wang, H. G. Yang*, Assembly of ultrathin PbBiO2Br nanosheets with enhanced visible light photocatalytic properties, RSC Advances, 2013, 3(27), 10687-10690.


杨以宁,王雪璐*,姚叶锋*.原位核磁共振技术研究反应环境对光催化甲醇重整过程的影响[J].波谱学杂志,2019doi:10. 11938/cjmr20192728


叶曼,杨以宁,张燃,王雪璐*,姚叶锋*.原位核磁共振技术研究不同共催化剂以及光照波长对甲醇光催化重整产物的影响[J].波谱学杂志,2019doi:10.11938/cjmr20192727


刘文卿,宋艳红,王雪璐*,姚叶锋*.光催化甲醇重整机理的原位核磁共振研究[J].波谱学杂志,2018doi:10.11938/cjmr20182680


杨化桂,姚叶锋,王雪璐等。“一种原位核磁共振测试反应器及检测方法”。申请号:201610318835.0.


杨化桂,王重午,房文祺,李宇航,王雪璐。“一种介孔单晶氧化铁的制备方法”。2015.11.12,中国,CN201510770624.6.


杨化桂,王雨蕾,李宇航,王雪璐。“一种氮氧锆铈固溶体及其制备方法和应用”。申请号:201710229881.8.







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