教育背景
2018.10-2020.03,美国佐治亚理工大学,联培博士
2016.09-2020.12,长安大学水利与环境学院,博士
2013.09-2016.07,陕西师范大学地理科学与旅游学院,硕士
2009.09-2013.06,长安大学水利与环境学院,学士
工作经历
2023.12-至今,十大菠菜导航网环境工程系,副教授
2021.04-2023.12,十大菠菜导航网环境工程系,讲师
个人成果
1.学术论文
[1] L. Wang, F. Dong, et.al. W. Guan⁎,The precursor-guided hydrothermal synthesis of CuBi2O4/WO3 heterostructure with enhanced photoactivity under simulated solar light irradiation and mechanism insight. Journal of Hazardous Materials, 381 (2020) 120956. (IF=13.6, JCR Q1 Top,高被引)
[2] L. Wang, Y. Li, C. Hou⁎, et.al. Construction of an S-scheme TiOF2/HTiOF3 heterostructures with abundant OVs and O-H groups: Performance, kinetics and mechanism insight, Journal of Colloid and Interface Science, 640 (2023) 15-30. (IF=9.7,JCR Q1 Top)
[3] L. Wang, Y. Xue*, Z. Liu*, et.al., Electronic structure regulation of an S-scheme CuBi2O4/Sr0.5NaTaO3 heterojunction with efficient carrier spatial transfer. Separation and Purification Technology, 317 (2023) 123856. (IF=8.6,JCR Q1 Top)
[4] L. Wang, M. Zhang*, C. Hou* et.al., The Ovs surface defecting of an S-scheme g-C3N4/H2Ti3O7 nanoheterostructures with accelerated spatial charge transfer. Journal of Colloid and Interface Science, 645(2023) 639-653. (IF=9.9,JCR Q1 Top)
[5] L. Wang, J. Guo, W. Guan*, et.al., Tuning the electronic structure of NaTaO3 via Sr doping strategy for its enhanced photoactivity and optical property, Chemosphere,273 (2021) 129748. (IF=8.8,JCR Q1 Top)
[6] L. Wang, W. Guan*, J. Crittenden, et.al. Fabrication of the flower-flake-like CuBi2O4/Bi2WO6 heterostructure as efficient visible-light driven photocatalysts: Performance, kinetics and mechanism insight, Applied Surface Science, 495 (2019) 143521. (IF=7.4,JCR Q1 Top)
[7] L. Wang, J. Lee*, et.al. Fluorescence imaging technology (FI) for high-throughput screening of selenide-modified nano-TiO2 catalysts. Chemical Communications, 52 (2016) 2944-2947. (IF=6.16,JCR Q1 Top)
[8] J. Li, et.al, J. Guo*, L.Wang*(通讯), Enhanced peroxymonosulfate activation by S-scheme AgI/Cu-BiVO4 heterojunction for efficient photocatalytic organics degradation and Microcystis aeruginosa inactivation: Performance, interfacial engineering and mechanism insight, Applied Catalysis B: Environment and Energy, 351 (2024) 124007. (IF=22.1,JCR Q1 Top)
[9] Z. Liu*, B. Wei, K. Liu, L.Wang*(通讯). DBS− -doped polypyrrole/CNTs with 3D conductive architecture connected with MoS2 as symmetrical electrodes for boosted CDI capability. Separation and Purification Technology, 345 (2024) 127380.(IF=8.6,JCR Q1 Top)
[10]C. Lu, et.al., W. Shi*, L. Wang*(通讯). Construction of a floating photothermal-assisted photocatalytic system with a three-dimensional hollow porous network structure. Chemosphere. 346(2024)140634. (IF=8.8,JCR Q1 Top)
[11] M. Zhang,et.al. L. Wang*(通讯), C. Hou*, In situ fluorine migration in ZIF-67/F-TiO2 Z-type heterojunction and its photocatalytic degradation mechanism of tetracycline hydrochloride. Applied Surface Science, 637 (2023) 157881. (IF=6.7,JCR Q1 Top)
[12] D. Yu†, L. Wang†, et.al, Tuning lewis acidity of iron-based metal-organic frameworks for enhanced catalytic ozonation, Chemical Engineering Journal, 404 (2021), 127075 (IF=15.1, 共同一作, JCR Q1 Top,2021年封面邀请)
[13] C.Hou, Zhou, X., et.al, L.Wang*(通讯), M. Zhang⁎. (2024). Promote the efficient co-combustion of toluene & CO in Pt/CeO2 catalyst: Orientally adjusting the oxidized SMSI to optimize acid site and oxygen vacancy. Separation and Purification Technology, 347 (2024) 127557. (IF=8.6,JCR Q1 Top)
[14] C. Hou, et.al, L.Wang*(通讯), Construction of an all-solid-state Z-scheme Ag@Ag3PO4/TiO2-(F2) heterostructure with enhanced photocatalytic activity, photocorrosion resistance and mechanism insight. Journal of Alloys and Compounds, 925 (2022) 166765. (IF=6.4,JCR Q1 Top)
[15] C. Hou, et.al, L. Wang*(通讯), Construction of an S-scheme g-C3N4/TiOF2 Heterostructures with abundant O vacancies: Enhanced photocatalytic activity and mechanism Insight, Journal of Alloys and Compounds, 938 (2023) 168560. (IF=6.4,JCR Q1 Top)
[16] X. Shi, L.Wang, et.al, Dan Qu*. Enhancing water quality and ecosystems of reclaimed water-replenished river: A case study of Dongsha River, Beijing, China. Science of the Total Environment, 926 (2024) 172024
[17] Z. Ran†, L. Wang†, Fang, Ma, Li, Catalysts, 9 (11):876, 2019. (IF=3.9,共同一作,JCR Q2).
[18] L. Wang, J. Guo, W. Guan*, et.al, Comparison of the photocatalytic performance of TiO2/AC and TiO2/CNT nanocomposites for methyl orange photodegradation, Water Science and Technology, 78 (2018) 1082-1093 (IF=1.65,JCR Q2).
[19]C. Hou, Y. Li, ,Y. Li. Y. Xie, P. Luo, M. Zhang*, L.Wang*(通讯), Journal of Water Process Engineering, 56 (2023) 104585 (IF=8,JCR Q1 )
[20] Z. Liu, B. Wei, L. Wang*(通讯), Environmental Engineering Research. 2024 29(2): 230204. (IF=3.5,JCR Q1)
[21]C. Hou, P. Yuan, M. Niu, Y. Li, L.Wang*(通讯), M. Zhang⁎, New Journal of Chemistry 46(23). (IF=3.3,JCR Q2)
2.科研项目
Ø 2024.1-2026.12,国家自然科学基金青年项目“氧缺陷型S异质结印迹催化体系的电荷输运机制及其对抗生素的靶向降解研究”(No.52300217),主持人
Ø 2021.1-2024.12,国家自然科学基金面上项目“金属氧化物/硫化物/离子液体三元复合催化剂构建及其光催化降解聚木质素Cβ-0/Cα-Cβ键性能控制研究”(No.B081003.生物质能源化工),核心骨干。
Ø 2018.01-2019.12,陕西省自然科学基金面上项目“面向溢油污染治理的磁响应高疏水空心碳球的生物诱导合成”(S2018-JC-YB-1720),主要负责材料结构表征及计算整理,核心骨干。