个人简介
徐熙焱,特别研究员/硕士、博士生导师、化工教工党支部书记、校团委副书记(挂职);中国化工学会环境保护专委会委员、中国核学会、中国环境科学学会高级会员;Sep. Purif. Technol.、Results in Engineering等期刊青年编委/客座编辑;工业和信息化部教育与考试中心、一带一路环境技术交流与转移中心(深圳)等专家库专家;2022国际分离纯化技术大会(ISPT 2022)等国内外会议组委会执行主任、委员。研究致力于分离和纯化技术提升与智能化,主要涉及吸附-催化水处理与资源化(核工业、石油、医药、城市污水等)、水处理过程智能化、水质监测与保障技术等。已主持国家重点研发计划项目子课题、国家自然科学基金青年项目、中国博士后基金项目,参与西班牙经济与工业部项目(欧盟与西班牙政府共同资助项目)等。获得RINENG Young Investigator Award, Elsevier (2022)。迄今在国内外学术刊物及会议上发表学术论文40余篇,授权多项发明专利。
个人主页:https://www.researchgate.net/profile/Xiyan-Xu-2
研究领域和方向
(1)吸附-催化水处理与资源化 (2)水处理过程智能化 (3)水质监测与保障
教育背景
2013.10-2017.09 西班牙马德里自治大学(UAM),工学博士 2009.09-2012.07 湖南大学,工学硕士 2005.09-2009.07 河南农业大学,工学学士
工作履历
2020.06-至今 新葡萄8883官网AMG,预聘副教授/特别研究员、硕士/博士生导师、校团委副书记(挂职,2022.09-)、化工教工党支书(2023.04-) 2018.01-2020.06 清华大学环境学院,博士后 2012.07-2013.09 交通部辽宁海事局,科员
研究成果
研究概况: 国家重点实验室基金,基于三维连续多级孔隙结构的高通量、超快速海水提铀吸附剂设计、合成及大面积制备. 2022-11至2024-10 国家重点实验室基金,独居石优溶渣盐酸浸出矿浆固液分离及复杂组分浸出液水溶液化学热力学解析研究. 2022-07至2024-12 国家重点研发计划项目课题: 典型行业高盐有机废水高效处理及资源化成套技术集成与示范. 2021-03至2025-02 国家自然科学基金青年项目: 磁性纳米复合新材料深度处理城市中水难降解有机污染物及其机制. 2019-01至2020-12 国防科工局核能开发项目, xxxx环境下xx平台系统关键技术研究, 2019-01 至 2022-12 国防科工局核能开发项目, 碘的驱除及捕集工艺和设备研制, 2018-12 至 2021-12 中国博士后科学基金面上项目: 氯作用下管材对泄漏停滞态脱盐再生水水质影响及其机理. 2018-05至2020-01 新葡萄8883官网AMG青年教师学术启动项目. 锕系金属离子体系作用下新型纳米复合吸附剂回收铀酰离子效率与传质过程机制研究. 2020-06至2023-06 西班牙经济与工业部项目(欧盟与西班牙政府共同资助项目): 基于新型催化剂的压裂水深度氧化处理与非传统油气藏开发. 2014-01至2016-12 国家自然科学基金青年项目: 催化湿式氧化降解垃圾渗滤液中难降解有机物的研究. 2011-01至2013-12 新葡萄8883官网AMG团学组织重大任务实践创新研究课题重点课题. 新时代背景下高校共青团组织“全人化”创新创业实践育人机制研究. 2023-1至2023-6 北京经开区“中国制造2025”试点示范企业项目: 经开再生水厂二期扩建工程及智能制水厂建设. 2018-08至2021-12 教学科研奖励: RINENG Young Investigator Award, Elsevier (2022) 第十八届“挑战杯”全国大学生课外学术科技作品竞赛校级特等奖指导教师(2023) 第八届中国国际“互联网+”大学生创新创业大赛北京赛区二等奖指导教师(“催化碧水”,2022) 第八届中国国际“互联网+”大学生创新创业大赛北京赛区二等奖指导教师(“水秀山明”,2022) 新葡萄8883官网AMG青年教师教学基本功比赛三等奖(2020) 荣誉称号: 全国五四红旗团委集体奖(2023) 发表学术论文40余篇,主要如下: 2023 [1]D. Li, Y. Liao, Z. Chen, X. Chang, X. Zhang, C. Chen, C. Cui, Z. Zhang, C. Muhire, W. Tang, D. Zhang*, J. Li, Xu Xiyan*, A 3D hierarchical porous adsorbent constructed by cryo-polymerization for ultrafast uranium harvesting from seawater, Journal of Materials Chemistry A, 11 (2023) 10384-10395. [2]W. Tang, D. Li, X. Zhang, F. Guo, C. Cui, M. Pan, D. Zhang*, J. Li, Xu Xiyan*, A modified freezing-casted conductive hierarchical porous polymer composite electrode for electrochemical extraction of uranium from water, Separation and Purification Technology, 319 (2023) 124087. [3]X. Zhang, Z. Guo, P. Sun, X. Liu, Z. Luo, J. Li, D. Zhang*, Xu Xiyan*, Removal of unsymmetrical dimethylhydrazine: A critical review with particular focus on photocatalytic oxidation, Separation and Purification Technology, 312 (2023) 123425. [4]P. Sun, X. Zhang, Z. Guo, X. Liu, Y. Lan, D. Zhang, H. Li, J. Li, H. Liu*, Xu Xiyan*, An adsorptive photo-Fenton-like removal of 1,2-benzisothiazolin-3-one by NH2-MIL-53(Fe) under simulated solar light, New Journal of Chemistry, 47 (2023) 8334-8346. [5]F. Zhao, C. Cui, S. Dong, Xu Xiyan*, H. Liu*, An overview on the corrosion mechanisms and inhibition techniques for amine-based post-combustion carbon capture process, Separation and Purification Technology, 304 (2023) 122091. 2022 [1]C. Muhire, A. Tesfay Reda, D. Zhang*, Xu Xiyan*, C. Cui, An Overview on Metal Oxide-based Materials for Iodine Capture and Storage, Chemical Engineering Journal, 2022, 431: 133816. [2]Xu Xiyan*, S. Liu, P. Sun, Z. Guo, K. Smith, D. Zhang*, H. Li, J. Bedia, C. Belver, Iron tungstate on nano-γ-alumina as photocatalyst for 1,4-dioxane solar degradation in water, Journal of Cleaner Production, 2022, 134232. [3]R. Tang#, C. Cui#, D. Zhang, D*. Li, J. Li, Xu Xiyan*, Experimental and CFD Simulation Study of the Air-Blowing Process of Iodine in Nitric Acid Solution, Industrial & Engineering Chemistry Research, 2022 61: 13694-1370. [4]C. Cui, D. Zhang*, M. Constantin, A.T. Reda, J. Li, Xu Xiyan*, Molecular reaction and dynamic mechanism of iodate reduction to molecular iodine by nitrogen(III) in aqueous solution, Physical Chemistry Chemical Physics, 2022, , 24: 22889. [5]S. Wang, M.-r. Chen, S.-b. Shen, C.-h. Cheng, A.-j. Cai, A.-j. Song, X.-l. Lu, G.-s. Gao, M.-z. Ma, Z.-w. Zhang*, Xu Xiyan*, Bifunctionalized Fe7S8@MoS2–O core-shell with efficient photocatalytic activity based on internal electric field, Journal of Cleaner Production, 2022, 335: 130375. [6]A. Tesfay Reda, D. Zhang*, Xu Xiyan*, S. Xu, Highly stable iodine capture by pillared montmorillonite functionalized Bi2O3@g-C3N4 nanosheets, Separation and Purification Technology, 2022, 292: 120994. [7]A. Tesfay Reda, D. Zhang*, Xu Xiyan*, LiAlO2-Melamine for efficient and rapid iodine capture, Journal of Environmental Chemical Engineering, 2022, 10: 107842. [8]M. Pan, C. Cui, W. Tang, Z. Guo, D. Zhang*, Xu Xiyan*, J. Li, Carbon cloth as an important electrode support for the high selective electrosorption of uranium from acidic uranium mine wastewater, Separation and Purification Technology, 2022, 281 119843. 2021 [1]M. Zahid, D. Zhang*, Xu Xiyan*, M. Pan, M.H. ul haq, A.T. Reda, W. Xu, Barbituric and thiobarbituric acid-based UiO-66-NH2 adsorbents for iodine gas capture: characterization, efficiency and mechanisms, Journal of Hazardous Materials, 2021, 125835. [2]A. Tesfay Reda, D. Zhang*, Xu Xiyan*, M. Pan, C. Chang, C. Muhire, X. Liu, S. Jiayi, Bismuth-impregnated aluminum/copper oxide-pillared montmorillonite for efficient vapor iodine sorption, Separation and Purification Technology, 2021, 270: 118848 [3]M. Pan, D. Zhang*, Xu Xiyan*, A.T. Reda, J. Li, Efficient electrosorption of uranyl ions by a homemade amidoxime-modified carbon paper-based electrode in acidic aqueous condition, Journal of Chemical Technology & Biotechnology, 2021, 96: 2916-2929. [4]A. Tesfay Reda, M. Pan, D. Zhang*, Xu Xiyan*, Bismuth-based materials for iodine capture and storage: A review, Journal of Environmental Chemical Engineering, 2021, 9: 105279. [5]Xu Xiyan, Y. Cui*, Z. Wang, H. Zhang, C. Li, K. Yu, Water quality deterioration of reclaimed water produced by reverse osmosis process in large pilot-scale distribution systems of different pipe materials, Journal of Water Reuse and Desalination, 2021, 11: 610-620. 2020 [1]Xie, G., Wang, H., Zhou, Y., Du, Y., Liang, C., Long, L., Lai, K., Li, W., Tan, X., Jin, Q., Qiu, G., Zhou, D., Huo, H., Hu, X.*, Xu Xiyan*. Simultaneous remediation of methylene blue and Cr(VI) by mesoporous BiVO4 photocatalyst under visible-light illumination. Journal of the Taiwan Institute of Chemical Engineers. 2020, 112, 357-365. [2]Xu Xiyan, Liu, S.*, Smith, K., Cui, Y., Wang, Z. An overview on corrosion of iron and steel components in reclaimed water supply systems and the mechanisms involved. Journal of Cleaner Production, 2020, 276, 124079. [3]Xu Xiyan; Liu S.*; Liu Y.; Smith K., Cui Y.*, Water quality induced corrosion of stainless steel valves during long-term service in a reverse osmosis system. Journal of Environmental Sciences, 2020, 89, 218-226. [4]Xiong Y.; Zhang J.; Xu Xiyan*; Yan Y.; Sun S.; Liu S. *, Strategies for improving the microclimate and thermal comfort modification effect of a classical Chinese garden in hot-summer and cold-winter zone. Energy and Buildings. 2020, 215, 109914. 2019 [1]Xu Xiyan*, Pliego G., Alonso C., Liu S., Nozal L., Rodriguez J.J., Reaction pathways of heat-activated persulfate oxidation of naphthenic acids in water. Chemical Engineering Journal. 2019, 370, 695-705. [2]Xu Xiyan, Liu Shuming*, Smith Kate, Wang Yujue, Hu Hongying, Light driven breakdown of 1,4-Dioxane for potable reuse: a review. Chemical Engineering Journal, 2019, 373, 508-518. [3]Xu Xiyan, Liu Y., Liu S.*, Li J., Guo G., Smith K. Real-time detection of potable-reclaimed water pipe cross-connection events by conventional water quality sensors using machine learning methods, Journal of Environmental Management. 2019, 238, 201-209. [4]Xu Xiyan, Liu S.*, Sun S., Zhang W., Liu Y., Lao Z., Guo G., Smith K., Cui Y., Liu W., Higueras García E., Zhu J., Evaluation of energy saving potential of an urban green space and its water bodies. Energy and Buildings. 2019, 188-189, 58-70. [5]Xu Xiyan; S. Liu*; Y. Liu; K. Smith; Y. Cui*. Corrosion on stainless steel valves in a reverse osmosis system of a reclaimed water plant: Correlation between formation of corrosion products and metal loss. Engineering Failure Analysis, 2019, 105, 40-51. [6]Xu Xiyan, Liu S.*, Cui Y., Wang X., Smith K., Wang Y. Solar-Driven removal of 1,4-Dioxane using WO3/nγ-Al2O3 Nano-catalyst in water, Catalysts. 2019, 9, 389. [7]Wang Z., Xu Xiyan (co-first author), Cui Y.*, The effect of fixed and removable gas-injection patterns on the expansion of reaction zones during underground coal gasification, Energy & Fuels. 2019, 33, 4740-4747. 2018 and before [1]Xu Xiyan*, Pliego G., Garcia-Costa A. L., Zazo J.A., Liu S., Casas J.A., Rodriguez J.J. Cyclohexanoic acid breakdown by two-step persulfate and heterogeneous Fenton-like oxidation. Applied Catalysis B: Environmental. 2018, 232, 429-435. [2]Xu Xiyan*, Pliego G, Zazo J.A., Liu S., Casas J.A., Rodriguez J.J. Two-step persulfate and Fenton oxidation of naphthenic acids in water. Journal of Chemical Technology & Biotechnology. 2018, 93, 2262-2270. [3]Xu Xiyan, Pliego G.*, Zazo J.A., Sun S., Garcia-munoz P., He L., Casas J.A., Rodriguez J.J., An overview on the application of advanced oxidation processes for the removal of naphthenic acids from water, Critical Reviews in Environmental Science & Technology, 2017, 47(15), 1337-1370. [4]Xu Xiyan, Sun S., Liu W., García E.H., He L.*, Cai Q., Xu S., Wang J., Zhu J.* The cooling and energy saving effect of landscape design parameters of urban park in summer: a case of Beijing, China. Energy and Buildings. 2017, 149, 91–100. [5]Sun S., Xu Xiyan* (co-first author), Lao Z., Liu W., Li Z., García E.H., He L., Zhu J.*, Evaluating the impact of urban green space and landscape design parameters on thermal comfort in hot summer by numerical simulation, Building and Environment. 2017, 123, 277-288. [6]Xu Xiyan, Pliego, G., Zazo, J.A., Casas, J.A., Rodriguez, J.J.* Mineralization of naphthenic acids with thermally-activated persulfate: The important role of oxygen. Journal of Hazardous Materials. 2016, 318, 355-362. [7]Xu Xiyan, Zeng G.-M.*, Peng Y.-R.*, Zeng Z. Potassium persulfate promoted catalytic wet oxidation of fulvic acid as a model organic compound in landfill leachate with activated carbon. Chemical Engineering Journal. 2012, 200, 25-31.