個人簡介
徐熙焱,特別研究員/碩士、博士生導(dǎo)師、化工教工黨支部書記、校團(tuán)委副書記(掛職);中國化工學(xué)會環(huán)境保護(hù)專委會委員、中國核學(xué)會、中國環(huán)境科學(xué)學(xué)會高級會員;Sep. Purif. Technol.、Results in Engineering等期刊青年編委/客座編輯;工業(yè)和信息化部教育與考試中心、一帶一路環(huán)境技術(shù)交流與轉(zhuǎn)移中心(深圳)等專家?guī)鞂<遥?022國際分離純化技術(shù)大會(ISPT 2022)等國內(nèi)外會議組委會執(zhí)行主任、委員。研究致力于分離和純化技術(shù)提升與智能化,主要涉及吸附-催化水處理與資源化(核工業(yè)、石油、醫(yī)藥、城市污水等)、水處理過程智能化、水質(zhì)監(jiān)測與保障技術(shù)等。已主持國家重點(diǎn)研發(fā)計(jì)劃項(xiàng)目子課題、國家自然科學(xué)基金青年項(xiàng)目、中國博士后基金項(xiàng)目,參與西班牙經(jīng)濟(jì)與工業(yè)部項(xiàng)目(歐盟與西班牙政府共同資助項(xiàng)目)等。獲得RINENG Young Investigator Award, Elsevier (2022)。迄今在國內(nèi)外學(xué)術(shù)刊物及會議上發(fā)表學(xué)術(shù)論文40余篇,授權(quán)多項(xiàng)發(fā)明專利。
個人主頁:https://www.researchgate.net/profile/Xiyan-Xu-2
研究領(lǐng)域和方向
(1)吸附-催化水處理與資源化
(2)水處理過程智能化
(3)水質(zhì)監(jiān)測與保障
教育背景
2013.10-2017.09 西班牙馬德里自治大學(xué)(UAM),工學(xué)博士
2009.09-2012.07 湖南大學(xué),工學(xué)碩士
2005.09-2009.07 河南農(nóng)業(yè)大學(xué),工學(xué)學(xué)士
工作履歷
2020.06-至今 北京理工大學(xué)化學(xué)與化工學(xué)院,預(yù)聘副教授/特別研究員、碩士/博士生導(dǎo)師、校團(tuán)委副書記(掛職,2022.09-)、化工教工黨支書(2023.04-)
2018.01-2020.06 清華大學(xué)環(huán)境學(xué)院,博士后
2012.07-2013.09 交通部遼寧海事局,科員
研究成果
研究概況:
國家重點(diǎn)實(shí)驗(yàn)室基金,基于三維連續(xù)多級孔隙結(jié)構(gòu)的高通量、超快速海水提鈾吸附劑設(shè)計(jì)、合成及大面積制備. 2022-11至2024-10
國家重點(diǎn)實(shí)驗(yàn)室基金,獨(dú)居石優(yōu)溶渣鹽酸浸出礦漿固液分離及復(fù)雜組分浸出液水溶液化學(xué)熱力學(xué)解析研究. 2022-07至2024-12
國家重點(diǎn)研發(fā)計(jì)劃項(xiàng)目課題: 典型行業(yè)高鹽有機(jī)廢水高效處理及資源化成套技術(shù)集成與示范. 2021-03至2025-02
國家自然科學(xué)基金青年項(xiàng)目: 磁性納米復(fù)合新材料深度處理城市中水難降解有機(jī)污染物及其機(jī)制. 2019-01至2020-12
國防科工局核能開發(fā)項(xiàng)目, xxxx環(huán)境下xx平臺系統(tǒng)關(guān)鍵技術(shù)研究, 2019-01 至 2022-12
國防科工局核能開發(fā)項(xiàng)目, 碘的驅(qū)除及捕集工藝和設(shè)備研制, 2018-12 至 2021-12
中國博士后科學(xué)基金面上項(xiàng)目: 氯作用下管材對泄漏停滯態(tài)脫鹽再生水水質(zhì)影響及其機(jī)理. 2018-05至2020-01
北京理工大學(xué)青年教師學(xué)術(shù)啟動項(xiàng)目. 錒系金屬離子體系作用下新型納米復(fù)合吸附劑回收鈾酰離子效率與傳質(zhì)過程機(jī)制研究. 2020-06至2023-06
西班牙經(jīng)濟(jì)與工業(yè)部項(xiàng)目(歐盟與西班牙政府共同資助項(xiàng)目): 基于新型催化劑的壓裂水深度氧化處理與非傳統(tǒng)油氣藏開發(fā). 2014-01至2016-12
國家自然科學(xué)基金青年項(xiàng)目: 催化濕式氧化降解垃圾滲濾液中難降解有機(jī)物的研究. 2011-01至2013-12
北京理工大學(xué)團(tuán)學(xué)組織重大任務(wù)實(shí)踐創(chuàng)新研究課題重點(diǎn)課題. 新時代背景下高校共青團(tuán)組織“全人化”創(chuàng)新創(chuàng)業(yè)實(shí)踐育人機(jī)制研究. 2023-1至2023-6
北京經(jīng)開區(qū)“中國制造2025”試點(diǎn)示范企業(yè)項(xiàng)目: 經(jīng)開再生水廠二期擴(kuò)建工程及智能制水廠建設(shè). 2018-08至2021-12
教學(xué)科研獎勵:
RINENG Young Investigator Award, Elsevier (2022)
第十八屆“挑戰(zhàn)杯”全國大學(xué)生課外學(xué)術(shù)科技作品競賽校級特等獎指導(dǎo)教師(2023)
第八屆中國國際“互聯(lián)網(wǎng)+”大學(xué)生創(chuàng)新創(chuàng)業(yè)大賽北京賽區(qū)二等獎指導(dǎo)教師(“催化碧水”,2022)
第八屆中國國際“互聯(lián)網(wǎng)+”大學(xué)生創(chuàng)新創(chuàng)業(yè)大賽北京賽區(qū)二等獎指導(dǎo)教師(“水秀山明”,2022)
北京理工大學(xué)化學(xué)與化工學(xué)院青年教師教學(xué)基本功比賽三等獎(2020)
榮譽(yù)稱號:
全國五四紅旗團(tuán)委集體獎(2023)
發(fā)表學(xué)術(shù)論文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.