环境科学与工程学院-刘雨导师介绍
刘雨
教授
博士生导师
男
环境科学与工程学院
环境工程
水污染控制与资源化
cyliu@nankai.edu.cn
https://env.nankai.edu.cn/2023/1222/c14180a532674/page.htm
刘雨,2023年国家高层次人才计划引进加入南开大学,现任南开大学讲席教授。于法国国立应用科学学院获博士学位;香港科技大学博士后、新加坡南洋理工大学李光耀博士后研究员。加入南开大学前,历任新加坡南洋理工大学土木与环境工程学院环境工程系教授(2001-2023)、新加坡南洋理工大学土木与环境工程学院科研副院长(2011-2014)、新加坡南洋理工大学先进环境生物技术中心主任(2014-2018)、新加坡南洋理工大学环境工程项目主任(2019-2022)、新加坡南洋理工大学“污水再生回用及生物固体废物资源化”项目主任(2021-2023)等。主持了多项新加坡政府机构和企业资助的基础研究和示范工程项目,多项技术转移授权给工业界。由Elsevier,Wiley,CRC Press,IWA Publishing等出版社出版英文论著8部。2019年在斯坦福大学和Elsevier依据Scopus数据库对全球近700万名学者的论文综合评价公开发布的“引用最多的前10万名科学家”的榜单中位列全球“环境工程”学科第25位。2023年全球前2%科学家中,位列终身榜单第6381位,年度榜单第3607位,子领域 “环境工程”第19位,“生物技术”第13位。获新加坡国家科技奖(新加坡最高科研奖),新加坡国家发展部研发奖,并于2014年由新加坡总统授予新加坡公共行政铜质勋章等奖励。
团队以“低碳非常规水源资源化与水质保障技术平台”为基础,围绕环境生物工程、环境微生物,环境化学和环境功能材料技术,以水污染治理和再生回用为研究对象,致力研发低碳非常规水源资源化与水质保障技术。团队致力培养科研与工程技术人才,热忱欢迎具有环境、生物、材料、化工、计算机等研究背景的学生及博士后加入!
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2023-至今 |
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2013-2023 |
新加坡南洋理工大学,土木与环境工程学院,教授,博导 |
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2005-2013 |
新加坡南洋理工大学,土木与环境工程学院,副教授,博导 |
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2001-2005 |
新加坡南洋理工大学,土木与环境工程学院,助理教授,博导 |
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1998-2001 |
新加坡南洋理工大学,土木与环境工程学院,李光耀博士后研究员 |
科研兴趣
基于废水及有机质固体废物处理的生物技术,包括好氧颗粒污泥,菌藻颗粒,主流厌氧氨氧化,新型能量自给自足生物处理组合工艺(新A-B工艺),餐厨垃圾资源化及能源化,好氧及厌氧膜生物反应器,膜生物反应器在线化学清洗过程中产生的卤代有机物,厌氧消化,剩余污泥减量化,生物法去除水体中氮磷等研究。在此基础上发展的相关技术大多已完成中试示范。
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科研项目
在研主持与参与科研项目:
1. 2025.01-2030.12 国家自然科学基金-区域联合重点项目(海南)U24A20188
2. 2024.01-2027.12 中国教育部国家高层次人才
3. 2023- 南开大学低碳非常规水源与水质保障平台
近5年新加坡主持项目
Ø PUB-CRP 新加坡国家水务局: 污水处理与资源化实现高效能源回收与污泥减量化示范 Demonstration of integrated usedwater reclamation processes towards enhanced energy recovery and minimizedsludge production. S$ 3,122,600.00, 2019.1-2022.7,项目负责人
Ø Urban Solutions and Sustainability(USS) Integration Fund (IF) 新加坡国家能源局: 餐厨垃圾零固体排放中试项目 Pilot demonstration of ultrafast conversion of food waste to biofertilizer with zerosolid discharge. S$ 969,640.00, 2018.12 -2021.12,项目负责人
Ø 中国-新加坡国际联合研究院, 将餐厨废弃物转化为生物甲烷技术示范. RMB 1 Million, 2017.7 -2021.3,项目负责人
Ø Singapore Ministry of Education 新加坡教育部: A novel environmentally friendlyintegrated pre-concentration and solidification technology for radioactivewastewater treatment. S$ 99500.00, 2019.11-2021.4,项目负责人
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研究成果
SCI论文
谷歌学术:https://scholar.google.com/citations?user=-xaymxAAAAAJ&hl=zh-CN
SCI引用率38000余次,h指数101(截至2025.2)
近5年发表论文:
[1] Tong C., Hu G.S., Ji B., Li A.J., Zhang X.Y., Liu Y. (2025). Light intensity-regulated glycogen synthesis and pollutant removal in microalgal-bacterial granular sludge for wastewater treatment. Water Research, 271:122988.
[2] Chen X.Y., Zhang X.Y*., Lu J.F., Jiang Y.S., Liu Y*. (2025). Photoelectric materials-assisted anammox systems: Performance, microbial community dynamics, metabolic responses and N-removal pathways. Chemical Engineering Journal, 505:159613.
[3] An L., Zhang X.Y*., Lu J.F., Wan J.F., Liu Y*. (2025). Valorization of food waste to biofertilizer and carbon source for denitrification with assistance of plant ash and biochar toward zero solid discharge. Bioresource Technology, 420:132119.
[4] Zhang X.Y., Jiang Y.S., Zhang C.J., Zhang M., Liu Y*. (2024). Capture of wastewater ammonium by microalgal-bacterial granular sludge: A green-to-green engineering solution for carbon neutrality. Chemical Engineering Journal, 482:148939.
[5] Zhao Y.L., Liao Y., Li C., Yin Y.R., Wang R., Liu Y*. (2024). Constructing nanofiltration membrane on hydrophobic PVDF and PTFE substrates via reverse interfacial polymerization. Separation and Purification Technology, 334:125944.
[6] Zhao Y., Liao Y., Li C., Yin Y., Wang R., Liu Y*. (2024). Constructing nanofiltration membrane on hydrophobic PVDF and PTFE substrates via reverse interfacial polymerization. Separation and Purification Technology, 334, 125944.
[7] Zhang X.Y., Jiang Y.S., Zhang C.J., Zhang M., Liu Y*. (2024). Capture of wastewater ammonium by microalgal-bacterial granular sludge: A green-to-green engineering solution for carbon neutrality. Chemical Engineering Journal, 482, 148939.
[8] Yu Y., Wang J.H., Liu Y., Yu P.F., Wang D.S., Zheng P., Zhang M. (2024). Revisit the environmental impact of artificial intelligence: the overlooked carbon emission source? Frontiers of Environmental Science & Engineering, 18(12):1-5.
[9] Wu J.L., Liu Z.H., Ma Q.G., Wan Y.P., Dang Z., Liu Y., Liu Y. (2024). Combined collection systems of sewage and rainfall runoff seriously affect the spatial distributions of natural estrogens and their conjugates in river water: Insights from the Pearl River of China. Water Research, 256:121588.
[10] Sun P.H., Ji B., Li A.J., Zhang X.Y., Liu Y. (2024). Efficient nitrogen removal by microalgal-bacterial granular sludge-marimo coupling process. Bioresource Technology, 402:130816.
[11] Shi Y.T., Ji B., Li A.J., Zhang X.Y., Liu Y. (2024). Enhancing the performance of microalgal-bacterial systems with sodium bicarbonate: A step forward to carbon neutrality of municipal wastewater treatment. Water Research, 266:122345.
[12] Shi Y.T., Xu C.X., Ji B., Li A.J., Zhang X.Y., Liu Y. (2024). Microalgal-bacterial granular sludge can remove complex organics from municipal wastewater with algae-bacteria interactions. Communications Earth & Environment, 5(1):347.
[13] Niu B.H., Zhang M., Meng S.J., Mao Z.Y., Liang D.W., Fan W.H., Yang L.Y., Dong Z.K., Liao Y., Wang J.Y., Liu Y. (2024). Integration of membrane bioreactor with a weak electric field: Mitigating membrane fouling and improving effluent quality targeting low energy consumption[J]. Chemical Engineering Journal, 495:153336.
[14] Jiang Y.S., Zhang X., An L., Liu Y*. (2024). A novel biochar-augmented enzymatic process for conversion of food waste to biofertilizers: Planting trial with leafy vegetable. Bioresource Technology, 399, 130554.
[15] Zhao Q., Ying H., Liu Y*., Wang H.B., Xu J.T., Wang W., Ren J., Meng S.J., Wang N., Mu R.M., Wang S.S., Li J.J. (2023). Towards low energy-carbon footprint: Current versus potential P recovery paths in domestic wastewater treatment plants. Journal of Environmental Management, 344:118653.
[16] Zhang X.Y., Jiang Y.S., Liu Y. (2023). Circular Economy-Driven Food Waste Valorization for Zero Solid Discharge: From Laboratory to Field Trial. Urban Solutions & Sustainability (USS) R&D Congress, Singapore.
[17] Zhang X.Y., Ji B., Tian J.L., Liu Y*. (2023). Development, performance and microbial community analysis of a continuous-flow microalgal-bacterial biofilm photoreactor for municipal wastewater treatment. Journal of Environmental Management, 338, 117770.
[18] Zhang X.Y*., Tian J.L., Jiang Y.S., Geng Y.K., Liu Y*. (2023). Direct ammonium recovery from the permeate of a pilot-scale anaerobic MBR by biochar to advance low-carbon municipal wastewater reclamation and urban agriculture. Science of The Total Environment, 877:162872.
[19] Zhang X.Y., An L., Tian J.L., Ji B., Lu J.F., Liu Y*. (2023). Microalgal capture of carbon dioxide: A carbon sink or source? Bioresource Technology, 390, 129824.
[20] Wei G.R., Wei T., Li Z.M., Wei C., Kong Q.P., Guan X.H., Qiu G.L., Hu Y., Wei C.H., Zhu S., Liu Y., Preis S. (2023). BOD/COD ratio as a probing index in the O/H/O process for coking wastewater treatment. Chemical Engineering Journal, 466:143257.
[21] Shi Y.T., Ji B., Zhang X.Y., Liu Y*. (2023). Auto-floating oxygenic microalgal-bacterial granular sludge. Science of the Total Environment, 856, 159175.
[22] Liu Y., Xiong Y.H., Zhou Y., Ng W.J. (2023) A Method For Rapid Start-Up Of Microbial Granulation In Wastewater Biotreatment Process. Malaysia Patent.
[23]刘雨,马英群. (2023). 一种利用自制复合水解酶处理厨余垃圾的方法, 202110170591.7
[24] Liu Y. (2023). BNR: A Potential Hurdle for Carbon-Neutral Municipal Wastewater Reclamation. IWA Resource Recovery Conference, Shenzhen, China.
[25] Li S.X., Geng Y.K., Teng B., Xu S.Q., Petkov P.S., Liao Z.Q., Jost B., Liu Y., Feng X.L., Wu B.Z., Zhang T. (2023). Nature-Inspired Pyrylium Cation-Based Vinylene-Linked Two-Dimensional Covalent Organic Framework for Efficient Sunlight-Driven Water Purification. Chemistry of Materials, 35(4):1594-1600.
[26] Kong D.M., Tang Z., Liu Z.H., Dang Z., Guo P.R., Song Y.M., Liu Y. (2023). Simultaneous determination of twelve natural estrogens in dairy milk using liquid–liquid extraction and solid-phase extraction coupled with gas chromatography-mass spectrometry. Environmental Science and Pollution Research, 30(52):112908-112921.
[27] Geng Y.K., Gu J., Zhang X.Y., Lim Z.K., Jiang Y.S., Zhang M., Zhou Y., Liu Y*. (2023). Multi-parameter control-based operation strategy for mainstream deammonification in an integrated anaerobic biofilm reactor-step feed MBR. Chemosphere, 333, 138941.
[28] Zhang X.Y., Liu Y*. (2022). Circular economy is game-changing municipal wastewater treatment technology towards energy and carbon neutrality. Chemical Engineering Journal, 429, 132114.
[29] Zhang X.Y., Liu Y*. (2022). Resource recovery from municipal wastewater: A critical paradigm shift in the post era of activated sludge. Bioresource Technology, 363, 127932.
[30] Zhang X.Y., Lei Z.F., Liu Y*. (2022). Microalgal-bacterial granular sludge for municipal wastewater treatment: From concept to practice. Bioresource Technology, 354, 127201.
[31] Zhang X.Y., Gu J., Meng S.J., Liu Y*. (2022). Dissolved methane in anaerobic effluent: Emission or recovery? Frontiers of Environmental Science & Engineering, 16(4), 54.
[32] Zhang X.Y., Gu J., Liu Y*. (2022). Necessity of direct energy and ammonium recovery for carbon neutral municipal wastewater reclamation in an innovative anaerobic MBR-biochar adsorption-reverse osmosis process. Water Research, 211, 118058.
[33] Zhang M., Ji B., Wang S.L., Gu J., Liu Y*. (2022). Granule size informs the characteristics and performance of microalgal-bacterial granular sludge for wastewater treatment. Bioresource Technology, 346, 126649.
[34] Zhang M., Gu J., Wang S.Y., Liu Y*. (2022). A mainstream anammox fixed-film membrane bioreactor with novel sandwich-structured carriers for fast start-up, effective sludge retention and membrane fouling mitigation. Bioresource Technology, 347, 126370.
[35] Zhang J., Zhong S.S., Zhao K.M., Liu Z.H., Dang Z., Liu Y*. (2022). Sulfite may disrupt estrogen homeostasis in human via inhibition of steroid arylsulfatase. Environmental Science and Pollution Research, 29(13), 19913-19917.
[36] Zhang J., Wan Y.P., Liu Z.H., Wang H., Dang Z., Liu Y*. (2022). Stability properties of natural estrogen conjugates in different aqueous samples at room temperature and tips for sample storage. Environmental Science and Pollution Research, 29(17), 24589-24598.
[37] Wang S.Y., Liu H., Gu J., Zhang M., Liu Y*. (2022). Towards carbon neutrality and water sustainability: An integrated anaerobic fixed-film MBR-reverse osmosis-chlorination process for municipal wastewater reclamation. Chemosphere, 287, 132060.
[38] Wang Q., Shen Q.Y., Wang J.X., Zhao J.M., Zhang Z.Y., Lei Z.F., Yuan T., Shimizu K., Liu Y., Lee D.J. (2022). Insight into the rapid biogranulation for suspended single-cell microalgae harvesting in wastewater treatment systems: Focus on the role of extracellular polymeric substances. Chemical Engineering Journal, 430.
[39] Wang Q., Li H., Shen Q.Y., Wang J.X., Chen X.Y., Zhang Z.Y., Lei Z.F., Yuan T., Shimizu K., Liu Y., Lee D.J. (2022). Biogranulation process facilitates cost-efficient resources recovery from microalgae-based wastewater treatment systems and the creation of a circular bioeconomy. Science of the Total Environment 828.
[40] Tang Z., Wan Y.P., Liu Z.H., Wang H., Dang Z., Liu Y*. (2022). Twelve natural estrogens in urines of swine and cattle: Concentration profiles and importance of eight less-studied. Science of the Total Environment, 803, 150042.
[41] Tang Z., Liu Z.H., Chen W., Wang C., Wu Y.J., Wang H., Dang Z., Liu Y*. (2022). Twelve natural estrogens in urines of six threatened or endangered mammalian species in Zoo Park: implications and their potential risk. Environmental Science and Pollution Research, 29(32), 49404-49410.
[42] Li X., Wang G.L., Chen J.B., Zhou X., Liu Y. (2022). Deciphering the concurrence of comammox, partial denitrification and anammox in a single low-oxygen mainstream nitrogen removal reactor. Chemosphere, 305:135409.
[43] Jiang M.Y., Wang P., Liu H.L., Dai X.H., Song S.Q., Liu Y. (2022). The Effect of Operating Strategies on the Anaerobic Digestion of Gentamicin Mycelial Residues: Insights into the Enhancement of Methane Production and Attenuation of Gentamicin Resistance. Environmental Science & Technology, 56(21):15130-15140.
[44] Ji B., Fan S.Q., Liu Y*. (2022). A continuous-flow non-aerated microalgal-bacterial granular sludge process for aquaculture wastewater treatment under natural day-night conditions. Bioresource Technology, 350.
[45] Gu J., Zhang M., Chaudhari B., Kicsi G., Barber J., Hong Y., Gu Y., Liu Y. (2022). Improving water reclamation efficiency with a novel A-B process. Innovation in Water Singapore.
[46] Gu J., Liu Y. (2022). Integrated deammonification process for wastewater reclamation. United States Patent.
[47] Gao Z., Ma Y.Q., Liu Y*., Wang Q.H. (2022). Waste cooking oil used as carbon source for microbial lipid production: Promoter or inhibitor. Environmental Research, 203.
[48] Cui B.H., Chen Z.H., Guo D.B., Liu Y*. (2022). Investigations on the pyrolysis of microalgal-bacterial granular sludge: Products, kinetics, and potential mechanisms. Bioresource Technology, 349:126328.
[49] Cui B.H., Chen Z.H., Wang F.H., Zhang Z.H., Dai Y.R., Guo D.B., Liang W., Liu Y. (2022). Facile Synthesis of Magnetic Biochar Derived from Burley Tobacco Stems towards Enhanced Cr(VI) Removal: Performance and Mechanism. Nanomaterials, 12(4).
[50] Chen Y.J., Ma R., Pu X.C., Fu X.Y., Ju X.Y., Arif M., Yan X.Q., Qian J., Liu Y. (2022). The characterization of a novel magnetic biochar derived from sulfate-reducing sludge and its application for aqueous Cr(Ⅵ) removal through synergistic effects of adsorption and chemical reduction. Chemosphere, 308:136258.
[51] Zhong S.S., Zhang J., Liu Z.H., Dang Z., Liu Y*. (2021). Inhibition Properties of Arylsulfatase and β-Glucuronidase by Hydrogen Peroxide, Hypochlorite, and Peracetic Acid. ACS Omega, 6(12), 8163-8170.
[52] Zhao Q., Tian J.Z., Zhang K.F., Wang H.B., Li M., Meng S.J., Mu R.M., Liu L., Yin M.M., Li J.J., Liu Y*. (2021). Phosphate recovery from the P-enriched brine of AnMBR-RO-IE treating municipal wastewater via an innovated phosphorus recovery batch reactor with nano-sorbents. Chemosphere, 284.
[53] Zhang X.Y., Liu Y*. (2021). Integrated forward osmosis-adsorption process for strontium-containing water treatment: Pre-concentration and solidification. Journal of Hazardous Materials, 414.
[54] Zhang X.Y., Liu Y*. (2021). Circular economy-driven ammonium recovery from municipal wastewater: State of the art, challenges and solutions forward. Bioresource Technology, 334.
[55] Zhang X.Y., Liu Y*. (2021). Reverse osmosis concentrate: An essential link for closing loop of municipal wastewater reclamation towards urban sustainability. Chemical Engineering Journal, 421.
[56] Zhang X.Y., Liu Y*. (2021). Concurrent removal of Cu(II), Co(II) and Ni(II) from wastewater by nanostructured layered sodium vanadosilicate: Competitive adsorption kinetics and mechanisms. Journal of Environmental Chemical Engineering, 9(5).
[57] Zhang M., Ji B., Liu Y*. (2021). Microalgal-bacterial granular sludge process: A game changer of future municipal wastewater treatment? Science of the Total Environment 752.
[58] Wang S.L., Ji B., Zhang M., Gu J., Ma Y.Q., Liu Y*. (2021). Tetracycline-induced decoupling of symbiosis in microalgal-bacterial granular sludge. Environmental Research, 197.
[59] Wang S.L.*, Ji B.*, Cui B.H.*, Ma Y.Q.*, Guo D.B.*, Liu Y*. (2021). Cadmium-effect on performance and symbiotic relationship of microalgal-bacterial granules. Journal of Cleaner Production, 282:125383.
[60] Wang H., Liu Z.H., Tang Z., Zhang J., Dang Z., Liu Y*. (2021). Possible overestimation of bisphenol analogues in municipal wastewater analyzed with GC-MS. Environmental Pollution, 273.
[61] Wan Y.P., Liu Z.H., Liu Y*. (2021). Veterinary antibiotics in swine and cattle wastewaters of China and the United States: Features and differences. Water Environment Research, 93(9), 1516-1529.
[62] Tang Z., Liu Z.-h., Wan Y.-p., Wang H., Dang Z., Liu Y*. (2021). Far-Less Studied Natural Estrogens as Ignored Emerging Contaminants in Surface Water: Insights from Their Occurrence in the Pearl River, South China. ACS ES&T Water, 1(8), 1776-1784.
[63] Tang Z., Liu Z.H., Wang H., Dang Z., Liu Y*. (2021). Occurrence and removal of 17α-ethynylestradiol (EE2) in municipal wastewater treatment plants: Current status and challenges. Chemosphere, 271.
[64] Tang Z., Liu Z.H., Wang H., Dang Z., Liu Y*. (2021). A review of 17α-ethynylestradiol (EE2) in surface water across 32 countries: Sources, concentrations, and potential estrogenic effects. Journal of Environmental Management, 292.
[65] Sun H.F., Liu H., Zhang M., Liu Y*. (2021). A novel single-stage ceramic membrane moving bed biofilm reactor coupled with reverse osmosis for reclamation of municipal wastewater to NEWater-like product water. Chemosphere, 268.
[66] Sun H., Liu Y*. (2021). Chemical Cleaning-Triggered Release of Dissolved Organic Matter from a Sludge Suspension in a Ceramic Membrane Bioreactor: A Potential Membrane Foulant. ACS ES&T Water, 1(12), 2497-2503.
[67] Meng X.H., Meng S.J., Liu Y*. (2021). The Limitations in Current Studies of Organic Fouling and Future Prospects. Membranes, 11(12).
[68] Meng X., Wang X., Meng S., Wang Y., Liu H., Liang D., Fan W., Min H., Huang W., Chen A., Zhu H., Peng G., Liu J., Qiu Z., Wang T., Yang L., Wei Y., Huo P., Zhang D., Liu Y. (2021). A Global Overview of SARS-CoV-2 in Wastewater: Detection, Treatment, and Prevention. ACS ES&T Water, 1(10), 2174-2185.
[69] Meng S.J., Wang R., Zhang K.J., Meng X.H., Xue W.C., Liu H.J., Liang D.W., Zhao Q., Liu Y. (2021). Transparent exopolymer particles (TEPs)-associated protobiofilm: A neglected contributor to biofouling during membrane filtration. Frontiers of Environmental Science & Engineering, 15(4).
[70] Liu Z.H., Dang Z., Yin H., Liu Y*. (2021). Making waves: Improving removal performance of conventional wastewater treatment plants on endocrine disrupting compounds (EDCs): their conjugates matter. Water Research, 188.
[70] Liu Z.H., Dang Z., Liu Y*. (2021). Legislation against endocrine-disrupting compounds in drinking water: essential but not enough to ensure water safety. Environmental Science and Pollution Research, 28(15), 19505-19510.
[72] Ji B., Zhu L., Wang S.L., Liu Y*. (2021). Temperature-effect on the performance of non-aerated microalgal-bacterial granular sludge process in municipal wastewater treatment. Journal of Environmental Management, 282.
[73] Ji B., Wang S.L., Silva M.R.U., Zhang M., Liu Y*. (2021). Microalgal-bacterial granular sludge for municipal wastewater treatment under simulated natural diel cycles: Performances-metabolic pathways-microbial community nexus. Algal Research, 54.
[74] Ji B., Liu Y*. (2021). Assessment of Microalgal-Bacterial Granular Sludge Process for Environmentally Sustainable Municipal Wastewater Treatment. ACS ES&T Water, 1(12), 2459-2469.
[75] Hu M., Guo D.B., Ma Y.Q., Liu Y. (2021). Thermal-Chemical Treatment of Sewage Sludge Toward Enhanced Energy and Resource Recovery. Sustainable Resource Management, Volume I. 2021: 247-273
[76] Zhou X., Wang G.L., Yin Z.Y., Chen J.B., Song J.J., Liu Y*. (2020). Performance and microbial community in a single-stage simultaneous carbon oxidation, partial nitritation, denitritation and anammox system treating synthetic coking wastewater under the stress of phenol. Chemosphere, 243.
[77] Zhao Q., Liu C.F., Song H.Q., Liu Y., Wang H.B., Tian F.Y., Meng S.J., Zhang K.F., Wang N., Mu R.M., Li M. (2020). Mechanism of phosphate adsorption on superparamagnetic microparticles modified with transitional elements: Experimental observation and computational modelling. Chemosphere, 258.
[78] Zhang X.Y., Liu Y*. (2020). Potential toxicity and implication of halogenated byproducts generated in MBR online-cleaning with hypochlorite. Journal of Chemical Technology and Biotechnology 95(1), 20-26.
[79] Zhang X.Y., Liu Y*. (2020). Nanomaterials for radioactive wastewater decontamination. Environmental Science: Nano, 7(4), 1008-1040.
[80] Zhang X.Y., Liu Y*. (2020). Ultrafast removal of radioactive strontium ions from contaminated water by nanostructured layered sodium vanadosilicate with high adsorption capacity and selectivity. Journal of Hazardous Materials, 398.
[81] Zhang X.Y., Zhang M., Liu Y*. (2020). One step further to closed water loop: Reclamation of municipal wastewater to high-grade product water. Chinese Science Bulletin-Chinese, 65(14):1358-1367.
[82] Wang S.Y., Chew J.W., Liu Y*. (2020). An environmentally sustainable approach for online chemical cleaning of MBR with activated peroxymonosulfate. Journal of Membrane Science, 600.
[83] Wang S.Y., Chew J.W., Liu Y*. (2020). Development of an integrated aerobic granular sludge MBR and reverse osmosis process for municipal wastewater reclamation. Science of the Total Environment 748.
[84] Wang S.L., Ji B., Zhang M., Ma Y.Q., Gu J., Liu Y*. (2020). Defensive responses of microalgal-bacterial granules to tetracycline in municipal wastewater treatment. Bioresource Technology, 312.
[85] Wang H., Liu Z.H., Tang Z., Zhang J., Yin H., Dang Z., Wu P.X., Liu Y*. (2020). Bisphenol analogues in Chinese bottled water: Quantification and potential risk analysis. Science of the Total Environment 713.
[86] Tang Z., Liu Z.H., Wang H., Dang Z., Yin H., Zhou Y., Liu Y*. (2020). Trace determination of eleven natural estrogens and insights from their occurrence in a municipal wastewater treatment plant and river water. Water Research, 182.
[87] Tan P.Y., Marcos, Liu Y*. (2020). Modelling bacterial chemotaxis for indirectly binding attractants. Journal of THEORETICAL BIOLOGY, 487.
[88] Ren J., Li J.F., Xu Z.Z., Liu Y., Cheng F.Q. (2020). Simultaneous anti-fouling and flux-enhanced membrane distillation via incorporating graphene oxide on PTFE membrane for coking wastewater treatment. Applied Surface Science, 531.
[89] Perera A.T.K., Pudasaini S., Ahmed S.S.U., Phan D.T., Liu Y., Yang C. (2020). Rapid pre-concentration of <i>Escherichia coli</i> in a microfluidic paper-based device using ion concentration polarization. ELECTROPHORESIS, 41(10-11), 867-874.
[90] Perera A.T.K., Phan D.T., Pudasaini S., Liu Y., Yang C. (2020). Enhanced sample pre-concentration by ion concentration polarization on a paraffin coated converging microfluidic paper based analytical platform. Biomicrofluidics, 14(1).
[91] Pang H.L., Li L., He J.G., Yan Z.S., Ma Y.Q., Nan J., Liu Y*. (2020). New insight into enhanced production of short -chain fatty acids from waste activated sludge by cation exchange resin -induced hydrolysis. Chemical Engineering Journal, 388.
[92] Pang H.L., Pan X.L., Li L., He J.G., Zheng Y.S., Qu F.S., Ma Y.Q., Cui B.H., Nan J., Liu Y. (2020) An innovative alkaline protease-based pretreatment approach for enhanced short-chain fatty acids production via a short-term anaerobic fermentation of waste activated sludge. Bioresource Technology, 312:123397.
[93] Meng S.J., Meng X.H., Fan W.H., Liang D.W., Wang L., Zhang W.X., Liu Y*. (2020). The role of transparent exopolymer particles (TEP) in membrane fouling: A critical review. Water Research, 181.
[94] Ma Y.Q., Shen Y.Q., Liu Y*. (2020). Food Waste to Biofertilizer: A Potential Game Changer of Global Circular Agricultural Economy. Journal of Agricultural and Food Chemistry, 68(18), 5021-5023.
[95] Ma Y.Q., Shen Y.Q., Liu Y*. (2020). State of the art of straw treatment technology: Challenges and solutions forward. Bioresource Technology, 313.
[96] Luo Q., Liu Z.H., Yin H., Dang Z., Wu P.X., Zhu N.W., Lin Z., Liu Y*. (2020). Global review of phthalates in edible oil: An emerging and nonnegligible exposure source to human. Science of the Total Environment 704.
[97] Liu H., Gu J., Wang S.Y., Zhang M., Liu Y*. (2020). Performance, membrane fouling control and cost analysis of an integrated anaerobic fixed-film MBR and reverse osmosis process for municipal wastewater reclamation to NEWater-like product water. Journal of Membrane Science, 593.
[98] Li Y.F., Sim L.N., Ho J.S., Chong T.H., Wu B., Liu Y*. (2020). Integration of an anaerobic fluidized-bed membrane bioreactor (MBR) with zeolite adsorption and reverse osmosis (RO) for municipal wastewater reclamation: Comparison with an anoxic-aerobic MBR coupled with RO. Chemosphere, 245.
[99] Ji B., Zhu L., Wang S.Y., Qin H., Ma Y.Q., Liu Y*. (2020). A novel micro-ferrous dosing strategy for enhancing biological phosphorus removal from municipal wastewater. Science of the Total Environment 704.
[100] Ji B., Zhang M., Wang L., Wang S.L., Liu Y*. (2020). Removal mechanisms of phosphorus in non-aerated microalgal-bacterial granular sludge process. Bioresource Technology, 312.
[101] Ji B., Zhang M., Gu J., Ma Y.Q., Liu Y*. (2020). A self-sustaining synergetic microalgal-bacterial granular sludge process towards energy-efficient and environmentally sustainable municipal wastewater treatment. Water Research, 179.
[102] Guo D.B., Hu M., Chen Z.H., Cui B.H., Zhang Q., Liu Y.H., Luo S.Y., Ruan R., Liu Y. (2020). Catalytic pyrolysis of <i>rain tree</i> biomass with nano nickel oxide synthetized from nickel plating slag: A green path for treating waste by waste. Bioresource Technology, 315.
[103] Guo D.B., Li Y.X., Cui B.H., Hu M., Luo S.Y., Ji B., Liu Y. (2020). Natural adsorption of methylene blue by waste fallen leaves of Magnoliaceae and its repeated thermal regeneration for reuse. Journal of Cleaner Production, 267:121903.
[104] Gu J., Zhang M., Liu Y*. (2020). A review on mainstream deammonification of municipal wastewater: Novel dual step process. Bioresource Technology, 299.
[105] Gu J., Liu Y. (2020). Integrated AB processes for municipal wastewater treatment. AB Processes: Towards Energy Self-sufficient Municipal Wastewater Treatment, IWA Publishing, London, UK, 69-111.
[106] Feng H., Liang L.L., Wu W.Y., Huang Z.H., Liu Y*. (2020). Architecting epitaxial-lattice-mismatch-free (LMF) zinc oxide/bismuth oxyiodide nano-heterostructures for efficient photocatalysis. Journal of Materials Chemistry C, 8(32), 11263-11273.
[107] Feng H., Liang L.L., Ge J.Y., Wu W.Y., Huang Z.H., Liu Y., Li L. (2020). Delicate manipulation of cobalt oxide nanodot clusterization on binder-free TiO<sub>2</sub>-nanorod photoanodes for efficient photoelectrochemical catalysis. Journal of Alloys and Compounds, 820.
[108] Cai W.W., Han J.R., Zhang X.R., Liu Y*. (2020). Formation mechanisms of emerging organic contaminants during on-line membrane cleaning with NaOCl in MBR. Journal of Hazardous Materials, 386.
[109] Zhao Q., Liu Y*. (2019). Is anaerobic digestion a reliable barrier for deactivation of pathogens in biosludge? Science of the Total Environment 668, 893-902.
[110] Zhang X.Y., Liu Y*. (2019). Halogenated organics generated during online chemical cleaning of MBR: An emerging threat to water supply and public health. Science of the Total Environment 656, 547-549.
[111] Zhang X.Y., Gu P., Liu Y*. (2019). Decontamination of radioactive wastewater: State of the art and challenges forward. Chemosphere, 215, 543-553.
[112] Zhang X.Y., Zhang M., Liu H., Gu J., Liu Y*. (2019). Environmental sustainability: a pressing challenge to biological sewage treatment processes. Current Opinion in Environmental Science & Health, 12:1-5.
[113] Zhang M., Wang S.Y., Ji B., Liu Y*. (2019). Towards mainstream deammonification of municipal wastewater: Partial nitrification-anammox versus partial denitrification-anammox. Science of the Total Environment 692, 393-401.
[114] Zhang M., Gu J., Liu Y*. (2019). Engineering feasibility, economic viability and environmental sustainability of energy recovery from nitrous oxide in biological wastewater treatment plant. Bioresource Technology, 282, 514-519.
[115] Xin X.D., Hong J.M., Liu Y*. (2019). Insights into microbial community profiles associated with electric energy production in microbial fuel cells fed with food waste hydrolysate. Science of the Total Environment 670, 50-58.
[116] Wu L.W., Ning D.L., Zhang B., Li Y., Zhang P., Shan X.Y., Zhang Q.T., Brown M.R., Li Z.X., Van Nostrand J.D., Ling F.Q., Xiao N.J., Zhang Y., Vierheilig J., Wells G.F., Yang Y.F., Deng Y., Tu Q.C., Wang A.J., Acevedo D., Agullo-Barcelo M., Alvarez P.J.J., Alvarez-Cohen L., Andersen G.L., de Araujo J.C., Boehnke K.F., Bond P., Bott C.B., Bovio P., Brewster R.K., Bux F., Cabezas A., Cabrol L., Chen S., Criddle C.S., Deng Y., Etchebehere C., Ford A., Frigon D., Sanabria J., Griffin J.S., Gu A.Z., Habagil M., Hale L., Hardeman S.D., Harmon M., Horn H., Hu Z.Q., Jauffur S., Johnson D.R., Keller J., Keucken A., Kumari S., Leal C.D., Lebrun L.A., Lee J., Lee M., Lee Z.M.P., Li Y., Li Z.X., Li M.Y., Li X., Ling F.Q., Liu Y., Luthy R.G., Mendonça-Hagler L.C., de Menezes F.G.R., Meyers A.J., Mohebbi A., Nielsen P.H., Ning D., Oehmen A., Palmer A., Parameswaran P., Park J., Patsch D., Reginatto V., de los Reyes F.L., Rittmann B.E., Noyola A., Rossetti S., Shan X.Y., Sidhu J., Sloan W.T., Smith K., de Sousa O.V., Stahl D.A., Stephens K., Tian R., Tiedje J.M., Tooker N.B., Tu Q., Van Nostrand J.D., De los Cobos Vasconcelos D., Vierheilig J., Wagner M., Wakelin S., Wang A., Wang B., Weaver J.E., Wells G.F., West S., Wilmes P., Woo S.-G., Wu L.W., Wu J.-H., Wu L.Y., Xi C.W., Xiao N.J., Xu M.Y., Yan T., Yang Y.F., Yang M., Young M., Yue H.W., Zhang B., Zhang P., Zhang Q.T., Zhang Y., Zhang T., Zhang Q., Zhang W., Zhang Y., Zhou H.D., Zhou J.Z., Wen X.H., Curtis T.P., He Q., He Z.L., Brown M.R., Zhang T., He Z.L., Keller J., Nielsen P.H., Alvarez P.J.J., Criddle C.S., Wagner M., Tiedje J.M., He Q., Curtis T.P., Stahl D.A., Alvarez-Cohen L., Rittmann B.E., Wen X.H., Zhou J.Z., Global Water Microbiome C. (2019). Global diversity and biogeography of bacterial communities in wastewater treatment plants. Nature Microbiology, 4(7):1183-1195.
[117] Wang S.Y., Liu H., Gu J., Sun H.F., Zhang M., Liu Y*. (2019). Technology feasibility and economic viability of an innovative integrated ceramic membrane bioreactor and reverse osmosis process for producing ultrapure water from municipal wastewater. Chemical Engineering Journal, 375.
[118] Wang H., Xu G.J., Qiu Z., Zhou Y., Liu Y*. (2019). NOB suppression in pilot-scale mainstream nitritation-denitritation system coupled with MBR for municipal wastewater treatment. Chemosphere, 216, 633-639.
[119] Wang H., Liu Z.H., Zhang J., Huang R.P., Yin H., Dang Z., Wu P.X., Liu Y*. (2019). Insights into removal mechanisms of bisphenol A and its analogues in municipal wastewater treatment plants. Science of the Total Environment 692, 107-116.
[120] Sun H.F., Liu H., Wang S.Y., Liu Y*. (2019). Remediation of oil spill-contaminated sands by chemical-free microbubbles generated in tap and saline water. Journal of Hazardous Materials, 366, 124-129.
[121] Qian J., Zhou J.M., Pei X.J., Zhang M.K., Liu Y*. (2019). Bioactivities and formation/utilization of soluble microbial products (SMP) in the biological sulfate reduction under different conditions. Chemosphere, 221, 37-44.
[122] Meng S.J., Yin Y., Liu Y*. (2019). Exploration of a high-efficiency and low-cost technique for maximizing the glucoamylase production from food waste. RSC Advances, 9(40), 22980-22986.
[123] Ma Y.Q., Liu Y*. (2019). Turning food waste to energy and resources towards a great environmental and economic sustainability: An innovative integrated biological approach. Biotechnology Advances, 37(7).
[124] Ma Y., Liu Y*., Chapter 21 - Biodiesel Production: Status and Perspectives, in: A. Pandey, C. Larroche, C.-G. Dussap, E. Gnansounou, S.K. Khanal, S. Ricke (Eds.), Biofuels: Alternative Feedstocks and Conversion Processes for the Production of Liquid and Gaseous Biofuels (Second Edition), Academic Press2019, pp. 503-522. https://doi.org/https://doi.org/10.1016/B978-0-12-816856-1.00021-X.
[125] Liu Y*., Ganguly R., Huynh H.V., Leong W.K. (2019). Platinum-Osmium Heterometallic Clusters Containing N-Heterocyclic Carbene Ligands and an Electron-Deficient Tetraosmium By-Product. EUROPEAN JOURNAL OF INORGANIC CHEMISTRY, (14), 1966-1969.
[126] Liu Y., Gu J., Zhang M. (2019). AB processes: Towards energy self-sufficient municipal wastewater treatment. IWA publishing.
[127] Liu H., Sun H.F., Zhang M., Liu Y*. (2019). Dynamics of microbial community and tetracycline resistance genes in biological nutrient removal process. Journal of Environmental Management, 238, 84-91.
[128] Ji B., Liang J.C., Ma Y.Q., Zhu L., Liu Y*. (2019). Bacterial community and eutrophic index analysis of the East Lake. Environmental Pollution, 252, 682-688.
[129] Gu J., Zhang M., Wang S.Y., Liu Y*. (2019). Integrated upflow anaerobic fixed-bed and single-stage step-feed process for mainstream deammonification: A step further towards sustainable municipal wastewater reclamation. Science of the Total Environment 678, 559-564.
[130] Gu J., Liu H., Wang S.Y., Zhang M., Liu Y*. (2019). An innovative anaerobic MBR-reverse osmosis-ion exchange process for energy-efficient reclamation of municipal wastewater to NEWater-like product water. Journal of Cleaner Production, 230, 1287-1293.
[131] Gao Z., Ma Y.Q., Ma X.Y., Wang Q.H., Liu Y*. (2019). A novel variable pH control strategy for enhancing lipid production from food waste: Biodiesel versus docosahexaenoic acid. ENERGY CONVERSION AND MANAGEMENT, 189, 60-66.
[132] Feng H., Liang L.L., Liu Y., Huang Z.H., Li L. (2019). Efficient nano-regional photocatalytic heterostructure design the manipulation of reaction site self-quenching effect. Applied Catalysis B: Environment and Energy, 243, 220-228.
受邀书籍章节
1. Ma YQ and Liu Y. (2019)Biodieselproduction: Status and perspectives. In: Biomass, Biofuels and BiochemicalsSeries, Chapter 21, pp 503-522, Elsevier.
2. Hu M.,Guo DB, Ma YQ and Liu Y. (2019).Thermal-chemical treatment of sewage sludge towards enhanced energy andresource recovery. Chapter 10 in Resource Recovery and Reuse for SustainableFuture, Wiley.
3. EsraUçkun Kiran and Liu Y. (2015) Renewableenergy derived from food waste and co-digestion of food waste with wasteactivated sludge. In: Renewal Energy. Springer.
4. LiuY.J., Liu Y. (2012) Membrane bioreactor for wastewaterreclamation. In: Wastewater Treatment:Biological Methods, Technology and Environmental Impact. NovaScience Publisher, New York.
5. Liu Y.J., Sun D. and Liu Y.(2011) Denitrification Processes for Wastewater Treatment. In: Denitrification: Processes, Regulation andEcological Significance, ed. by Savaglio N. and Puopolo R., Nova SciencePublishers, New York.
6. Liu Y.Q., Liu Y., TayJ.H. and Hung Y.T. (2010) Biological Phosphorus Removal Processes. pp 497-521,In: Environmental Bioengineering, ed. by Lawrence K. Wang, Tay J.H., Tay S.T.L.and Hung Y.T., Springer, New York.
7. Jiang B., Liu Y., Chen G.H. and Paul E. (2009)Uncoupled Energy Metabolism for Sludge Reduction in the Activated SludgeProcess. In: Biochemical Engineering. Ed. by Dumont F.E. and Sacco J.A., NovaScience Publisher, New York.
8. Lin Y.M., Tay J.H., Liu Y.and Hung Y.T. (2009) Biological nitrification and denitrificaiton processes.pp. 539-588. In: Biological Treatment Processes. Ed. by Wang L.K, Norman C.P.,Hung Y.T. Springer, New York.
9. Shammas N.K., Liu Y.and Wang L.K. (2009) Principles and kinetics of biological processes. pp. 1-57,In: Advanced Biological Treatment Processes. Ed. by Wang L.K., Shammas N.K. andHung Y.T. Springer, New York.
10. Tay J.H., Liu Y., TayS.T.L. and Hung Y.T. (2009) Aerobic granulation technology. pp. 109-128. In:Advanced Biological Treatment Processes. Ed. by Wang L.K., Shammas N.K. andHung Y.T. Springer, New York.
11. Wang Z.W. and Liu Y. (2007) Modelling of Heavy MetalBiosorption by Aerobic Granules. pp. 221-245. In: New Colloid and SurfaceScience Research, ed. Lawrence V. Schwartz, Nova Science Publishers, Inc., NewYork.
12. Liu Y. (2001) Technology for minimizing activated sludge production. pp.232-244. In: Technology for Paper Industrial Wastewater Treatment, edited byYang X.F. Chinese Chemical Industry Press.
13. Tay J.H., Liu Q.S., Liu Y., Show K.Y.,Ivanov V., Tay S.T.L. (2005) A comparative study of aerobic granulation inpilot- and lab-scale SBRs. In: Aerobic Granular Sludge, ed. by Bathe S., de Kreuk M., McSwain B. and Schwarzenbeck N., p.125-134, IWA Publishing, London, UK, 2005.
14. Qin L., Tay J.H., Yang S.F. and LiuY. (2004) Aerobic granulation under alternating aerobic and anaerobicconditions in sequencing batch reactors. In: Water Environmental ManagementBook Series, ed. by Lens P. and Stuetz R., pp.3-10, IWA Publishing, London, UK,2004.
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学校介绍
南开大学是教育部直属重点综合性大学,是敬爱的周恩来总理的母校。新中国成立以来,学校发展始终得到党和国家的亲切关怀。毛泽东主席题写校名、亲临视察;周恩来总理三回母校指导;邓小平同志会见数学大师陈省身,批示成立南开数学研究所;江泽民同志、胡锦涛同志先后视察南开。特别是党的十八大以来,习近平总书记多次对南开的发展给予肯定,并对相关工作回信和勉励,更在百年校庆之际亲临南开视察。
南开大学由严修、张伯苓秉承教育救国理念创办,肇始于1904年,成立于1919年。1937年校园遭侵华日军炸毁,学校南迁。1938年与北京大学、清华大学合组西南联合大学,被誉为“学府北辰”。1946年回津复校并改为国立。
新中国成立后,经历高等教育院系调整,成为文理并重的全国重点大学。改革开放以来,天津对外贸易学院、中国旅游管理干部学院相继并入,经教育部与天津市共建支持,学校发展成为国家“211工程”和“985工程”重点建设的综合性研究型大学。2015年9月,新校区建成启用后,初步形成了八里台校区、津南校区、泰达学院“一校三区”办学格局。2017年9月,入选国家42所世界一流大学建设高校,且为36所A类高校之一。
南开大学坚持“允公允能,日新月异”的校训,弘扬“爱国、敬业、创新、乐群”的传统和“文以治国、理以强国、商以富国”的理念,以“知中国,服务中国”为宗旨,以杰出校友周恩来为楷模,作育英才,繁荣学术,强国兴邦,传承文明,努力建设世界一流大学。
南开大学占地443.12万平方米,其中八里台校区占地121.60万平方米,津南校区占地245.89万平方米,泰达学院占地6.72万平方米。校舍建筑总面积195.19万平方米。按照“独立办学、紧密合作”的原则,与天津大学全面合作办学。
南开大学是国内学科门类齐全的综合性、研究型大学之一。在长期办学过程中,形成了文理并重、基础宽厚、突出应用与创新的办学特色。有专业学院26个,学科门类覆盖文、史、哲、经、管、法、理、工、农、医、教、艺等。
南开大学拥有一支公能兼备、业务精湛、奋发有为、充满活力的师资队伍。有专任教师2202人。其中,博士生导师885人、硕士生导师783人,教授898人、副教授857人。
南开大学具备培养学士、硕士和博士的完整教育体系。有在校学生31418人,其中本科生17005人,硕士研究生10299人,博士研究生4114人。有网络专科学生40230人,网络本科学生73029人。
学校积极构建和发展适应21世纪经济社会发展和人才培养需要的学科体系,有本科专业93个(其中国家级特色专业18个),硕士学位授权一级学科11个,硕士专业学位授权点27个,博士学位授权一级学科31个,不在一级学科覆盖下的二级博士点1个,博士后科研流动站28个。有国家“双一流”建设学科5个,一级学科国家重点学科6个(覆盖35个二级学科),二级学科国家重点学科9个,一级学科天津市重点学科32个,国家级一流本科专业建设点21个,省级一流本科专业建设点2个。有国家重点实验室2个,国家工程研究中心1个,国家地方联合工程研究中心1个,2011协同创新中心3个。教育部重点实验室7个,教育部工程研究中心3个,教育部国际合作联合实验室2个,国家环境保护重点实验室1个,国家人权教育与培训基地1个,教育部人文社会科学重点研究基地6个,省部共建协同创新中心1个,教育部国别和区域研究基地7个(培育基地1个、备案基地6个),示范性国家国际科技合作基地4个。国家级实验教学示范中心5个,国家级虚拟仿真实验教学中心2个,国家虚拟仿真实验教学项目2项,国家基础学科人才培养和科学研究基地9个,国家教材建设重点研究基地1个,国家大学生文化素质教育基地1个,中华传统文化传承基地2个,国家创新人才培养示范基地1个。天津市重点实验室20个,天津市工程技术中心4个,天津市普通高等学校实验教学示范中心14个,天津市普通高等学校实验教学示范中心建设单位1个,天津市国际科技合作基地22个,天津市人文社科重点研究基地9个,天津市高校智库8个,天津市社科实验室5个,天津市爱国主义教育基地1个。
有中国科学院院士11人,中国工程院院士4人,发展中国家科学院院士8人,教育部“长江学者奖励计划”特聘教授44人、青年学者19人,“国家杰出青年科学基金”获得者57人、“国家优秀青年科学基金”获得者39人,国家“万人计划”领军人才27人、青年拔尖人才15人,国家“百千万人才工程”入选者30人,教育部“跨世纪人才基金”获得者21人、“新世纪优秀人才支持计划”入选者158人,国家级有突出贡献的专家22人,国务院学位委员会学科评议组成员16人,国家自然科学基金创新研究群体负责人6人,“国家高技术研究发展计划(863计划)”首席科学家3人,“国家重点基础研究发展计划(973计划)”首席科学家15人,国家重点研发计划项目负责人24人。国家级教学名师奖获得者7人,国家级教学团队9个,教育部“高校青年教师奖”获得者8人。天津市杰出人才8人,天津市“人才发展特殊支持计划”领军人才3人、青年拔尖人才11人、高层次创新创业团队带头人11人,天津市有突出贡献专家7人,天津市杰出津门学者3人,天津市“131”创新人才培养工程第一层次人选63人、创新型人才团队带头人17人,“天津市杰出青年科学基金”获得者40人,天津市级教学名师奖获得者35人,天津市级教学团队18个。
南开大学既是教学中心,又是科研中心,取得了一批国内外公认的优秀成果。2019年,周其林院士领衔完成的“高效手性螺环催化剂的发现”项目获国家自然科学奖一等奖。2007—2018年以第一单位获得国家自然科学二等奖4项,国家科技进步二等奖1项,国家技术发明二等奖1项。获国家教学成果奖46项,国家级精品资源共享课31门,国家级精品视频公开课15门,国家级一流本科课程31门,中国专利优秀奖1项,中国青年科技奖2项,全国百篇优秀博士论文累计入选20篇。2018年以来,南开学者团队以第一完成单位在Science上发表研究论文6篇。
南开大学秉承“知中国,服务中国”的优良传统,立足“四个服务”职责使命,聚焦“一带一路”、京津冀协同发展、雄安新区建设等国家和区域发展战略,积极发挥学科、人才和技术优势,努力为国家和地方经济社会发展服务。习近平新时代中国特色社会主义思想研究院、21世纪马克思主义研究院、亚太经济合作组织研究中心、中国新一代人工智能发展战略研究院、经济与社会发展研究院、滨海开发研究院、人权研究中心、津南研究院、统计研究院、生态文明研究院等研究机构是国家有关部委和地方政府的“智囊团”和“人才库”。学校按照“国家急需,世界一流”的原则,全面对接“创新驱动发展”战略、“中国制造2025”等的实施,积极推动各类协同创新中心和若干高层次交叉科学中心建设,与一批高校、企业、科研院所、政府部门建立了紧密合作关系。
南开大学重视学生德、智、体、美、劳全面发展,构建南开特色的“公能”素质教育体系,探索“课堂教学-校园文化-社会实践”三位一体育人模式。以“注重素质、培养能力、强化基础、拓宽专业、严格管理、保证质量”为教学指导思想,实行弹性学制、学分制、主辅修制、双学位制。注重培育优良校风,大力加强校园文化建设,为学生营造丰富高雅、活泼向上的成长氛围。推进创新创业教育,开办“创业班”,推进“南开大学学生创新创业实践基地”建设,提升学生创新能力,助力学生创业计划落地。大力开展“师生同行”社会实践,搭建师生“受教育、长才干、作贡献”的互动平台。南开毕业生以专业基础扎实、综合素质全面、富于开拓精神和实践能力而受到社会各界青睐。
南开大学有着广泛的国际影响,与320多所国际知名大学和国际学术机构建立了合作与交流关系;有专兼职外国专家400余人,以及来自114个国家和地区的2000余名留学生在校学习;承建了英国格拉斯哥大学孔子学院等8所海外孔子学院;与英国牛津大学、伯明翰大学、韩国SK集团共建国际联合研究中心;与世界经济论坛(达沃斯论坛)、全球大学领导者论坛(GULF)、国际公立大学联盟(IFPU)、国际大学联合会(IAU)、世界工程组织联合会(WFEO)等国际组织保持着密切联系,通过积极参与各类国际组织活动,进一步推动与世界一流大学、机构的实质性、深层次合作。
南开大学先后授予数学家陈省身、物理学家吴大猷、经济学家扬·米尔达尔、美国科学院院士蒋-卡洛·若塔、哈佛大学医学院教授摩斯·居达·福克曼、台湾海基会前董事长江丙坤、美国莱斯大学校长李达伟、世界经济论坛主席克劳斯·施瓦布、新加坡总统陈庆炎、法国宪法委员会主席洛朗·法比尤斯等10位国际著名人士名誉博士称号。诺贝尔奖获得者杨振宁、李政道、罗伯特·蒙代尔、彼得·杜赫提、卡尔·巴里·夏普莱斯、弗农·洛马克斯·史密斯、罗伯特·恩格尔、巴里·詹姆斯·马歇尔、托马斯·萨金特,美国前国务卿基辛格,韩国前总统金大中,欧盟委员会前主席、意大利前总理罗马诺·普罗迪,著名作家金庸等被聘为名誉教授,一批海内外知名学者、著名政治家、企业家任客座教授、兼职教授。
南开大学将深入贯彻落实习近平总书记来校视察重要讲话精神,全面贯彻党的教育方针,坚持社会主义办学方向,落实立德树人根本任务,践行“四个服务”重要使命,加快建设南开品格、中国特色、世界一流大学,培养德智体美劳全面发展的社会主义建设者和接班人,为实现中华民族伟大复兴做出新一代南开人的历史贡献。
(数据截至2020年12月)
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