吴有庭，男，1968年11月生于浙江省兰溪市。1990、1993、1996年分别获得浙江大学化学系理学本科、理学硕士、及浙江大学化工系工学博士学位。1996年12月进入南京大学化学化工学院博士后流动站，从事精密精细蒸馏过程及其设备的研究。1998年9月在南京大学被授予副教授资格。1999年2月博士后出站，赴葡萄牙Minho大学生物工程系生化分离中心，从事果胶酶发酵生产与双水相分离的博士后研究。2000年10月，赴美国北卡州立大学化工系从事绿色表面清洗过程与检测等方面的博士后研究。2002年1月转至挂靠北卡州立大学化工系的美国国家自然科学基金会CO₂科技中心，从事石英晶体微天平及其表面膜溶解与吸收CO₂等方面的研究。2003年8月转任为该CO₂中心的副研究员（Research Associate）。2004年3月回国任南京大学教授，2009年增选为博士生导师。已经发表各类学术论文150余篇，其中在包括Nat. Catal., Angew, AIChE J., Chem. Eng. J., Adv. Energy Mater., Chem. Commun., Green Chem., Environ. Sci. Technol.等一流刊物上发表的SCI论文130余篇；出版国家十一五规划教材1部（2011年教育部精品教材）；申请专利40余项，已授权30多项；获国家科学技术进步二等奖1次（2011年），教育部（1998年）、江苏省（2003年）和中石化（2010年）科技进步一等奖各1次，中华环保联合会环保科技创意设计大赛优秀教师奖1次（2011年）、2022年中国产学研合作创新奖（排名第一）；入选江苏省“333高层次人才工程”（2007年）、中国能源学会理事会常务理事（2010年）、中国化工学会离子液体专业委员会委员（2012年至今）等。现主要从事绿色过程化工、化工传质分离、碳捕获与减排、反应分离耦合与过程强化、离子液体材料合成与应用、化工热力学等领域或方向的教学和科研工作。

（1）化工分离与过程集成、绿色化工过程（离子液体合成与应用、酸性气体捕集与资源化)；（2）离子液体作为电解质用于钠离子电池/电容器；（3）离子液体/低共熔剂膜材料用于酸性气体分离；（4）化工热力学与过程模拟计算（反应-分离集成）

Selected publications

33.Pan,Y.;Liu,Y.;Zhang,X.;Shi,M.;Tu,Z.;*Hu,X.;*Wu,Y.;*Design of deep eutectic solvents with multiple-active-sites for HCl separation and storage, Sep. Purif. Technol., 2022, 300, 121799.

32.Xiong,W.;Yin,Z.;Zhang,X.;*Tu,Z.;Hu,X.;Wu,Y.;* Ionic Liquids Endowed with Novel Hybrid Anions for Supercapacitors, ACS Omega 2022, 7, 26368-26374.

31.Xiong,W.;Shi,M.;Lu,Y.;Zhang,X.;*Hu,X.;Tu,Z.;*Wu,Y.;*Efficient conversion of H2S into mercaptan alcohol by tertiary-amine functionalized ionic liquids, Chinese J. Chem. Eng. 2022, doi.org/10.1016/j.cjche.2022.07.001, in press.

30.Peng,L.;Shi,M.;Pan,Y.;Tu,Z.;*Hu,X.;Zhang,X.;*Wu,Y.;* Ultrahigh carbon monoxide capture by novel protic cuprous-functionalized dicationic ionic liquids through complexation interactions, Chem. Eng. J. 2023, 451, 138519.

29.Xu,G.;Shi,M.;Zhang,P.;Tu,Z.;*Hu,X.;Zhang,X.;*Wu,Y.;*Tuning the composition of deep eutectic solvents consisting of tetrabutylammonium chloride and n-decanoic acid for adjustable separation of ethylene and ethane, Sep.Purif.Technol. 2022, 298, 121680.

28.Tu,Z.;Zhang,P.;Shi,M.;Zhang,X.;*Wu,Y.;*Hu,X.;*Selective and simultaneous membrane separation of CO and H2 from N2 by protic chlorocuprate ionic liquids, Renew. Energ. 2022,196, 912-920.

27.Wu,H.;Xiong,W.;Wen,S.;Zhang,X.;*Zhang,S.;*Homologue-paired liquids as special non-ionic deep eutectic solvents for efficient absorption of SO2, Chem. Commun. 2022,58,7801-7804.

26.Ji,J.;Xiong,W.;Zhang,X.;*Peng,L.;Shi,M.;Wu,Y.;*Hu,X.;*Reversible absorption of NF3 with high solubility in Lewis acidic ionic liquids, Chem. Eng. J. 2022,440,135902.

25.Zhang, P.;Xiong, W.;Shi, M.;Tu, Z.;*Hu,X.;Zhang, X.;* Wu, Y.;* Natural deep eutectic solvent-based gels with multi-site interaction mechanism for selective membrane separation of SO2 from N2 and CO2, Chem. Eng. J. 2022,438,135626.

24.Peng, L.L.; Shi, M.Z.; Zhang, X.M.;* Xiong, W.J.; Hu, X.B.; Tu, Z.H.;* Wu, Y.T.* Facilitated transport separation of CO₂ and H₂S by supported liquid membrane based on task specific protic ionic liquids, Green Chem. Eng. 2022, 3, 259-266.

23.Shi, M.Z.; Xiong, W.J.; Zhang, X. M.;* Ji, J.L.; Hu, X.B.; Tu, Z.H.;* Wu, Y. T.* Highly efficient and selective H₂S capture by task-specific deep eutectic solvents through chemical dual-site absorption, Sep. Purif. Technol. 2022, 283, 120167.

22. Xu, S.; Zhang, X.M.;* Xiong, W.J.; Li, P.; Ma, W.T.; Hu, X.B.;* Wu, Y.T.;* Aerobic oxidation of aldehydes to acids in water with cyclic (alkyl)(amino)carbene copper under mild conditions, Chem. Commun. 2022, 58, 2132-2135.

21. Xiong W. J.; Shi M. Z.; Zhang X. M.*; Tu Z. H.; Hu X. B.; Wu Y. T.*, The Efficient Conversion of H₂S into Mercaptan Alcohols Mediated in Protic Ionic Liquids under Mild Condition. Green Chem., 2021, 23,7969-7975.

20. Xiong, W. J.; Tu, Z. H.; Yin, Z.Y.; Zhang, X. M.*; Hu, X. B.; Wu, Y. T.*  Supported Ionic Liquid Gel Membranes Enhanced by Ionization Modification for Sodium Metal Batteries，ACS Sustain. Chem. Eng. 2021, 9, 12100−12108.

19. Zhang, X. M.; Xiong, W. J.; Shi, M.Z.; Wu, Y. T.*; Hu, X. B.* “Task-specific ionic liquids as absorbents and catalysts for efficient capture and conversion of H₂S into value-added mercaptan acids”. Chem. Eng. J. 2021, 408, 127866.

18. Shi, M. Z.; Xiong, W. J.; Tu, Z. H.; Zhang, X. M.*; Hu, X. B.; Wu, Y. T.* Task-specific deep eutectic solvents for the highly efficient and selective separation of H₂S, Sep. Purif. Technol. 2021, 276, 119357.

17. Xiong, W. J.; Shi, M. Z.; Peng, L. L.; Zhang, X. M.*; Hu, X. B.;Wu, Y. T.* Low Viscosity Superbase Protic Ionic Liquids for the Highly Efficient Simultaneous Removal of H₂S and CO2 from CH4, Sep. Purif. Technol. 2021, 263, 118417.

16. Tu, Z. H.; Shi, M. Z.; Zhang, X. M.; Liu, P. P.; Wu, Y. T.*; Hu, X. B.* Selective membrane separation of CO2 using novel epichlorohydrin-amine-based crosslinked protic ionic liquids: Crosslinking mechanism and enhanced salting-out effect, J. CO2 Utili. 2021, 46, 101473.

15. Tu, Z. H.; Liu, P. P.; Zhang, X. M.; Shi, M. Z.; Zhang, Z.; Luo, S. L.; Chen, L. P.; Wu, Y. T.*; Hu, X. B.* Highly-selective separation of CO2 from N2 or CH4 in task-specific ionic liquid membranes: Facilitated transport and salting-out effect, Sep. Purif. Technol. 2021, 254, 117621.

14. Zhang, X. M.; Xiong, W. J.; Peng, L. L.; Wu, Y. T.*; Hu, X. B.* “Highly selective absorption separation of H₂S and CO₂ from CH₄ by novel azole-based protic ionic liquids”. AIChE J. 2020, 66, e16936.

13. Zhang, X. M.; Xiong, W. J.; Yin, Z. Y.; Chen, Y. L.; Wu, Y. T. *; Hu, X. B.*  A novel proton-gradient-transfer acid complexes as an efficient and reusable catalyst for fatty acid esterification. Green Energy Environ. 2022, 7, 137-144.

12. Zhao, T. X.; Hu, X. B.*; Wu, Y. T.*; Zhang, Z. B. “Hydrogenation of CO₂ to Formate with H₂: Transition Metal Free Catalyst Based on a Lewis Pair”. Angew. Chem. Int. Ed. 2019, 58, 722-726.

11. Tu, Z. H.; Zhang, Y. Y.; Wu, Y. T.*; Hu, X. B.* “Self-enhancement of CO reversible absorption accompanied by phase transition in protic chlorocuprate ionic liquids for effective CO separation from N₂”. Chem. Commun. 2019, 55, 3390-3393.

10. Zhang, X. M.; Xiong, W. J.; Tu, Z. H.; Peng, L. L.; Wu, Y. T.*; Hu, X. B.* Supported Ionic Liquid Membranes with Dual-Site Interaction Mechanism for Efficient Separation of CO2. ACS Sustain. Chem. Eng. 2019, 7, 10792−10799.

9. Mendes, T.; Zhang, X. M.*; Wu, Y. T.*; Howlett, P. T.; Forsyth, M.; MacFarlane, D. R.* "Supported Ionic Liquid Gel Membrane Electrolytes for a Safe and Flexible Sodium Metal Battery". ACS Sustain. Chem. Eng. 2019, 7, 3722−3726.

8. Zhang, X. M.; M. Kar.; T. C. Mendes.; Wu, Y. T.*; and D. R. MacFarlane.*; “Supported ionic liquid gel membrane electrolytes for flexible supercapacitors”. Adv. Energy Mater. 2018, 8, 1702702.

7. Zheng, W. T.; Huang, K.; Wu, Y. T.*; Hu, X. B.* “Protic Ionic Liquid as Excellent Shuttle of MDEA for Fast Capture of CO₂”. AIChE J. 2018, 64, 209-219.

6. Zhang, X. M.; Tu, Z. H.; Li, H.; Li, L.; Wu, Y. T.*; Hu, X. B. “Supported protic-ionic-liquid membranes with facilitated transport mechanism for the selective separation of CO₂”, J. Membr. Sci. 2017, 527, 60-67.

5. Zhang, X. M.;Tu, Z. H.; Li, H.; Huang, K.; Hu, X. B.*; Wu, Y. T.*; MacFarlane, D. R.* "Selective separation of H2S and CO2 from CH4 by supported ionic liquid membranes",J. Membr. Sci., 2017, 543, 282–287.

4. Huang, K.; Zhang, X. M.; Hu, X. B.; Wu, Y. T.* “Hydrophobic protic ionic liquids tethered with tertiary amine group for highly efficient and selective absorption of H₂S from CO₂”. AIChE J. 2016, 62, 4480-4490.

3. Huang, K.; Feng, X.; Zhang, X.; Wu, Y. T.*; Hu, X. B.*“The ionic liquid-mediated Claus reaction: a highly efficient capture and conversion of hydrogen sulfide”. Green Chem., 2016, 18, 1859-1863.

2. Zhang, X. M.; Huang, K.; Xia, S.; Chen, Y. L.; Wu, Y. T.*; Hu, X. B.* Low-viscous fluorine-substituted phenolic ionic liquids with high performance for capture of CO2. Chem. Eng. J., 2015, 274, 30-38.

1. Huang, K.; Zhang, X. M.; Xu, Y.; Wu, Y. T.*; Hu, X. B.*“Protic ionic liquids for the selective absorption of H₂S from CO₂: Thermodynamic Analysis”. AIChE J. 2014, 60, 4232-4240.

《化工热力学》

《分离过程专题》