個人簡歷

教育簡歷

• 2001年9月-2005年7月        北京航空航天大學環境工程系，本科

• 2005年9月-2011年年7月      北京大學環境工程系，直博

工作簡歷

• 2011年8月-2016年7月        美國Pennsylvania State University (PSU)🧑🏽‍🎨， 博士後

• 2016年8月-2021年7月        美國Louisiana State University (LSU), 助理教授

• 2021年9月-                   沐鸣2平台，教授

碩士生導師/方向

朱秀萍教授本科畢業於北京航空航天大學🏋🏿‍♀️，2011年7月在北京大學獲得博士學位，師從於中國科學院院士倪晉仁教授👨🏻‍🦯‍➡️，博士學位論文《摻硼金剛石膜電極電化學氧化難降解有機汙染物機理及廢水處理研究》被評為2013年全國優秀博士學位論文🧘🏼‍♂️。2011年8月-2016年7月在賓夕法尼亞州立大學美國工程院院士Bruce Logan課題組從事博士後研究👩🏻‍🦯🤷🏽‍♂️，2016年8月-2021年7月在路易斯安那州立大學擔任助理教授🕌，2021年9月通過海外高層次人才引進計劃（青年項目）以教授身份加入沐鸣2开户。主要從事電化學水處理及資能源回收利用方面的研究工作，目前已在Environmental Science & Technology, Water Research, Nature Sustainability 等國際知名期刊發表SCI 論文80余篇，引用3000余次, H指數 36 (基於Google Scholar).

學術兼職

• National Science Open (NSO) 副主編⏩🏪，2021

• Environmental Science & Ecotechnology (ESE) 青年編委🙍🏼‍♂️，2021

• Chemical Engineering Journal Advances 編委會委員🤝👰🏽‍♂️，2020

• Journal of Hazardous Materials Letters 咨詢委員會委員♏️，2020

• Frontiers in Environmental Science 客座編輯，2021

• Advances in Polymer Technology客座編輯🧑‍🧑‍🧒，2020

榮譽與獎勵

• 2021年海外高層次人才引進計劃（青年項目）

• 2013年全國百篇優秀博士學位論文

• 2010年教育部博士研究生學術新人獎

• 2009年上海同濟高廷耀環保科技發展基金會青年博士生傑出人才獎學金

• 2005年北京市優秀畢業生

人才培養

本科生課程👊🏼♍️：

• Water and Wastewater Treatment

• Environmental Engineering III: Water Chemistry

• Renewable Energy and Power Generation

研究生課程🎎：

• Advanced Topics in Water Quality and Treatment

科學研究

主持和參與的主要項目🏄🏼：

• Development of novel-battery systems to harvest salinity gradient energy between seawater and river water (主持). Louisiana Board of Regents, Research Competitiveness Subprogram. June 1, 2017-June 30, 2020.

• Microbial electrodialysis cells for wastewater treatment and water recycling in space (主持). NASA, LaSPACE Research Enhancement Award. July 1, 2017 – June 30, 2018.

• Desalination of salt water for agriculture based on a novel battery system (主持). Louisiana Water Resources Research Institute. March 1, 2017- February 28, 2018.

• Optimizing the microbial electrodialysis cell for wastewater treatment and water recycling in space. (主持). Louisiana NASA EPSCoR, Research Awards Program, Feb. 1, 2019 – Jan. 31, 2020.

• A low cost and low energy consumption desalination battery for brackish and seawater treatment (主持). Louisiana Water Resources Research Institute. March 1, 2019 - February 29, 2020.

• Solar-driven microbial electrodialysis cells for water recycling and H2 generation in space. (主持). NASA, LaSPACE Research Enhancement Award SCC Award. February 24, 2020 to May 31, 2020.

教研成果

代表性論文：

1. Tan, G. C.; Xu, N.; Gao, D. X.; Zhu, X. P.* Facile designed manganese oxide/biochar for efficient salinity gradient energy recovery in concentration flow cells and influences of mono/multivalent ions. ACS Applied Materials & Interfaces, 2021, 13, 19855−19863.

2. Lu, S. D.; Lan, J., Sun, W. L., He, X. J.; Zhu, X. P.* High energy recovery from salinity gradients in a concentration flow cell enhanced by bioelectrochemical currents. Chemical Engineering Journal, 2021, 426, 130826.

3. Lu, S. D.; Lu, B. Y.; Tan, G. C.; Moe, W.; Xu, W. W.; Wang, Y.; Xing, D. F.; Zhu, X. P.* Mo2N nanobelt cathodes for efficient hydrogen production in microbial electrolysis cells with shaped biofilm microbiome. Biosensors and Bioelectronics, 2020, 167, 112491.

4. Tan, G. C.; Lu, S. D.; Xu, N.; Gao, D. X.; Zhu, X. P.* Pseudocapacitive behaviors of polypyrrole grafted activated carbon and MnO2 electrodes to enable fast and efficient membrane-free capacitive deionization. Environmental Science & Technology 2020, 54, 9, 5843–5852.

5. Palakkal, V. M.; Nguyen, T.; Nguyen, R.; Chernova, M.; Rubio, J.; Venugopalan, G.; Hatzell, M.; Zhu, X. P.*; Arges, G. C.*. High power thermally regenerative ammonia-copper redox flow battery enabled by a zero gap cell design, low-resistant membranes, and electrode coatings. ACS Applied Energy Materials 2020, 3, 5, 4787–4798

6. Zhu, H. H.; Lai, J. W.; Arges, G. C.; Wang, Y.; Zhu, X. P.* Engineering the interlayer spacing of molybdenum disulfide for efficient salinity gradient energy recovery in concentration flow cells. Electrochimica Acta, 2020, 342, 136103.

7. Tan, G. C.; Zhu, X. P.* Polyelectrolyte-coated copper hexacyanoferrate and bismuth oxychloride electrodes for efficient salinity gradient energy recovery in capacitive mixing. Energy Technology, 2020, 1900863.

8. Tan, G. C.; Lu, S. D.; Fan, J. Z.; Li, G. Q.; Zhu, X. P.* Chloride-ion concentration flow cells for efficient salinity gradient energy recovery with bismuth oxychloride electrodes. Electrochimica Acta, 2019, 322, 134724.

9. Whiddon, E.; Zhu, H. H.; Zhu, X. P.* Sodium-ion concentration flow cell stacks for salinity gradient energy recovery: Power generation of series and parallel configurations. Journal of Power Sources, 2019, 435, 226796.

10. Lu, S. D.; Li, H. N.; Tan, G. C.; Wen, F.; Flynn, M. T.; Zhu, X. P.* Resource recovery microbial fuel cells for urine-containing wastewater treatment without external energy consumption. Chemical Engineering Journal, 2019, 373, 1072-1080.

11. Zhu, H. H.; Xu, W. W.; Tan, G. C.; Whiddon, E.; Wang, Y.; Arges, C. G.; Zhu, X. P.* Carbonized peat moss electrodes for efficient salinity gradient energy recovery in a capacitive concentration flow cell. Electrochimica Acta, 2019, 294, 240-248.

12. Wang, W. G.; Tian, H.; Shu, G. Q.*, Huo, D. X.; Zhang, F.; Zhu, X. P.* A bimetallic thermally-regenerative ammonia-based battery for high power density and efficiently harvesting low-grade thermal energy. Journal of Materials Chemistry A, 2019, 7, 5991-6000.

13. Tan, G. C.; Li, H. N.; Zhu, H. H.; Lu, S. D.; Fan, J. Z.; Li, G.Q.; Zhu, X. P.* Concentration flow cells based on chloride-ion extraction and insertion with metal chloride electrodes for efficient salinity gradient energy harvest. ACS Sustainable Chemistry & Engineering, 2018, 6, 15212-15218.

14. Lu, L.; Guest, J. S.; Peters, C. A; Zhu, X. P.; Rau G. H., Ren, Z. Y. Wastewater treatment for carbon capture and utilization. Nature Sustainability, 2018, 1, 750-758.

15. Zhu, X. P.*; Xu, W.W.; Tan, G.C.; Wang, Y. Concentration Flow Cells for Efficient Salinity Gradient Energy Recovery with Nanostructured Open Frameowork Hexacyanoferrate Electrodes. ChemistrySelect, 2018, 3, 5571-5580.

16. Wang W. G.; Shu G. Q.*; Tian H.*; Zhu X. P.*; A numerical model for a thermally-regenerative ammonia-based flow battery using for low grade waste heat recovery. Journal of Power Sources. 2018, 388: 32-44.

17. Rahimi, M.; Straub, A. P.; Zhang, F., Zhu, X.P.; Elimelech, M.; Gorski, C. A.; Logan, B. E. Emerging electrochemical and membrane-based systems to convert low-grade heat to electricity. Energy & Environmental Science. 2018, 11: 276-285

18. Zhu, X. P.*; Kim, T.; Rahimi, M.; Gorski, C.A.; Logan, B. E. Integrating Reverse-electrodialysis stacks with flow batteries for improved energy recovery from salinity gradient and energy storage. ChemSusChem. 2017, 10: 1-8

19. Zhu, X. P.; Rahimi, M.; Gorski, C.; Logan, B. E. A thermally-regenerative ammonia-based flow battery for electrical energy recovery from waste heat. ChemSusChem, 2016, 9: 873–879

20. Zhu, X. P.; He, W. H.; Logan, B. E. Influence of solution concentration and composition on the performance of reverse electrodialysis cells. Journal of Membrane Science 2015, 494, 154-160.

21. Zhu, X. P.; He, W. H.; Logan, B. E. Reducing pumping energy by using different flow rates of high and low concentration solutions in reverse electrodialysis cells. Journal of Membrane Science 2015, 486:215-221.

22. Zhu, X. P.; Siegert, M.; Yates, M. D.; Logan, B. E. Alamethicin suppresses methanogenesis and promotes acetogenesis in bioelectrochemical systems. Applied and Environmental Microbiology 2015, 81: 3863-3868.

23. Zhu, X. P.; Yang, W. L., Hatzell, M. C.; Logan, B. E. Energy recovery from solutions with different salinities based on swelling and contraction of hydrogels. Environmental Science & Technology 2014, 48:7157-7163.

24. Zhu, X. P.; Yates, M. D.; Hatzell, M. C.; Rao, H. A.; Saikaly, P. E.; Logan, B. E. Microbial community composition is unaffected by anode potential. Environmental Science & Technology 2014, 48: 1352-1358.

25. Zhu, X. P.; Yates, M. D.; Hatzell, M. C.; Rao, H. A.; Saikaly, P. E.; Logan, B. E. Reply to “Strain level variation in biofilms selected at different anode potentials: a response to Zhu et al.”. Environmental Science & Technology 2014, 48: 14853-14854.

26. Zhu, X. P.; Hatzell, M. C.; Logan, B. E. Microbial reverse-electrodialysis electrolysis and chemical-production cell for H2 production and CO2 sequestration. Environmental Science & Technology Letters 2014, 1:231-235.

27. Zhu, X. P.; Logan, B. E. Microbial electrolysis desalination and chemical-production cell for CO2 sequestration. Bioresource Technology 2014, 159:24-29.

28. Zhu, X. P.; Logan, B. E. Copper anode corrosion affects power generation in microbial fuel cells. Journal of Chemical Technology and Biotechnology 2014, 89: 471-474.

29. Zhu, X. P.; Hatzell, M. C.; Cusick, R. D.; Logan, B. E. Microbial reverse-electrodialysis chemical-production cell for acid and alkali production. Electrochemistry Communications 2013, 31, 52-55.

30. Zhu, X. P.; Logan, B. E. Using single-chamber microbial fuel cells as renewable power sources for electro-Fenton treatment of organic pollutants. Journal of Hazardous Materials 2013, 252-253, 198-203.

31. Zhu, X. P.; Tokash, J. C.; Hong, Y. Y; Logan, B.E. Controlling the occurrence of power overshoot by adapting microbial fuel cells to high anode potentials. Bioelectrochemistry 2013, 90, 30-35.

32. Zhu, X. P.; Yates, M. D.; Logan, B. E. Set potential regulation reveals additional oxidation enzyme peaks of Geobacter sulfurreducens anodic biofilms. Electrochemistry Communications 2012, 22, 116-119.

33. Zhu, X. P.; Ni, J. R.; Wei, J. J.; Xing, X.; Li, H. N.; Jiang, Y. Scale-up of B-doped diamond anode system for electrochemical oxidation of phenol simulated wastewater in batch mode. Electrochimica Acta 2011, 56, 9437-9447.

34. Zhu, X. P.; Ni, J. R. The improvement of boron-doped diamond anode system in electrochemical degradation of p-nitrophenol by zero-valent iron. Electrochimica Acta 2011, 56, 10371-10377.

35. Zhu, X. P.; Ni, J. R.; Xing, X.; Li, H. N.; Jiang, Y. Synergies between electrochemical oxidation and activated carbon adsorption in three-dimensional boron-doped diamond anode system. Electrochimica Acta 2011, 56, 1270-1274.

36. Zhu, X. P.; Ni, J. R.; Wei, J. J.; Xing, X.; Li, H. N.; Jiang, Y. Destination of organic pollutants during electrochemical oxidation of biologically-pretreated dye wastewater using boron-doped diamond anode. Journal of Hazardous Materials 2011, 189, 127-133.

37. Zhu, X. P.; Ni, J. R.; Li, H. N.; Jiang, Y.; Xing, X.; Borthwick, A. Effects of ultrasound on electrochemical oxidation mechanisms of p-substituted phenols at BDD and PbO2 anodes. Electrochimica Acta 2010, 55, 5569-5575.

38. Zhu, X. P.; Ni, J. R.; Wei, J. J.; Xing, X.; Li, H. N.; Jiang, Y. Scale-up of BDD anode system for electrochemical oxidation of phenol simulated wastewater in continuous mode. Journal of Hazardous Materials 2010, 184, 493-498.

39. Zhu, X. P.; Ni, J. R. Simultaneous processes of electricity generation and p-nitrophenol degradation in a microbial fuel cell. Electrochemistry Communications 2009, 11, 274-277.

40. Zhu, X. P.; Ni, J. R.; Lai P. Advanced treatment of biologically pretreated coking wastewater by electrochemical oxidation using boron-doped diamond electrodes. Water Research 2009, 43, 4347-4355.

41. Zhu, X. P.; Tong, M. P.; Shi, S. Y.; Zhao, H. Z.; Ni, J. R. Essential explanation of the strong mineralization performance of boron-doped diamond electrodes. Environmental Science & Technology 2008, 42, 4914- 4920.

42. Zhu, X. P.; Shi, S. Y.; Wei, J. J.; Lv, F. X.; Zhao, H. Z.; Kong, J. T.; He, Q.; Ni, J. R. Electrochemical oxidation characteristics of p-substituted phenols using a boron-doped diamond electrode. Environmental Science & Technology 2007, 41, 6541-6546.