姓名	張芳
單位	地下水與土壤環(huán)境教研所
職稱	副教授、博導
辦公地址	清華大學中意環(huán)境節(jié)能樓707
電話/傳真	010-62789655
電子郵箱	fangzhang@tsinghua.edu.cn
個人主頁	http://www.fangzhangthu.com

 

教育背景

2008.8-2012.8 美國賓夕法尼亞州立大學土木與環(huán)境工程系，環(huán)境工程專業(yè)，博士

2008.8-2010.5 美國賓夕法尼亞州立大學土木與環(huán)境工程系，環(huán)境工程專業(yè)，碩士

2006.8-2008.7 清華大學經(jīng)濟管理學院，經(jīng)濟學專業(yè)，第二學士

2004.8-2008.7 清華大學環(huán)境學院，環(huán)境工程專業(yè)，學士

工作履歷

2017.7-今          清華大學環(huán)境學院，副教授

2015.6-2017.7   清華大學環(huán)境學院，助理教授

2015.1-2015.6   清華大學環(huán)境學院，訪問學者

2012.8-2014.11 美國賓夕法尼亞州立大學土木與環(huán)境工程系，博士后研究員？？

學術兼職

國際微生物電化學技術協(xié)會（ISMET，2012至今）、美國化學協(xié)會（ACS，2010至今）、環(huán)境科學與工程教授協(xié)會（AEESP，2010至今）、國際水協(xié)（IWA，2016至今）會員

Environmental Science & Technology, Energy & Environmental Science, Angewandte Chemie, ES&T Letters, Journal of Power Sources, Bioresource Technology, Electrochemistry Communications, Bioelectrochemistry等20余部期刊審稿人

 

研究領域

地下水電化學修復

劣質(zhì)地下水資源化

微生物電化學技術

研究概況

1.污染場地安全修復技術國家工程實驗室開放基金，電場遷移-電阻加熱相協(xié)同的原位修復體系構建研究，2018/01-2019/12，主持

2.國家自然科學基金面上項目，基于能量耦合的低滲透介質(zhì)氯代烴電化學修復的體系建立和機制研究，2017/01-2020/12，主持

3.國家重點研發(fā)計劃政府間國際科技創(chuàng)新合作重點專項，原位熱修復技術在污染場地土壤修復中的應用，2016/12-2019/12，子課題負責人

4.清華大學自主科研計劃，地下水氯代烴氧化-礦化的電化學協(xié)同反應過程與體系研究，2015/10-2018/9，主持

5.環(huán)境模擬與污染控制國家重點聯(lián)合實驗室（清華大學）2015年度自由探索課題，基于電化學的氧化-吸附協(xié)同去除地下水中砷的機制研究，2015/7-2017/6，主持

 

(課題組長期招收本科、碩士及博士生。有意者請將簡歷發(fā)至fangzhang@tsinghua.edu.cn。)

獎勵與榮譽

 

入選中國科協(xié)“青年人才托舉工程”，2015

入選清華大學骨干人才支持計劃，2015

Environmental Science & Technology Letters Excellence in Review Award, 2015

Journal of Power Sources Outstanding Reviewer Status, 2015？

國家優(yōu)秀自費留學生獎學金，2011

美國化學協(xié)會環(huán)境化學學部優(yōu)秀研究生，2011

美國化學協(xié)會環(huán)境化學學部優(yōu)秀口頭報告，2010

清華大學優(yōu)良本科畢業(yè)生, 2008

國家獎學金（清華大學綜合一等獎學金），2007

匯豐銀行獎學金（清華大學綜合一等獎學金）, 2006

清華大學環(huán)境學院體育之星，2006

嘉里糧油獎學金（清華大學綜合二等獎學金）, 2005

清華大學環(huán)境學院優(yōu)秀本科生，2005

學術成果

期刊文章

1.Yang, J.; Li, G.; Qian, Y.; Zhang, F.*, Increased soil methane emissions and methanogenesis in oil contaminated areas. Land Degradation & Development, 2018, in press. (IF 9.787)

2.Rahimi, M.; Straub, A. P.; Zhang, F.; Zhu, X.; Elimelech, M.; Gorski, C.; Logan, B. E., Emerging electrochemical and membrane-based systems to convert low-grade heat to electricity. Energy Environ. Sci. 2018, in press. (IF 29.518)

3.Zhang, H.; Wan, X.; Li, G.; Zhang, F.*, A three-electrode electro-Fenton system supplied by self-generated oxygen with automatic pH-regulation for groundwater remediation. Electrochimica Acta 2017, 250, 42-48. (IF 4.798)

4.Si, Y.; Li, G.*; Zhang, F.*, Energy-Efficient Oxidation and Removal of Arsenite from Groundwater Using Air-Cathode Iron Electrocoagulation. Environ. Sci. Technol. Lett. 2017, 4, (2), 71-75. (IF 5.308)

5.Sun, D.; Cheng, S.; Zhang, F.; Logan, B. E., Current density reversibly alters metabolic spatial structure of exoelectrogenic anode biofilms. J. Power Sources 2017, 356, 566-571. (IF 6.395)

6.Rahimi, M.; Schoener, Z.; Zhu, X.; Zhang, F.; Gorski, C. A.; Logan, B. E., Removal of copper from water using a thermally regenerative electrodeposition battery. J. Hazard. Mater. 2017, 322, 551-556. (IF 6.065)

7.Jiang, J.; Li, G.; Li, Z.; Zhang, X.; Zhang, F.*, An Fe–Mn binary oxide (FMBO) modified electrode for effective electrochemical advanced oxidation at neutral pH. Electrochimica Acta 2016, 194, 104-109. (IF 4.798)

8.Zhang, F.; Li, G., China released the action plan on prevention and control of soil pollution. Frontier of Environmental Science & Engineering 2016, 10(4): 19 (IF 1.716)

9.Coulon, F.; Jones, K.; Li, H.; Hu, Q.; Gao, J.; Li, F.; Chen, M.; Zhu, Y.-G.; Liu, R.; Liu, M.; Canning, K.; Harries, N.; Bardos, P.; Nathanail, P.; Sweeney, R.; Middleton, D.; Charnley, M.; Randall, J.; Richell, M.; Howard, T.; Martin, I.; Spooner, S.; Weeks, J.; Cave, M.; Yu, F.; Zhang, F.; Jiang, Y.; Longhurst, P.; Prpich, G.; Bewley, R.; Abra, J.; Pollard, S., China's soil and groundwater management challenges: Lessons from the UK's experience and opportunities for China. Environment International 2016, 91, 196-200. (IF 7.088)

10.柯杭，張芳，李廣賀，張旭；鐵源對碳熱合成磁性碳質(zhì)吸附劑的影響，環(huán)境工程學報，2016

Prior to Joining THU

11.Zhang, F.; Liu, J.; Yang, W.; Logan, B.E., A thermally regenerative ammonia-based battery for efficient harvesting of low-grade thermal energy as electrical power. Energy & Environmental Science 2015, 8, 343-3249. (IF 29.518)

12.Zhang, F.; Labarge, N.; Yang, W.; Liu, J.; Logan, B.E., Enhancing the performance of low-grade thermal energy recovery in a thermally regenerative ammonia-based battery (TRAB) using elevated temperatures. ChemSusChem 2015, 8, 1043-1048. (IF 7.226)

13.Zhang, F.; Liu, J.; Ivanov, I.; Hatzell, M.C.; Yang, W.; Ahn, Y.; Logan, B.E., Reference and counter electrode positions affect electrochemical characterization of bioanodes in microbial electrochemical systems. Biotechnology and Bioengineering 2014, 111, 1931-1939. (IF 4.481)

14.Zhang, F.; Ahn, Y.; Logan, B.E., Treating refinery wastewaters in microbial fuel cells using separator electrode assembly or spaced electrode configurations. Bioresource Technology 2014, 152, 46-52. (IF 5.651)

15.Zhang, F., Xia, X., Luo, Y., Sun, D.; Call, D., Logan, B.E., Improving startup performance with carbon mesh anodes in separator electrode assembly microbial fuel cells. Bioresource Technology 2013, 133, 74-81. (IF 5.651)

16.Zhang, F.; Chen, G.; Hickner, M.A.; Logan, B.E., Novel anti-flooding poly(dimethylsiloxane) (PDMS) catalyst binder for microbial fuel cell cathodes. Journal of Power Sources 2012, 218, 100-105. (IF 6.395)

17.Zhang, F.; Pant, D.; Logan, B.E., Long-term performance of activated carbon air cathodes with different diffusion layer porosities in microbial fuel cells. Biosensors and Bioelectronics 2011, 30, 49-55. (IF 7.780)

18.Zhang, F.; Merrill, M.D.; Tokash, J.C.; Saito, T.; Cheng, S.; Hickner, M.A.; Logan, B.E., Mesh optimization for microbial fuel cell cathodes constructed around stainless steel mesh current collectors. Journal of Power Sources 2011, 196, 1097-1102. (IF 6.395)

19.Zhang, F.; Saito, T.; Cheng, S.; Hickner, M.A.; Logan, B.E., Microbial fuel cell cathodes with poly(dimethylsiloxane) diffusion layers constructed around stainless steel mesh current collectors. Environmental Science & Technology 2010, 44, 1490-1495. (IF 6.198)

20.Zhang, F.; Cheng, S.; Pant, D.; Bogaert, G.V.; Logan, B.E., Power generation using an activated carbon and metal mesh cathode in a microbial fuel cell. Electrochemistry Communications 2009, 11, 2177-2179. (IF 4.396)

21.Liu, J.; Zhang, F.; He, W.; Yang, W.; Feng, Y.; Logan, B.E., A microbial fluidized electrode electrolysis cell for enhanced hydrogen production. Journal of Power Sources 2014, 271, 530-533. (IF 6.395)

22.Luo, X.; Zhang, F.; Liu, J.; Zhang, X.; Huang, X.; Logan, B.E., Methane production in microbial reverse-electrodialysis methanogenesis cells (MRMC) using thermolytic solutions. Environmental Science & Technology 2014, 48, 8911-8918. (IF 6.198)

23.Yang, W.; Zhang, F.; He, W.; Liu, J.; Hickner, M.A.; Logan, B.E., Poly(vinylidene fluoride-co- hexafluoropropylene) phase inversion coating as a diffusion layer to enhance the cathode performance in microbial fuel cells. Journal of Power Sources 2014, 269, 379-384. (IF 6.395)

24.Liu, J.; Zhang, F.; He, W.; Zhang, X.; Feng, Y.; Logan, B.E., Intermittent contact of fluidized anode particles containing exoelectrogenic biofilms for continuous power generation in microbial fuel cells. Journal of Power Sources 2014, 261, 278–284. (IF 6.395)

25.Ahn, Y.; Zhang, F.; Logan, B.E., Air humidity and water pressure effects on the performance of air-cathode microbial fuel cell cathodes. Journal of Power Sources 2014, 247, 655-659. (IF 6.395)

26.Yang, W.; He, W.; Zhang, F.; Hickner, M.A.; Logan, B.E., Single-step fabrication using a phase inversion method of poly(vinylidene fluoride) (PVDF) activated carbon air cathodes for microbial fuel cells. Environmental Science & Technology Letters 2014, 1, 416-420. (IF 5.308)

27.Zhang, X.; Pant, D.; Zhang, F.; Liu, J.; Logan, B.E., Long-term performance of chemically and physically modified activated carbons in microbial fuel cell air-cathodes. ChemElectroChem 2014, 1 (11), 1859-1866. (IF 4.136)

28.Ahn, Y.; Hatzell, M.C.; Zhang, F.; Logan, B.E., Different electrode configurations to optimize performance of multi-electrode microbial fuel cells for generating power or treating domestic wastewater. Journal of Power Sources 2014, 249, 440-445. (IF 6.395)

29.Ren, L.; Ahn, Y.; Hou, H.; Zhang, F.; Logan, B.E., Electrochemical study of multi-electrode microbial fuel cells under fed-batch and continuous flow conditions. Journal of Power Sources 2014, 257, 454-460. (IF 6.395)

30.Liu, J.; Geise, G.M.; Luo, X.; Hou, H.; Zhang, F.; Feng, Y.; Hickner, M.A.; Logan, B.E., Patterned ion exchange membranes for improved power production in microbial reverse-electrodialysis cells. Journal of Power Sources 2014, 271, 437-443. (IF 6.395)

31.Xia, X.; Zhang, F.; Zhang, X.; Liang, P.; Huang, X.; Logan, B.E., Use of pyrolyzed iron ethylenediaminetetraacetic acid modified activated carbon as air-cathode catalyst in microbial fuel cells. ACS Applied Materials & Interfaces 2013, 5, 7862-7866. (IF 7.504)

32.Chen, G.; Zhang, F.; Logan, B.E.; Hickner, M.A., Poly(vinyl alcohol) separators improve the coulombic efficiency of activated carbon cathodes in microbial fuel cells. Electrochemistry Communications 2013, 34, 150-152. (IF 4.396)

33.Luo, Y.; Zhang, F.; Wei, B.; Liu, G.; Zhang, R.; Logan, B.E., The use of cloth fabric diffusion layers for scalable microbial fuel cells. Biochemical Engineering Journal 2013, 73, 49-52. (IF 2.892)

34.Cusick, R.D.; Hatzell, M.C.; Zhang, F.; Logan, B.E., Minimal RED cell pairs markedly improve electrode kinetics and power production in microbial reverse electrodialysis cells. Environmental Science & Technology 2013, 47, 14518-14524. (IF 6.198)

35.Xia, X.; Tokash, J.C.; Zhang, F.; Liang, P.; Huang, X.; Logan, B.E., Oxygen-reducing biocathodes operating with passive oxygen transfer in microbial fuel cells. Environmental Science & Technology 2013, 47, 2085-2091. (IF 6.198)

36.Wei, B.; Tokash, J.C.; Zhang, F.; Kim, Y.; Logan, B.E., Electrochemical analysis of separators used in single-chamber, air-cathode microbial fuel cells. Electrochimica Acta 2013, 89, 45-51. (IF 4.798)

37.Luo, X.; Nam, J.-Y.; Zhang, F.; Zhang, X.; Liang, P.; Huang, X.; Logan, B.E., Optimization of membrane stack configuration for efficient hydrogen production in microbial reverse-electrodialysis electrolysis cells coupled with thermolytic solutions. Bioresource Technology 2013, 140, 399-405. (IF 5.651)

38.Hays, S.; Zhang, F.; Logan, B.E., Performance of two different types of anodes in membrane electrode assembly microbial fuel cells for power generation from domestic wastewater. Journal of Power Sources 2011, 196, 8293-8300. (IF 6.395)

39.Luo, Y.; Zhang, F.; Wei, B.; Liu, G.; Zhang, R.; Logan, B.E., Power generation using carbon mesh cathodes with different diffusion layers in microbial fuel cells. Journal of Power Sources 2011, 196, 9317-9321. (IF 6.395)

 

發(fā)明專利

 

40.張芳，蔣晶，李廣賀，張旭；納米鐵錳復合氧化物負載的氣體擴散電極及其制備與應用，201510080569.8

41.黃霞；王麗；梁鵬；魏錦程；夏雪；張芳；布魯斯？洛根，含氮過渡金屬微生物燃料電池催化劑及其制備方法。專利號：ZL201110021367.8