馬杰,教授,、博士生導師,,現(xiàn)就職于中國石油大學(北京)化學工程與環(huán)境學院,同時為重質(zhì)油國家重點實驗室固定成員,。2009年本科畢業(yè)于北京大學環(huán)境科學專業(yè),,2011年碩士畢業(yè)于美國Rice University環(huán)境工程專業(yè),2013年博士畢業(yè)于美國Rice University環(huán)境工程專業(yè),,導師為Pedro Alvarez教授(美國工程院院士,、中國工程院外籍院士)。馬杰教授長期聚焦于“污染場地風險評估與修復”方面的研究,,獨立出版了國內(nèi)首部有關VOCs污染場地治理的學術專著《污染場地VOCs蒸氣入侵風險評估與管控》,,發(fā)表論文第一/通訊作者SCI論文35篇,包括7篇Environmental Science & Technology和3篇Water Research,,1篇論文入選ESI高引論文,,1篇期刊封面論文。另外還合作編寫本科生教材1部,、英文學術專著1章,。擔任《Petroleum Science》和《Water Environmental Research》青年編輯,《Geofluids》客座編輯,。除基礎研究以外,,還參與了國內(nèi)多個污染場地的調(diào)查評估研究工作,并參與多項場地國家標準(HJ標準)的制定,,擔任十余個省市生態(tài)環(huán)境的土壤污染防治專家?guī)斐蓡T,。先后獲得環(huán)境保護科學二等獎技術獎(第二完成人)(2021年),北京市科技新星(2018年),,校優(yōu)秀青年學者(2022),、校青年拔尖人才(2014年)等獎項。
郵箱:[email protected]
【教育經(jīng)歷】
2011-2013 美國Rice University 環(huán)境工程博士 導師:Pedro Alvarez院士
2009-2011 美國Rice University 環(huán)境工程碩士 導師:Pedro Alvarez院士
2005-2009 北京大學 環(huán)境學院 環(huán)境科學學士
【工作經(jīng)歷】
2021-至今 中國石油大學 教授
2015-2021 中國石油大學 副教授
2014-2015 中國石油大學 講師
2013-2014 美國Rice University 博士后
【教學工作】
環(huán)境微生學物(本科生)
環(huán)境生物工程(研究生)
生產(chǎn)實習(本科生)
認知實習(本科生)
高等儀器分析(研究生全英文課)
環(huán)境科學與工程前沿講座(研究生)
【研究領域】
l 污染場地調(diào)查與風險評估
l 污染場地修復與風險管控
l VOCs在土壤地下水環(huán)境中的遷移轉(zhuǎn)化歸趨
l VOCs蒸氣入侵調(diào)查評估
l 監(jiān)控自然衰減與強化自然衰減
l 化學氧化耦合生物修復
l 多相抽提,、氣相抽提與生物通風,、地下水曝氣與生物曝氣
【研究項目】
主持縱向課題9項(國家級3項,省部級2項),,橫向課題10項
1. 國家自然科學基金面上項目(42177042),,石油污染場地氣相自然衰減機理研究與評估方法構建,2022/1-2025/12,,74.1萬,,在研,主持
2. 國家自然科學基金面上項目(21878332),過硫酸鹽化學氧化-強化生物降解耦合修復石油污染土壤研究,,2019/1-2022/12,,79.2萬,在研,,主持
3. 國家自然科學基金青年項目(21407180),,基于柱實驗和數(shù)值模型模擬研究土壤氣體對流對于蒸汽入侵過程的影響,2015/1-2017/12,,25萬,,已結題,主持
4. 北京市科學技術委員會 北京市科技新星人才計劃(Z181100006218088),,ISCO化學氧化耦合生物強化修復藥劑配方開發(fā)及機理研究,,2018/1-2020/12,35萬,,已結題,,主持
5. 中石油科技創(chuàng)新基金(2018D-5007-0607),石油污染土壤化學氧化耦合生物修復的理論探索及技術開發(fā),,2018/7-2020/6,,18萬,已結題,,主持
6. 中國石油大學(北京)優(yōu)秀青年學者人才基金(2462022QNXZ006),,近自然的石油污染物含水層修復方法研究,2022/6-2024/12,,20萬,,在研,主持
7. 中國石油大學(北京)青年拔尖人才基金(2462014YJRC016),,汽油中新型有機污染物蒸汽入侵風險的模擬研究,,2015/1-2017/12,40萬,,已結題,,主持
8. 中國石油大學(北京)學院自主課題(2462022YXZZ011),,石油污染物場地本源修復技術研究,,2022/1-2022/12,20萬,,在研,,主持
9. 石油石化污染物控制與處理國家重點實驗室開放課題(PPC2019019),煉化場地難降解有機物的非生物自然衰減途徑研究,,2020/1-2021/12,,15萬,已結題,主持
【獲得獎勵】
人才稱號
1. 2021年獲中國石油大學優(yōu)秀青年學者(A崗)
2. 2021年獲Water Environment Research New Engineer to Watch (全球共11人入選)
3. 2017年獲北京市科技新星
4. 2014年獲中國石油大學青年拔尖人才(A崗)
會議/論文獎勵
1. 2021年獲得環(huán)境保護科學技術二等獎(第二完成人)
2. 2018年獲國家自然基金委第八屆化工青年學者交流會最佳報告獎
3. 2017年獲國家自然基金委第三屆地下水青年科學論壇最佳口頭報告獎
4. 2012年獲第八屆Battelle Chlorinated Conference最佳論文獎
5. 2012年獲Texas Water年會最佳論文獎
6. 2011年發(fā)表在《Ground Water Monitoring & Remediation》上的論文被選為期刊封面論文
【學術兼職】
1. 《Water Environment Research》青年編輯
2. 《Petroleum Science》青年編輯
3. 《Geofluids》客座編輯
【社會兼職】
北京,、重慶,、廣東、山東,、山西,、河北、遼寧,、吉林,、深圳、青島土壤污染防治專家?guī)斐蓡T
【論文著作】
學術專著
馬杰(2020) 《污染場地VOCs蒸氣入侵風險評估與管控》科學出版社北京54萬字
第一或通訊作者(*為通訊作者)
1. Ma, J., Rixey, W. G., and Alvarez, P.J.* (2013) Microbial processes influencing the transport, fate and groundwater impacts of fuel ethanol releases. Current Opinion in Biotechnology 24(3): 457-466.(SCI, EI, IF 8.288)
2. Ma, J.*, McHugh, T., Beckley, L., DeVaull, G., Lahvis, M., and Jiang, L. (2020) Vapor intrusion investigations and decision-making: A critical review. Environmental Science & Technology 54(12): 7050-7069.(SCI, EI, IF 7.864)
3. Ma, J., McHugh, T.*, Eklund, B. (2020) Flux chamber measurements should play a more important role in contaminated site management. Environmental Science & Technology 54(19): 11645-11647.(SCI, EI, IF 7.864)
4. Zhang, R., Jiang, L.*, Zhong, M.*, Han, D., Zheng, R., Fu, Q., Zhou, Y.* and Ma, J.*(2019) Applicability of soil concentration for VOC-contaminated site assessments explored using field data from the Beijing-Tianjin-Hebei urban agglomeration. Environmental Science & Technology 53(2): 789-797.(SCI, EI, IF 7.864)
5. Ma, J. *, Jiang, L.*, Lahvis, M. * (2018) Vapor intrusion management in China: lessons learned from the United States. Environmental Science & Technology 52(6): 3338-3339(SCI, EI, IF 7.864)
6. Yao, Y., Wu, Y., Wang, Y., Verginelli, I., Zeng, T., Suuberg, E.M., Jiang, L., Wen, Y.*, Ma, J.*, (2015) A petroleum vapor intrusion model involving upward advective soil gas flow due to methane generation. Environmental Science & Technology 49(19): 11577-11585.(SCI, EI, IF 7.864)
7. Ma, J., Luo, H., DeVaull, G.E., Rixey, W.G., and Alvarez, P.J.* (2014) Numerical model investigation for methane explosion and benzene vapor intrusion potential associated with ethanol-blended fuel releases. Environmental Science & Technology 48(1): 474-481.(SCI, EI, IF 7.864)
8. Ma, J., Rixey, W. G., DeVaull, G. E., Stafford, B. P., and Alvarez, P. J.* (2012) Methane bioattenuation and implications for explosion risk reduction along the groundwater to soil surface pathway above plume of dissolved ethanol. Environmental Science & Technology 46(11): 6013-6019.(SCI, EI, IF 7.864)
9. Ma, Y., Feng, Y, Feng, Y.L., Liao, G.M., Sun, Y., Ma, J.*(2020) Characteristics and mechanisms of controlled-release KMnO4 for groundwater remediation: experimental and modeling investigations. Water Research 171: 115385.(SCI, EI, IF 9.13)
10. Ma, J.*, Nossa, Carlos W., and Alvarez, P.J. (2015) Groundwater ecosystem resilience to organic contaminations: microbial and geochemical dynamics throughout the 5-year life cycle of a surrogate ethanol blend fuel plume. Water Research 80: 119-129.(SCI, EI, IF 9.13)
11. Ma, J., Rixey, W.G., and Alvarez, P.J.*, (2015) Increased fermentation activity and persistent methanogenesis in a model aquifer system following source removal of an ethanol blend release. Water Research 68: 479-486.(SCI, EI, IF 9.13)
12. Ma, J., Yang, X., Jiang, X., Wen, J., Li, J., Zhong, Y., Chi, L. and Wang, Y.* (2020) Percarbonate persistence under different water chemistry conditions. Chemical Engineering Journal, 389: 123422(SCI, EI, IF 10.652)
13. Ma, J.*, Xiong, D., Li, H., Ding, Y., Xia, X., Yang, Y., (2017) Vapor intrusion risk of fuel ether oxygenates methyl tert-butyl ether (MTBE), tert-amyl methyl ether (TAME) and ethyl tert-butyl ether (ETBE): A modeling study. Journal of Hazardous Materials 332: 10-18(SCI, EI, IF 9.038)
14. Ma, J.*, Yan, G.*, Li, H., Guo, S. (2016) Sensitivity and uncertainty analysis for Abreu & Johnson numerical vapor intrusion model. Journal of Hazardous Materials 304: 522-531.(SCI, EI, IF 9.038)
15. Ma, J.*#, Li, H.#, Spiese, R., Wilson, J., Guo, S., and Yan, G. (2016) Vapor intrusion risk of lead scavengers 1,2-dibromoethane (EDB) and 1,2-dichloroethane (DCA). Environmental Pollution 213: 825-832.(SCI, EI, IF 6.793)
16. Ma, J., Deng Y., Yuan T., Zhou J., and Alvarez, P.J.* (2015) Succession of microbial functional communities in response to a pilot-scale ethanol-blended fuel release throughout the plume life cycle. Environmental Pollution 198: 154-160.(SCI, EI, IF 6.793)
17. Ma, J., Nossa, Carlos W., Xiu, Z.M., Rixey, W.G., and Alvarez, P.J.* (2013) Adaptive microbial population shifts in response to continuous ethanol blend release increases biodegradation potential. Environmental Pollution 178: 419-425.(SCI, EI, IF 6.793)
18. Ma, J.*, Xie, X., Ma, Y., Luo, Y., Zhong, Y., (2018) Stability of dissolved percarbonate and its implications for groundwater remediation. Chemosphere 205:41-44.(SCI, EI, IF 5.778)
19. Ma, J.*, Yang, Y., Jiang, X., Xie, Z., Li, X., Chen, C., Chen, H., (2018) Impacts of inorganic anions and natural organic matter on thermally activated persulfate oxidation of BTEX in water. Chemosphere 190:296-306.(SCI, EI, IF 5.778)
20. Ma, J.*, Li, H., Chi, L.,(2018) Response to the comments on ‘‘Changes in activation energy and kinetics of heat-activated persulfate oxidation of phenol in response to changes in pH and temperature’’ by Ma, J., Li, H., Chi, L., Chen, H., & Chen, C. [Chemosphere 189 (2017) 86–93]. Chemosphere 194:403-404.(SCI, EI, IF 5.778)
21. Ma, J.*, Li, H., Chi, L., Chen, H., Chen, C.,(2017) Changes in activation energy and kinetics of heat-activated persulfate oxidation of phenol in response to changes in pH and temperature. Chemosphere 189:86-93.(SCI, EI, IF 5.778)
22. Ma, J., Yang, Y., Dai, X., Chen, Y., Deng, H., Zhou, H., Guo, S., Yan, G.*, (2016) Effects of adding bulking agent, inorganic nutrient and microbial inocula on biopile treatment for oil-field drilling waste. Chemosphere 150:17-23.(SCI, EI, IF 5.778)
23. Ma, J.*, Ma, Y., Rong, X., Song, Q., Wu, B., Lan, X., Feng, Y., Qiu, X. and Zhang, P. (2021) Persulfate-based controlled release beads for in situ chemical oxidation of common organic pollutants. Journal of Environmental Chemical Engineering 9(5), 105627. (SCI, EI, IF 5.909)
24. Cai, B.#, Ma, J.#, Yan, G.*, Dai, X., Li, M. and Guo, S. (2016) Comparison of phytoremediation, bioaugmentation, and natural attenuation for remediating saline soil contaminated by heavy crude oil. Biochemical Engineering Journal 112:170-177.(SCI, EI, IF3.475)
25. Sun, Y., Ma, J.*, Yue, G.., Liu, S., Liu, H., Song, Q., and Wu, B. (2021) Comparisons of four methods for measuring total petroleum hydrocarbons and short-term weathering effect in soils contaminated by crude oil and fuel oils. Water Air and Soil Pollution 239(9): 381 (SCI, EI, IF 1.9)
26. Ma, J., Yang, Y., Dai, X., Li, C., Chen, C., Wang, Q., Yan, G.*and Guo, S. (2016) Bioremediation enhances the pollutant removal efficiency of soil vapor extraction (SVE) in treating petroleum drilling waste. Water Air and Soil Pollution 227(12): 465.(SCI, EI, IF 1.9)
27. Ma, J., Yan, G.*, Ma, W., Cheng, C., Wang, Q., Guo, S. (2015) Isolation and characterization of oil-degrading microorganisms for bench-scale evaluations of autochthonous bioaugmentation for soil remediation. Water Air and Soil Pollution 226(8): 1-10.(SCI, EI, IF 1.9)
28. Ma, J.*, and Matt, L.(2020) Rationale for Soil Gas Sampling to Improve Vapor Intrusion Risk Assessment in China. Ground Water Monitoring & Remediation 40(1): 12-13.(SCI, EI, IF 1.283)
29. Ma, J., Xiu, Z.M., Monier, A.L., Mamonkina, I., Zhang, Y., He, Y.Z., Stafford, B.P., Rixey, W.G., and Alvarez, P.J.* (2011) Aesthetic groundwater quality impacts from a continuous pilot-scale release of an ethanol blend. Ground Water Monitoring & Remediation 31(3): 47-54.(SCI, EI, IF 1.283)
30. Ma, J.*, Ding, Y., Gu, C., Zhai, G., Liu, Y., Wen, J., Rong, X., Luo, C., Qiu, Y., and Zhang, P.* (2021) Degradation of benzothiazole pollutant by sulfate radical-based advanced oxidation process. Environmental Technology DOI: 10.1080/09593330.2021.1906326(SCI, EI, IF 2.213)
31. Ma, J.*, Ding, Y., Chi, L., Yang, X., Zhong, Y., Wang, Z. and Shi, Q. (2021) Degradation of benzotriazole by sulfate radical-based advanced oxidation process. Environmental Technology, 42(2): 238-247(SCI, EI, IF 2.213)
32. Ma, J.*, Feng, Y., Yang, X., Wu, Y., Wang, S., Zhang, C. and Shi, Q. (2020) Sulfate radical oxidation of benzophenone: Kinetics, mechanisms and influence of water matrix anions. Environmental Technology, DOI: 10.1080/09593330.2020.1756422(SCI, EI, IF 2.213)
33. Yan, G., Ma, W., Chen, C., Wang, Q., Guo, S., Ma, J.*(2016) Combinations of surfactant flushing and bioremediation for removing fuel hydrocarbons from contaminated soil. CLEAN – Soil, Air, Water 44(8): 984-991.(SCI, EI, IF 1.603)
34. Ma, J.*, Li H., Yang Y. and Li X. (2018) Influence of water matrix species on persulfate oxidation of phenol: reaction kinetics and formation of undesired degradation byproducts. Water Science and Technology, 2017(2):340-350, DOI:10.2166/wst.2018.147(SCI, EI, IF 1.638)
35. 馬杰* (2020) 污染場地土壤氣被動采樣技術研究進展 環(huán)境科學研究, 33(2), 494-502
36. 廖高明, 馬杰*, 谷春云, 杜顯元, 宋權威 (2021) 污染場地土壤氣被動采樣技術研究進展 環(huán)境科學研究, 34(3), 231-243
37. 馬杰* (2021) 我國揮發(fā)性有機污染地塊調(diào)查評估中存在的問題及對策建議 環(huán)境工程學報, 15(1), 3-7
38. 馬杰* (2021) 土壤氣監(jiān)測在污染地塊調(diào)查評估中的優(yōu)勢,、局限及解決思路 環(huán)境工程學報, 15(8), 2531-2534
39. 馬杰* (2022) 地下水監(jiān)測在污染場地管理中的重要作用、存在問題與對策建議 環(huán)境工程學報, 16(4), 1063-1067
其他作者論文
40. Liu, J.-W., Wei, K.-H., Xu, S.-W., Cui, J., Ma, J., Xiao, X.-L., Xi, B.-D. and He, X.-S. (2021) Surfactant-enhanced remediation of oil-contaminated soil and groundwater: A review. Science of The Total Environment 756, 144142
41. Garcia-Segura, S., Qu, X.L., Alvarez, P.J.J., Chaplin, B.P., Chen, W., Crittenden, J.C., Feng, Y.J., Gao, G.D., He, Z., Hou, C.H., Hu, X., Jiang, G.B., Kim, J.H., Li, J.S., Li, Q.L., Ma, J., Ma, J.X., Nienhauser, A.B., Niu, J.F., Pan, B.C., Quan, X., Ronzani, F., Villagran, D., Waite, T.D., Walker, W.S., Wang, C., Wong, M.S. and Westerhoff, P. (2020) Opportunities for nanotechnology to enhance electrochemical treatment of pollutants in potable water and industrial wastewater - a perspective. Environmental Science-Nano 7(8), 2178-2194. (SCI, IF7.704)
42. Zhang, T., Lowry, G.V., Capiro, N.L., Chen, J., Chen, W., Chen, Y., Dionysiou, D.D., Elliott, D.W., Ghoshal, S., Hofmann, T., Hsu-Kim, H., Hughes, J., Jiang, C., Jiang, G., Jing, C., Kavanaugh, M., Li, Q., Liu, S., Ma, J., Pan, B., Phenrat, T., Qu, X., Quan, X., Saleh, N., Vikesland, P.J., Wang, Q., Westerhoff, P., Wong, M.S., Xia, T., Xing, B., Yan, B., Zhang, L., Zhou, D. and Alvarez, P.J.J. (2019) In situ remediation of subsurface contamination: opportunities and challenges for nanotechnology and advanced materials. Environmental Science-Nano 6(5), 1283-1302.(SCI, IF7.704)
43. Zhang R., Jiang L., Zhong M., DeVaull G, Lahvis M, Ma J., Zhou Y., Zheng R., Fu Q. (2019) A source depletion model for vapor intrusion involving the influence of building characteristics. Environmental Pollution 2019;246:864-72.(SCI, IF 4.358)
44. Dong, H., Song, Z., Dong, H., Wang, W., Wang, J., Sun, S., Zhang, Z*,Ke, M., Zhang, Z., Wu, W., Ma, J., (2018) A high-efficiency denitrification bioreactor for the treatment of acrylonitrile wastewater using waterborne polyurethane immobilized activated sludge. Bioresource Technology 239: 472-481(SCI, IF 5.651)
45. Verginelli, I., Yao, Y.*, Wang, Y., Ma, J.Suuberg, E.M. (2016) Estimating the oxygenated zone beneath building foundations for petroleum vapor intrusion assessment Journal of Hazardous Materials312: 84-96.(SCI, IF6.065)
46. Da Silva,* M.; Cant?o, M.; Mezzari, M.; Ma, J.; and Nossa, C. (2015) Assessment of bacterial and archaeal community structure in swine wastewater treatment processes. Microbial Ecology70(1):77-87.(SCI, IF 3.63)
47. Xiu, Z.M., Ma, J., and Alvarez, P.J.*(2011) Differential effect of common ligands and molecular oxygen on antimicrobial activity of silver nanoparticles versus silver ions. Environmental Science & Technology45(20): 9003-9008.(SCI, IF 6.198)
48. 盧曉霞*, 李秀利, 馬杰, 吳淑可, 陳超琪, 吳蔚(2011)焦化廠多環(huán)芳烴污染土壤的強化微生物修復研究, 環(huán)境科學, 32: 864-869.(中文核心期刊)
其他作者著作
49. 郭春梅,,趙朝成,,陳進富,詹亞力,,陳春茂,,孔繁鑫,羅一菁,,馬杰,,(2018)《環(huán)境工程概論》,中國石油大學出版社,,ISBN9787563659920
50. Da Silva, M., Ma, J., Alvarez, P.J.*(2015) Methods to assess the fate and impacts of biofuels in aquifer systems, in: McGenity, T.J., Timmis, K.N., Nogales, B. (Eds.), Hydrocarbon and Lipid Microbiology Protocols DOI:10.1007/8623_2015_164(英文專著)
