劉媛媛(南京大學地球科學與工程學院副教授)

劉媛媛,女,博士,南京大學地球科學與工程學院副教授。

基本介紹

  • 中文名:劉媛媛 
  • 畢業院校:美國伊利諾伊大學
  • 學位/學歷:博士
  • 專業方向:環境工程
  • 任職院校:南京大學
人物經歷,教育背景,工作經歷,研究方向,科研項目,獲獎情況,主要論著,

人物經歷

教育背景

2007-2012 美國伊利諾伊大學香檳分校 環境工程博士
2002-2005 中國科學院生態環境研究中心 環境工程碩士
1998-2002 南京大學 環境科學學士

工作經歷

2017-至今 南京大學地球科學與工程學院 副教授
2013-2017 美國西北太平洋國家實驗室 地球化學博士後
2005-2007 四川電力設計諮詢有限責任公司 助理工程師

研究方向

重金屬、碳、氮、鐵元素的生物地球化學過程
土壤和地下水污染及修復過程中的生物地球化學機制
分子生物學、原位觀測技術、多尺度流體反應器和數值模擬在地下環境污染物反應-遷移中的套用

科研項目

(2)國家自然科學基金面上項目,土壤-地下水環境微生物群落對鉻遷移轉化的影響機制和模型研究,2018-2021,在研,主持
(1)美國地質勘探局(USGS), Illinois State Water Resources Research Institute Program, Attachment and transport mechanisms of Cryptosporidium parvumoocysts in subsurface environments: A multi-scale study, 2009-2010,已結題,共同主持

獲獎情況

2017年第十三批中組部
2011年美國化學會環境化學全美研究生獎(ACS Graduate Student Award in Environmental Chemistry)
2010年美國伊利諾伊大學Chester P. Siess獎

主要論著

(25) Yang C., Zheng F., Liu Y., Zhang Y., Liu W., Zhang Q., Yang X.†“Modeling hydro-biogeochemical transformation of chromium in hyporheic zone: Effects of spatial and temporal resolutions” Journal of Hydrology, 2019, 579: 124152.
(24) Zhou C., Liu Y., Liu C., Liu Y., Tfaily M. “Compositional Changes of Dissolved Organic Carbon during its Dynamic Desorption from Hyporheic Zone Sediments” Science of The Total Environment, 2019, 658: 16-23.
(23) Yang C., Zhang Y., Liu Y., Yang X., Liu C.†, “Model-Based Analysis of the Effects of Dam-Induced River Water and Groundwater Interactions On Hydro-Biogeochemical Transformation of Redox Sensitive Contaminants in a Hyporheic Zone”, Water Resources Research, 2018, 54: 5973-5985.
(22) Nelson K. L.†, Boehm A. B., Davies-Colley. R. J., Dodd M. C., Kohn T., Linden K. G., Liu Y., Maraccini P. A., McNeill K., Mitch W. A., Nguyen T. H., Parker K. M., Rodriguez R. A., Sassoubre L. M., Silverman A. I., Wigginton K. R., and Zepp R. G. “Sunlight-mediated Inactivation of Health-relevant Microorganisms in Water: A Review of Mechanisms and Modeling Approaches”, Environmental Science: Processes & Impacts, 2018, 20: 1089-1122.
(21) Huang K., Liu Y., Yang C., Duan Y., Liu C.†, “Identification of Hydro-Biogeochemical Processes Controlling Seasonal Variations in Arsenic Concentrations within a Riverbank Aquifer at Jianghan Plain, China”, Water Resources Research, 2018, 54: 4294-4308.
(20) Xu F., Liu Y.*, and Liu C.†, “A Generalized-Rate Model for Describing and Scaling Redox Kinetics in Sediments Containing Variable Redox-Reactive Materials”, Environmental Science & Technology, 2018, 52(9), 5268-5276.
(19) Yan A., Liu C.†, Liu Y., and Xu F., “Effect of Ion Exchange on the Rate of Aerobic Microbial Oxidation of Ammonium in Hyporheic Zone Sediments”, Environmental Science and Pollution Research, 2018, 25: 8880-8887.
(18) Liu Y., Liu C.†, Nelson W., Liang S., Xu F., Liu Y., Yan A., Zhong L., Thompson C., Fredrickson J., and Zachara J., “Effect of Water Chemistry and Hydrodynamics on Nitrogen Transformation Activity and Microbial Community Functional Potential in Hyporheic Zone Sediment Columns”, Environmental Science & Technology, 2017, 51(9), 4877-4886.
(17) Liu Y., Xu F.*, and Liu C.†, “Coupled Hydro-Biogeochemical Processes Controlling Cr Reductive Immobilization in Columbia River Hyporheic Zone”, Environmental Science & Technology, 2017, 51(3), 1508-1517. (Editor’s Choice)
(16) Xu F., Liu Y.†, Zachara J., Bowden M., Kennedy D., Plymale A., and Liu C.†, “Redox Transformation and Reductive Immobilization of Cr(VI) in the Columbia River Hyporheic Zone Sediments”, Journal of Hydrology, 2017, 555, 278-287.
(15) Yan Z., Liu C.†, Liu Y., Bailey V., “Multiscale Investigation on Biofilm Distribution and its Impact on Macroscopic Biogeochemical Reaction Rates”, Water Resources Research, 2017, 53: 8698-8714.
(14) Li M, Gao Y., Qian W., Shi L., Liu Y., Nelsonb W., Nicorab C., Resch C., Thompson C., Yan S., Fredrickson J., Zacharab J., and Liu C.†, “Targeted Quantification of Functional Enzyme Dynamics in Environmental Samples for Microbially Mediated Biogeochemical Processes”, Environmental Microbiology Reports, 2017, 9(5): 512-521.
(13) Yan Z., Liu C.†, Todd-Brown K. E., Liu Y., Bond-Lambert B., Bailey V., “Pore-scale Investigation on the Response of Heterotrophic Respiration to Moisture Conditions in Heterogeneous Soils”, Biogeochemistry, 2016, 131(1): 121-134.
(12) Yan S., Liu Y., Liu C.†, Shi L., Shang J., Shan H., Zachara J., Fredrickson J., Kennedy D., Resch C., Thompson C. and Fansler S., “Nitrate Bioreduction in Redox-Variable Low Permeability Sediments”, Science of the Total Environment, 2016, 539: 185-195.
(11) Liu Y., Liu C.†, Kukkadapu R., McKinley J., Zachara J., Plymale A., Miller M., Varga T. and Resch C., “99Tc(VII) Retardation, Reduction, and Redox Rate Scaling in Naturally Reduced Sediments”, Environmental Science & Technology, 2015, 49(22): 13403-13412.
(10) Liu Y., Liu C.†, Zhang C., Yang X. and Zachara J. M., “Pore and Continuum Scale Study of the Effect of Subgrid Transport Heterogeneity on Redox Reaction Rates”, Geochimica et Cosmochimica Acta, 2015, 163: 140-155.
(9) Liu Y.†, Dong S., Kuhlenschmidt M. S., Kuhlenschmidt T. B., Drnevich J. and Nguyen, T. H.,“Inactivation Mechanisms of Cryptosporidium parvum Oocysts by Solar Ultraviolet Irradiation”,Environmental Science: Water Research & Technology, 2015, 1: 188-198.
(8) Liu C.†, Liu Y., Kerisit S. and Zachara J., “Pore Scale Process Coupling and Effective Surface Reaction Rates in Heterogeneous Subsurface Materials”, Reviews in Mineralogy and Geochemistry, 2015, 80: 191-216.
(7) Zhong, L.†, Szecsody J., Truex M., Williams M., and Liu Y., “Ammonia gas transport and reactions in unsaturated sediment: Implications for use as an amendment to immobilize inorganic contaminants”. Journal of Hazardous Material, 2015,289: 118-129.
(6) Liu Y., Zhang C., Hu D., Kuhlenschmidt M. S., Kuhlenschmidt T. B., Mylon S. E., Kong R., Bhargava, R. and Nguyen, T. H.†,“Role of Collector Alternating Charged Patches on Transport of Cryptosporidium Parvum Oocysts in a Patchwise Charged Heterogeneous Micromodel”, Environmental Science & Technology, 2013, 47(6): 2670-2678.
(5) Pan G.†, Dan W., and Liu Y., “Photocatalytic degradation pathways and adsorption modes of H-acid in TiO2suspensions”, Chinese Science Bulletin, 2012, 57(10): 1102-1108.
(4) Liu Y., Zhang C., Hilpert M., Kuhlenschmidt M. S., Kuhlenschmidt T. B. and Nguyen, T. H.†, “Transport of Cryptosporidium Parvum Oocysts in a Silicon Micromodel”, Environmental Science & Technology, 2012, 46(3): 1471-1479.
(3) Liu Y., Kuhlenschmidt M. S., Kuhlenschmidt T. B. and Nguyen, T. H.†,“Composition and Conformation of Cryptosporidium Parvum Oocysts WallSurface Macromolecules and Their Effect on Adhesion Kinetics of Oocysts on Quartz Surface”, Biomacromolecules,2010, 11(8): 2109-2115.
(2) Janjaroen D., Liu Y., Kuhlenschmidt M. S., Kuhlenschmidt T. B. and Nguyen, T. H.†,“Role of Divalent Cations on Deposition Kinetics of Cryptosporidium parvum Oocysts on Natural Organic Matter Surfaces”,Environmental Science & Technology, 2010, 44(12): 4519-4524.
(1) Liu Y., Janjaroen D., Kuhlenschmidt M. S., Kuhlenschmidt T. B. and Nguyen, T. H.†,“Deposition of Cryptosporidium ParvumOocysts on Natural Organic Matter Surfaces: Microscopic Evidence for Secondary Minimum Deposition in a Radial Stagnation Point Flow Cell”, Langmuir, 2009, 25: 1594-1605.

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