教授 博士生导师 硕士生导师
曾获荣誉 : 2015年度优秀女教职工
2017-2018年度优秀共产党员
性别 : 女
毕业院校 : 中国地质大学(武汉)
学历 : 博士研究生
学位 : 工学博士学位
在职信息 : 在职
所在单位 : 环境学院
入职时间 : 2008年07月15日
学科 : 环境工程
办公地点 : 中国地质大学(武汉)未来城校区科教四环境学院512
Email : yamin.deng@cug.edu.cn
邓娅敏,中国地质大学(武汉)环境学院教授,博士生导师, NSFC“环境水文地质”创新研究群体成员,自然资源部“劣质地下水成因与水质改良创新团队”成员,国际医学地质学协会(IMGA)中国-爱尔兰医学地质联盟秘书。完成地质调查项目成果“流域地球关键带调查与示范”荣获2019年度中国地质调查局地质科技奖二等奖(排名第三)。主要研究方向:地下水污染与防治、水岩相互作用及其环境效应。
科研项目
作为项目负责人主持的科研项目:
1. 湖北省重点研发计划项目重点项目“江汉平原四湖流域湿地-地下水系统中氮磷溯源与归趋研究”. 2021-2022. 200万元
2. 国家自然科学基金面上项目“浅层地下水系统中锰-铁-砷耦合作用机制及其对砷迁移转化的影响". (No. 41977174), 2020-2023. 61万元
3. 国家自然科学基金面上项目“高砷含水层中微生物参与下铁的氧化还原循环对砷季节性动态的控制作用”. (No. 41572226), 2016-2019. 91万元
4. 国家自然科学基金青年基金项目“地表水-地下水相互作用对江汉平原地下水砷释放的影响机制研究” (No.41102153) , 2012 -2014. 25万元
5. 湖北省环保科技项目“江汉平原典型地区地下水和土壤砷污染调查与评价研究”, 2012-2013. 40万元
6. 中央高校基本科研业务费专项摇篮计划“地下水系统生物地球化学过程及砷的季节性动态响应”(CUGL140412), 2014-2016. 40万元
7. 生物地质与环境地质国家重点实验室优先资助开放课题 “微生物介导下硫氧化还原循环对含水层中砷迁移转化的控制”(No.128-GBL21711),2017-2019. 10万元
作为技术负责或项目骨干(排名前三)参与的科研项目:
1. 中国地质调查局二级项目委托项目“洞庭湖-鄱阳湖(调关幅、白马寺幅、星子县幅、波阳县幅、三叉港幅、漉湖芦苇场幅)1:5万综合地质调查“,2019-2021. 1200万元(技术负责)
2. 中国地质调查局二级项目委托项目“海口江东新区综合地质调查红树林湿地土壤环境质量分析及评价“,2019. 275万元(技术负责)
3. 中国地质调查局二级项目“汉江下游旧口-沔阳段地球关键带1:5万环境地质调查” (No. 121201001000150121), 2016-2018. 1783万元(技术负责)
4. 科技部国家国际科技合作专项“地下水复合污染监测技术联合研发”(No.2014DFA20720) , 2014-2017. 290万元 (排名第三)
5. 中国地质调查局地质调查工作项目“江汉平原重点地区1:5万水文地质调查”(No.12120114069301) 2014-2015. 1200万元 (技术负责)
6. 国家自然科学基金国际(地区)合作与交流项目“地热流体来源砷的环境生物地球化学研究”. (No. 41120124003), 2012-2016. 310万元 (排名第三)
7. 中国地质调查局地质工作项目专题“江汉平原典型地区地下水砷污染与农药污染调查与评价研究”(No.1212011089007), 2011-2014. 490万元(技术负责)
国际学术交流报告
2007 第十二届水岩相互作用国际会议,中国昆明
2009 GSA美国地质学会年会,美国波特兰
2010 第十三届水岩相互作用国际会议, 墨西哥
2014 第十届地球表层地球化学国际会议,法国巴黎
2014 Goldschmidt国际地球化学年会,美国Sacramento
2016 GRACE-IUCES暑期学校,德国莱茵河畔
2017 第一届微生物组国际会议,中国武汉
2017 Goldschmidt国际地球化学年会,法国巴黎
2018 第七届环境中的砷国际学术会议,中国北京
2018 Goldschmidt国际地球化学年会,美国波士顿
2019 第八届医学地质学国际会议,中国贵阳
2019 第46届国际水文地质学家大会,西班牙马拉加
代表性论著 (* 通讯作者 )
1. Du, Y., Deng, Y.M. *, Liu, Z.H., Huang, Y.W., Zhao, X.W., Li, Q.H., Ma, T., Wang, Y.X. 2021. Novel insights into dissolved organic matter processing pathways in a coastal confined aquifer system with the highest known concentration of geogenic ammonium. Environmental Science & Technology, 55(21): 14676-14688.
2. Xue, J.K., Deng, Y.M. *, Luo, Y.P., Du, Y., Yang, Y.J., Cheng, Y.H., Xie, X.J., Gan, Y.Q., Wang, Y.X. 2021. Unraveling the impact of iron oxides-organic matter complexes on iodine mobilization in alluvial-lacustrine aquifers from central Yangtze River Basin. Science of the Total Environment, 151930.
3.Tao, D.Y., Shi, C.Z., Guo, W.*, Deng, Y.M., Peng, Y.E., He, Y.H., Lam, P.K.S., He, Y., Zhang, K. 2022. Determination of As species distribution and variation with time in extracted groundwater samples by on-site species separation method. Science of the Total Environment, 808:151913.
4.Gao, J., Zheng, T.L., Deng, Y.M. *, Jiang, H.C. 2021. Microbially mediated mobilization of arsenic from aquifer sediments under bacterial sulfate reduction. Science of the Total Environment, 768:144709.
5.Xiong, Y.J., Du, Y.*, Deng, Y.M., Ma, T., Li, D., Xun, X.L., Liu, G.N., Wang, Y.X. 2021. Contrasting sources and fate of nitrogen compounds in different groundwater systems in the Central Yangtze River Basin. Environmental Pollution, 290: 118119.
6.Yan, L., Xie, X.J. *, Peng, K., Wang, N.D., Zhang, Y.Y., Deng, Y.M., Gan, Y.Q., Li, Q.H., Zhang, Y.P. 2021. Sources and compositional characterization of chromophoric dissolved organic matter in a Hainan tropical mangrove-estuary. Journal of Hydrology, 600: 126572.
7.Huang, Y.W., Du, Y. *, Ma, T., Deng, Y.M., Tao, Y.Q., Xu, Y., Leng, Z.C. 2021. Dissolved organic matter characterization in high and low ammonium groundwater of Dongting Plain, central China. Ecotoxicology and Environmental Safety, 208, 111779.
8.Sun, X.L., Du, Y. *, Deng, Y.M., Fan, H.C., Tao, Y.Q., Ma, T. 2021. Contribution of groundwater discharge and associated contaminants input to Dongting Lake, Central China, using multiple tracers (222Rn, 18O, Cl−). Environmental Geochemistry and Health. 43(3): 1239-1255.
9.Zhong, X.L., Gan, Y.Q. *, Deng, Y.M. 2021. Distribution, origin and speciation of soil selenium in the black soil region of Northeast China. Environmental Geochemistry and Health, 43(3): 1257-1271.
10.Cao, H.L., Xie, X.J. *, Wang, Y.X. *, Deng, Y.M. 2021. The interactive natural drivers of global geogenic arsenic contamination of groundwater. Journal of Hydrology, 597, 126214.
11. Wang, Y.X. *, Li, J.X., Ma, T., Xie, X.J., Deng, Y.M., Gan, Y.Q. 2021. Genesis of geogenic contaminated groundwater: As, F and I. Critical Reviews in Environmental Science and Technology, 51(24): 2895-2933.
12. Yang, Y., Deng, Y.M. *, Xie, X., Gan, Y., Li, J. 2020. Iron isotope evidence for arsenic mobilization in shallow multi-level alluvial aquifers of Jianghan Plain, central China. Ecotoxicology and Environmental Safety, 206, 111120.
13. Du, Y., Deng, Y.M.,Ma, T., Xu, X., Tao, Y.Q., Huang, Y.W., Liu, R., Wang, Y.X. * 2020. Enrichment of Geogenic Ammonium in Quaternary Alluvial−Lacustrine Aquifer Systems: Evidence from Carbon Isotopes and DOM Characteristics. Environmental Science & Technology, 54:6104-6114.
14. Yang, Y.J., Yuan, X.F., Deng, Y.M. *, Xie, X.J., Gan, Y.Q., Wang, Y.X. 2020. Seasonal dynamics of dissolved organic matter in high arsenic shallow groundwater systems. Journal of Hydrology, 589:125120.
15. Tao, Y.Q., Deng, Y.M. *, Du, Y. *, Xu, Y., Leng, Z.C., Ma, T., Wang, Y.X. 2020. Sources and enrichment of phosphorus in groundwater of the Central Yangtze River Basin. Science of the Total Environment, 737:139837.
16. Zheng, T.L., Deng, Y.M. *, Wang, Y.X.*, Jiang, H.C., Xie, X.J., Gan, Y.Q. 2020. Microbial sulfate reduction facilitates seasonal variation of arsenic concentration in groundwater of Jianghan Plain, Central China. Science of the Total Environment. 735:139327.
17.Du, Y., Deng, Y.M., Ma, T.*, Shen, S., Lu, Z.J., Gan, Y.Q. 2020. Spatial Variability of Nitrate and Ammonium in Pleistocene Aquifer of Central Yangtze River Basin. Groundwater. 58(1): 110-118.
18.Wang, Y.X. *, Wang, Q.R., Deng, Y.M., Chen, Z., Cappellen P.V., Yang, Y.J., Goldscheider, N. 2020. Assessment of the impact of geogenic and climatic factors on global risk of urinary stone disease. Science of the Total Environment, 721:137769.
19.Xie, X.J. *, Peng, K., Wang, Y.X., Li, J.X., Qian, K., Deng, Y.M., Gan, Y.Q. 2020. In situ arsenic immobilization by chemical oxidation: Field trial and reactive transport modelling. Journal of Hydrology, 583:124645.
20. Cao, H.L., He, J.R., Xie, X.J. *, Wang, Y.X., Li, J.X., Qian, K., Deng, Y.M., Gan, Y.Q. 2020. The effect of groundwater velocities on sulfidation of arsenic-bearing ferrihydrite: Insight from column experiments. Journal of Hydrology, 586:124827.
21. Yan, L., Xie, X.J. *, Wang, Y.X., Qian, K., Chi, Z.Y., Li, J.X., Deng, Y.M., Gan Y.Q. 2020. Organic-matter composition and microbial communities as key indicators for arsenic mobility in groundwater aquifers: Evidence from PLFA and 3D fluorescence. Journal of Hydrology, 591:125308
22.Zheng, T.L., Deng, Y.M. *, Wang, Y.X. *, Jiang, H.C., O’Loughlin, E.J., Flynn, T.M., Gan, Y.Q., Ma, T. 2019. Seasonal microbial variation accounts for arsenic dynamics in shallow alluvial aquifer systems. Journal of Hazardous Materials, 367: 109-119.
23. Wu, G., Yang, J., Jiang, H.C. *, Deng, Y.M., Lear, G. 2019. Distribution of potentially pathogenic bacteria in the groundwater of the Jianghan Plain, central China. International Biodeterioration & Biodegradation, 143:104711.
24.Wang, Y.X. *, Pi, K.F., Fendorf, S., Deng, Y.M., Xie, X.J. 2019. Sedimentogenesis and hydrobiogeochemistry of high arsenic Late Pleistocene-Holocene aquifer systems. Earth-Science Reviews, 189:79-98.
25.Duan, Y.H., Michael V.S., Wang, Y.X. *, Gan,Y.Q., Yu, K., Deng, Y.M., Fendorf, S. 2019. Experimental constraints on redox-induced arsenic release and retention from aquifer sediments in the central Yangtze River Basin. Science of the Total Environment, 649:629-639.
26.Shen, S., Ma, T. *, Du, Y., Luo, K.W., Deng, Y.M., Lu, Z.J. 2019. Temporal variations in groundwater nitrogen under intensive groundwater/surface-water interaction. Hydrogeology Journal. 27(5): 1753-1766.
27. Zhang, J.W., Liang, X. *, Jin, M.G., Ma, T., Deng, Y.M., Ma, B. 2019. Identifying the groundwater flow systems in a condensed river-network interfluve between the Han River and Yangtze River (China) using hydrogeochemical indicators. Hydrogeology Journal. 27(7):2415-2430.
28. Deng, Y.M. *, Zheng, T.L., Wang, Y.X*., et al. 2018. Effect of microbially mediated iron mineral transformation on temporal variation of arsenic in the Pleistocene aquifers of the central Yangtze River basin. Science of the Total Environment. 619-620C:1147-1158.
29. Du, Y., Deng, Y.M. *, Ma, T., et al. 2018. Hydrogeochemical evidences for targeting sources of safe groundwater supply in arsenic-affected multi-level aquifer systems. Science of the Total Environment. 645:1159-1171.
30.Wang, Y.X., Deng, Y.M. 2018. Chapter 30 Environmental Geochemistry of High Arsenic Aquifer Systems in Handbook of Advanced Industrial and Hazardous Wastes Management. edited by Lawrence K. Wang, Mu-Hao S. Wang, Yung-Tse Hung, Nazih K. Shammas, Jiaping Paul Chen. Taylor and Francis & CRC Press. ISBN 9781466513419.
31.Du, Y., Ma, T. *, Deng, Y.M., et al. 2018. Characterizing groundwater-surface water interactions in the interior of the Jianghan Plain, central China. Hydrogeology Journal. 26(4):1047-1059.
32. Gan, Y.Q., Zhao, K., Deng, Y.M., et al. 2018. Groundwater flow and hydrogeochemical evolution in the Jianghan Plain, central China.Hydrogeology Journal. 26(5):1609-1623.
33. Du,Y., Ma, T. *, Deng,Y.M. *, et al. 2017. Sources and fate of high levels of ammonium in surface water and shallow groundwater of the Jianghan Plain, Central China. Environmental Science-Processes& Impacts, 19(2):161-172.
34. Liu, N.J., Deng, Y.M. *, Wu, Y. 2017. Arsenic, iron and organic matter in Quaternary Aquifer Sediments from western Hetao Basin, Inner Mongolia. Journal of Earth Science, 28(3):473-483.
35. Yao, L.L., Wang, Y.X. *, Tong, L., Deng, Y.M., et al. 2017. Occurrence and risk assessment of antibiotics in surface water and groundwater from different depths of aquifers: A case study at Jianghan Plain, central China. Ecotoxicology and Environmental Safety, 135: 236-242.
36.Chen, X.M., Zeng, X.C. *, Wang, J.N., Deng, Y.M. et al. 2017. Microbial communities involved in arsenic mobilization and release from the deep sediments into groundwater in Jianghan plain, Central China. Science of the Total Environment. 579:989-999.
37.Lu, X.L., Wang, N., Wang, H.M. *, Deng, Y.M., Ma, T., et al. 2017. Molecular Characterization of the Total Bacteria and Dissimilatory Arsenate-Reducing Bacteria in Core Sediments of the Jianghan Plain, Central China. Geomicrobiology Journal. 34 (5): 467-479.
38.Duan, Y.H., Gan, Y.Q., Wang, Y.X.*, Liu, C.X., Yu, K., Deng, Y.M., et al. 2017. Arsenic Speciation in Aquifer Sediment Under Varying Groundwater Regime and Redox Conditions at Jianghan Plain of Central China. Science of the Total Environment, 607-608: 992-1000.
39.Yang, Y.J., Deng, Y.M., Wang, Y.X.*.2016. Major geogenic factors controlling geographical clustering of urolithiasis in China. Science of the Total Environment, 571:1164-1171.
40. Duan, Y.H., Wang, Y.X. *, Gan, Y.Q., Deng, Y.M. et al. 2015. Temporal variation of groundwater level and arsenic concentration at Jianghan Plain, central China. Journal of Geochemical Exploration, 149:106-119.
41. Gan, Y.Q., Wang, Y.X. *, Duan, Y.H., Deng, Y.M., Guo, X.X., Ding, X.F. 2014. Hydrogeochemistry and arsenic contamination of groundwater in the Jianghan Plain, central China. Journal of Geochemical Exploration, 138:81-93.
42. Li, M.D., Wang, Y.X., Li, P., Deng, Y.M., Xie, X.J. 2014. δ34S and δ18O of dissolved sulfate as biotic tracer of biogeochemical influences on arsenic mobilization in groundwater in the Hetao Plain, Inner Mongolia, China. Ecotoxicology. 23(10): 1958-1968.
43. He, X., Ma, T.*, Wang, Y.X., Shan, H.M., Deng, Y.M. 2013. Hydrogeochemistry of high fluoride groundwater in shallow aquifers, Hangjinhouqi, Hetao Plain. Journal of Geochemical Exploration, 135: 63-70.
44.Guo, Y., Bao Z.Y., Deng, Y.M., Ma, Z.D., Yan S. 2011. Environmental Geochemistry of Abandoned Flotation Tailing Reservior from the Tonglvshan Fe-Cu Sulfide Mine in Daye, Central China. Bulletin of Environmental Contamination and Toxicology, 87: 91-95.
45. Deng, Y.M. , Nordstrom, D.K.*, McCleskey, R.B. 2011. Fluoride geochemistry of hydrothermal waters in Yellowstone National Park: I. Fluoride aqueous speciation. Geochimica et Cosmochimica Acta, 75:4476-4489.
46. Deng, Y.M., Wang, Y.X.*, Ma, T., Yang H., He J. 2011. Arsenic association in sediments from shallow aquifers of northern Hetao Basin, Northern China. Environmental Earth Sciences, 64:2001-2011.
47. Deng, Y.M., Wang, Y.X.*, and Ma, T. 2009. Isotope and minor element geochemistry of high arsenic groundwater from Hangjinhouqi of the Hetao Plain, Inner Mongolia. Applied Geochemistry, 24: 587-599.
48. Deng, Y.M. , Wang, Y.X.*, Ma, T., and Gan, Y.Q. 2009. Speciation and enrichment of arsenic in strongly reducing shallow aquifers at western Hetao Plain, northern China. Environmental Geology, 56(7): 1467-1477.
49. Wang, Y.X. and Deng, Y.M. 2009. Environmental Geochemistry of High-Arsenic Aquifer Systems. In: Lawrence K. Wang, Jiaping Paul Chen, Yung-Tse Hung. (Eds), Heavy Metals in the Environment, Chapter 5, London: Taylor & Francis Group. ISBN 978-1-4200-7316-4, 123-154.
50. He, J., Ma, T.*, Deng, Y.M., Yang, H., and Wang, Y.X. Environmental geochemistry of high arsenic groundwater at western Hetao plain, Inner Mongolia. Frontiers of Earth Science in China, 2009. 3: 63-72.
51. 李典, 邓娅敏 *,杜尧,颜港归,孙晓梁,范红晨. 2021. 长江中游河湖平原浅层地下水中砷空间异质性的同位素指示. 地球科学.
52. 罗义鹏, 邓娅敏 *,杜尧,薛江凯,孙晓梁. 2021. 长江中游故道区高碘地下水分布与形成机理. 地球科学.
53. 薛江凯, 邓娅敏 *,杜尧,罗义鹏,程一涵. 2021. 长江中游沿岸地下水中有机质分子组成特征及其对碘富集的指示. 地球科学. 46(11): 4140-4149.
54. 徐雨潇,郑天亮,高杰, 邓娅敏 *,蒋宏忱. 2021. 江汉平原浅层含水层中土著硫酸盐还原菌对砷迁移释放的影响. 地球科学. 46(2): 652-660
55. 孙晓梁,杜尧*, 邓娅敏,陶艳秋,马腾. 2020. 1996-2017年枯水期地下水排泄对洞庭湖水量均衡的贡献及其时间变异性. 地球科学. 46(07), 2555-2564.
56. 黄艳雯,杜尧*,徐宇,陶艳秋, 邓娅敏,马腾. 2020. 洞庭湖平原西部地区浅层承压水中铵氮的来源与富集机理. 地质科技通报. 39(6):165-174.
57. 袁晓芳, 邓娅敏 *,杜尧,甘义群. 2020. 江汉平原高砷地下水稳定碳同位素特征及其指示意义.地质科技通报. 39(05),156-163
58. 马腾*,沈帅, 邓娅敏,杜尧,梁杏,王志强,於昊天. 2020. 流域地球关键带调查理论方法:以长江中游江汉平原为例. 地球科学. 45(12):4498-4511.
59. 王焰新*,甘义群, 邓娅敏,谢先军. 2020. 海岸带海陆交互作用过程及其生态环境效应研究进展.地质科技通报,39(1):1-10.
60. 李俊琦,马腾*, 邓娅敏,杜尧,王志强,姜月华. 2019. 江汉平原地球关键带监测网建设进展. 中国地质调查,6(05): 115-123.
61. 田飞翔,郑天亮,李琦, 邓娅敏 *. 2018.江汉平原第四系沉积物中砷的垂向分布规律及其对地下水中砷浓度的影响. 地质科技情报, 37 (3): 226-234
62. 郑天亮, 邓娅敏 *, 鲁宗杰,甘义群. 2017.江汉平原浅层高砷含水层稀土元素地球化学特征. 地球科学, 42(5): 693-706.
63. 鲁宗杰, 邓娅敏 *,杜尧,沈帅,马腾. 2017. 江汉平原高砷地下水中DOM三维荧光特征及其指示意义.地球科学, 42(5): 771-782.
64. 高杰,郑天亮, 邓娅敏 *,蒋宏忱. 2017. 江汉平原高砷地下水原位微生物的铁还原及其对砷释放的影响. 地球科学, 42(5): 716-726.
65. 杜尧, 马腾*, 邓娅敏, 廖曼, 郑倩琳. 2017. 潜流带水文-生物地球化学:原理、方法及其生态意义. 地球科学, 42(5), 661-673.
66. 於昊天, 马腾*, 邓娅敏, 杜尧, 沈帅, 鲁宗杰. 2017. 江汉平原东部地区浅层地下水水化学特征. 地球科学, 42(5), 685-692.
67. 沈帅, 马腾*, 杜尧, 邓娅敏, 於昊天, 罗可文. 2017. 江汉平原典型地区季节性水文条件影响下氮的动态变化规律. 地球科学, 42(5), 674-684.
68. 邓娅敏 *,王焰新,李慧娟等. 2015. 江汉平原砷中毒病区地下水砷形态季节性变化特征. 地球科学. 40(11):1876-1886.
69. 李红梅, 邓娅敏 *,罗莉威等. 2015. 江汉平原高砷含水层沉积物地球化学特征. 地质科技情报. 34(3): 178-184.
70. 邓娅敏,徐恒力*,佟元清. 2006.“有序”开采:北方地区地下水资源利用中两难选择的途径. 中国人口,资源与环境. 16(1):127-131
人才培养
近5年来指导的研究生获奖情况:
研究生国家奖学金获得者: 薛江凯(2021年)、李典(2021年)、孙晓梁(2020年)、郑天亮(2019年)、高杰(2017年)
校级优秀硕士学位论文获得者: 罗义鹏(2020年)、孙晓梁(2020年)
校级研究生科技论文报告会获奖 :薛江凯(2021年一等奖)、徐雨潇(2020年一等奖)、高杰(2020年二等奖)、郑天亮(2019年二等奖、2018年二等奖)
研究生高杰在2018年第七届环境中的砷国际会议上获得最佳展板论文奖。
研究生郑天亮获得第七届全国地质微生物学术研讨会最佳展板奖。
自然资源部“劣质地下水成因与水质改良创新团队”
由王焰新教授负责的团队以地下水水质为核心研究对象,通过理论、方法和技术创新,长期致力于地下水污染成因和水污染控制技术研究。针对我国典型盆地广泛存在的高砷、高氟、高碘、高铁锰、高硬度与高矿化度地下水,及岩溶煤系地层分布区的老窖水等,以水文地质调查与地下水环境监测为基础,重点开展地下水系统中有害物质迁移转化和地下水环境修复新方法研究,查明劣质水成因机制,研发水质改良技术,为供水水质安全与地下水环境保护提供科学依据。
NSFC“环境水文地质”创新研究群体
本创新群体以国家***科学基金获得者王焰新教授为学术带头人,包括***、国家***计划入选者等学术骨干在内共21位成员,围绕学科领域前沿和国家重大需求、经多学科交叉和长期合作自然凝聚形成。群体以精细刻画和认识地下水系统中有害物质迁移转化规律为核心命题,以地下水污染防治为应用导向,发展环境水文地质理论方法和地下水污染监测、示踪、模拟与修复技术,以实现跨学科的交叉融合和学术思想的推陈出新。其研究成果不仅为推动水文地质学科的发展做出了贡献,而且为水环境保护提供了科学依据。群体拟基于已有工作基础,依托长期研究基地(大同及江汉)野外工作和系统的实验室研究,重点开展地下水系统中有害物质迁移转化机理和地下水环境修复新方法研究,力争在破解核心命题上取得理论和方法的新突破,进而强化群体的学术优势与特色。通过创新研究群体项目的实施,建成一个有重要国际学术影响、学风严谨、团结协作、锐意进取的优秀创新研究群体。
