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讲座教授

郑春苗

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美国威斯康星(麦迪逊)大学博士学位(主修水文地质,辅修环境工程)。现任南方科技大学领军教授及环境科学与工程学院院长。曾任北京大学讲席教授、北京大学水资源研究中心主任、中组部“千人计划”国家特聘专家、美国阿拉巴马大学地质科学系助理教授至Lindahl终身讲席教授。已主持60余项美国和中国政府资助的科研项目。发表了专著5部,包括Applied Contaminant Transport Modeling ,及论文200多篇,内容涉及水文过程模拟、地下水污染机理、以及水资源可持续利用。开发了地下水污染模拟标准软件MT3D和MT3DMS,在100多个国家得到广泛使用。现任或已经担任过国际水资源领域顶级刊物(Water Resources Research, Journal of Hydrology, Ground Water & Hydrogeology Journal)的副主编、美国国家研究理事会(National Research Council)水文科学核心小组成员、国际水文科协(IAHS)国际地下水委员会主席。荣誉包括美国地质学会会士、美国地下水协会1998年度John Hem杰出贡献奖、中国国家自然科学基金委2006年度海外杰出青年合作基金获得者。2009年作为首位华裔科学家,获得美国地质学会Birdsall-Dreiss杰出讲席奖,应邀到世界各地70所大学和科研机构讲演及学术交流。2013年同时获得美国地质学会O.E. Meinzer奖(国际水文地质界最高荣誉)及美国地下水协会M. King Hubbert奖(该协会最高科学奖)。2014年获得美国威斯康星大学地学系杰出校友奖(Distinguished Alumni Award)。

目前任职

南方科技大学环境科学与工程学院,讲座教授、院长

教育背景

1984-1988:博士(主修水文地质、辅修环境工程),美国威斯康星大学

1983-1984:教育部出国代培研究生,成都地质学院

1979-1983:学士(水文地质),成都地质学院(现成都理工大学)

工作经历

2015-至今:南方科技大学环境科学与工程学院 讲座教授、院长

2010-2015:北京大学水科学研究中心(原北京大学水资源研究中心) 讲席教授、主任

2010-2013:美国阿拉巴马大学地质科学系 George Lindahl讲席教授

2002-2009:美国阿拉巴马大学地质科学系 教授

1997-2002:美国阿拉巴马大学地球科学系 副教授(终身职)

1993-1997:美国阿拉巴马大学地球科学系 助理教授

1988-1993:美国S.S. Papadopulos & Associates环境与水资源咨询公司水文地质专家

学术经历

2001:英国谢菲尔德大学土木工程系 访问学者

2000:美国斯坦福大学地质与环境科学系 访问副教授

1995:澳大利亚国家原子能科学技术机构 访问学者

获奖情况及荣誉

2014:威斯康星大学麦迪逊地质科学系杰出校友奖

2013:美国地质学会迈因策尔奖(O.E. Meinzer Award)

2013:美国地下水协会金·哈博奖(M. King Hubbert Award)

2009:美国地质学会水文地质杰出讲席奖(Birdsall-Dreiss Distinguished Lecturer)

2008:美国 University of Delaware DuPont Lecturer

2007:《纽约时报》中国水问题专家

2006:中国国家自然科学基金委海外杰出青年合作基金

2005:美国德克萨斯大学Oliver Lecturer

2004:美国阿拉巴马大学文理学院S.S. Papadopulos & Associates (SSPA)荣誉教员

1999:美国地质学会 Fellow

1998:美国地下水协会John Hem杰出贡献奖

学术兼职(部分)

2015-至今:国家基金委重大研究计划“西南河流源区径流变化与适应性利用”专家组副组长

2013-至今:地质学报(英文版)(Acta Geologica Sinica)副主编

2009-至今:国家基金委重大研究计划“黑河流域生态水文过程集成研究”专家组成员

2007-至今:国际水文科协(IAHS)国际地下水委员会当选主席、主席、前主席

2005-至今:美国国家研究委员会(National Research Council) 水文科学核心小组成员

2005-至今:北京师范大学水科学院客座教授

2004-至今:南京大学地球科学系客座教授

2004-至今:成都理工大学土木环境学院客座教授

1998-至今:国际地下水模拟学术会议系列“MODFLOW and MORE”组织人

2010-2014:国际学术刊物《Water Resources Research》副主编

2007-2014:国际学术刊物《Journal of Hydrology》副主编

1998-2010:国际学术刊物《Ground Water》副主编及软件版主编

2005-2008:美国大学水文科学联合会(CUAHSI)行政负责人之一(Treasurer)

2004-2007:国际学术刊物《Hydrogeology Journal》副主编

2004-2005:国际中国地球科学促进会(IPACES)2004-05年度主席

1996-2005:美国地球物理协会地下水专业委员会委员

研究领域:

 

1)地下水污染物迁移过程与生物地球化学反应的理论及试验研究

2)流域尺度生态-水文过程的集成研究

3)土壤与地下水污染修复

4)水资源可持续性管理

简要介绍:

1)地下水污染物迁移过程与生物地球化学反应的理论及试验研究

分米或更小尺度的优先水流通道在野外含水层中是一种普遍现象,但对溶质运移的影响一直未引起人们的重视。2003年以来,郑春苗团队在密西西比野外试验场和多个其它试验场地大量数据分析总结的基础上,针对存在小尺度优先通道的非均质含水层,通过理论分析和模拟证明了分米或更小尺度的优先通道流对溶质迁移具有重要的控制作用,计算结果表明经典的溶质对流-扩散模型不适用于含有小尺度优先通道流的非均质含水层。该研究结果从一个新的角度较好地解析了含水层非均质性影响溶质运移的原因和机理(Zheng and Gorelick, 2003; Liu et al., 2004, 2007, 2010;  Zheng, 2006; Bianchi et al., 2011; Zheng et al., 2011)。目前,郑春苗团队正在继续发展可以较好解决小尺度优先水流通道影响下的污染物迁移过程的场地观测与数学模拟方法(Bianchi and Zheng, 2016)。

如何考虑地下水污染物在非均质介质中的三维迁移过程,又能容纳污染物与水-岩之间的多组分地球化学反应,是一个十分重要而又非常棘手的问题。郑春苗教授和合作者将MT3DMS三维迁移模型和模拟多组分复杂地球化学反应的PHREEQC模型耦合起来,可以成功地解决一系列地下水污染物反应迁移问题,为地下水污染的预测,整治,管理,提供了宝贵的手段与工具。郑春苗教授曾经作为共同负责人(Co-PI),参加了美国能源部资助的、为期5年的、位于华盛顿州Hanford场地的地下水放射性污染物迁移试验与模拟研究。该项研究揭示了反应性污染物U(VI)在物理和化学特征都高度非均质的介质中迁移和归趋特征,定量刻画了地表水-地下水交互过程对反应性污染物迁移和归趋的重大影响,并基于这些发现,提出了更为正确的多组分多速率动态吸附模型模型。目前,相关的研究工作在继续中。

2)流域尺度生态-水文过程的集成研究

作为国家自然科学基金委员会重大研究计划“黑河流域生态水文过程集成研究”(2009-2017)指导专家组成员,郑春苗教授参与了该计划的顶层设计,特别是在如何定量描述流域尺度地表水-地下水相互转化以及水文与生态过程的相互影响方面,发挥了重要作用。同时,作为集成项目“黑河流域中下游生态水文过程的系统行为及调控研究”的负责人,郑春苗教授领导了黑河流域中下游生态水文过程耦合模型(HEIFLOW)的开发及其应用。目前,郑春苗团队正在利用这一先进的生态水文模拟研究平台,分析干旱-半干旱流域水循环过程的特有规律、生态水文过程的尺度效应,以及基于生态保护的水资源高效利用策略。相关研究成果发表在国际水资源著名期刊上,包括《Water Resources Research》, 《Journal of Geophysical Research-Biogeosciences》, 《Environmental Modeling and Software》,和《Hydrometeorology》等。 

3)土壤与地下水污染修复

通常情况下,含水层受到污染后,其修复和治理的费用极其昂贵。运用模拟优化手段寻找最经济的地下水污染治理方式是多年地下水和环境工程学科的重要任务之一。地下水中污染物反应运移数值模拟的复杂性决定了优化过程必须有更高效的计算理论和方法。在这方面,郑春苗团队将先进的整体优化方法,包括Tabu 搜索、基因算法(Genetic algorithms)、模拟退火算法(Simulated annealing)等,用于污染含水层的优化治理方案研究中。另外,郑春苗教授与合作者还将基因算法和“噪声” 基因算法(Noisy GA) 引进到地下水污染监测网在野外复杂和不确定性的条件下的优化设计。签于整体搜索优化方法计算量十分大的事实,郑春苗团队将象Tabu 这样的整体搜索方法与一个局部搜索方法, 比如线性规划, 耦和起来, 作为突破优化计算速度瓶颈问题的重要途径之一。研究成果发表在《Advances in Water Resources》、《Journal of Contaminant Hydrology》、《Water Resources Research》等刊物上。

4)水资源可持续性管理

在气候变化和人类活动(城市化、人口增长、经济发展)的双重影响下,全球目前所面临的水资源短缺问题存在进一步加剧的风险。郑春苗团队正在发展基于复杂适应性系统理论的系统模型,用以评估不同的水资源政策和管理措施组合,并提出全球变化下水资源管理的适应性策略。研究目标是为全球变化下水资源的可持续利用提供重要的科学依据和先进决策方法,以便更好地应对被全球变化加剧的水挑战。

讲授的本科生及研究生课程:

 

(1)    Hydrogeology

(2)    Introduction to Groundwater Modeling

(3)    Concepts and Models in Contaminant Hydrogeology

(4)    Geostatistics

(5)    Coupled Geochemical and Transport Modeling

(6)    Groundwater Management

(7)    Advanced Groundwater Hydrology

(8)    土壤与地下水污染防治的美国经验

(*为通讯作者;Google Scholar总引用数6900:至2016.6.20):

论文与专著:

1) Huang, X., C.B. Andrews, J. Liu, Y. Yao, C. Liu, S.W. Tyler, J.S. Selker, C. Zheng*, 2016, Assimilation of temperature and hydraulic gradients for quantifying the spatial variability of streambed hydraulics. Water Resour. Res., doi:10.1002/2015WR018408.

2) Cao, G., B.R. Scanlon, D. Han, C. Zheng, 2016, Impacts of thickening unsaturated zone on groundwater recharge in the North China Plain, Journal of Hydrology, 537:260-270.

3) Hou, L., H. Li, C. Zheng, Q. Ma, C. Wang, X. Wang, W. Qu, 2016, Seawater-groundwater exchange in a silty tidal flat in the south coast of Laizhou Bay, China, Journal of Coastal Research, Special Issue 74 - Environmental Processes and the Natural and Anthropogenic Forcing in the Bohai Sea, Eastern Asia: pp. 136-148.

4) Cao, G., D. Han, M.J. Currell, C. Zheng, 2016, Revised conceptualization of the North China Basin groundwater flow system: Groundwater age, heat and flow simulations, Journal of Asian Earth Sciences, http://dx.doi.org/10.1016/j.jseaes.2016.05.025.

5) Zhang, A., W. Liu, Z. Yin, G. Fu, and C. Zheng*, 2016, How Will Climate Change Affect the Water Availability in the Heihe River Basin, Northwest China? Journal of Hydrometeorology, 17:5:1517-1542.

6) Xie, Y., P.G. Cook, M. Shanafield, C.T. Simmons, C. Zheng, 2016, Uncertainty of natural tracer methods for quantifying river–aquifer interaction in a large river, Journal of Hydrology, 535: 135-147.

7) Li, X., J. Liu, C. Zheng*, G. Han, H. Hoff, 2016, Energy for water utilization in China and policy implications for integrated planning, International Journal of Water Resources Development, 32(3): 477-494.

8) Lu, X., G. Cao, X. Huang, T.P. Clement, C. Zheng, 2016, Performance evaluation of inertial pumps used for sampling groundwater from small-diameter wells, Environmental Earth Sciences, 75: 203.

9) Huang, X., H. Deng, C. Zheng, G. Cao, 2016, Hydrogeochemical signatures and evolution of groundwater impacted by the Bayan Obo tailing pond in northwest China, Science of The Total Environment, 543: 357-372.

10) Tian, Y., Y. Zheng, C. Zheng, 2016, Development of a visualization tool for integrated surface water–groundwater modeling, Computers & Geosciences, 86: 1-14.

11) Hu, Y., Y. Lu, J.W. Edmonds, C. Liu, S. Wang, O. Das, J. Liu, C. Zheng, 2016, Hydrological and Land Use Control of Watershed Exports of DOM in a Large Arid River Basin in Northwestern China, Journal of Geophysical Research: Biogeosciences, 121, doi:10.1002/2015JG003082.

12) Cai, Y., W. Huang, F. Teng, B. Wang, K. Ni, C. Zheng, 2016, Spatial variations of river–groundwater interactions from upstream mountain to midstream oasis and downstream desert in Heihe River basin, China, Hydrology Research, 47 (2), 501-520.

13) Bianchi, M., C. Zheng, 2016, A lithofacies approach for modeling non-Fickian solute transport in a heterogeneous alluvial aquifer, Water Resources Research, 52(1): 552-565.

14) Gao, S., P. Xu, F. Zhou, H. Yang, C. Zheng, W. Cao, S. Tao, S. Piao, Y. Zhao, X. Ji, Z. Shang, M. Chen, 2016, Quantifying nitrogen leaching response to fertilizer additions in China's cropland, Environmental Pollution, 211: 241-251.

15) Zhang, Y., H. Li, X. Wang, C. Zheng, C. Wang, K. Xiao, L. Wan, X. Wang, X. Jiang, H. Guo, 2016, Estimation of submarine groundwater discharge and associated nutrient fluxes in eastern Laizhou Bay, China using 222Rn, Journal of Hydrology, 533: 103-113.

16) Wu, X., Y. Zheng, B. Wu, Y. Tian, C. Zheng, 2015, Optimizing conjunctive use of surface water and groundwater for irrigation to address human-nature water conflicts: A surrogate modeling approach, Agricultural Water Management, 63(1): 380-392.

17) Xie, Y., P.G. Cook, C.T. Simmons, C. Zheng, 2015, On the limits of heat as a tracer to estimate reach-scale river-aquifer exchange flux, Water Resources Research, 51(9): 7401-7416.

18) Wu, M., J. Wu, J. Liu, J. Wu, C. Zheng, 2015, Effect of groundwater quality on sustainability of groundwater resource: A case study in the North China Plain, Journal of Contaminant Hydrology, 179: 132-147.

19) Cao, G., C. Zheng, 2015, Signals of short-term climatic periodicities detected in the groundwater of North China Plain, Hydrological Processes, 30(4): 515-533.

20) Yao, Y., X. Huang, J. Liu, C. Zheng, X. He, C. Liu, 2015, Spatiotemporal variation of river temperature as a predictor of groundwater/surface-water interactions in an arid watershed in China, Hydrogeology Journal, 23(5): 999-1007.

21) Liu, C., J. Liu, X. Wang, C. Zheng, 2015, Analysis of groundwater–lake interaction by distributed temperature sensing in Badain Jaran Desert, Northwest China, Hydrological Processes.

22) Tian, Y., Y. Zheng, C. Zheng, H. Xiao, W. Fan, S. Zou, B. Wu, Y. Yao, A. Zhang, J. Liu, 2015, Exploring scale‐dependent ecohydrological responses in a large endorheic river basin through integrated surface water‐groundwater modeling, Water Resources Research, 51(6): 4065-4085.

23) Anid, N.M., M. Panero, C. Zheng, J. Liu, 2015, EcoPartnership on water quality management and conservation in the U.S. and China, Journal of Renewable and Sustainable Energy, 7(4): 041516.

24) Liu, C., J. Liu, Y. Hu, H. Wang, C. Zheng, 2015, Airborne thermal remote sensing for estimation of groundwater discharge to a river, Groundwater.

25) Gorelick, S.M., C. Zheng, 2015, Global change and the groundwater management challenges, Water Resour. Res. (50th anniversary edition), v.51, doi:10.1002/2014WR016825.

26) Wu, B., Y. Zheng, X. Wu, Y. Tian, F. Han, J. Liu, and C. Zheng, 2015, Optimizing water resources management in large river basins with integrated surface water-groundwater modeling: A surrogate-based approach, Water Resour. Res., 51(4): 2153-2173. doi:10.1002/2014WR016653.

27) Liu, J., C. Zheng, 2015, Using distributed temperature sensing for hydrogeological studies in China. Groundwater, 53(1):17-18.

28) Zhang, A., C. Zheng*, S. Wang, Y. Yao, 2015, Analysis of streamflow variations in the Heihe River Basin, northwest China: Trends, abrupt changes, driving factors and ecological influences. Journal of Hydrology: Regional Studies, 3:106-124.

29) Tian, Y., Y. Zheng, B. Wu, X. Wu, J. Liu, C. Zheng ,2015, Modeling surface water-groundwater interaction in arid and semi-arid regions with intensive agriculture. Environmental Modelling & Software, 63: 170-184.

30) Yao, Y., C. Zheng*, Y. Tian, J. Liu, Y. Zheng, 2015, Numerical modeling of regional groundwater flow in the Heihe River Basin, China: Advances and new insights. Science China Earth Sciences, 58(1):3-15, DOI: 10.1007/s11430-014-5033-y.

31) Lu, Z., S. Zou, H. Xiao, C. Zheng, Z. Yin, W. Wang, 2015, Comprehensive hydrologic calibration of SWAT and water balance analysis in mountainous watersheds in northwest China. Physics and Chemistry of the Earth, Parts A/B/C, DOI:10.1016/j.pce.2014.11.003.

32) Hu, Y, C. Liu, Y. Lu, J. Liu, C. Zheng*, 2014, Application of environmental isotopes in understanding hydrological processes of the Heihe River Basin, Advances in Earth Science, 29(10):1158-1166.

33) Yu, L., G. Cao, M. Xu, J. Liu, C. Zheng, 2014, Application of centrifuges in experimental studies of contaminant transport, Advances in Earth Science, 29(2):227-237.

34) Yao, Y., C. Zheng*, J. Liu, G. Cao, H. Xiao, H. Li, W. Li, 2014, Conceptual and numerical models for groundwater flow in an arid inland river basin. Hydrological Processes, DOI: 10.1002/hyp.10276.

35) Yao, Y., J. Liu, A Zhang, X Li, Y Tian, C. Zheng, 2014, Impacts of stream runoff change and human activities on the groundwater regime in the Heihe River Basin, northwest China, Quaternary Science, 34(5): 973-981.

36) Wu, B., Y. Zheng, Y. Tian, X. Wu, Y. Yao, F. Han, J. Liu, C. Zheng, 2014, Systematic assessment of the uncertainty in integrated surface water-groundwater modeling based on the probabilistic collocation method. Water Resour. Res., 50(7), 5848-5865.

37) Rayne, T., K. Bradbury, C. Zheng, 2014, Correct Delineation of Capture Zones Using Particle Tracking under Transient Conditions. Groundwater, DOI: 10.1111/gwat.12141

38) Yu, C., Y. Yao, G. Cao, C. Zheng, 2014, A field demonstration of groundwater vulnerability assessment using transport modeling and groundwater age modeling, Beijing Plain, China. Environ. Earth Sciences, DOI 10.1007/s12665-014-3769-5.

39) Yi, S., H. Ma, C. Zheng, G. Ren, X. Hu, 2014, A field-scale long-term study on radionuclide transport through weathered granites at a site in southern China. Environ. Earth Sciences, 72(11), DOI: 10.1007/s12665-014-3343-1

40) Ma, R., C. Zheng, C. Liu, J. Greskowiak, H. Prommer, and J. M. Zachara, 2014, Assessment of controlling processes for field-scale uranium reactive transport under highly transient flow conditions, Water Resour. Res., 50, 1006–1024, doi:10.1002/2013WR013835.

41) Ma, R., C. Liu, J. Greskowiak, H. Prommer, J. Zachara, C. Zheng*, 2014, Influence of calcite on uranium(VI) reactive transport in the groundwater–river mixing zone, J. Contam. Hydrol., 156:27–37.

42) Huang, X., G. Cao, J. Liu, H. Prommer, C. Zheng*, 2014, Reactive transport modeling of thorium in a cloud computing environment, J. Geochem. Explor., http://dx.doi.org/10.1016/j.gexplo.2014.03.006.

43) Zheng, C., J. Liu, 2013, China’s “Love Canal” moment? Science, v. 340, p. 810.

44) Qin, H., G. Cao, M. Kristensen, J. C. Refsgaard, M. O. Rasmussen, X. He, J. Liu, Y. Shu, and C. Zheng*, 2013, Integrated hydrological modeling of the North China Plain and implications for sustainable water management, Hydrol. Earth Syst. Sci., 17, 3759–3778.

45) Cao, G. C. Zheng*, B.R. Scanlon, J. Liu, and W. Li, 2013, Use of flow modeling to assess sustainability of groundwater resources in the North China Plain, Water Resour. Res., 49, 159-175, doi:10.1029/2012WR011899.

46) Yang, Y., J. Wu, X. Sun, J. Wu, C. Zheng, 2013, A niched Pareto tabu search for multi-objective optimal design of groundwater remediation systems, J. Hydrol., http://dx.doi.org/10.1016/j.jhydrol.2013.03.022.

47) Yang, Y., J. Wu, X. Sun, J. Wu, C. Zheng, 2013, Development and application of a master-slave parallel hybrid multi-objective evolutionary algorithm for groundwater remediation design, Environ Earth Sci., doi 10.1007/s12665-013-2291-5.

48) Ma, R., C. Zheng*, C. Liu, 2012, Groundwater Impacts of Radioactive Wastes and Associated Environmental Modeling Assessment. In: R. A. Meyers ed. Encyclopedia of Sustainability Science and Technology, 4774-4784, Springer.

49) National Research Council, 2012, Challenges and Opportunities in the Hydrologic Sciences, The National Academies Press, Washington DC (C. Zheng was a member of the committee that authored the report).

50) Song, X., J. Liu, C. Zheng, 2012, Image analysis of concentration distribution in two-dimensional sandbox tracer experiment. Acta Scientiae Circumstantiae, 32(10):2470-2475

51) Zheng, C., M.C. Hill, G. Cao, R. Ma, 2012, MT3DMS: Model use, calibration, and validation, Transactions of the ASABE, 55(4): 1549-1559.

52) Ma, R., C. Zheng*, J.M. Zachara, M. Tonkin, 2012, Utility of bromide and heat tracers for aquifer characterization affected by highly transient flow conditions, Water Resour. Res., 48, W08523, doi:10.1029/2011WR011281.

53) Hunt, R.J., C. Zheng, 2012, The current state of modeling, Ground Water, 50(3): 329-333.

54) Qin, H., A. Sun, J. Liu, C. Zheng*, 2012, System dynamics analysis of water supply and demand in the North China Plain, Water Policy, 14: 214–231.

55) Yi, S., H. Ma, C. Zheng, X. Zhu, H. Wang, X. Li, X. Hu, J. Qin, 2012, Assessment of site conditions for disposal of low- and intermediate-level radioactive wastes: A case study in southern China, Science of the Total Environment, 414: 624–631.

56) Yu, C., B. Zhang, Y. Yao, F. Meng, C. Zheng*, 2012, A field demonstration of the entropy-weighted fuzzy DRASTIC method for groundwater vulnerability assessment, Hydrological Sciences Journal, 57(7), doi:10.1080/02626667.2012.715746.

57) Huang, L., C. Zheng*, J. Liu, H. Xiao, 2012, Application of distributed temperature sensing to study groundwater-surface water interactions in the Heihe River Basin, Hydrogeology and Engineering Geology (China), 39(2).

58) Wang, X., C. Zheng*, G. Liu, W. Li, S. Knobbe, E. Reboulet, J. J. Butler Jr., 2012, A review of recent developments in using direct-push technologies for rapid, high-resolution hydraulic conductivity measurements, Hydrogeology and Engineering Geology (China), 39(1).

59) Yi, S., H. Ma, C. Zheng, 2011, Advances in research on disposal of radioactive waste, Acta Geoscientica Sinica, 32(5): 592-600.

60) Zheng, C., M. Bianchi, S.M. Gorelick, 2011, Lessons learned from 25 years of research at the MADE site, Ground Water, 49(5): 649–662, doi: 10.1111/j.1745-6584.2010.00753.x.

61) Lerner, D.N. and C. Zheng, 2011, Integrated catchment management: path to enlightenment, Hydrol. Process., 25(16): 2635–2640, doi: 10.1002/hyp.8064.

62) Zheng, C., 2011, Reflections: 2002-2009, Ground Water, 49: 129-132, doi: 10.1111/j.1745-6584.2010.00787.x.

63) Greskowiak, J., M. Hay, H. Prommer, C. Liu, V. Post, R. Ma, J. A. Davis, C. Zheng, J. Zachara, 2011, Simulating adsorption of U(VI) under transient groundwater flow and hydrochemistry - Physical versus chemical non-equilibrium model, Water Resour. Res., 47, W08501, doi:10.1029/2010WR010118.

64) Liu, J., G. Cao, C. Zheng*, 2011, Sustainability of groundwater resources in the North China Plain, in Sustaining Groundwater Resources, J.A.A. Jones, ed., Springer, New York.

65) Ma, R., C. Zheng*, M. Tonkin, J.M. Zachara, 2011, Importance of considering intraborehole flow in solute transport modeling under highly dynamic flow conditions, Journal of Contaminant Hydrology, 123: 11-19, doi:10.1016/j.jconhyd.2010.12.001.

66) Ma, R., C. Zheng*, 2011, Not all mass transfer rate coefficients are created equal, Ground Water, 49(6): 772-774, doi: 10.1111/j.1745-6584.2011.00822.x.

67) Ma, R., Y. Wang, Z. Sun, C. Zheng, T. Ma, H. Prommer, 2011, Geochemical evolution of groundwater in carbonate aquifers in Taiyuan, northern China, Applied Geochemistry, 26: 884–897, doi:10.1016/j.apgeochem.2011.02.008.

68) Bianchi, M., C. Zheng*, C. Wilson, G. Tick, G. Liu, S.M. Gorelick, 2011, Spatial connectivity in a highly heterogeneous aquifer: From cores to preferential flow paths, Water Resources Research, 47, W05524, doi:10.1029/2009WR008966.

69) Bianchi, M., C. Zheng*, G. R. Tick, S. M. Gorelick, 2011, Investigation of small-scale preferential flow with a forced-gradient tracer test, Ground Water, 49(4): 503-514, doi: 10.1111/j.1745-6584.2010.00746.x.

70) Ma, R., C. Zheng*, H. Prommer, J. Greskowiak, 2011, Modeling field-scale uranium mass transfer at the Hanford IFRC site. In Wang, Y. S. Ge, M.C. Hill, C. Zheng (eds.), Calibration and Reliability in Groundwater Modeling: Managing Groundwater and the Environment, IAHS Publication 341, IAHS Press, Wallingford, UK, p. 141-146.

71) Cao, G., C. Zheng*, J. Zhao, M. Wu, 2011, Simulation of land subsidence caused by groundwater exploitation in the Hangzhou-Jiaxing-Huzhou Plian, south China. In Wang, Y. S. Ge, M.C. Hill, C. Zheng (eds.), Calibration and Reliability in Groundwater Modeling: Managing Groundwater and the Environment, IAHS Publication 341, IAHS Press, Wallingford, UK, p. 245-251.

72) Wu, J., W. Peng, J. Qian, J. Wu, C Zheng, 2011, INPGA-based multiobjective management model for optimal design of groundwater remediation system: II. Application to the MMR site, Geological Review, 67(3):437-443.

73) Hill, M.C., E. Poeter, C. Zheng, 2010, Foreword: Groundwater modeling and public policy, Ground Water, 48(5):625–626, doi: 10.1111/j.1745-6584.2010.00734.x.

74) Hill, M.C., E. Poeter, C. Zheng, eds., 2010, Groundwater modeling and public policy: A special theme issue, Ground Water, 48(5):625-780.

75) Lu, Z., A. V. Wolfsberg, Z. Dai, C. Zheng, 2010, Characteristics and controlling factors of dispersion in bounded heterogeneous porous media, Water Resour. Res., 46, W12508, doi:10.1029/2009WR008392.

76) Yu, C. and C. Zheng*, 2010, HYDRUS: Software for flow and transport modeling in variably saturated media, Ground Water, 48(6):787-791, doi: 10.1111/j.1745-6584.2010.00751.x.

77) Ronayne, M. J., S. M. Gorelick, C. Zheng, 2010, Geological modeling of sub-meter scale heterogeneity and its influence on tracer transport in a fluvial aquifer, Water Resour. Res., 46, W10519, doi:10.1029/2010WR009348.

78) Wu, Q., B.X. Hu, L. Wan, C. Zheng*, 2010, Coal mine water management: optimization models and field application in North China, Hydrological Sciences Journal, 55(4): 609-623, doi:10.1080/02626661003798310.

79) Zheng, C., J. Liu, G. Cao, E. Kendy, H. Wang, Y. Jia, 2010, Can China cope with its water crisis?—Perspectives from the North China Plain, Ground Water, 48(3): 350-354, doi: 10.1111/j.1745-6584.2010.00695.x.

80) Ma, R., C. Zheng*, H. Prommer, J. Greskowiak, C. Liu, J. Zachara, M. Rockhold, 2010, A Field-scale reactive transport model for U(VI) migration influenced by coupled multi-rate mass transfer and surface complexation reactions, Water Resources Research, 46, W05509, doi:10.1029/2009WR008168.

81) Greskowiak, J., H. Prommer, C. Liu, V.E.A. Post, R. Ma, C. Zheng, J.M. Zachara, 2010, Comparison of parameter sensitivities between a laboratory and field scale model of uranium transport in a dual-domain, distributed-rate reactive system, Water Resources Research, 46, W09509, doi:10.1029/2009WR008781.

82) Yu, C., Y. Yao, G. Hayes, B. Zhang and C. Zheng, 2010, Quantitative assessment of groundwater vulnerability using index system and transport simulation, Huangshuihe catchment, China, Science of The Total Environment, 408(24):6108-6116.

83) Ma, R., C. Zheng*, 2010, Effects of density and viscosity in modeling heat as a groundwater tracer, Ground Water, 48 (3), 380–389, doi:10.1111/j.1745-6584.2009.00660.x.

84) Liu, G., C. Zheng*, G.R. Tick, J.J. Butler, Jr., and S.M. Gorelick, 2010, Relative importance of dispersion and rate-limited mass transfer in highly heterogeneous porous media: Analysis of a new tracer test at the Macrodispersion Experiment (MADE) site, Water Resources Research, 46, W03524, doi:10.1029/2009WR008430.

85) Wang, P., C. Zheng*, and S.M. Gorelick, 2010, A Multivariate Markovian arrival process for modeling contaminant transport through Porous Media, in review for Water Resources Research.

86) Zheng, C., and R. Ma, 2010, IGW/DL: A Digital library for teaching and learning hydrogeology and groundwater modeling, Ground Water, doi:10.1111/j.1745-6584.2010.00693.x.

87) Liu, J., M. Zhang, and C. Zheng*, 2010, Role of ethics in groundwater management, Ground Water, 48(1), doi: 10.1111/j.1745-6584.2009.00611.x.

88) Zheng, C. and others, 2009, Challenges and Opportunities in Chinese Groundwater Science, Science Press, Beijing, China, 200 pp.

89) Zheng, C., 2009, Recent developments and future directions for MT3DMS and related transport codes, Ground Water, 47(5), doi: 10.1111/j.1745-6584.2009.00602.x.

90) Bianchi, M. and C. Zheng*, 2009, SGeMS: a free and versatile tool for three-dimensional geostatistical applications, Ground Water, 47(1), doi: 10.1111/j.1745-6584.2008.00522.x.

91) Zheng, C. and X. Feng, eds., 2008, Environmental Geosciences, Higher Education Press, Beijing, China, p. 254.

92) Wu, J. and C. Zheng, 2008, Advances in optimal design of contaminant monitoring network design, in Environmental Geosciences, C. Zheng and X. Feng, eds., p. 189-222, Higher Education Press, Beijing, China.

93) Liu, J., C. Zheng*, L. Zheng, and Y. Lei, 2008, Ground water sustainability: Methodology and application to the North China Plain, Ground Water, 46(6), doi: 10.1111/j.1745-6584.2008.00486.x.

94) Zheng, C., 2008, Zhang Hongren and the introduction of transient flow theory to China, Ground Water, 46(2):341-343.

95) Lin, J., J.B. Snodsmith, C. Zheng*, J. Wu, 2008, A modeling study of seawater intrusion in Alabama Gulf Coast, USA, Environmental Geology, 54, DOI 10.1007/s00254-008-1288-y.

96) Bianchi, M., C. Zheng*, G. Tick, S.M. Gorelick, 2008, Evaluation of Fickian and non-Fickian models for solute transport in porous media containing decimeter-scale preferential flow paths, in Calibration and Reliability in Groundwater Modelling: Credibility of Modelling, IAHS Publ. 320.

97) Guan, J., F.J. Molz, Q. Zhou, H.H. Liu and C. Zheng, 2008, Behavior of the mass transfer coefficient during the MADE-2 experiment: New insights, Water Resour. Res., 44, W02423, doi:10.1029/2007WR006120.

98) Liu, J., K. Rich, and C. Zheng*, 2008, Sustainability analysis of groundwater resources in a coastal aquifer, Alabama, Environmental Geology, 54(1):43-52.

99) Liu, G., C. Zheng*, and S.M. Gorelick, 2007, Evaluation of the applicability of the dual-domain mass transfer model in porous media containing connected high-conductivity channels, Water Resources Research, 43, W12407, doi:10.1029/2007WR005965.

100) Spiessl, S.M, H. Prommer, T. Licha, M. Sauter, and C. Zheng, 2007, A process-based reactive hybrid transport model for coupled discrete conduit-continuum systems, J. Hydrol., 347:23-34.

101) Bowling, J.C., A.B. Rodriguez, D.L. Harry, and C. Zheng, 2007, Integrated geophysical and geological investigation of a heterogeneous fluvial aquifer in Columbus, Mississippi, Journal of Applied Geophysics, 62 (2007): 58–73.

102) He, K., L. Zheng, S. Dong, L. Tang, J. Wu, and C. Zheng, 2007, PGO: a parallel computing platform for global optimization based on genetic algorithm, Computers and Geosciences, 33: 357–366.

103) Kendy, E., J. Wang, D. J. Molden, C. Zheng, C. Liu, and T.S. Steenhuis, 2007, Can urbanization solve inter-sector water conflicts? Insight from a case study in Hebei Province, North China Plain, Water Policy, vol. 9, Supplement 1:75–93.

104) Promma, K., C. Zheng, and P. Asnachinda, 2007, Groundwater and surface-water interactions in a confined alluvial aquifer between two rivers: effects of groundwater flow dynamics on high iron anomaly, Hydrogeology Journal, 15: 495–513, DOI 10.1007/s10040-006-0110-8.

105) Lin, J., J Wu, and C. Zheng*, 2007, MF2K-GWM: A Ground water management modeling tool based on MODFLOW-2000, Ground Water, 45(2):122-124.

106) Lin, J., C. Zheng*, J. Wu, and C.C. Calvin, 2007, Groundwater simulation-optimization model based on genetic algortihm under variable density conditions, Chinese Journal of Water Resources, 38(10): 1236-1244.

107) Zheng, C., E. Poeter, M.C. Hill, and J. Doherty, 2006, Foreword: Understanding through modeling, Ground Water, 44: 769-770. doi: 10.1111/j.1745-6584.2006.00270.x.

108) Zheng, C., E. Poeter, M.C. Hill, and J. Doherty, eds., 2006, Understanding through Modeling: A special theme issue, Ground Water, 44(6):769-879.

109) Zheng, C., 2006, Accounting for aquifer heterogeneity in solute transport modeling: a case study from the macrodispersion experiment (MADE) site in Columbus, Mississippi, in Handbook of Groundwater Engineering, 2nd edition, Delleur, J.W., ed., CRC Press.

110) Becker, D., B. Minsker, R. Greenwald, Y. Zhang, K. Harre, K. Yager, C. Zheng, and R. Peralta, 2006, Reducing long-term remedial costs by transport modeling optimization, Ground Water, 44(6): 864–875.

111) Molz, F.J., C. Zheng, S.M. Gorelick, and C. Harvey, 2006, Discussion of “Investigating the Macrodispersion Experiment (MADE) site in Columbus, Mississippi, using a three-dimensional inverse flow and transport model” by H.C. Barlebo, M.C. Hill, and D. Rosbjerg, Water Resources Research, 42, W06603, doi:10.1029/2005WR004265.

112) Bowling, J.C., C. Zheng*, A.B. Rodriguez, and D.L. Harry, 2006, Geophysical constraints on contaminant transport modeling in a heterogeneous fluvial aquifer, J Contam. Hydrol., 85:72–88, doi:10.1016/j.jconhyd.2006.01.006.

113) Zheng, C., J. Lin, and D.R. Maidment, 2006, Internet data sources for groundwater modeling, Ground Water, 44(2):136-138, doi: 10.1111/j.1745-6584.2006.00196.x.

114) Wu, J., C. Zheng*, C.C. Chien, and L. Zheng, 2006, A comparative study of Monte Carlo simple genetic algorithm and noisy genetic algorithm for cost-effective sampling network design under uncertainty, Advances in Water Resources, 29:899–911, doi:10.1016/j.advwatres.2005.08.005.

115) Gorelick, S. M., G. Liu, and C. Zheng, 2005, Quantifying mass transfer in permeable media containing conductive dendritic networks, Geophysical Research Letters, 32, L18402, doi:10.1029/2005GL023512.

116) Bowling, J.C., A.B. Rodriguez, D.L. Harry, and C. Zheng, 2005, Delineating alluvial aquifer heterogeneity using resistivity and GPR data, Ground Water, 43(6):890–903.

117) Wang, P.P., C. Zheng*, and S. M. Gorelick, 2005, A general solution approach to advective-dispersive transport with multirate mass transfer, Advances in Water Resources, 28:33-42.

118) Wang, P.P., and C. Zheng*, 2005, Contaminant transport models under random sources, Ground Water, 43(3): 423-433.

119) Wu, J., C. Zheng*, and C. C. Chien, 2005, Cost-effective sampling network design for contaminant plume monitoring under general hydrogeological conditions, J. Contaminant Hydrology, 77: 41– 65, doi:10.1016/j.jconhyd.2004.11.006.

120) Lu, G., C. Zheng*, and A. Wolfsberg, 2005, Effect of uncertain hydraulic conductivity on the fate and transport of BTEX compounds at a field site, J. Environmental Engineering, v. 131, no. 5, 767-776.

121) Zheng, C., 2004, Model Viewer: a three-dimensional visualization tool for ground water modelers (software review), Ground Water, 42(2): 164-166.

122) Liu, G., C. Zheng*, and S. M. Gorelick, 2004, Limits of applicability of the advection-dispersion model in aquifers containing high-conductivity channels, Water Resources Research, v.40:W08308, doi:10.1029/2003WR002735.

123) Wu, J., and C. Zheng*, 2004, Contaminant monitoring network design: recent advances and future directions, Advance in Earth Sciences (in Chinese), 19(3):429-436.

124) Lu, G., and C. Zheng*, 2004, Natural attenuation of fuel hydrocarbon contaminants: Correlation of biodegradation with hydraulic conductivity in a field case study, Advance in Earth Sciences (in Chinese), 19(3):403-408.

125) Wu, J., and C. Zheng*, 2004, A general simulation-optimization approach for groundwater sampling network design, in Proc. International Symposium on Water Resources and the Urban Environment, China University of Geosciences-Wuhan, China.

126) Poeter, E., C. Zheng, M. C. Hill, and J. Doherty, eds., 2003, Proceedings of “MODFLOW and More 2003” International Conference (Volumes I and II), Colorado School of Mines, Golden, Colorado.

127) Zheng, C., and S.M. Gorelick, 2003, Analysis of solute transport in flow fields influenced by preferential flowpaths at the decimeter scale, Ground Water, 41(2): 142-155.

128) Prommer, H., D.A. Barry, and C. Zheng, 2003, A MODFLOW/MT3DMS based multicomponent reactive transport model, Ground Water, 41(2): 247-257.

129) Huang, W.E., S. Oswald, D.N. Lerner, C.C. Smith, and C. Zheng, 2003, Dissolved oxygen imaging in a porous medium to investigate biodegradation in a plume with limited electron acceptor supply, Environ. Sci. Tech, 37(9): 1905-1911.

130) Xie, X., J.J. Jiao, Z. Tang, and C. Zheng, 2003, Evolution of abnormally low pressure and its implications for the hydrocarbon system in the southeast uplift zone of Songliao basin, China, AAPG Bulletin, 87(1), 99–119.

131) Chien, C.C., M.A. Medina, Jr., G.F. Pinder, D.R. Reible, B.E. Sleep, C. Zheng, eds., 2003, Contaminated Ground Water and Sediment: Modeling for Management and Remediation, Lewis Publishers, FL, 288 p.

132) Hill, M.C., E. Poeter, C. Zheng, and J. Doherty, 2003, Foreword: MODFLOW-2001 and other modeling odysseys, Ground Water, 41(2):113-113.

133) Hill, M.C., E. Poeter, C. Zheng, and J. Doherty, eds., 2003, MODFLOW-2001 and other modeling odysseys: A special theme issue, Ground Water, 41(1):113-288.

134) Zheng, C., and G.D. Bennett, 2002, Applied Contaminant Transport Modeling 2nd edition, John Wiley & Sons, New York, 621 pp.

135) Barry, D.A., H. Prommer, C.T. Miller, P. Engesgaard, A. Brun, and C. Zheng, 2002, Modeling the fate of oxidisable organic contaminants in groundwater, Advances in Water Resources (25th anniversary edition), 25(8-12): 945–983.

136) Zheng C., and P.P. Wang, 2002, A field demonstration of the simulation-optimization approach for remediation system design, Ground Water, 40(3): 258-265.

137) Zheng, C., 2002, TopoDrive and ParticleFlow: Simple tools for learning ground water modeling (software review), Ground Water, 40(3):222-223.

138) Spiessl, S. M., M. Sauter, C. Zheng, and G. Liu, 2002, Comparison of two numerical methods for advection in a pipe network coupled to a continuum transport model, in Calibration and Reliability in Groundwater Modelling: A Few Steps Closer to Reality, IAHS Publ. 277:60-68, International Association of Hydrological Sciences.

139) Spiessl, S.M., H. Prommer, M. Sauter, and C. Zheng, 2002, Numerical simulation of uranium transport in flooded underground mines. In Uranium in the Aquatic Environment, Merkel, B.J., B. Planer-Friedrich, and C. Wolkersdorfer, eds., Springer Berlin, p. 273-282.

140) Spiessl, S.M., M. Sauter, H.S. Viswanathan, and C. Zheng, 2002, Simulation of dissolved uranium release from flooded underground mines under equilibrium conditions, in Uranium Deposits: From Their Genesis to Their Environmental Aspects, Kribek, B. and J. Zeman, eds., p. 167-170.

141) Julian, H.E., J.M. Boggs, C. Zheng, and C.E. Feehley, 2001, Numerical simulation of a natural gradient tracer experiment for the Natural Attenuation Study: flow and physical transport, Ground Water, 39(4): 534-545.

142) Zheng, C., and P.P. Wang, 2001, Application of evolutionary algorithms for remediation system design optimization on the Massachusetts Military Reservation, In Proc. 2001 World Environmental and Water Resources Congress, Orlando, FL.

143) Seo, S., E.P. Poeter, C. Zheng, and O. Poeter, eds., 2001, Proceedings of “MODFLOW 2001” International Conference (Volumes I and II), Colorado School of Mines, Golden, Colorado.

144) Wang, P.P., C. Zheng, D.T. Feinstein, 2001, A positivity preserving scheme for modeling advection-dominated solute transport, In Proc. MODFLOW 2001 International Conference, Colorado School of Mines, Golden, Colorado.

145) Liu, G., P.P. Wang, and C. Zheng, 2001, An explicit mass-conservative TVD scheme for solute transport modeling, In Proc. MODFLOW 2001 International Conference, Colorado School of Mines, Golden, Colorado.

146) Zheng, C., and S.M. Gorelick, 2001, Effect of decimeter-scale preferential flow paths on solute transport: implications for groundwater remediation, In Groundwater Quality: Natural and Enhanced Restoration of Groundwater Pollution, Thornton, S.F. and .E. Oswald, eds., IAHS Publ. 275:463-469, International Association of Hydrological Sciences.

147) Sun, M. and C. Zheng, 2000, Calibration of 3-D groundwater model using hydrogeological parameter zones, In Computational Methods in Water Resources, Proc. XIII International Conference on Computational Methods in Water Resources, Alberta, Canada.

148) Feehley C.E., C. Zheng*, and F.J. Molz, 2000, A dual-domain mass transfer approach for modeling solute transport in heterogeneous porous media, application to the MADE site, Water Resources Research, 36(9): 2501-2515.

149) Ouyang, Y. and C. Zheng, 2000, Surficial processes and CO2 flux in soil ecosystem, Journal of Hydrology, 234: 54-70.

150) Lu, G., C. Zheng*, R.J. Donahoe and W.B. Lyons, 2000, Controlling Processes in a CaCO3 precipitating Stream in Huanglong Natural Scenic District, Sichuan, China, Journal of Hydrology, 230(1-2).

151) Wang, P.P. and C. Zheng, 1999, Contaminant transport modeling under random sources, in Calibration and Reliability in Groundwater Modeling, Copying with Uncertainty, Stauffer, F. W. Kinzelbach, K. Kovar, and E. Hoehn, eds., IAHS Publ. 265:317-323, International Association of Hydrological Sciences.

152) Ouyang, Y. and C. Zheng, 1999, Density-driven transport of dissolved chemicals through unsaturated soil, Soil Science, 164(6): 376-390.

153) Zheng, C., and P.P. Wang, 1999, An integrated global and local optimization approach for remediation system design, Water Resources Research, 35(1): 137-146.

154) Lu, G., T.P. Clement, C. Zheng*, and T.H. Wiedemeier, 1999, Natural attenuation of BTEX compounds, model development and field-scale application, Ground Water, 37(5): 707-717.

155) Sun, M. and C. Zheng, 1999, Long-term groundwater management by a MODFLOW based dynamic optimization tool, Journal of American Water Resources Association, 35(1): 99-111.

156) Hunt, R. and C. Zheng, 1999, Debating complexity in modeling, EOS , Transactions, American Geophysical Union, 80(3): 29.

157) Zheng, C., C.E. Feehley, P.P. Wang, and M.S. Dortch, 1998, The ULTIMATE scheme for modeling three-dimensional multicomponent transport in heterogeneous aquifers, in Proc. MODFLOW’98 International Conference, Poeter, E.P., C. Zheng, and M.C. Hill, ed., Colorado School of Mines, Golden, CO.

158) Poeter, E.P., C. Zheng, and M.C. Hill, eds., 1998, Proceedings of “MODFLOW’98” International Conference on Groundwater Modeling (Volumes I and II), Colorado School of Mines, Golden, Colorado.

159) Zheng, C., P.P. Wang, C.C. Chien, and K.P. Garon, 1998, New advances in combining simulation and optimization for solving groundwater management problems, in Proc. MODFLOW’98 International Conference, Poeter, E.P., C. Zheng, and M.C. Hill, eds., Colorado School of Mines, Golden, CO.

160) Guerin, M. and C. Zheng, 1998, GMT3D – Coupling multicomponent, three-dimensional transport with geochemistry, , in Proc. MODFLOW’98 International Conference, Poeter, E.P., C. Zheng, and M.C. Hill, eds., Colorado School of Mines, Golden, CO.

161) Clement, T.P., Y. Sun, and C. Zheng, RT3D (v.20), 1998, A MODFLOW family reactive transport simulator, in Proc. MODFLOW’98 International Conference, Poeter, E.P., C. Zheng, and M.C. Hill, eds., Colorado School of Mines, Golden, CO.

162) Neville, C.J., M.J. Riley, and C. Zheng, Implicit modeling of low permeability features: an appraisal for solute transport, in Proc. MODFLOW’98 International Conference, Poeter, E.P., C. Zheng, and M.C. Hill, eds., Colorado School of Mines, Golden, CO.

163) Wang, M. and C. Zheng, 1998, Application of genetic algorithms and simulated annealing in groundwater management: formulation and comparison, Journal of American Water Resources Association, 34(3): 519-530.

164) Jiao, J.J. and C. Zheng*, 1998, Abnormal fluid pressures caused by erosion and subsidence of sedimentary basins, Journal of Hydrology, 204: 124-137.

165) Zheng, C. and J.J. Jiao, 1998, Numerical simulation of tracer tests in a heterogeneous aquifer, Journal of Environmental Engineering, 124(6): 510-516.

166) Wang, P.P. and C. Zheng*, 1998, An efficient approach for successively perturbed groundwater models, Advances in Water Resources, 21: 499-508.

167) Wang, M. and C. Zheng*, 1997, Optimal remediation policy selection under general conditions, Ground Water, 35(5): 757-764.

168) Jiao, J.J. and C. Zheng*, R. J.-C. Hennet, 1997, Analysis of underpressured geological formations for disposal of hazardous wastes, Hydrogeology Journal, 5(3): 19-31.

169) Jiao, J.J. and C. Zheng*, 1997, The difference in the characteristics of aquifer parameters and the implication on pump-test analysis, Ground Water, 35(1): 25-29.

170) Zheng, C. and P.P. Wang, 1996, Parameter structure identification using tabu search and simulated annealing, Advances in Water Resources, 19(4): 215-224.

171) Wang, M. and C. Zheng. 1996. Parameter estimation for transient and steady-state flow models using genetic algorithms, in ModelCARE 96: Calibration and Reliability in Groundwater Modeling, K. Kavar and P. van de Heijde, eds., IAHS Publ. 237: 21-30, International Association of Hydrological Sciences.

172) Zheng, C., and G.D. Bennett, 1995, More on the role of simulation in hydrogeology, Ground Water, 33(6): 1040-41.

173) Zheng, C., and G.D. Bennett, 1995, Applied Contaminant Transport Modeling: Theory and Practice, Van Nostrand Reinhold (now John Wiley & Sons), New York, 440 pp.

174) Hill, M.C. and C. Zheng, 1995, Progress made in groundwater flow and transport modeling, EOS, Trans., AGU, 76(40): 393-394.

175) Zheng, C, 1994, Analysis of particle tracking errors associated with spatial discretization, Ground Water, 32(5): 821-828.

176) Sun M. and C. Zheng, 1994. An accurate and efficient local grid refinement approach for finite difference groundwater models. In Proc. 2nd International Conference on Groundwater Ecology, Atlanta, Georgia.

177) Sun, M., C. Zheng, and D. Tian. 1994. A backward random walk particle tracking method for predicting groundwater flow and contaminant levels at observation sites. In Proc. 1994 Groundwater Modeling Conference, Colorado State University, Fort Collin, p. 163-172.

178) Zhou, W. and C. Zheng, 1994. Numerical modeling of unsaturated seepage near a cavity in fractured rock. In Proc. 1994 Groundwater Modeling Conference, Colorado State University, Fort Collin, p. 395-403.

179) Zheng, C., 1993, Extension of the method of characteristics for simulation of solute transport in three dimensions, Ground Water, 31(3): 456-465.

180) Zheng, C., G.D. Bennett and C. B. Andrews, 1992, Reply to discussion of “Analysis of ground water remedial alternatives at a Superfund site”, Ground Water, 30(3): 440-442.

181) Zheng, C., K.R. Bradbury, and M.P. Anderson, 1992. A Computer Model for Calculation of Groundwater Paths and Travel Times in Transient Three-Dimensional Flows, Wisconsin Geological and Natural History Survey Information Circular 70, 21 pp.

182) Zheng, C., G.D. Bennett and C. B. Andrews, 1991, Analysis of ground water remedial alternatives at a Superfund site. Ground Water, 29(6): 838-848.

183) Zheng, C., M. P. Anderson, and K. R. Bradbury, 1989, Effectiveness of hydraulic methods for controlling groundwater pollution. In Groundwater Contamination, L.M. Abriola, ed., IAHS Publication 185, p. 173-179, International Association of Hydrological Sciences.

184) Zheng, C., H.F. Wang, M. P. Anderson, and K. R. Bradbury, 1988, Analysis of interceptor ditches for control of ground-water pollution, Journal of Hydrology, 98: 67-81.

185) Zheng, C., K.R. Bradbury, and M.P. Anderson, 1988, Role of interceptor ditches in limiting the spread of contaminants in ground water. Ground Water, 26(6): 734-742.

186) Zheng, C. and M.P. Anderson, 1986, A review of application of stream functions to ground-water flows. J. Chengdu College of Geology (China), 13(3): 109-118.

 

中文专著:

187) 郑春苗、万力等,2009,中国地下水科学的机遇与挑战,科学出版社,北京。

188) 郑春苗、冯夏红、编辑,2008,环境地球科学,高等教育出版社,北京。

189) 齐永强、石效卷、郑春苗等,2015,潜行的宝藏-写给环保人的地下水科学,中国环境出版社,北京。

中文译著:

190) 刘杰、郑春苗(译),2015,水文科学的挑战与机遇(Challenges and Opportunities in the Hydrologic Sciences),美国国家研究理事会,科学出版社,北京。

计算机软件:

191) Zheng, C., 2010, MT3DMS v5.3 Supplemental User’s Guide, Report to the US Army Engineer Research and Development Center, Department of Geological Sciences, University of Alabama. (下载网址:http://hydro.geo.ua.edu/mt3d).

192) Zheng, C., and P.P. Wang, 2003, MGO: A Modular Groundwater Optimizer incorporating MODFLOW and MT3DMS; Documentation and User’s Guide, The University of Alabama and Groundwater Systems Research Ltd. (下载网址:http://www.frtr.gov/estcp/source_codes.htm).

193) Zheng, C., M.C. Hill, and P.A. Hsieh, 2001, MODFLOW-2000, The U.S. Geological Survey Modular Ground-Water Model—User Guide to the LMT6 Package, the Linkage with MT3DMS for Multi-Species Mass Transport Modeling, US Geological Survey Open-File Report 01-82, Reston, Virginia. (下载网址:http://water.usgs.gov/software/modflow-2000.html).

194) Zheng, C. and P.P. Wang, 1999, MT3DMS: A Modular Three-Dimensional Multi-species Transport Model for Simulation of Advection, Dispersion and Chemical Reactions of Contaminants in Groundwater Systems; Documentation and User’s Guide, Contract Report SERDP-99-1, U.S. Army Engineer Research and Development Center, Vicksburg, MS, 169 pp. (网址网址:http://hydro.geo.ua.edu/mt3d).

195) Zheng, C., 1997, ModGA: A Genetic Algorithm Based Groundwater Flow and Transport Optimization Model MODFLOW and MT3D, Report to DuPont Company, Hydrogeology Program, University of Alabama, 95 pp.

196) Zheng, C., 1997, ModGA_P: Parameter Estimation Using Genetic Algorithms, Report to DuPont Company, Hydrogeology Program, University of Alabama, 35 pp.

197) Zheng, C., 1990, MT3D, A Modular Three-Dimensional Transport Model for Simulation of Advection, Dispersion and Chemical Reactions of Contaminants in Groundwater Systems, Report to the United States Environmental Protection Agency, 170 pp. (网址网址:http://www.epa.gov/ada/csmos.html).

198) Zheng, C., 1990. MT3D Documentation and User's Guide, S.S. Papadopulos & Associates, Inc., 180 pp.

199) Zheng, C., 1989. PATH3D: A Ground-Water Path and Travel-Time Simulator, User's Manual. S.S. Papadopulos & Associates, Inc., 50 pp.