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杨志兵

通讯员：发布时间：2022-03-02 点击数：

个人简介：杨志兵，男，湖南人，1982年生，澳门新永利网站教授、博士生导师。2005年6月获山西大学环境工程工学学士学位，2008年6月获北京师范大学环境工程专业硕士学位，2012年获瑞典乌普萨拉大学地球科学系地下水水文学博士学位。博士期间(2009-2010)曾作为访问博士生在美国科罗拉多矿业学院环境科学与工程系学习。2013年1月至2014年11月在瑞典乌普萨拉大学从事博士后研究，2014年12月至2016年12月在美国麻省理工学院土木与环境工程系开展博士后研究。2017年聘为澳门新永利网站教授。2012年度获国家优秀自费职工奖学金。2017年入选国家海外优秀人才引进计划青年项目。曾主持瑞典科学基金会项目1项（262.5万SEK）、国家自然科学基金面上项目2项、国家重点研发计划子课题1项、国家重点实验室仪器研发项目1项。

个人主页: http://jszy.whu.edu.cn/zhibingyang/zh_CN/index.htm

研究方向：长期致力于地质介质多相渗流机理与控制方法研究，目前主要研究方向：(1)多孔及裂隙介质多相渗流机理；(2)地下水模拟及污染物迁移与修复（化工/石油污染物、矿区污染、岩溶地下水环境等）；(3)二氧化碳地质封存(数值模拟、不确定性分析、储层容量评估等)；(4)多相渗流-颗粒力学耦合机理及应用。以第一和通讯作者在ES&T、GRL、WRR、WR等国内外主流期刊发表论文40余篇，参与编写英文专著1部，授权/申请国家发明专利4项。渗流机理与控制研究成果将服务于我国重大水利水电工程建设与长期安全、土壤与地下水污染防治、双碳愿景目标实现等重要战略。

研究方法和条件：多尺度数值模拟（分子动力学模拟、孔隙网络模型、离散元模拟、CFD-DEM、深地储层多相流模拟器TOUGH系列软件、岩溶含水层地下水流动和污染物迁移模拟（KarstFlow3D、KarstTrans3D）、土壤与地下水污染修复模拟等）、微观渗流可视化试验（激光扫描共聚焦显微镜、光学倒置显微镜、平面激光扫描成像、微流控技术等）。

教学工作：工程地质、水文学与水文地质、自然地理、地质实习、水利工程渗流分析与控制 （澳门新永利网站）；Groundwater、Global Hydrology、Runoff and Groundwater Modelling （at Uppsala University）；Computer Programming for Scientific and Engineering Applications （at MIT，as Postdoc Teaching Fellow）

Zhibing Yang is a professor at the School of Water Resources and Hydropower Engineering, Wuhan University. His main research interests focus on the complex transport phenomena of fluids and particles in geological media across scales with applications in, e.g., subsurface hydrology, environmental remediation and earth resources engineering.

Ph.D., Uppsala University, 2008-2012 (Supervisor: Prof. Auli Niemi; Prof. Fritjof Fagerlund)

Visiting Scholar, Colorado School of Mines, 2009-2010 (Supervisor: Prof. Tissa Illangasekare)

Postdoctoral researcher, Uppsala University, 2013-2014 (Supervisor: Prof. Auli Niemi)

Postdoctoral researcher, MIT, 2014-2016 (Supervisor: Prof. Ruben Juanes)

具体方向主要论文Selected publications（下划线作者为指导或合作指导的研究生）：

多相渗流和非饱和渗流 (Multiphase flow and unsaturated flow in porous and fractured media)：

Zhou, Z., Yang, Z., Xue, S., Hu, R., & Chen, Y. F. (2022). Liquid breakthrough time in an unsaturated fracture network. Water Resources Research, e2021WR031012. (click here)

A, H., Yang, Z., Hu, R., Chen, Y. F. (2022). Roles of energy dissipation and asymmetric wettability in spontaneous imbibition dynamics in a nanochannel. Journal of Colloid and Interface Science, 607, 1023-1035. (click here)

Zhou, Z., Yang, Z., Luo, C., Xue, S., Yao, C., Hu, R., & Chen, Y.-F. (2023). Influence of Inertia on Liquid Splitting at Fracture Intersections. Journal of Hydrology, 129270. (click here)

A, H., Yang, Z., Hu, R., & Chen, Y.-F. (2023). Molecular Origin of Wetting Characteristics on Mineral Surfaces. Langmuir, 39(8), 2932–2942. (click here)

Xue, S., Yang, Z., Hu, R., & Chen, Y.-F. (2020). Splitting Dynamics of Liquid Slugs at a T-Junction. Water Resources Research, 56(8), e2020WR027730. (click here)

Yang, Z., Méheust, Y., Neuweiler, I., Hu, R., Niemi, A., & Chen, Y. F. (2019). Modeling immiscible two‐phase flow in rough fractures from capillary to viscous fingering. Water Resources Research, 55(3), 2033-2056. (click here)

A, H., Yang, Z., Hu, R., Chen, Y. F., & Yang, L. (2020). Effect of Solid–Liquid Interactions on Substrate Wettability and Dynamic Spreading of Nanodroplets: A Molecular Dynamics Study. J. Phys. Chem. C, 124, 23260-23269. (click here)

Yang, Z., Xue, S., Zheng, X., & Chen, Y. F. (2019). Partitioning Dynamics of Gravity‐Driven Unsaturated Flow Through Simple T‐Shaped Fracture Intersections. Water Resources Research, 55(8), 7130-7142. (click here)

Yang, Z., Li, D., Xue, S., Hu, R., & Chen, Y. F. (2019). Effect of aperture field anisotropy on two-phase flow in rough fractures. Advances in Water Resources, 132, 103390. (click here)

Yang, Z., I. Neuweiler, Y. Méheust, F. Fagerlund, & A. Niemi (2016). Fluid trapping during capillary displacement in fractures. Advances in Water Resources, 95, 264-275. (click here)

Yang, Z., A. Niemi, F. Fagerlund & T. Illangasekare (2013). Two-phase flow in rough-walled fractures: comparison of continuum and invasion-percolation models. Water Resources Research. 49(2), 993–1002. (click here)

Yang, Z., A. Niemi, F. Fagerlund, & T. Illangasekare (2012). A generalized approach for estimation of in-plane curvature in invasion percolation models for drainage in fractures. Water Resources Research, 48(9), W09507. (click here)

Hu, R., Wu, D. S., Yang, Z., & Chen, Y. F. (2018). Energy conversion reveals regime transition of imbibition in a rough fracture. Geophysical Research Letters, 45(17), 8993-9002. (click here)

da Silva, J. A., Kang, P. K., Yang, Z., Cueto‐Felgueroso, L., & Juanes, R. (2019). Impact of Confining Stress on Capillary Pressure Behavior During Drainage Through Rough Fractures. Geophysical Research Letters, 46(13), 7424-7436. (click here)

Zhao, B., MacMinn, C. W., Primkulov, B. K., Chen, Y., Valocchi, A. J., Zhao, J., Q. Kang, K. Bruning, J. E. McClure, C. T. Miller, A. Fakhari, D. Bolster, T. Hiller, M. Brinkmann, L. Cueto-Felgueroso, D. A. Cogswell, R. Verma, M. Prodanović, J. Maes, S. Geiger, M. Vassvik, A. Hansen, E. Segre, R. Holtzman, Z. Yang, C. Yuan, B. Chareyre, R. Juanes (2019). Comprehensive comparison of pore-scale models for multiphase flow in porous media. Proceedings of the National Academy of Sciences, 201901619. (click here)

渗流-颗粒力学耦合机理 (Coupled processes of flow and granular mechanics)

Zhang, R., Yang, Z., Detwiler, R., Li, D., Ma, G., Hu, R., & Chen, Y.-F. (2023). Liquid cohesion induced particle agglomeration enhances clogging in rock fractures. Geophysical Research Letters, 50(5), e2022GL102097. (click here)

Li, D., Yang, Z., Zhang, R., Hu, R., & Chen, Y. F. (2022). Morphological patterns and interface instability during withdrawal of liquid-particle mixtures. Journal of Colloid and Interface Science, 608, 1598-1607. (click here)

Wu, T., Yang, Z., Hu, R., Chen, Y.F., Zhong, H., Yang, L. & Jin, W. (2021). Film entrainment and microplastic particles retention during gas invasion in suspension-filled microchannels. Water Research, 194, p.116919. (click here)

Yang, Z., & Juanes, R. (2018). Two sides of a fault: Grain-scale analysis of pore pressure control on fault slip. Physical Review E, 97(2), 022906. (click here)

Hu, X., Yang, Z., & Chen, Y. F. (2021). Fluid-driven particle transport patterns in a confined geometry: Effect of flow velocity and particle concentration. Journal of Natural Gas Science and Engineering, 92, 103998. (click here)

Meng, Y., Primkulov, B. K., Yang, Z., Kwok, C. Y., & Juanes, R. (2020). Jamming transition and emergence of fracturing in wet granular media. Physical Review Research, 2(2), 22012. (click here)

地下水污染与修复（Groundwater contamination and remediation: NAPLs, microplastics, colloids）:

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Wu, T., Yang, Z., Hu, R., Chen, Y.F. (2023). Three-Dimensional Visualization Reveals Pore-Scale Mechanisms of Colloid Transport and Retention in Two-Phase Flow. Environmental Science & Technology, 57, 1997−2005. (click here, ES&T cover)

Xiong, X., Yang, Z., Hu, R., & Chen, Y. F. (2023). Predicting colloid transport and deposition in an array of collectors. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 659, 130762. (click here)

Wang, Z., Yang, Z., Hu, R., & Chen, Y. F. (2022) Mass transfer during surfactant-enhanced DNAPL remediation: pore-scale experiments and new correlation, Journal of Hydrology, 621, 129586 (click here)

He, H., Wu, T., Chen, Y.F., Yang, Z. (2023). A pore-scale investigation of microplastics migration and deposition during unsaturated flow in porous media. Science of the Total Environment, 858, 159934. (click here)

Wang, Z., Yang, Z., Fagerlund, F., Zhong, H., Hu, R., Niemi, A., Illangasekare, T., & Chen, Y. F. (2022). Pore-Scale Mechanisms of Solid Phase Emergence During DNAPL Remediation by Chemical Oxidation. Environmental Science & Technology, 56, 16, 11343–11353. (click here)

Xiong, X., Yang, Z., Hu, R., & Chen, Y. F. (2022). Evaluating Single-Collector Efficiencies of Colloid Deposition from Lagrangian Simulations: Geometric Models and Particle Release Scenarios. Water Resources Research, e2022WR033821. (click here)

He H., Wu, T., Chen, Y.F., Yang, Z. (2022). A pore-scale investigation of microplastic migration and deposition during unsaturated flow in porous media. Science of the Total Environment, 159934. (click here)

Yang, Z., A. Niemi, F. Fagerlund, T. Illangasekare & R. Detwiler (2013). Dissolution of dense non-aqueous phase liquids in vertical fractures: effect of finger residuals and dead-end pools. Journal of Contaminant Hydrology, 149, 88-99. (click here)

Yang, Z., A. Niemi, F. Fagerlund, & T.H. Illangasekare (2012). Effect of single-fracture aperture statistics on entrapment, dissolution and source depletion behavior of dense non-aqueous phase liquids. Journal of Contaminant Hydrology, 133, 1-16. (click here)

Yang, Z., H. Zandin, A. Niemi, & F. Fagerlund (2013), The role of geological heterogeneity and variability in water infiltration on non-aqueous phase liquid migration. Environmental Earth Sciences, 68(7), 2085-2097. (click here)

二氧化碳地质封存（Geological storage of CO₂）：

Joodaki, S., Yang, Z., Bensabat, J., & Niemi, A. (2020). Model analysis of CO2 residual trapping from single-well push pull test based on hydraulic withdrawal tests -- Heletz, residual trapping experiment I. International Journal of Greenhouse Gas Control, 97, 103058. (click here)

Yang, Z., Chen, Y.-F., & Niemi, A. (2020). Gas migration and residual trapping in bimodal heterogeneous media during geological storage of CO2. Advances in Water Resources, 103608. (click here)

Basirat, F., Yang, Z., Bensabat, J., Levchenko, S., Pan, L., & Niemi, A. (2020). Characterization of CO2 self-release during Heletz Residual Trapping Experiment I (RTE I) using a coupled wellbore-reservoir simulator. International Journal of Greenhouse Gas Control, 102, 103162. (click here)

Basirat, F., Z. Yang, & Niemi A. (2017). Pore-scale modeling of wettability effects on CO2–brine displacement during geological storage. Advances in Water Resources, 109, 181-195. (click here)

Yang, Z., A. Niemi, L. Tian, Saba Joodaki, & M. Erlström (2015). Modeling of pressure buildup and estimation of maximum injection rate for geological CO2 storage at the South Scania site, Sweden. Greenhouse Gases: Science and Technology, 5(3), 277-290. (click here)

Yang Z., L. Tian, B. Jung, S. Joodaki, F. Fagerlund, R. Pasquali, R. Vernon, N. O’Neill, & A. Niemi (2015). Assessing CO2 storage capacity in the Dalders Monocline of the Baltic Sea Basin using dynamic models of varying complexity. International Journal of Greenhouse Gas Control. 43, 149-160. (click here)

Yang, Z., L. Tian, A. Niemi & F. Fagerlund (2013). Upscaling of the constitutive relationships for CO2 migration in multimodal heterogeneous formations. International Journal of Greenhouse Gas Control. 19, 743-755. (click here)

岩溶水文地质 （Karst Hydrogeology）：

Zheng, X., Yang, Z., Wang, S., Chen, Y. F., Hu, R., Zhao, X. J., ... & Yang, X. L. (2021). Evaluation of hydrogeological impact of tunnel engineering in a karst aquifer by coupled discrete-continuum numerical simulations. Journal of Hydrology, 597, 125765. (click here)

Zhou, B. Q., Yang, Z., Hu, R., Zhao, X. J., & Chen, Y. F. (2021). Assessing the impact of tunneling on karst groundwater balance by using lumped parameter models. Journal of Hydrology, 599, 126375. (click here)

郑小康, 杨志兵. 岩溶含水层饱和-非饱和流动与污染物运移数值模拟[J]. 地质科技通报, 2022, 41(5): 357-366. (click here)

专利与软件著作权 （Patents and Software）：

杨志兵，薛松，郑小康，陈益峰，赵先进. 一套模拟交叉裂隙渗流的可视化试验装置及方法，专利号：ZL 201810896871.4, 授权时间2019年7月

杨志兵，薛松，李东奇，陈益峰. 一种快速测量液滴动态接触角的装置及方法. 专利号：ZL202010071170.4, 授权时间: 2021年5月4日

杨志兵，李东奇，薛松，陈益峰. 变开度可拆卸的仿真裂隙试验装置及试验方法. 专利号：ZL202010298229.3, 授权时间: 2021年2月19日

杨志兵，郑小康等，岩溶地下水三维数值模拟软件（KarstFlow3D v1.0），计算机软件著作权登记，2022SR0781934

杨志兵，郑小康等，岩溶地下水溶质运移三维数值模拟软件（KarstTrans3D v1.0），计算机软件著作权登记，2022SR0825428

课题组与美国、瑞典、德国、法国等国家的多所著名高校的知名学者、团队有着密切的合作关系。

课题组诚招1-2名优秀博士后合作研究，欢迎推荐或自我推荐！

课题组诚招硕士、博士研究生一起在科研征程中攻坚克难，欢迎感兴趣的同学报考!

邮箱：zbyang[at]whu.edu.cn