职称:教授,博士生导师
邮箱:whuran@whu.edu.cn
个人学术网站:https://www.researchgate.net/profile/Ran_Hu4
https://scholar.google.com/citations?user=pgmuIF0AAAAJ&hl=en
研究方向:岩土多相渗流、渗流-侵蚀-变形耦合、CO2地质封存、库坝渗流
招生专业:水工结构工程
招生类型:学术博士、学术学位硕士、专业学位硕士
研究内容:岩土多相渗流是水利、地学、能源和环境等领域共同关注的前沿研究方向,在库坝长期防渗安全、CO2地质封存和油气资源高效开采等工程实践中具有广阔的应用前景。本研究组的主要研究内容包括:多相渗流多尺度可视化实验技术与细观数值模拟方法;力学变形和化学反应等复杂条件下多相渗流的细观-宏观机理、岩土多相渗流-侵蚀-变形耦合机理;岩土多相渗流-变形大尺度高效模拟方法与工程应用
2008/09-2013/06 350vip浦京集团官方授权 水工结构工程,博士
2011/07-2012/07美国劳伦斯伯克利国家实验室,访问学者
2004/09-2008/06 350vip浦京集团官方授权 水利水电工程,本科
2019/11至今 350vip浦京集团官方授权,教授(2018年9月聘为博导)
2015/11-2019/11 350vip浦京集团官方授权,副教授
2015/03-2016/08 美国劳伦斯伯克利国家实验室,博士后
2013/11-2015/11 350vip浦京集团官方授权,讲师
《工程地质》(本科生)
《海洋工程概论》(本科生)
《岩石力学与岩体工程》(研究生)
《水利工程渗流分析与控制》(研究生)
[1] 国家自然科学基金优秀青年基金项目:岩土多相渗流理论(2022/01~2024/12,主持)
[2] 国家自然科学基金面上项目:超临界CO2-水两相渗流条件下岩石溶蚀机理与储层渗透性演化规律(2024/01~2027/12,主持)
[3] 国家自然科学基金基础科学中心项目课题:岩体结构面渗流/多相渗流-侵蚀耦合机理(2020/01~2024/12,主持)
[4] 中央高校优秀青年团队项目:流域库坝群安全控制理论与关键技术(2023/01~2024/12,主持)
[5] 国家重点实验室科研仪器设备研制项目:耐高温高压条件孔隙尺度多相流可视化实验系统(2020/01~2022/12,主持)
[6] 国家自然科学基金面上项目:孔隙介质超临界CO2毛细捕获机制与两相流宏观特性(2018/01~2021/12,主持)
[7] 国家自然科学基金青年基金:库水涨落区全强风化岩水-力-损伤耦合特性与岸坡失稳机制(2014/01~2016/12,主持)
[8] 国家重点研发计划子课题:库区与枢纽区地质环境演化规律及预测方法(2018/07~2021/12,主持)
[9] 国家重点研发计划子课题:原地浸矿工艺的适用性评价和可控堆浸工艺流场调控(2019/10~2022/09,主持)
[10] 中国博士后第八批特别资助项目:库水涨落区第四纪土坡水-力全耦合特性与时效变形机制(2015/06~2017/03,主持)
2023至今,《Journal of Rock Mechanics and Geotechnical Engineering》(SCI)科学编辑(Scientific Editors)
2023至今,《Biogeotechnics》编委
2020至今,《Advances in Geo-Energy Research》(EI),青年编委
2020至今,中国大坝工程学会库坝渗流与控制专委会 副秘书长
2019至今,中国水利学会地下水科学与工程专委会 委员
2018至今,中国岩石力学与工程学会青年工作委员会 委员
2016至今,美国地球物理联合会 会员
湖北省科技进步一等奖(2022,排名第2)
教育部科技进步一等奖(2016,排名第4)
350vip浦京集团官方授权珞珈青年学者(2016,排名第1)
湖北省优秀博士论文奖(2015,排名第1)
湖北省科技进步一等奖(2012,排名第9)
以第一或通讯作者在地学领域顶级期刊GRL(6篇)和JGR: Solid Earth、水利领域TOP1期刊WRR(7篇)、流体力学领域顶级期刊JFM和PRFluids(2篇),以及《力学学报》等高水平期刊上发表论文40余篇,引用3000余次,出版专著1部,授权发明专利10项,软著权登记3项,参编标准2部。近年发表的重要论文如下(所有论文见个人学术网站):
-2024-
[1] Chen, X.-S., Hu, R.*, Zhou, C.-X., Xiao, Y., Yang, Z., Chen, Y.-F. Capillary-driven backflow during salt precipitation in a rough fracture. Water Resources Research, 2024, 60(3), e2023WR035451.
[2] Li, K., Hu, R.*, Wang, T., Yang, Z., & Chen, Y.-F. (2024). Buoyancy-Driven Dissolution Instability in a Horizontal Hele-Shaw Cell. Langmuir, 40(8), 4186–4197. 【封面论文】
[3] Li, K., Hu, R.*, Chen, X.-S., Yang, Z., Chen, Y.-F. Phase diagram and permeability evolution for dissolving vertical fractures in a gravity field. Advances in Water Resources, 2024, 185, 104633.
-2023-
[4] Guo, W., Hu, R.*, Zhou, C.-X., Yang, Z., & Chen, Y.-F. (2023). Dissolution regimes of a horizontal channel in a gravity field. Physical Review Fluids, 8(12), 123902.
[5] Zhou, C.-X., Hu, R.*, Deng, H., Ling, B.*, Yang, Z., & Chen, Y.-F. (2023). Surface-volume scaling controlled by dissolution regimes in a multiphase flow environment. Geophysical Research Letters, 50, e2023GL104067.【代表作】
[6] Hu, R.*, Li, K.*, Zhou, C.-X., Wang, T., Yang, Z., & Chen, Y.-F. On the role of gravity in dissolving horizontal fractures. Journal of Geophysical Research: Solid Earth, 2023, 128, e2022JB025214. 【代表作】
[7] Wang, T., Hu, R.*, Yang, Z., Chen, Y.-F., Li, Y., & Zhou, C.-B. Reactive-infiltration instability in a Hele-Shaw cell influenced by initial aperture and flow rate. Physical Review Fluids, 2023, 8(4), 043901.
[8] 胡冉*, 钟翰贤, 陈益峰. 变开度岩体裂隙多相渗流实验与有效渗透率模型. 力学学报, 2023, 55(2), 543–553. https://doi.org/10.6052/0459-1879-22-500
[9] 张子翼, 胡冉*, 廖震, 陈益峰. 重力条件下粗糙裂隙溶蚀过程的可视化试验研究. 水文地质工程地质, 2023, 50(0): 1-11. doi: 10.16030/j.cnki.issn.1000-3665.202204044
[10] 王冠雄, 胡冉*, 兰天, 陈益峰. 多孔介质中角膜-液桥流对毛管压力曲线的影响. 土木与环境工程学报(中英文), 2023 doi: 10.11835/j.issn.2096-6717.2023.108
-2022-
[11] Zhou, C.-X., Hu, R.*, Li, H.-W., Yang, Z., & Chen, Y.-F. Pore-scale visualization and quantification of dissolution in microfluidic rough channels. Water Resources Research, 2022, 58, e2022WR032255.
[12] Lan, T., Hu, R.*, Guo, W., Wei, G.-J., Chen, Y.-F.*, & Zhou, C.-B. Direct prediction of fluid-fluid displacement efficiency in ordered porous media using the pore structure. Water Resources Research, 2022, 58, e2021WR031875.
[13] Wang T., Hu, R.*, Yang, Z., Zhou, C.-X., Chen, Y.-F.*, Zhou, C.-B. Transitions of dissolution patterns in rough fractures, Water Resources Research, 2022, doi: 10.1029/2021WR030456
[14] Lan, T., Hu, R.*, Yang, Z. and Chen, Y.-F. A pore filling-based model to predict quasi-static displacement patterns in porous media with pore size gradient. Frontiers in Physics, 2022, 10: 993398.
[15] Guo, W., Hu, R.*, Chen, X.-S., Yang, Z., & Chen, Y.-F. Crossover from diffusive to convective regimes during miscible displacements in 2D porous media. International Journal of Heat and Mass Transfer, 2022, 196, 123306.
[16] Chen, Y.-F.*, Ye, Y., Hu, R.*, Yang, Z., Zhou, C.-B. Modeling unsaturated flow in fractured rocks with scaling relationships between hydraulic parameters. Journal of Rock Mechanics and Geotechnical Engineering, 2022, 14(6), 1697–1709.
-2021-
[17] Hu, R., Wang, T., Yang, Z., Xiao, Y., Chen, Y.-F., Zhou, C.-B. Dissolution Hotspots in Fractures. Geophysical Research Letters, 2021, 48(20), e2021GL094118. 【代表作】
[18] Wu, D.-S., Hu, R.*, Lan, T., Chen, Y.-F. Role of Pore-Scale Disorder in Fluid Displacement: Experiments and Theoretical Model. Water Resources Research, 2021, 57(1), e2020WR028004.
[19] Chen X.-S., Hu, R.*, Guo, W., Chen, Y.-F. Experimental observation of two distinct finger regimes during miscible displacement in fracture, Transport in Porous Media, 2021, doi: 10.1007/s11242-021-01547-9
[20] 魏鹳举, 胡冉*, 廖震, 陈益峰. 湿润性对孔隙介质两相渗流驱替效率的影响. 力学学报, 2021, 53(4): 1008-1017.
-2020-
[21] Lan, T., Hu, R.*, Yang, Z., Wu, D.-S., Chen, Y.-F*. Transitions of Fluid Invasion Patterns in Porous Media. Geophysical Research Letters, 2020, 47(20), e2020GL089682.
[22] Chen, Y.-F.*, Yu, H., Ma, H.-Z., Li, X., Hu, R.*, Yang, Z. Inverse modeling of saturated-unsaturated flow in site-scale fractured rocks using the continuum approach: A case study at Baihetan dam site, Southwest China. Journal of Hydrology, 2020, 584:124693.
-2019-
[23] Hu, R.*, Zhou, C.-X., Wu, D.-S., Yang, Z., Chen, Y.-F*. Roughness control on multiphase flow in rock fractures. Geophysical Research Letters, 2019, 46(21), 12002-12011.
[24] Hu, R.*, Lan, T., Wei, G.-J., Chen, Y.-F*. Phase diagram of quasi-static immiscible displacement in disordered porous media. Journal of Fluid Mechanics, 2019, 875: 448-475.
-2018-
[25] Hu, R., Wan, J., Yang, Z., Chen, Y.-F.*, Tokunaga, T. Wettability and flow rate impacts on immiscible displacement: A theoretical model. Geophysical Research Letters, 2018, 45(7): 3077-3086. 【代表作】
[26] Hu, R., Wu, D.-S.*, Yang, Z., Chen, Y.-F*. Energy conversion reveals regime transition of imbibition in a rough fracture. Geophysical Research Letters, 2018, 45(17): 8993-9002.
[27] Chen, Y.-F., Guo, N., Wu, D.-S., Hu, R*. Numerical investigation on immiscible displacement in 3D rough fracture: Comparison with experiments and the role of viscous and capillary forces. Advances in Water Resources, 2018, 118:30-49.
[28] Chen, Y.-F.*, Ling, X.-M., Liu, M.-M., Hu, R.*, Yang, Z. Statistical distribution of hydraulic conductivity of rocks in deep-incised valleys, Southwest China. Journal of Hydrology, 2018, 556: 216-226.
[29] Chen, Y.-F., Wu, D.-S., Fang, S., Hu, R*. Experimental study on two-phase flow in rough fracture: Phase diagram and localized flow channel. International Journal of Heat and Mass Transfer, 2018, 122: 1298-1307.
[30] Hu, R., Hong, J.-M., Chen, Y.-F.*, Zhou, C.-B. Hydraulic hysteresis effects on the coupled flow–deformation processes in unsaturated soils: Numerical formulation and slope stability analysis. Applied Mathematical Modelling, 2018,54:221-245.
[31] 胡冉, 陈益峰, 万嘉敏, 周创兵, 超临界CO2-水两相流与CO2毛细捕获: 微观孔隙模型实验与数值模拟研究, 力学学报, 2017, 49(3), 638-648.
-2017-
[32] Chen, Y. F., Fang, S., Wu, D. S., Hu, R*. Visualizing and quantifying the crossover from capillary fingering to viscous fingering in a rough fracture. Water Resources Research, 2017, 53(9): 7756–7772. 【代表作】
[33] Hu, R., Wan, J.*, Kim, Y., Tokunaga, T. K. Wettability impact on supercritical CO2 capillary trapping: Pore-scale visualization and quantification. Water Resources Research, 2017,53(8): 6377-6394.
[34] Hu, R., Chen, Y.-F.*, Zhou, C.-B., Liu, H.-H. A numerical formulation with unified unilateral boundary condition for unsaturated flow problems in porous media. Acta Geotechnica,2017,12: 277-291.
[35] Hu, R., Wan, J.*, Kim, Y., Tokunaga, T. K. Wettability effects on supercritical CO2–brine immiscible displacement during drainage: Pore-scale observation and 3D simulation. International Journal of Greenhouse Gas Control, 2017, 60: 129-139.
-2016-
[36] Hu, R., Chen, Y. F.*, Liu, H. H., Zhou, C. B. A coupled two‐phase fluid flow and elastoplastic deformation model for unsaturated soils: theory, implementation, and application. International Journal for Numerical and Analytical Methods in Geomechanics, 2016, 40(7): 1023-1058.
-2015-
[37] Hu, R., Chen, Y.-F.*, Liu, H.-H., Zhou, C.-B. A coupled stress–strain and hydraulic hysteresis model for unsaturated soils: Thermodynamic analysis and model evaluation. Computers and Geotechnics, 2015, 63: 159-170.
[38] Hu, R., Chen, Y.F.*, Liu, H., Zhou, C. B. A relative permeability model for deformable soils and its impact on coupled unsaturated flow and elasto-plastic deformation processes. Science China Technological Sciences, 2015, 58(11): 1971-1982.
[39] 胡冉, 陈益峰, 周创兵, 考虑变形效应的非饱和土相对渗透系数模型, 岩石力学与工程学报, 2013, 32(6), 1279-1287.
[40] Hu, R., Chen, Y. F.*, Liu, H. H., Zhou, C. B. A water retention curve and unsaturated hydraulic conductivity model for deformable soils: consideration of the change in pore size distribution. Géotechnique, 2013, 63(16): 1389-1405. 【代表作】
[41] Hu, R., Liu, H.-H., Chen, Y., Zhou, C. B.*, Gallipoli, D. A constitutive model for unsaturated soils with consideration of inter-particle bonding. Computers and Geotechnics, 2014, 59: 127-144.
[42] Hu, R., Chen, Y. F.*, Zhou, C. B. Modeling of coupled deformation, water flow and gas transport in soil slopes subjected to rain infiltration. Science China Technological Sciences, 2011, 54(10): 2561-2575.
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