胡冉,1985年生,湖北崇阳人,教授、博士生导师,国家优秀青年基金获得者(2021),9001cc金沙珞珈青年学者(2017)。2008年6月和2013年6月分别获9001cc金沙学士和博士学位,2015年11月晋升副教授,2015年3月至2016年8月在美国劳伦斯伯克利国家实验室开展博士后研究,2019年晋升教授。长期从事岩土体渗流与多相渗流方面的教学与科研工作,研发了“精度高且成本低”、“视野宽且采集快”的多相渗流多尺度可视化实验技术,发现了岩体结构面“集中通道流”和“溶蚀热点”两种新的物理现象,提出了考虑复杂影响因素的多相渗流流动模式理论判据,发展了岩土多相渗流分析与控制技术。主持国家自然科学基金优青项目、面上项目和青年项目各1项、国家自然科学基金基础科学中心项目课题1项、国家重点研发计划子课题2项。获教育部科技进步一等奖(排名第四)。以第一或通讯作者在地学顶级/自然指数期刊Geophysical Research Letters(5篇)、水资源顶级期刊Water Resources Research(5篇)、流体力学顶级期刊Journal of Fluid Mechanics以及国内主流期刊《力学学报》等期刊上发表论文50余篇,SCI他引600余次,出版专著1部,授权发明专利6项。
诚邀对岩石力学、渗流与多相渗流感兴趣的员工加入研究团队!
硕士、博士报考专业:水工结构工程。
个人学术网站:
https://www.researchgate.net/profile/Ran_Hu4
https://scholar.google.com/citations?user=pgmuIF0AAAAJ&hl=en
电子邮箱:whuran@whu.edu.cn
学习与工作经历
● 2019年11月晋升教授、2018年9月聘为博士生导师
● 2015/11 ~ 2019/11,9001cc金沙,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 ~ 2015/11,9001cc金沙,讲师
● 2011/07 ~ 2012/07,美国劳伦斯伯克利国家实验室,访问学者
● 2008/09 ~ 2013/06,9001cc金沙,水工结构工程博士
● 2004/09 ~ 2008/06,9001cc金沙,水利水电工程学士
研究方向
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,在重大水利水电工程渗流长期安全与控制、二氧化碳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。本研究组的主攻方向为多孔裂隙介质多相渗流理论与应用,主要聚焦如下三个方面:
●多相渗流多尺度可视化技术与数值模拟方法
●变形与相变等条件下多相渗流的非线性规律
●多相渗流宏观本构模型与分析方法
教学工作
● 本科生:工程地质、水文地质、岩石力学、海洋工程概论
● 研究生:岩石力学、水利工程渗流分析与控制
主要科研项目
[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 ~ 2025/12,主持
[3]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
[4]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
[5]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
[6]国家重点研发计划子课题,枢纽工程重要构筑物(群)与地质环境互馈作用机制与控制技术,课题:库区与枢纽区地质环境演化规律及预测方法(课题编号:2018YFC0407001),2018年7月至2021年12月,主持
[7]国家重点研发计划子课题,离子吸附型稀土资源高效绿色开发与生态修复一体化技术,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(课题编号:2019YFC0605001),2019年10月至2022年9月,主持
[8]9001cc金沙学科交叉类资助项目,岩石裂隙多相流-溶蚀变形可视化实验与耦合机理(批准号:2042019kf0217),2019年6月至2021年6月,主持
[9]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(批准号:2015T80833),2015年6月至2017年3月,主持
[10]横向科研项目,溪洛渡拱坝长期安全特性评估枢纽区三维渗流特性及防渗系统长期安全性分析,2015年1月至2023年12月,主要参与人
荣誉与奖励
● 2017年,9001cc金沙珞珈青年学者
● 2016年,教育部科技进步一等奖(排名第4)
● 2015年,湖北省优秀博士论文奖
● 2012年,湖北省科技进步一等奖(排名第9)
学术兼职
● 中国力学学会会员
● 中国岩石力学与工程学会会员
● 美国地球物理联合会(AGU)会员
● 国际多孔介质协会(Interpore)会员
学术专著
[1]胡冉.非饱和土水力耦合模型与数值模拟方法研究.武汉:9001cc金沙出版社, 2016.
期刊论文
在JFM(力学)、GRL(地学)和WRR(水利)等权威期刊上发表论文50余篇【前10篇为代表作,*为通讯作者】:
[1]Wang T.,Hu, R.*, Yang, Z., Zhou, C.-X., Chen, Y.-F.*, Zhou, C.-B. (2022). Transitions of dissolution patterns in rough fractures,Water Resources Research, 58, e2021WR030456.
[2]Hu, R., Wang, T.*, Yang, Z., Xiao, Y., Chen, Y.-F.*, & Zhou, C.-B. (2021). Dissolution Hotspots in Fractures.Geophysical Research Letters, 48(20), e2021GL094118.
[3]Wu, D.-S.,Hu, R.*, Lan, T., & Chen, Y.-F. (2021). Role of pore-scale disorder in fluid displacement: experiments and theoretical model.Water Resources Research, 57(1), e2020WR028004.
[4]Lan, T.,Hu, R.*, Yang, Z., Wu, D.-S., Chen, Y.-F*. (2020). Transitions of fluid invasion patterns in porous media.Geophysical Research Letters, 47(20), e2020GL089 682.
[5]Hu, R.*, Lan, T., Wei, G.-J., Chen, Y.-F*. (2019). Phase diagram of quasi-static immiscible displacement in disordered porous media.Journal of Fluid Mechanics, 875: 448-475.
[6]Hu, R.*, Zhou, C.-X., Wu, D.-S., Yang, Z., Chen, Y.-F*. (2019). Roughness control on multiphase flow in rock fractures.Geophysical Research Letters, 46(21), 12002-12011.
[7]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(7), 8993–9002.
[8]Hu, R., Wan, J., Yang, Z., Chen, Y.-F.*, Tokunaga, T. (2018). Wettability and flow rate impacts on immiscible displacement: A theoretical model,Geophysical Research Letters, 45(7), 3077-3086.
[9]Hu, R., Wan, J. M.*, Kim, Y., Tokunaga, T. (2017). Wettability impact on supercritical CO2capillary trapping: Pore-scale visualization and quantification.Water Resources Research, 53(8), 6377-6394.
[10]Chen, Y. F., Fang, S., Wu, D. S.,Hu, R.*(2017). Visualizing and quantifying the crossover from capillary fingering to viscous fingering in a rough fracture.Water Resources Research, 53(9), 7756–7772.
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[11]ChenX.-S.,Hu, R.*, Guo, W., Chen, Y.-F. (2021). Experimental observation of two distinct finger regimes during miscible displacement in fracture,Transport in Porous Media, doi: 10.1007/s11242-021-01547-9
[12]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, 116919.
[13]Xue, S., Yang, Z.*,Hu, R., Chen, Y.F. (2020). Splitting Dynamics of Liquid Slugs at a T‐Junction.Water Resources Research, 56(8), 2020WR027730.
[14]Chen, Y.-F.*, Yu, H., Ma, H.-Z., Li, X.,Hu, R.*, Yang, Z. (2020). 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, 584:124693.
[15]Yang, Z.*, Meheust, 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.
[16]Chen, Y. F., Wu, D. S., Fang, S.,Hu, R.*(2018). Experimental study on two-phase flow in rough fracture: Phase diagram and localized flow channel.International Journal of Heat and Mass Transfer, 53(9), 7756-7772.
[17]Chen, Y. F.*, Ling, X. M., Liu, M. M.,Hu, R.*, Yang, Z. (2018). Statistical distribution of hydraulic conductivity of rocks in deep-incised valleys, Southwest China.Journal of Hydrology, 566, 216-226.
[18]Chen, Y. F., Guo, N., Wu, D. S.,Hu, R.*(2018). Numerical investigation on immiscible displacement in 3D rough fracture: Comparison with experiments and the role of viscous and capillary forces.Advances in Water Resources, 118, 30-49.
[19]Hu, R.,Hong, J. M., Chen, Y. F.*, Zhou, C. B. (2018). Hydraulic hysteresis effects on the coupled flow-deformation processes in unsaturated soils: Numerical formulation and slope stability analysis.Applied Mathematical Modelling, 54, 221–245.
[20]Li, X., Chen, Y.,Hu, R., Yang, Z. (2017). Towards an optimization design of seepage control: A case study in dam engineering.Science China Technological Sciences, 60(12): 1903-1916.
[21]Hu, R., Wan, J. M.*, Kim, Y., Tokunaga, T. (2017). Wettability effects on supercritical CO2-brine immiscible displacement during drainage: Pore-scale observation and 3D simulation.International Journal of Greenhouse Gas Control, 60,129-139.
[22]Hu, R., Chen, Y. F.*, Liu, H. H., Zhou, C. B. (2017). A numerical formulation with unified unilateral boundary condition for unsaturated flow problems in porous media.Acta Geotechnica, 12(2), 277-291.
[23]Liu, W., Chen, Y. F.,Hu, R., Zhou, W., Zhou, C. B. (2016). A two-step homogenization based permeability model for deformable fractured rocks with consideration of coupled damage and friction effects.International Journal of Rock Mechanics and Mining Sciences, 89, 212-226.
[24]Hu, R.,Chen, Y. F.*, Liu, H. H., Zhou, C. B. (2016). 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, 40(7), 1023-1058.
[25]Hu, R., Chen, Y. F*., Liu, H. H., Zhou, C. B. (2015). A relative permeability model for deformable soils and its impact on coupled unsaturated flow and elastoplastic deformation processes.Science China Technological Sciences, 58(11), 1971-1982.
[26]Chen, Y. F., Zhou, J. Q., Hu, S. H.,Hu, R., Zhou, C. B. (2015). Evaluation of Forchheimer equation coefficients for non-Darcy flow in deformable rough-walled fractures.Journal of Hydrology, 529, 993-1006.
[27]Hu, R., Chen, Y. F.*, Liu, H. H., Zhou, C. B. (2015). A coupled stress-strain and hydraulic hysteresis model for unsaturated soils: thermodynamic analysis and model evaluation.Computers and Geotechnics, 63, 159-170.
[28]Chen, Y.*, Zhou, S.,Hu, R., Zhou, C. B. (2015). A homogenization-based model for estimating effective thermal conductivity of unsaturated compacted bentonites.International Journal of Heat and Mass Transfer, 83, 731-740.
[29]Chen, Y.-F., Hu, S.-H.,Hu, R., & Zhou, C.-B. (2015). Estimating hydraulic conductivity of fractured rocks from high‐pressure packer tests with an Izbash’s law‐based empirical model.Water Resources Research, 51(4), 2096-2118.
[30]Hu, R., Liu, H. H., Chen, Y. F., Zhou, C. B*. (2014). A constitutive model for unsaturated soils with consideration of inter-particle bonding.Computers and Geotechnics, 59, 127-144.
[31]Hu, R., Chen, Y. F.*, Liu, H. H., Zhou, C. B. (2013). A water retention curve and unsaturated hydraulic conductivity model for deformable soils: consideration of the change in pore size distribution.Géotechnique, 63(16), 1389-1405.
[32]Chen, Y. F.,Hu, R., Zhou, C. B.*, Li, D. Q., Rong, G. (2011). A new parabolic variational inequality formulation of Signorini’s condition for non-steady seepage problems with complex seepage control systems.International Journal for Numerical and Analytical Methods in Geomechanics,35(9), 1034-1058.
[33]Chen, Y. F.,Hu, R., Lu, W. B., Li, D. Q., Zhou, C. B*. (2011). Modeling coupled processes of non-steady seepageflow and non-linear deformation for a concretefaced rockfall dam.Computers and Structures, 89(13-14), 1333-1351.
[34]Hu, R.,Chen, Y. F.*, Zhou, C. B. (2011). Modeling of coupled deformation, water flow and gas transport in soil slopes subjected to rain infiltration.Science China Technological Sciences, 54(10), 2561-2575.
[35]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.
[36]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.
[37]刘武,陈益峰,胡冉,周创兵.基于非稳定渗流过程的岩体渗透特性反演分析.岩石力学与工程学报, 2015, 34(2), 362-373.
[38]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.
[39]胡冉,陈益峰,周创兵,基于孔隙分布的变形土土水特征曲线模型,岩土工程学报, 2013, 35(8), 1451-1462.
[40]胡冉,陈益峰,李典庆,周创兵,唐小松,心墙堆石坝渗透稳定可靠性分析的随机响应面法,岩土力学, 2012, 33(4), 1051-1060.
[41]陈益峰,胡冉,周嵩,周伟,周创兵,高堆石坝水力耦合模型及工程应用,岩土工程学报, 2011, 33(9), 1340-1347.
[42]胡冉,陈益峰,周创兵,李典庆,非稳定渗流问题的变分不等式方法及工程应用,水动力学研究与进展: A辑, 2011, 26(2), 239-251.
[43]胡冉,陈益峰,周创兵,降雨入渗过程中土质边坡的固-液-气三相耦合分析,中国科学:技术科学, 2011, 41(11), 1469-1482.
[44]胡冉,李典庆,周创兵,陈益峰,基于随机响应面法的结构可靠度分析,工程力学, 2010, 27(9), 192-200.
[45]陈益峰,周创兵,胡冉,李典庆,荣冠,大型水电工程渗流分析的若干关键问题研究,岩土工程学报, 2010, 28 (9), 1448-1454.
发明专利与软著权
[1]胡冉,武东生,陈益峰,方舒.一种透明岩石节理复制品制备方法, 2019.11.04-2039.11.04,中国,发明专利,ZL201710114653.6
[2]胡冉,武东生,陈益峰,周晨星,王一凡,魏鹳举,赵先进.用于地质过程化学溶蚀研究的微流控芯片及制作方法. 2020.08.06-2040.08.06,中国,发明专利,ZL201810114670.6
[3]胡冉,魏鹳举,廖震,周晨星,陈旭升,郭威,武东生,王一凡,一种表面湿润性可变的微观孔隙模型及其制作和使用方法, ZL202011007033.0
[4]胡冉,魏鹳举,廖震,周晨星,郭威,陈旭升,王一凡,武东生,陈益峰. 2.5D孔隙结构微流体芯片及其制作和使用方法, ZL202011098551.8
[5]陈益峰,胡少华,魏凯,胡冉,周创兵,低渗岩石瞬态气压脉冲渗透率测量方法, 2015.7.29-2035.7.29,中国,发明专利,ZL201310207056.X
[6]陈益峰,胡少华,魏凯,胡冉,周创兵,一种岩石三轴压缩-水(气)耦合装置及试验方法, 2015.9.02-2035.9.2,中国,发明专利, ZL201310232298.4
[7]胡冉,陈益峰,岩土介质水/气两相流-弹塑性变形耦合分析软件[简称: F2Mus3D],软件著作权, 2019SR0198982.
[8]胡冉,陈益峰,含复杂边界的三维饱和-非饱和渗流有限元分析软件[简称: SUFLOW3D],软件著作权, 2019SR0155267
[9]胡冉,陈益峰,大型水利水电工程三维非稳定渗流有限元分析软件[简称: NS2FLOW3D],软件著作权, 2019SR0198978
