王禮春,男,博士,現任天津大學副教授。
基本介紹
- 中文名:王禮春
- 畢業院校:德克薩斯大學奧斯汀分校
- 學位/學歷:博士
- 職業:教師
- 專業方向:水文與水資源工程
- 主要成就:2013.05,AAPG(美國石油地質學家協會)獎學金
- 就職院校:天津大學
研究方向,人物經歷,學習經歷,工作經歷,主講課程,學術成果,科研項目,學術論文,榮譽獎項,
研究方向
1、多孔和裂隙介質中流體運動與物質傳輸
2、地下水-地表水相互作用
3、岩石(裂隙)水力耦合
4、流域氮循環
5、二氧化碳地質儲存
6、地下水資源管理與評價
人物經歷
學習經歷
2003.09~2007.07,中國地質大學(北京),本科:水文與水資源工程 (水文地質)。
2007.09~2010.07,中國地質大學(北京),碩士:水文與水資源工程 (水文地質)。
2010.08~2015.06,德克薩斯大學奧斯汀分校,博士:地球科學 (水文地質)。
工作經歷
2015.06~2018.07,德克薩斯大學奧斯汀分校,博士後。
2018.09~今,天津大學,副教授。
主講課程
水資源與生態環境
學術成果
科研項目
2020.01~2023.12,裂隙兩相流與非費克物質傳輸特徵及耦合機理研究,國家自然科學基金面上項目。
學術論文
(1)
J-Q Zhou, L. Wang* (王禮春),C. Li*, H. Tang, L. Wang,2020,Effect of fluid slippage on eddy growth and non-Darcian flow in rock fractures,Journal of Hydrology,doi: 10.1016/j.jhydrol.2019.124440.
(2)
L. Zheng, L. Wang*(王禮春), T. Wang, K. Singh, Z-L. Wang, X. Chen,2020,Can homogeneous slip boundary condition affect effective dispersion in single fractures with Poiseuille flow?,Journal of Hydrology,doi: 10.1016/j.jhydrol.2019.124385.
(3)
L. Zheng, L. Wang*(王禮春), and S. C. James,2019,When can the local advection–dispersion equation simulate non-Fickian transport through rough fractures?,Stochastic Environmental Research Risk Assessment,doi: 10.1007/s00477-019-01661-7.
(4)
J.-Q. Zhou, Y.-F. Chen*, L. Wang(王禮春), and M. B. Cardenas,2019,Universal relationship between viscous and inertial permeability of geologic porous media,Geophysical Research Letters,doi: 10.1029/2018GL081413.
(5)
L. Zheng, L. Wang*(王禮春), and W. Deng,2019,Seismicity enhances macrodispersion in finite porous and fractured domains: A pore-scale perspective,Journal of Geophysical Research: Solid Earth,doi: 10.1029/2018jb016921.
(6)
L. Zheng and L. Wang*(王禮春),2019,Scale‐dependent Poiseuille flow alternatively explains enhanced dispersion in geothermal environments,Hydrological Processes,doi: 10.1002/hyp.13339.
(7)
L Zheng*, MB Cardenas, L Wang(王禮春), D Mohrig,2019,Ripple effects: bedform morphodynamics cascading into hyporheic zone biogeochemistry,Water Resources Research.
(8)
J.-Q. Zhou, L. Wang*(王禮春), Y.-F. Chen*, and M. B. Cardenas,2019,Mass Transfer Between Recirculation and Main Flow Zones: Is Physically Based Parameterization Possible?,Water Resources Research,doi: 10.1029/2018wr023124.
(9)
X. Xia, N. Zhou, L. Wang(王禮春), X. Li, S. Jiang*,2019,Identification of transient contaminant sources in aquifers through a surrogate model based on a modified self-organizing-maps algorithm,Hydrogeology Journal.
(10)
J-Q Zhou, Y-F Chen*, H Tang*, L Wang(王禮春), M.B Cardenas,2019,Disentangling the simultaneous effects of inertial losses and fracture dilation on permeability of pressurized fractured rocks,Geophysical Research Letters.
(11)
L. Wang*(王禮春) and M. B. Cardenas,2019,Analysis of permeability change in dissolving rough fractures using depth-averaged flow and reactive transport models,International Journal of Greenhouse Gas Control.
(12)
S. James*, L. Wang(王禮春), and C.V. Chrysikopoulos,2018,Modeling colloid transport in fractures with spatially variable aperture and surface attachment,Journal of Hydrology,doi: 10.1016/j.jhydrol.2018.09.047.
(13)
Z. Yan, T. Wang, L. Wang(王禮春), X. Yang, P. Smith, M. Hilpert, S. Li, V. Bailey, C. Liu*,2018,Microscale Water Distribution and its Effects on Organic Carbon Decomposition in Unsaturated Soils,Science of the Total Environment.
(14)
J-Q Zhou, M Wang, L. Wang(王禮春), Y-F Chen, CB Zhou,2018,Emergence of nonlinear laminar flow in fractures during shear,Rock Mechanics and Rock Engineering,doi: 10.1007/s00603-018-1545-7.
(15)
L. Wang*(王禮春) and M. B. Cardenas,2018,Connecting pressure-saturation and relative permeability models to fracture properties: the case of supercritical CO2 and brine two-phase flow,Water Resources Research,doi: 10.1029/2018wr023526.
(16)
L. Wang*(王禮春) and M. B. Cardenas,2017,Transition from non-Fickian to Fickian longitudinal transport through 3-D rough fractures: Scale-(in)sensitivity and roughness dependence,Journal of Contaminant Hydrology,doi: 10.1016/j.jconhyd.2017.02.002.
(17)
D. Liu*, A. P. Jivkov*, L. Wang(王禮春), G. Si, and J. Yu,2017,Non-Fickian dispersive transport of strontium in laboratory-scale columns: Modelling and evaluation,Journal of Hydrology,doi:10.1016/j.jhydrol.2017.03.053.
(18)
L. Wang*(王禮春) and M. B. Cardenas,2017,Linear permeability evolution of expanding conduits due to feedback between flow and fast phase change,Geophysical Research Letters,doi: 10.1002/2017gl073161.
(19)
L. Zheng*, M. B. Cardenas, and L. Wang(王禮春),2016,Temperature effects on nitrogen cycling and nitrate removal-production efficiency in bed form-induced hyporheic zones,Journal of Geophysical Research - Biogeosciences,doi: 10.1002/2015JG003162.
(20)
L. Wang*(王禮春) and M. B. Cardenas,2016,Development of an empirical model relating permeability and specific stiffness for rough fractures from numerical deformation experiments,Journal of Geophysical Research - Solid Earth,doi: 10.1002/2016JB013004.
(21)
L. Wang*(王禮春), M. B. Cardenas, D. T. Slottke, R. A. Ketcham, and J. M. Sharp, Jr.,2015,Modification of the Local Cubic Law of fracture flow for weak inertia, tortuosity, and roughness,Water Resources Research,doi: 10.1002/2014WR015815.
(22)
L. Wang*(王禮春) and M. B. Cardenas,2015,An efficient quasi-3D particle tracking-based approach for transport through fractures with application to dynamic dispersion calculation,Journal of Contaminant Hydrology,doi: 10.1016/j.jconhyd.2015.05.007.
(23)
L. Wang*(王禮春) and M. B. Cardenas,2014,Non-Fickian transport through two-dimensional rough fractures: Assessment and prediction,Water Resources Research,doi: 0.1002/2013wr014459.
(24)
L. Wang*(王禮春), M. B. Cardenas, W. Deng, and P. C. Bennett,2012,Theory for dynamic longitudinal dispersion in fractures and rivers
榮譽獎項
2013.05,AAPG(美國石油地質學家協會)獎學金