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An analytical study on artesian flow conditions in unconfined-aquifer drainage basins.

Authors :
Jun-Zhi Wang
Xiao-Wei Jiang
Li Wan
Wörman, Anders
Heng Wang
Xu-Sheng Wang
Hailong Li
Source :
Water Resources Research; Oct2015, Vol. 51 Issue 10, p8658-8667, 10p
Publication Year :
2015

Abstract

Although it has been reported that flowing artesian wells could be topographically controlled, there is no quantitative research on artesian flow conditions in unconfined aquifers. In this study, the water table, which has a lower amplitude than the land surface, is damped from the topography and used as the boundary condition to obtain the analytical solution of hydraulic head of a unit basin with a single flow system. The term artesian head is defined to characterize the condition of flowing artesian wells. The zone with positive artesian head is called artesian zone while with negative artesian head is nonartesian zone. The maximum artesian head and the size of artesian zones are found to increase with the damping factor and the anisotropy ratio, and decrease with the ratio of basin width to depth and the depth-decay exponent of hydraulic conductivity. Moreover, the artesian head increases with depth nearby the valley and decreases with depth near by the divide, and the variation rates are influenced by the decay exponent and the anisotropy ratio. Finally, the distribution of flowing artesian wells and the artesian head measurements in different depths of a borehole in a small catchment in the Ordos Plateau, Northwestern China is used to illustrate the theoretical findings. The change in artesian head with depth was used to estimate the anisotropy ratio and the decay exponent. This study opens up a new door to analyze basin-scale groundwater flow. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00431397
Volume :
51
Issue :
10
Database :
Complementary Index
Journal :
Water Resources Research
Publication Type :
Academic Journal
Accession number :
111187629
Full Text :
https://doi.org/10.1002/2015WR017104