Abstract
In this paper, spatial variability in steady one-dimensional unconfined groundwater flow in heterogeneous formations is investigated. An approach to deriving the variance of the hydraulic head is developed using the nonlinear filter theory. The nonlinear governing equation describing the one-dimensional unconfined groundwater flow is decomposed into three linear partial differential equations using the perturbation method. The linear and quadratic frequency response functions are obtained from the first- and second-order perturbation equations using the spectral method. Furthermore, under the assumption of the exponential covariance function of log hydraulic conductivity, the analytical solutions of both the spectrum and the variance of the hydraulic head produced from the linear system are derived. The results show that the variance derived herein is less than that of Gelhar (1977). The reason is that the log transmissivity is linearized in Gelhar’s work. In addition, the analytical solutions of both the spectrum and the variance of the hydraulic head produced from the quadratic system are derived as well. It is found that the correlation scale and the trend in mean of log hydraulic conductivity are important to the dimensionless variance ratio.
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This paper is based on research partially supported by the National Science Council, Taiwan, under Grants NSC86-2621-E-002-008 and 87-2211-E-002-052.
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Lin, GF., Chen, CM. Stochastic analysis of spatial variability in unconfined groundwater flow. Stochastic Environmental Research and Risk Assessment 18, 100–108 (2004). https://doi.org/10.1007/s00477-002-0119-z
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DOI: https://doi.org/10.1007/s00477-002-0119-z