Effects of rate-limited mass transfer on water sampling with partially penetrating wells

• Published in: Ground water Vol. 42; no. 2; pp. 203 - 222
• Main Author: Cosler, D.J
• Format: Journal Article
• Language: English
• Published: Oxford, UK Blackwell Publishing Ltd 01.03.2004; National Ground Water Association; Ground Water Publishing Company
• Subjects: Aquifers; Effluents; Environmental Monitoring; Groundwater; Groundwater flow; Models, Theoretical; Sediment transport; Soil; Solute movement; Water Movements; Water quality; Water Supply; Water, Underground; Wells
• ISSN: 0017-467X; 1745-6584
• DOI: 10.1111/j.1745-6584.2004.tb02668.x

Nonequilibrium concentration type curves are numerically developed and sensitivity analyses are performed to examine the relationships between effluent concentrations in partially penetrating monitoring/extraction wells, the vertical plume shape, and the mass transfer characteristics of the aquifer. The governing two‐dimensional, axisym‐metric nonequilibrium solute transport equation is solved in three stages using an operator‐splitting approach. In the first two stages, the advection and dispersion terms are solved with the Eulerian‐Lagrangian method, based on the backward method of characteristics for advection and the standard implicit Galerkin finite element method for dispersion. In the third step, the first‐order, immobile‐mobile domain mass transfer term is computed analytically for both two‐site and lognormally distributed, multirate models. Effluent concentration variations with time and contour plots of the pore water concentration distribution in the aquifer are compared for a wide range of field‐ and laboratory ‐measured mass transfer rates, various plume shapes, and relevant physical/chemical parameter values, including pumping rate, vertical anisotropy ratio, retardation factor, and porosity. The simulation results show that rate‐limited mass transfer can have a significant impact on sample and aquifer pore water concentrations during three‐dimensional transport to a partially penetrating well. An alternative dimensionless form of the nonequilibrium solute transport equation is derived to illustrate the key parameter groupings that quantify rate‐limited sorption effects and show the relative importance of individual parameters. A hypothetical field application example demonstrates the fitting of dimensional type curves to discrete‐interval sampling data in order to evaluate the mass transfer characteristics of an aquifer and shows how type curve superposition can be used to model complex plume shapes.