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3 - Incorporating uncertainty into aquifer management models

Published online by Cambridge University Press:  04 December 2009

Steven M. Gorelick
Affiliation:
Stanford University
Gedeon Dagan
Affiliation:
Tel-Aviv University
Shlomo P. Neuman
Affiliation:
University of Arizona
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Summary

INTRODUCTION

The aim of aquifer simulation is to predict how hydraulic heads and solute concentrations respond to system stresses such as pumping and recharge. In many cases, simulation alone does not provide the results necessary to manage groundwater resources. What is needed is a design tool to find the best arrangement of pumping and recharge in order to control the heads and concentrations over space and time. One might want the managed head declines to be limited to some target value, or to ensure that solute concentrations never exceed water quality standards at supply wells. These controls must be maintained while achieving some objective, such as minimizing cost or risk. The recognition that simulation is not an end in itself has led to the development of aquifer management models.

During the past 30 years, the field of aquifer management modeling has developed as a distinct discipline. It has provided a framework which replaces trial and error simulations. Modern aquifer management models combine simulation tools with optimization techniques. The optimization techniques were developed in fields such as operations research and applied physics, and were adapted to unite with aquifer simulation models. This combination of formal optimization and aquifer simulation provides a framework that forces the engineer or hydrologist to formulate carefully the groundwater management problem. The problem must contain a series of constraints on heads, drawdowns, pumping rates, hydraulic gradients, groundwater velocities, and solute concentrations. In addition, an objective, usually involving costs, cost surrogates, or risk, must be stated. The power underlying this union of highly computational technologies was unleashed when computers became fast and cheap.

Type
Chapter
Information
Subsurface Flow and Transport
A Stochastic Approach
, pp. 101 - 112
Publisher: Cambridge University Press
Print publication year: 1997

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