Welcome to the new version of CaltechAUTHORS. Login is currently restricted to library staff. If you notice any issues, please email coda@library.caltech.edu
Published October 8, 2009 | Submitted
Report Open

Computer simulation of surface water hydrology and salinity with an application to studies of Colorado River management

Abstract

Management of a large river basin requires information regarding the interactions of variables describing the system. A method has been developed to determine these interactions so that the resources management within a given river basin can proceed in an optimal way. The method can be used as a planning tool to display how different management alternatives affect the behavior of the river system. Direct application is made to the Colorado River Basin. The Colorado River has a relatively low and highly variable streamflow. Allocated rights to the consumptive use of the river water exceed the present long-term average flow. The naturally high total dissolved solids concentration of the river water continues to increase due to the activities of man. Current management policies in the basin have been the products of compromises between the seven states and two countries which are traversed by the river or its tributaries. The anticipated use of the scarce supply of water in the extraction and processing of energy resources in the basin underwrites the need for planning tools which can illuminate many possible management alternatives and their effects upon water supply, water quality, power production, and the other concerns of the Colorado River water users. A computer simulation model has been developed and used to simulate the effects of various management alternatives upon water conservation, water quality, and power production. The model generates synthetic sequences of streamflows and total dissolved solids (TDS) concentrations. The flows of water and TDS are then routed through the major reservoirs of the system, Lakes Powell and Mead. Characteristics of system behavior are examined from simulations using different streamflow sequences, upstream depletion levels, and reservoir operating policies. Reservoir evaporation, discharge, discharge salinity, and power generating capacity are examined. Simulation outputs show that the probability with which Lake Powell fails to supply a specified target discharge is highly variable. Simulations employing different streamflow sequences result in probabilities of reservoir failure which differ by as much as 0.1. Three levels of Upper Colorado River Basin demands are imposed on the model: 3.8 MAF/yr (4.7 km^3/yr), 4.6 MAF/yr (5.7 km^3/yr), and 5.5 MAF/yr (6.8 km^3/yr). Two levels of water demand are imposed below Lake Mead: 8.25 MAF/yr (10.2 km^3/yr) and 7.0 MAF/yr (6.8 km^3/yr). Although the effects of reservoir operations upon water quality are made uncertain by a lack of knowledge regarding the chemical limnology of Lake Powell, two possible lake chemistry models have been developed, and the predicted impacts of changes in reservoir operation upon water quality are presented. The current criteria for the operations of Lakes Powell and Mead are based upon 75 years of compromises and agreements between the various water interests in the Colorado River Basin. Simulations show that Lake Powell will be unable to conform to these operating constraints at the higher levels of water demand. An alternative form of reservoir operation is defined and compared to the existing policy on the basis of reliability of water supply, conservation of water, impact upon water quality, and the effect upon power generation. Ignoring the current institutional operating constraints, and attempting only to provide a reliable supply of water at the locations of water demand, is shown to be a superior management policy. This alternate policy results in the conservation of as much as 0.25 MAF/yr (0.3 km^3/yr) of water. The impact of the alternate operating policy upon hydroelectric power generation and the potential use of the conserved water for development of energy resources is discussed.

Additional Information

© 1976 Environmental Quality Report. California Institute of Technology. The author wishes to acknowledge the persons who assisted him in the pursuit of this research topic and in the preparation of this report. He is especial ly i ndebted to Dr. E. John List, Dr. James J. Morgan, and Dr. Norman H. Brooks for their comments and suggestions throughout the course of the study. The author extends his gratitude to Dr . Robert C. Y. Koh for his suggestions and computer programming assistance. Special credit is also due Ms. Patricia Rankin and Ms. Pat McCall for their work on the manuscript, and Ms. Elizabeth Krieg and Mr. Bruce Cameron Bury for their help in preparing many of the figures and attending to other details of the final draft. The work has been financially supported by the Environmental Quality Laboratory from grants received from the National Science Foundation (1971-74, Grant No. 4-GI 29726); the Ford Foundation. (1974-76, Grant No. 740-0469); and various gifts to EQL from corporations and individuals.

Attached Files

Submitted - EQLReport12.pdf

Files

EQLReport12.pdf
Files (10.3 MB)
Name Size Download all
md5:68d65bbf2d6286495b7966c390b23198
10.3 MB Preview Download

Additional details

Created:
August 19, 2023
Modified:
January 13, 2024