Abstract

In many regions of the U.S., low dissolved oxygen (DO) is a common freshwater impairment. States, territories,and tribes of the U.S. are required by federal law to develop Total Maximum Daily Loads (TMDLs) for waters not meetingestablished DO standards. Regulators and other professionals are increasingly relying on mathematical simulation modelsto develop these TMDLs. Because of the wide variety of potential applications and the number of models in existence,consistent and comprehensive model evaluations are needed to ensure that TMDL developers are able to select appropriatemodels for their application. The goal of this article is to provide a guide to mathematical simulation models available fordeveloping DO TMDLs. For this work, a model is defined as easily available software that can be used to simulate DOdynamics in lotic systems. Four commonly used DO simulation models (QUAL2E, HSPF, EFDC, and WASP) are describedin detail, while the characteristics of several others are summarized in tabular form. A case study is used to illustrate theprocess of developing a DO TMDL. DO models continue to become more sophisticated and thus better able to simulate thenatural environment. Despite advancements, many DO models are still not capable of simulating some of the most complexdrivers of DO dynamics, partly because the scientific community does not yet fully understand these processes, and continueto require user-estimated inputs for these processes. Because these processes are complex and difficult to quantify, model usersare forced to rely on the few published data, which may or may not be applicable to their conditions. To overcome theselimitations, future research must focus on understanding these processes and creating comprehensive and easily accessibledatabases of DO parameters.