A Basic Introduction to Pollutant Fate and Transport: An Integrated Approach with Chemistry, Modeling, Risk Assessment, and Environmental Legislation
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More About This Title A Basic Introduction to Pollutant Fate and Transport: An Integrated Approach with Chemistry, Modeling, Risk Assessment, and Environmental Legislation

English

A uniquely accessible text on environmental modeling designed for both students and industry personnel

Pollutant fate and modeling are becoming increasingly important in both regulatory and scientific areas. However,the complexity of the software and models often act as an inhibitor to the advancement of water quality science.

A Basic Introduction to Pollutant Fate and Transport fills the need for a basic instructional tool for students and environmental professionals who lack the rigorous mathematical background necessary to derive the governing fate and transport equations. Taking a refreshingly simple approach to the subject that requires only a basic knowledge of algebra and first-year college chemistry, the book presents and integrates all of the aspects of fate and transport, including chemistry, modeling, risk assessment, and relevant environmental legislation; approaching each topic first conceptually before introducing the math necessary to model it.

The first half of the book is dedicated to the chemistry and physics behind the fate and transport models, while the second half teaches and reinforces the logical concepts underlying fate and transport modeling. This better prepares students for support jobs in the environmental arena surrounding chemical industry and Superfund sites.

Contributing to the book's ease of use are:

  • An extremely user-friendly software program, Fate, which uses basic models to predict the fate and transport of pollutants in lakes, rivers, groundwater, and atmospheric systems
  • The use of "canned" models to evaluate the importance of model parameters and sensitivity analysis
  • A wealth of easy-to-understand examples and problems
  • A chapter on environmental legislation in the United States and Europe
  • A set of lab exercises, as well as a downloadable set of teaching aids

A much-needed basic text for contemporary hydrology or environmental chemistry courses and support courses forthe environmental industry, this is a valuable desk reference for educators and industry professionals.

English

FRANK M. DUNNIVANT is an Assistant Professor of Chemistry at Whitman College in Washington State and has worked for several labs, such as Oak Ridge National Laboratory, the Idaho National Environmental and Engineering Laboratory, and the Swiss Federal Institute for Water and Wastewater Pollution. He has extensive experience with practical applications, research, and writing on environmental engineering and analytical science.

ELLIOT ANDERS holds a degree in environmental chemistry and has extensive programming experience. He is the cofounder of Educational Solutions, a company that produces a variety of software products for college use. Currently he works as a Network Technician in the public school system.

English

PREFACE xv

To the Instructor xvi

To the Student xvi

To the Environmental Professional xvi

How to Use the Book with Fate® and Associated Software xvii

Acknowledgments xvii

SYMBOLS xix

GLOSSARY xxi

PART I INTRODUCTION

CHAPTER 1 SOURCES AND TYPES OF POLLUTANT, WHY WE NEED MODELING, AND HISTORICAL CONTAMINATION EVENTS 3

1.1 Introduction 3

1.2 The Need for Modeling of Pollutants in Environmental Media 4

1.3 Pollution Versus Contamination; Pollutant Versus Contaminant 5

1.4 Pollution Classifications 5

1.5 Sources of Pollution 6

1.6 Historic Examples of Where Fate and Transport Modeling are Useful 16

1.6.1 Surface Water 16

1.6.2 Groundwater 20

1.6.3 Atmosphere 25

1.7 Environmental Laws 26

References 26

PART II CHEMISTRY OF FATE AND TRANSPORT MODELING

CHAPTER 2 BASIC CHEMICAL PROCESSES IN POLLUTANT FATE AND TRANSPORT MODELING 31

2.1 The Liquid Medium: Water and the Water Cycle 31

2.2 Unique Properties of Water 33

2.3 Concentration Units 39

2.4 Chemical Aspects of Environmental Systems 40

2.4.1 pH 40

2.4.2 Activity 40

2.4.3 Solubility 45

2.4.4 Vapor Pressure 59

2.4.5 Henry’s Law Constant 60

2.5 Reactions and Equilibrium 61

2.5.1 Acid–base Chemistry 61

2.5.2 Oxidation–Reduction Chemistry 66

2.6 Complexation 73

2.7 Equilibrium Sorption Phenomena 74

2.7.1 Sorption Surfaces 76

2.7.2 Organic Matter 81

2.7.3 Organic Sorbates 82

2.7.4 Partition Coefficients, Kd and Kp 84

2.7.5 Ion Exchange Phenomena for Ionic Pollutants 85

2.8 Transformation/Degradation Reactions 87

2.8.1 Abiotic Chemical Transformations/Degradations 87

2.8.2 Photochemical Transformation/Degradation Reactions 89

2.8.3 Nuclear 92

2.8.4 Biological 92

2.9 Summary 93

References 95

CHAPTER 3 QUANTITATIVE ASPECTS OF CHEMISTRY TOWARD MODELING 97

3.1 Introduction 97

3.2 Calculation of the Free Metal Ion Concentration in Natural Waters 97

3.2.1 Calculating Chemical Equilibria 97

3.2.2 Equilibrium Applied to More Complex Speciation Problems 105

3.3 Methods for Determining Kd and Kp 119

3.4 Kinetics of the Sorption Process 124

3.5 Sorption Isotherms 125

3.5.1 A General Approach 125

3.6 Kinetics of Transformation Reactions 129

3.7 Putting It All Together: Where Chemistry Enters into the Modeling Effort 130

Case I: A Metal Pollutant 131

Case II: Hydrophobic Pollutants 131

References 141

PART III MODELING

CHAPTER 4 AN OVERVIEW OF POLLUTANT FATE AND TRANSPORT MODELING 145

4.1 Modeling Approaches 145

4.1.1 Algebraic Solutions 145

4.1.2 Modeling Using Differential Equations 146

4.1.3 The General Approach for the Models Used in this Text 152

4.1.4 Numerical Methods of Analysis 152

4.2 The Quality of Modeling Results 154

4.3 What Do You Do with Your Modeling Results? 156

References 156

CHAPTER 5 FATE AND TRANSPORT CONCEPTS FOR LAKE SYSTEMS 157

Case Study: Lake Onondaga 157

5.1 Introduction 159

5.2 Types of lakes and lake-forming events 159

5.3 Input Sources 162

5.4 Stratification of Lake Systems 165

5.5 Important Factors in the Modeling of Lakes: Conceptual Model Development 168

5.5.1 Definitions of Terms: 168

5.5.2 Detention Times and Effective Mixing Volumes 169

5.5.3 Chemical Reactions 170

5.5.4 Sedimentation 170

5.6 Two Basic Mathematical Models for Lakes 173

5.6.1 Continuous (State) Model 173

5.6.2 Instantaneous (Pulse) Pollutant Input Model 176

5.7 Sensitivity Analysis 180

5.8 Limitations of Our Models 181

5.9 Remediation 181

References 186

CHAPTER 6 FATE AND TRANSPORT OF POLLUTANTS IN RIVERS AND STREAMS 187

Case Study: The Rhine River 187

6.1 Introduction 188

6.2 Examples of Rivers and Volumetric Flows of Water 188

6.3 Input Sources 189

6.4 Important Factors in the Modeling of Streams: Conceptualization of Terms 190

6.4.1 Definition of Terms 190

6.4.2 The Stream Channel 191

6.4.3 Mixing and Dispersion in Rivers 191

6.4.4 Removal Mechanisms 193

6.5 Mathematical Development of Simple Transport Models 197

6.5.1 Solution of the Differential Equation for the Instantaneous Input (Pulse) 197

6.5.2 Solution of the Differential Equation for the Step Input 200

6.6 Sensitivity Analysis 204

6.7 Limitations of Our Models 204

6.8 Remediation of Polluted Streams Systems 205

References 209

CHAPTER 7 DISSOLVED OXYGEN SAG CURVES IN STREAMS: THE STREETER–PHELPS EQUATION 211

Case Study: Any Stream, Anywhere in the World 211

7.1 Introduction 212

7.2 Basic Input Sources (Wastewater Flow Rates and BOD Levels) 216

7.3 Mathematical Development of Model 218

7.4 Sensitivity Analysis 224

7.5 Limitations of Our Model 225

7.6 Remediation 225

References 229

CHAPTER 8 FATE AND TRANSPORT CONCEPTS FOR GROUNDWATER SYSTEMS 231

Case Study: The Test Area North Deep Well Injection Site at the Idaho National Environmental and Engineering Laboratory (INEEL) 231

8.1 Introduction 232

8.2 Input Sources 234

8.3 Monitoring Wells 235

8.3.1 Cable Tool Percussion Method 236

8.3.2 Direct Rotary Drill Method 237

8.3.3 Earth Augers 240

8.3.4 Well Casing, Grouting, and Sealing the Well Casing 240

8.3.5 Well Development 242

8.3.6 But How good is our well? 244

8.4 Chemistry Experiments Used to Support Modeling Efforts 244

8.4.1 Kd and Kp Values 246

8.4.2 Relationship Between K and the Groundwater Fate and Transport Equation 246

8.4.3 Column Studies for Evaluating Pollutant Transport in Subsurface Media 247

8.5 Direction of Water Flow (the Three-Point Problem) 251

8.6 Physical Parameters Important in Pollutant Fate and Transport 254

8.6.1 Sources of Dispersion in Geological Media 255

8.6.2 A Case Study: The INEEL Water and Tracer Infiltration Experiment 256

8.6.3 Towards a Universal Estimate Technique for Dispersion 263

8.7 Mathematical Models 265

8.8 Sensitivity Analysis 270

8.9 Limitations of Our Models 270

8.10 Remediation 270

References 275

CHAPTER 9 FATE AND TRANSPORT CONCEPTS IN ATMOSPHERIC SYSTEMS 277

Case Study: The Accident at Union Carbide—Bhopal 277

9.1 Introduction 278

9.2 Input Sources 278

9.3 Important Factors in the Modeling of Atmospheric Pollution: Conceptual Model Development 279

9.3.1 One- Versus Two- Versus Three-Dimensional Models 279

9.3.2 Mixing and Dispersion in Atmospheric Systems 279

9.4 Mathematical Development of Model 284

9.4.1 Step Input (Plume Model) of Pollutant 284

9.4.2 Instantaneous Input (Pulse or Puff Model) of Pollution 289

9.5 Sensitivity Analysis 296

9.6 Limitations of our model 296

9.7 Remediation 296

References 298

PART IV RISK ASSESSMENT

CHAPTER 10 RISK AND THE CALCULATION OF HEALTH RISK FROM EXPOSURE TO POLLUTANTS 303

10.1 The Concept of Risk 304

10.2 Dose Rates from Various Sources 306

10.2.1 Ingestion of Pollutants from Drinking Water 312

10.2.2 Ingestion of Water While Swimming 314

10.2.3 Dermal Contact with Pollutants in Water While Swimming 314

10.2.4 Ingestion of Pollutants in Soil 315

10.2.5 Intake from Dermal Contact with Pollutants in Soil 315

10.2.6 Inhalation of Airborne (Vapor Phase) Pollutants 316

10.2.7 Ingestion of Contaminated Fish and Shellfish 317

10.2.8 Ingestion of Contaminated Fruits and Vegetables 318

10.2.9 Ingestion of Contaminated Meat, Eggs, and Dairy Products 318

10.3 Health Risk Calculations for Carcinogens 319

10.4 Health Risk Calculations for Noncarcinogens 323

10.5 Bioconcentration Calculations 325

10.6 Putting It All Together: Margin of Error (Uncertainty) of the Entire Estimation Process 327

References 332

PART V ENVIRONMENTAL LEGISLATION IN THE UNITED STATES AND EUROPE

CHAPTER 11 ENVIRONMENTAL LAWS 337

11.1 Environmental Movements in the United States 337

11.2 The History of the Environmental Protection Agency (U.S. EPA): Administrators 340

11.2.1 Timeline of the U.S. Environmental Movement 337

11.3 Major U.S. Environmental Laws 344

11.3.1 The Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA) 346

11.3.2 The Air Quality Act, The Clean Air Act, and Amendments 347

11.3.3 The National Environmental Policy Act 351

11.3.4 The Solid Waste Disposal Act, Resource Conservation and Recovery Act (RCRA), and Amendments 354

11.3.5 Occupational Safety and Health Act (OSH Act) 357

11.3.6 The Federal Water Pollution Control Act, the Clean Water Restoration Act, the Safe Drinking Water Act, and Amendments 357

11.3.7 The Toxic Substances Control Act 360

11.3.8 The Comprehensive Environmental Response, Compensation, and Liability Act 361

11.3.9 The Oil Pollution Act 364

11.3.10 The Pollution Prevention Act 364

11.3.11 The Endangered Species Act of 1966 and Amendments 365

11.3.12 Marine Protection, Research, and Sanctuaries Act (MPRSA) of 1972 365

11.4 EPA’s Record 366

11.5 International Agreements/Treaties Involving the United States 374

11.5.1 U.S.–Canada Environmental Agreements 374

11.5.2 Multinational Agreements 375

11.6 Environmental Policy in the European Union 378

11.6.1 Brief Introduction to the European Union 378

11.6.2 History of Environmental Policy 378

11.6.3 Economy and the Environment 380

11.6.4 The Union Versus Member States 381

11.6.5 The Making of Environmental Policy 382

11.6.6 Existing Environmental Policy 384

11.6.7 Implementation of Environmental Policy 388

11.6.8 Public and the Environment 390

11.6.9 The Future of Environmental Policy 391

References 393

PART VI POLLUTANT CASE STUDIES

CHAPTER 12 CASE STUDIES OF SELECTED POLLUTANTS 399

12.1 Mercury 399

12.1.1 Sources 399

12.1.2 Production/Use 400

12.1.3 Fate and Environmental Distribution 400

12.1.4 Health Effects 401

12.2 Lead 402

12.2.1 Sources 402

12.2.2 Production/Use 402

12.2.3 Fate 403

12.2.4 Environmental Distribution 403

12.2.5 Health Effects 404

12.3 PCBs 406

12.3.1 Sources 406

12.3.2 Production/Use 406

12.3.3 Fate and Environmental Distribution 408

12.3.4 Health Effects 409

12.4 DDT 409

12.4.1 Sources 409

12.4.2 Production/Use 410

12.4.3 Fate 410

12.4.4 Environmental Distribution 410

12.4.5 Health Effects 410

12.5 Endocrine Disruptors 412

12.5.1 Sources 412

12.5.2 Uses and Points of Contact 412

12.5.3 Fate and Environmental Distribution 413

12.5.4 Health Effects 414

References 416

PART VII SUPPORTING LABORATORY EXPERIMENTS

CHAPTER 13 EXPERIMENTS 421

13.1 The Determination of Alkalinity in Water Samples 421

13.2 Total Suspended and Dissolved Solids in Water Samples 424

13.3 The Determination of Hardness in a Water Sample 426

13.4 The Determination of Dissolved Oxygen in Water Using the Winkler Method (Iodiometric Titration Method) 429

13.5 The Determination of the Biochemical Oxygen Demand (BOD) of Sewage Influent: BOD5 and/or BOD20 434

13.6 Determination of a Clay–Water Distribution Coefficient for Copper 438

13.7 The Measurement of Dispersion in a Simulated Lake System 442

13.8 The Measurement of Dispersion in a Simulated River System 446

13.9 The Measurement of Dispersion and Sorption in a Simulated Groundwater System 448

13.10 A Field Study of a Stream 453

APPENDIX I GLOSSARY OF IRIS TERMS 455

APPENDIX II LIST OF DRINKING WATER CONTAMINANTS AND MCLS 461

APPENDIX III LIST OF CONTAMINANTS AND THEIR MCLS 463

APPENDIX IV PERIODIC TABLE OF THE ELEMENTS 475

INDEX 477

English

"...an extremely well-written and presented instructions tool on fate and transport modeling." (Journal of Environmental Quality, July/August 2006)

"...unique instructional tool..." (International Journal of Environmental and Analytical Chemistry, 2006)

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