A practical approach to environmental chemistry,Elements of Environmental Chemistry, 3rd Edition provides readers with the fundamentals of environmental chemistry and a toolbox for putting them into practice. This is a concise, accessible, and hands-on volume designed for students and professionals working in the chemical and environmental sciences.

The 3rd Edition has been completely revised and rearranged. The first chapter on tool skills has been expanded to include thermodynamic considerations and measurement issues. The former chapter on the partitioning of organic compounds has been expanded to cover the fates of organic compounds, with an emphasis on developing the readers chemical intuition for predicting a chemicals fate based on structure. The material on lead, mercury, pesticides, PCBs, dioxins, and flame retardants has been expanded and combined into the last chapter and supplemented with more references to the literature. The problem sets have been extended and now include over 130 problems, some of which can be solved using Excel.

Jonathan D. Raff, PhD, is an Associate Professor in the O'Neill School of Public and Environmental Affairs at Indiana University. He was the recipient of a National Science Foundation American Competitiveness in Chemistry Fellowship and early career awards from the National Science Foundation and the U.S. Department of Energy.

Ronald A. Hites, PhD, is a Distinguished Professor Emeritus in the O'Neill School of Public and Environmental Affairs at Indiana University. He is a Fellow of the American Chemical Society, of the American Association for the Advancement of Science, and of the Society for Environmental Toxicology and Chemistry. He was an editor ofEnvironmental Science and Technology from 1990-2019.

Preface xi

1 Simple Tool Skills1

1.1 Unit Conversions 1

1.2 Estimating 4

1.3 Ideal Gas Law 6

1.4 Stoichiometry 9

1.5 Thermodynamic Considerations 10

1.5.1 Enthalpy 11

1.5.2 Entropy 13

1.5.3 Gibbs Free Energy 14

1.6 Measurement Issues 15

1.7 Problem Set 24

2 Mass Balance and Kinetics29

2.1 Steady-State Mass Balance 29

2.1.1 Flows, Stocks, and Residence Times 29

2.1.2 Adding Multiple Flows 35

2.1.3 Fluxes Are Not Flows! 37

2.2 Nonsteady-State Mass Balance 39

2.2.1 Up-Going Curve 40

2.2.2 Down-Going Curve 43

2.2.3 Working with Real Data 45

2.3 Chemical Kinetics 49

2.3.1 First-Order Reactions 50

2.3.2 Second-Order Reactions 50

2.3.3 MichaelisMenten Kinetics 52

2.4 Problem Set 56

3 Atmospheric Chemistry63

3.1 Atmospheric Structure 63

3.2 Light and Photochemistry 65

3.3 Atmospheric Oxidants 69

3.4 Kinetics of Atmospheric Reactions 70

3.4.1 Pseudo-Steady-State Example 70

3.4.2 Arrhenius Equation 71

3.5 Stratospheric Ozone 72

3.5.1 Formation and Loss Mechanisms 72

3.5.2 Chapman Reaction Kinetics 77

3.6 Smog 80

3.7 Problem Set 84

4 Climate Change93

4.1 Historical Perspective 93

4.2 Blackbody Radiation and Earths Temperature 94

4.3 Absorption of Infrared Radiation 97

4.4 Greenhouse Effect 98

4.5 Earths Radiative Balance 99

4.5.1 Greenhouse Gases 99

4.5.2 Albedo 101

4.5.3 Solar Constant 101

4.5.4 Combined Effects 101

4.6 Aerosols and Clouds 101

4.7 Radiative Forcing 103

4.8 Global Warming Potentials 104

4.9 Concluding Remarks 106

4.10 Problem Set 108

5 Carbon Dioxide Equilibria113

5.1 pH and Equilibrium Constants 113

5.2 Pure Rain 116

5.3 Polluted Rain 119

5.4 Additional Acid Rain Chemistry and Implications 123

5.5 Surface Water 125

5.6 Ocean Acidification 128

5.7 Problem Set 132

6 Fates of Organic Compounds139

6.1 Molecular Interactions 140

6.1.1 Electronegativity 140

6.1.2 Molecular Dipoles and Quadrupoles 141

6.1.3 Types of Weak Interactions 142

6.2 Vapor Pressure 145

6.3 Aqueous Solubility 149

6.3.1 Solubility of Pure Liquids and Solids 149

6.3.2 Solubility of Gases 154

6.4 Partitioning into Organic Phases 158

6.5 Partitioning into Biota 160

6.5.1 Bioconcentration 161

6.5.2 Bioaccumulation 161

6.5.3 Biomagnification 162

6.6 Adsorption 162

6.7 WaterAir Transfer 165

6.8 Reactive Fates of Organic Pollutants 168

6.9 Putting It All Together: Partitioning and Persistence 169

6.10 Problem Set 172

7 Toxic Stuff: Mercury, Lead, Pesticides, Polychlorinated Biphenyls, Dioxins, and Flame Retardants181

7.1 Mercury 181

7.2 Lead 183

7.3 Pesticides 188

7.3.1 Pesticide History 189

7.3.2 Legacy Pesticides 190

7.3.3 Current Use Herbicides 194

7.3.4 Current Use Insecticides 198

7.3.5 Current Use Fumigants 201

7.3.6 Current Use Fungicides 203

7.4 Polychlorinated Biphenyls (PCBs) 203

7.4.1 PCB Nomenclature 204

7.4.2 PCB Production and Use 205

7.4.3 PCBs in the Hudson River 206

7.4.4 PCBs in Bloomington, Indiana 209

7.4.5 Yusho and Yu-Cheng Diseases 211

7.4.6 PCB Conclusions 213

7.5 Polychlorinated Dibenzo-p-dioxins and Dibenzofurans 214

7.5.1 Dioxin Nomenclature 214

7.5.2 Chick Edema Disease 215

7.5.3 Agent Orange 216

7.5.4 Times Beach, Missouri 218

7.5.5 Seveso, Italy 219

7.5.6 Combustion Sources of Dioxins 222

7.5.7 US Dioxin Reassessment and Conclusions 224

7.6 Brominated and Other Flame Retardants 225

7.6.1 Polybrominated Biphenyls 226

7.6.2 Polybrominated Diphenyl Ethers 228

7.6.3 Other Flame Retardants 229

7.7 Lessons Learned 231

A Primer on Organic Structures and Names 233

B Periodic Table of the Elements 243

C Useful Physical and Chemical Constants 245

D Answers to Problem Sets 247

Chapter 1 247

Chapter 2 248

Chapter 3 251

Chapter 4 252

Chapter 5 254

Chapter 6 257

Index 259