A problem-solving approach to aquatic chemistry

A Problem-Solving Approach to Aquatic Chemistry Enables civil and environmental engineers to understand the theory and application of aquatic equilibrium chemistry The second edition of A Problem-Solving Approach to Aquatic Chemistry provides a detailed introduction to aquatic equilibrium chemistry, calculation methods for systems at equilibrium, applications of aquatic chemistry, and chemical kinetics. The text directly addresses two required ABET program outcomes in environmental engineering: "... chemistry (including stoichiometry, equilibrium, and kinetics)" and "material and energy balances, fate and transport of substances in and between air, water, and soil phases." The book is very student-centered, with each chapter beginning with an introduction and ending with a summary that reviews the chapter's main points. To aid in reader comprehension, important terms are defined in context and key ideas are summarized. Many thought-provoking discussion questions, worked examples, and end of chapter problems are also included. Each part of the text begins with a case study, a portion of which is addressed in each subsequent chapter, illustrating the principles of that chapter. In addition, each chapter has an Historical Note exploring connections with the people and cultures connected to topics in the text. A Problem-Solving Approach to Aquatic Chemistry includes: Fundamental concepts, such as concentration units, thermodynamic basis of equilibrium, and manipulating equilibria Solutions of chemical equilibrium problems, including setting up the problems and algebraic, graphical, and computer solution techniques Acid-base equilibria, including the concepts of acids and bases, titrations, and alkalinity and acidity Complexation, including metals, ligands, equilibrium calculations with complexes, and applications of complexation chemistry Oxidation-reduction equilibria, including equilibrium calculations, graphical approaches, and applications Gas-liquid and solid-liquid equilibrium, with expanded coverage of the effects of global climate change Other topics, including chemical kinetics of aquatic systems, surface chemistry, and integrative case studies For advanced/senior undergraduates and first-year graduate students in environmental engineering courses, A Problem-Solving Approach to Aquatic Chemistry serves as an invaluable learning resource on the topic, with a variety of helpful learning elements included throughout to ensure information retention and the ability to apply covered concepts in practical settings.

Preface xix Part I Fundamental Concepts 1 Getting Started with the Fundamental Concepts 3 1.1 Introduction 3 1.2 Why Calculate Chemical Species Concentrations at Equilibrium? 3 1.3 Primary Variables: Importance of pH and pe 6 1.4 Properties of Water 7 1.5 Part I Roadmap 9 1.6 Chapter Summary 9 1.7 Part I Case Study: Can Methylmercury be Formed Chemically in Water? 10 Chapter Key Ideas 11 Chapter Glossary 11 Historical Note: S.P.L. Sorensen and the p in pH 11 Chapter References 12 2 Concentration Units 13 2.1 Introduction 13 2.2 Units Analysis 13 2.3 Molar Concentration Units 14 2.4 Mass Concentration Units 19 2.5 Dimensionless Concentration Units 24 2.6 Equivalents 25 2.7 Review of Units Interconversion 26 2.8 Common Concentration Units in the Gas Phase 27 2.9 Common Concentration Units in the Solid Phase 28 2.10 Activity 28 2.11 Chapter Summary 30 2.12 Part I Case Study: Can Methylmercury Be Formed Chemically in Water? 30 Chapter Key Ideas 31 Chapter Glossary 31 Historical Note: Amadea Avogadro and Avogadro's Number 32 Problems 33 Chapter References 34 3 Thermodynamic Basis of Equilibrium 35 3.1 Introduction 35 3.2 Thermodynamic Properties 36 3.3 Why Do We Need Thermodynamics to Calculate Species Concentrations? 39 3.4 Thermodynamic Laws 42 3.5 Gibbs Free Energy 45 3.6 Properties of Thermodynamic Functions 48 3.7 Changes in Thermodynamic Properties During Chemical Reactions 50 3.8 Relating Gibbs Free Energy to Species Concentrations 55 3.9 Chemical Equilibrium and the Equilibrium Constant 60 3.10 Chapter Summary 62 3.11 Part I Case Study: Can Methylmercury Be Formed Chemically in Water? 63 Chapter Key Ideas 63 Chapter Glossary 64 Historical Note: Josiah Willard Gibbs 66 Problems 67 Chapter References 68 4 Manipulating Equilibrium Expressions 69 4.1 Introduction 69 4.2 Chemical and Mathematical Forms of Equilibria 69 4.3 Units of Equilibrium Constants 73 4.4 Reversing Equilibria 75 4.5 Effects of Stoichiometry 76 4.6 Adding Equilibria 78 4.7 Creating Equilibria 81 4.8 Chapter Summary 87 4.9 Part I Case Study: Can Methylmercury Be Formed Chemically in Water? 87 Chapter Key Ideas 88 Chapter Glossary 89 Historical Note: Henri- Louis Le Chatelier and Le Chatelier's Principle 89 Problems 90 Chapter References 91 Part II Solving Chemical Equilibrium Problems 5 Getting Started withSolving Equilibrium Problems 95 5.1 Introduction 95 5.2 A Framework for Solving Chemical Equilibrium Problems 95 5.3 Introduction to Defining the Chemical System 97 5.4 Introduction to Enumerating Chemical Species 98 5.5 Introduction to Defining the Constraints on Species Concentrations 98 5.6 Part II Roadmap 100 5.7 Chapter Summary 100 5.8 Part II Case Study: Have You Had Your Zinc Today? 101 Chapter Key Ideas 101 Chapter Glossary 101 Historical Note: "Active Mass" and Familial Relations 102 Chapter References 103 6 Setting Up Chemical Equilibrium Calculations 105 6.1 Introduction 105 6.2 Defining the Chemical System 105 6.3 Enumerating Chemical Species 106 6.4 Defining the Constraints on Species Concentrations 112 6.5 Review of Procedures for Setting up Equilibrium Systems 120 6.6 Concise Mathematical Form for Equilibrium Systems 121 6.7 Chapter Summary 122 6.8 Part II Case Study: Have You Had Your Zinc Today? 123 Chapter Key Ideas 126 Chapter Glossary 126 Historical Note: Salts of the Ocean 127 Problems 129 Chapter References 130 7 Algebraic Solutions to Chemical Equilibrium Problems 131 7.1 Introduction 131 7.2 Background on Algebraic Solutions 131 7.3 Method of Substitution 133 7.4 Method of Approximation 139 7.5 Chapter Summary 148 7.6 Part II Case Study: Have You Had Your Zinc Today? 148 Chapter Key Ideas 152 Historical Note: What's in a Name? 152 Problems 153 8 Graphical Solutions to Chemical Equilibrium Problems 155 8.1 Introduction 155 8.2 Log Concentration and pC- pH Diagrams 156 8.3 Using pC- pH Diagrams with More Complex Systems 162 8.4 Special Shortcuts for Monoprotic Acids 167 8.5 When Graphical Methods Fail: The Proton Condition 171 8.6 Chapter Summary 177 8.7 Part II Case Study: Have You Had Your Zinc Today? 178 Chapter Key Ideas 179 Chapter Glossary 180 Historical Note: Who Was First? 180 Problems 181 Chapter Reference 182 9 Computer Solutions to Chemical Equilibrium Problems 183 9.1 Introduction 183 9.2 Chapter Problem 183 9.3 Spreadsheet Solutions 184 9.4 Equilibrium Calculation Software 188 9.5 Nanoql SE 190 9.6 The Tableau Method and Other Equilibrium Calculation Apps 192 9.7 Visual MINTEQ 201 9.8 Chapter Summary 202 9.9 Part II Case Study: Have You Had Your Zinc Today? 202 Chapter Key Ideas 203 Chapter Glossary 203 Historical Note: ALGOL to VBA 203 Problems 204 Chapter References 205 Part III Acid-Base Equilibria in Homogenous Aqueous Systems 10 Getting Started with Acid-Base Equilibrium in Homogenous Aqueous Systems 209 10.1 Introduction 209 10.2 Homogeneous Systems 209 10.3 Types of Reactions in Homogeneous Systems 211 10.4 The Wonderful World of Acids and Bases 212 10.5 Part III Roadmap 215 10.6 Chapter Summary 215 10.7 Part III Case Study: Acid Rain 215 Chapter Key Ideas 216 Chapter Glossary 216 Historical Note: "An Evil of the Highest Magnitude" 217 Chapter References 218 11 Acids and Bases 219 11.1 Introduction 219 11.2 Definitions of Acids and Bases 219 11.3 Acid and Base Strength 223 11.4 Polyprotic Acids 228 11.5 Alpha Values (Distribution Functions) 236 11.6 Chapter Summary 239 11.7 Part II Case Study: Acid Rain 239 Chapter Key Ideas 241 Chapter Glossary 242 Historical Note: Why Is a Base a Base? 242 Problems 243 Addendum: A Surprising Exact Solution 245 Chapter References 248 12 Acid-Base Titrations 249 12.1 Introduction 249 12.2 Principles of Acid-Base Titrations 250 12.3 Equivalence Points 255 12.4 Titration of Polyprotic Acids 265 12.5 Buffers 269 12.6 Interpretation of Acid-Base Titration Curves with Complex Mixtures 277 12.7 Chapter Summary 279 12.8 Part III Case Study: Acid Rain 280 Chapter Key Ideas 282 Chapter Glossary 283 Historical Note: Mohr about Titrations 284 Problems 285 Chapter References 286 13 Alkalinity and Acidity 287 13.1 Introduction 287 13.2 Alkalinity and the Acid Neutralizing Capacity 287 13.3 Alkalinity and the Charge Balance 290 13.4 Characteristics of Alkalinity and Acidity 292 13.5 Using the Definitions of Alkalinity to Solve Problems 302 13.6 Effects of Other Weak Acids and Bases on Alkalinity 308 13.7 Chapter Summary 310 13.8 Part III Case Study: Acid Rain 310 Chapter Key Ideas 311 Chapter Glossary 312 Historical Note: Can You Pass the Litmus Test? 313 Problems 314 Chapter References 316 Part IV Other Equilibria in Homogenous Aqueous Systems 14 Getting Started with Other Equilibria in Homogeneous Aqueous Systems 319 14.1 Introduction 319 14.2 Electron- Sharing Reactions 319 14.3 Electron Transfer 321 14.4 Part IV Roadmap 323 14.5 Chapter Summary 323 14.6 Part IV Case Study: Which Form of Copper Plating Should You Use? 323 Chapter Key Ideas 324 Historical Note: Hauptvalenz and Nebenvalenz 324 Chapter References 325 15 Complexation 327 15.1 Introduction 327 15.2 Metals 327 15.3 Ligands 330 15.4 Equilibrium Calculations with Complexes 335 15.5 Systems with Several Metals and Ligands 345 15.6 Applications of Complexation Chemistry 357 15.7 Chapter Summary 361 15.8 Part IV Case Study: Which Form of Copper Plating Should You Use? 362 Chapter Key Ideas 364 Chapter Glossary 365 Historical Note: British Anti- Lewisite - A WMD- Inspired Ligand 366 Problems 368 Chapter References 369 16 Oxidation and Reduction 371 16.1 Introduction 371 16.2 A Few Definitions 371 16.3 Balancing Redox Reactions 374 16.4 Which Redox Reactions Occur? 383 16.5 Redox Thermodynamics and Oxidant and Reductant Strength 386 16.6 Manipulating Half Reactions 393 16.7 Algebraic Equilibrium Calculations in Systems Undergoing Electron Transfer 396 16.8 Graphical Representations of Systems Undergoing Electron Transfer 399 16.9 Applying Redox Equilibrium Calculations to the Real World 413 16.10 Chapter Summary 414 16.11 Part IV Case Study: Which Form of Copper Plating Should You Use? 415 Chapter Key Ideas 417 Chapter Glossary 418 Historical Note: Walther Hermann Nernst 419 Problems 420 Chapter References 422 Part V Heterogeneous Systems 17 Getting Started with Heterogeneous Systems 425 17.1 Introduction 425 17.2 Equilibrium Exchange Between Gas and Aqueous Phases 426 17.3 Equilibrium Exchange Between Solid and Aqueous Phases 427 17.4 Part V Roadmap 428 17.5 Chapter Summary 428 17.6 Part V Case Study: The Killer Lakes 428 Chapter Key Ideas 429 Historical Note: "A Spirit Case and a Gasogene" 429 Chapter References 430 18 Gas-Liquid Equilibria 431 18.1 Introduction 431 18.2 Raoult's Law and Henry's Law 431 18.3 Equilibrium Calculations Involving Gas-Liquid Equilibria 438 18.4 Dissolved Carbon Dioxide 449 18.5 Chapter Summary 456 18.6 Part V Case Study: The Killer Lakes 456 Chapter Key Ideas 457 Chapter Glossary 458 Historical Note: A Brief History of Carbon Dioxide 459 Problems 460 Chapter References 462 19 Solid-Liquid Equilibria 463 19.1 Introduction 463 19.2 Saturation and the Activity of Pure Solids 463 19.3 Equilibrium Calculations with Solid-Liquid Equilibria 466 19.4 Factors Affecting Metal Solubility 474 19.5 Solubility of Calcium Carbonate 480 19.6 Models for the Acid-Base Chemistry of Natural Waters 484 19.7 Chapter Summary 491 19.8 Part V Case Study: The Killer Lakes 491 Chapter Key Ideas 492 Chapter Glossary 493 Historical Note: Black Smokers and White Smokers 493 Problems 494 Addendum: Information Requirements 497 Chapter References 498 Part VI Beyond Dilute Solutions at Equilibrium 20 Getting Started with Beyond Dilute Solutions at Equilibrium 501 20.1 Introduction 501 20.2 Extensions to Nonideal and Nonstandard Conditions 502 20.3 The Strange World of Surfaces 503 20.4 Nonequilibrium Conditions 504 20.5 Integrated Case Studies 504 20.6 Part VI Roadmap 505 20.7 Chapter Summary 505 Chapter Key Ideas 506 Chapter Glossary 506 Historical Note: "Harcourt, Come to Me!" 506 Chapter References 507 21 Thermodynamics Revisited: The Effects of Ionic Strength, Temperature, and Pressure 509 21.1 Introduction 509 21.2 Effects of Ionic Strength 510 21.3 Effects of Temperature on Equilibrium Constants 522 21.4 Effects of Pressure on Equilibrium Constants 528 21.5 Chapter Summary 529 Chapter Key Ideas 530 Chapter Glossary 531 Historical Note: Jacobus Henricus van't Hoff 531 Problems 532 Chapter References 534 22 Aquatic Chemistry ofSurfaces 535 22.1 Introduction 535 22.2 Nomenclature 535 22.3 Isotherms and Ion Exchange 538 22.4 Introduction to Surface Complexation Modeling 543 22.5 Surface Complexation Modeling 546 22.6 Chapter Summary 552 Chapter Key Ideas 553 Chapter Glossary 553 Historical Note: From "Cat's Cradle" to the "Swiss Model" to Surface Complexation Modeling 554 Problems 555 Addendum: The Freundlich Isotherm and Adsorption Equilibria 556 Chapter References 557 23 Chemical Kinetics of Aquatic Systems 559 23.1 Introduction 559 23.2 The Need for Chemical Kinetics 560 23.3 Reaction Rates 561 23.4 Common Rate Expressions 569 23.5 More Complex Kinetic Forms 577 23.6 Effects of Temperature and Ionic Strength on Kinetics 582 23.7 Chapter Summary 587 Chapter Key Ideas 587 Chapter Glossary 588 Historical Note: Arrhenius, Chick, and Foote 589 Problems 590 Chapter References 592 24 Putting It All Together: Integrated Case Studies in Aquatic Chemistry 593 24.1 Introduction 593 24.2 Integrated Case Study 1: Metal Finishing 594 24.3 Integrated Case Study 2: Oxidation of Fe(+II) by Oxygen 598 24.4 Integrated Case Study 3: Inorganic Mercury Chemistry in Natural Waters 603 24.5 Integrated Case Study 4: Phosphate Buffers 607 24.6 Integrated Case Study 5: Global Climate Change 610 24.7 Chapter Summary 613 Historical Note: Stumm and Morgan 614 Chapter References 614 Appendix A: Background Information 617 A.1 Introduction 617 A.2 Chemical Principles 617 A.3 Mathematical Principles 619 A.4 Spreadsheet Skills 620 Chapter Key Ideas 623 Chapter Glossary 623 Useful Physical Constants and Conversions 623 Appendix B: Equilibrium Revisited 625 B.1 Introduction 625 B.2 Equilibrium and Steady State 625 B.3 Energy Minimization and Algebraic Solutions 628 Chapter Key Ideas 631 Chapter Glossary 631 Appendix C: Summary of Procedures 633 C.1 Oxidation States and Balancing Reactions 633 C.2 Setting Up Chemical Equilibrium Systems (Section 6.5) 634 C.3 Algebraic Solution Techniques 635 C.4 Graphical Solutions 635 C.5 Computer Solutions: Tableau Method (Section 9.6.6) 637 C.6 Acid-Base Titrations 638 C.7 Complexation (Section 15.4.4) 638 C.8 Ionic Strength Effects (Section 21.2.7) 639 C.9 Surface Complexation Modeling Method (Section 22.5.4) 639 C.10 Chemical Kinetics (Section 23.3.4) 639 Appendix D: Selected Equilibrium Constants 641 Chapter References 651 Appendix E: Animations and Example Spreadsheet Files 653 E.1 Introduction to Animations 653 E.2 Variation of the Equilibrium pH of a Monoprotic Acid Solution with the Total Acid Concentration and K a 653 E.3 How to Draw pC- pH Diagrams for Monoprotic Acids 654 E.4 Equilibrium pH During the Titration of a Monoprotic Acid with a Strong Base 656 E.5 Spreadsheet Examples 657 Appendix F: Nanoql SE 661 F.1 Introduction 661 F.2 Entering Your System 661 F.3 How to Solve Systems and Vary System Parameters 663 F.4 Nanoql SE Examples 666 Chapter Reference 668 Index 669 Biographical Index 677