John H. Seinfeld is Louis E. Nohl Professor at the California Institute of Technology. He is a member of the U.S. National Academy of Engineering, the U.S. National Academy of Sciences, and a Fellow of the American Academy of Arts and Sciences. He is the recipient of numerous honors and awards, including the American Chemical Society Award for Creative Advances in Environmental Science and Technology, the NASA Public Service Award, the Nevada Medal, the Fuchs Award, and the 2012 Tyler Prize.

Spyros N. Pandis is Professor of Chemical Engineering at the University of Patras, Greece, and Research Professor of Chemical Engineering and Engineering and Public Policy at Carnegie Mellon University. He is the recipient of the Whitby Award by the American Association for Aerosol Research and the European Research Council Advanced Investigator IDEAS award. He is a Fellow of the American Association for Aerosol Research.

Preface to the First Edition xxiii

Preface to the Third Edition xxv

PART I | The Atmosphere and Its Constituents

Chapter 1 | The Atmosphere 3

1.1 History and Evolution of Earth's Atmosphere 3

1.2 Climate 5

1.3 Layers of the Atmosphere 5

1.4 Pressure in the Atmosphere 7

1.5 Temperature in the Atmosphere 10

1.6 Expressing the Amount of a Substance in the Atmosphere 10

1.7 Airborne Particles 14

1.8 Spatial and Temporal Scales of Atmospheric Processes 14

Problems 16

References 17

Chapter 2 | Atmospheric Trace Constituents 18

2.1 Atmospheric Lifetime 19

2.2 Sulfur-Containing Compounds 23

2.3 Nitrogen-Containing Compounds 27

2.4 Carbon-Containing Compounds 32

2.5 Halogen-Containing Compounds 40

2.6 Atmospheric Ozone 44

2.7 Particulate Matter (Aerosols) 47

2.8 Mercury 55

2.9 Emission Inventories 55

Appendix 2.1 US Air Pollution Legislation 56

Appendix 2.2 Hazardous Air Pollutants (Air Toxics) 57

Problems 59

References 61

PART II | Atmospheric Chemistry

Chapter 3 | Chemical Kinetics 69

3.1 Order of Reaction 69

3.2 Theories of Chemical Kinetics 71

3.3 The Pseudo-Steady-State Approximation 76

3.4 Reactions of Excited Species 77

3.5 Termolecular Reactions 78

3.6 Chemical Families 81

3.7 Gas-Surface Reactions 83

Problems 84

References 87

Chapter 4 | Atmospheric Radiation and Photochemistry 88

4.1 Radiation 88

4.2 Radiative Flux in the Atmosphere 91

4.3 Beer . Lambert Law and Optical Depth 93

4.4 Actinic Flux 95

4.5 Atmospheric Photochemistry 97

4.6 Absorption of Radiation by Atmospheric Gases 100

4.7 Absorption by O2 and O3 105

4.8 Photolysis Rate as a Function of Altitude 109

4.9 Photodissociation of O3 to Produce O and O(1D) 112

4.10 Photodissociation of NO2 114

Problems 117

References 117

Chapter 5 | Chemistry of the Stratosphere 119

5.1 Chapman Mechanism 122

5.2 Nitrogen Oxide Cycles 129

5.3 HOx Cycles 134

5.4 Halogen Cycles 139

5.5 Reservoir Species and Coupling of the Cycles 144

5.6 Ozone Hole 146

5.7 Heterogeneous (Nonpolar) Stratospheric Chemistry 155

5.8 Summary of Stratospheric Ozone Depletion 162

5.9 Transport and Mixing in the Stratosphere 165

5.10 Ozone Depletion Potential 167

Problems 168

References 173

Chapter 6 | Chemistry of the Troposphere 175

6.1 Production of Hydroxyl Radicals in the Troposphere 176

6.2 Basic Photochemical Cycle of NO2, NO, and O3 179

6.3 Atmospheric Chemistry of Carbon Monoxide 181

6.4 Atmospheric Chemistry of Methane 188

6.5 The NOx and NOy Families 192

6.6 Ozone Budget of the Troposphere and Role of NOx 195

6.7 Tropospheric Reservoir Molecules 203

6.8 Relative Roles of VOC and NOx in Ozone Formation 208

6.9 Simplified Organic/NOx Chemistry 212

6.10 Chemistry of Nonmethane Organic Compounds in the Troposphere 214

6.11 Atmospheric Chemistry of Biogenic Hydrocarbons 233

6.12 Atmospheric Chemistry of Reduced Nitrogen Compounds 244

6.13 Atmospheric Chemistry (Gas Phase) of Sulfur Compounds 246

6.14 Tropospheric Chemistry of Halogen Compounds 249

6.15 Atmospheric Chemistry of Mercury 253

Appendix 6 Organic Functional Groups 254

Problems 256

References 259

Chapter 7 | Chemistry of the Atmospheric Aqueous Phase 265

7.1 Liquid Water in the Atmosphere 265

7.2 Absorption Equilibria and Henry's Law 268

7.3 Aqueous-Phase Chemical Equilibria 271

7.4 Aqueous-Phase Reaction Rates 284

7.5 S(IV)-S(VI) Transformation and Sulfur Chemistry 286

7.6 Dynamic Behavior of Solutions with Aqueous-Phase Chemical Reactions 295

Appendix 7.1 Thermodynamic and Kinetic Data 301

Appendix 7.2 Additional Aqueous-Phase Sulfur Chemistry 305

7A.1 S(IV) Oxidation by the OH Radical 305

7A.2 Oxidation of S(IV) by Oxides of Nitrogen 308

7A.3 Reaction of Dissolved SO2 with HCHO 309

Appendix 7.3 Aqueous-Phase Nitrite and Nitrate Chemistry 311

7A.4 NOx Oxidation 311

7A.5 Nitrogen Radicals 311

Appendix 7.4 Aqueous-Phase Organic Chemistry 312

Appendix 7.5 Oxygen and Hydrogen Chemistry 313

Problems 314

References 317

PART III | Aerosols

Chapter 8 | Properties of the Atmospheric Aerosol 325

8.1 The Size Distribution Function 325

8.2 Ambient Aerosol Size Distributions 342

8.3 Aerosol Chemical Composition 352

8.4 Spatiotemporal Variation 354

Problems 357

References 359

Chapter 9 | Dynamics of Single Aerosol Particles 362

9.1 Continuum and Noncontinuum Dynamics: the Mean Free Path 362

9.2 The Drag on a Single Particle: Stokes' Law 368

9.3 Gravitational Settling of an Aerosol Particle 372

9.4 Motion of an Aerosol Particle in an External Force Field 376

9.5 Brownian Motion of Aerosol Particles 376

9.6 Aerosol and Fluid Motion 385

9.7 Equivalent Particle Diameters 388

Problems 393

References 394

Chapter 10 | Thermodynamics of Aerosols 396

10.1 Thermodynamic Principles 396

10.2 Aerosol Liquid Water Content 409

10.3 Equilibrium Vapor Pressure Over a Curved Surface: the Kelvin Effect 419

10.4 Thermodynamics of Atmospheric Aerosol Systems 423

10.5 Aerosol Thermodynamic Models 440

Problems 442

References 443

Chapter 11 | Nucleation 448

11.1 Classical Theory of Homogeneous Nucleation: Kinetic Approach 449

11.2 Classical Homogeneous Nucleation Theory: Constrained Equilibrium Approach 457

11.3 Recapitulation of Classical Theory 464

11.4 Experimental Measurement of Nucleation Rates 465

11.5 Modifications of the Classical Theory and More Rigorous Approaches 467

11.6 Binary Homogeneous Nucleation 468

11.7 Binary Nucleation in the H2SO4-H2O System 473

11.8 Nucleation on an Insoluble Foreign Surface 475

11.9 Ion-Induced Nucleation 478

11.10 Atmospheric New-Particle Formation 480

Appendix 11 The Law of Mass Action 487

Problems 489

References 490

Chapter 12 | Mass Transfer Aspects of Atmospheric Chemistry 493

12.1 Mass and Heat Transfer to Atmospheric Particles 493

12.2 Mass Transport Limitations in Aqueous-Phase Chemistry 503

12.3 Mass Transport and Aqueous-Phase Chemistry 511

12.4 Mass Transfer to Falling Drops 526

12.5 Characteristic Time for Atmospheric Aerosol Equilibrium 527

Appendix 12 Solution of the Transient Gas-Phase Diffusion Problem: Equations (12.4)-(12.7) 532

Problems 533

References 535

Chapter 13 | Dynamics of Aerosol Populations 537

13.1 Mathematical Representations of Aerosol Size Distributions 537

13.2 Condensation 538

13.3 Coagulation 544

13.4 The Discrete General Dynamic Equation 557

13.5 The Continuous General Dynamic Equation 558

Appendix 13.1 Additional Mechanisms of Coagulation 560

13A.1 Coagulation in Laminar Shear Flow 560

13A.2 Coagulation in Turbulent Flow 560

13A.3 Coagulation from Gravitational Settling 561

13A.4 Brownian Coagulation and External Force Fields 562

Appendix 13.2 Solution of (13.73) 567

Problems 568

References 571

Chapter 14 | Atmospheric Organic Aerosols 573

14.1 Chemistry of Secondary Organic Aerosol Formation 574

14.2 Volatility of Organic Compounds 582

14.3 Idealized Description of Secondary Organic Aerosol Formation 583

14.4 Gas-Particle Partitioning 590

14.5 Models of SOA Formation and Evolution 596

14.6 Primary Organic Aerosol 605

14.7 The Physical State of Organic Aerosols 608

14.8 SOA Particle-Phase Chemistry 610

14.9 Aqueous-Phase Secondary Organic Aerosol Formation 615

14.10 Estimates of the Global Budget of Atmospheric Organic Aerosol 622

Problems 623

References 626

Chapter 15 | Interaction of Aerosols with Radiation 633

15.1 Scattering and Absorption of Light by Small Particles 633

15.2 Visibility 644

15.3 Scattering, Absorption, and Extinction Coefficients From Mie Theory 647

15.4 Calculated Visibility Reduction Based on Atmospheric Data 651

Appendix 15 Calculation of Scattering and Extinction Coefficients by Mie Theory 654

Problems 654

References 656

PART IV | Physical and Dynamic Meteorology, Cloud Physics, and Atmospheric Diffusion

Chapter 16 | Physical and Dynamic Meteorology 661

16.1 Temperature in the Lower Atmosphere 661

16.2 Atmospheric Stability 665

16.3 The Moist Atmosphere 670

16.4 Basic Conservation Equations for the Atmospheric Surface Layer 683

16.5 Variation of Wind with Height in the Atmosphere 692

Appendix 16.1 Properties of Water and Water Solutions 701

16A.1 Specific Heat of Water and Ice 701

16A.2 Latent Heats of Vaporization and Melting for Water 701

16A.3 Water Surface Tension 701

Appendix 16.2 Derivation of the Basic Equations of Surface-Layer Atmospheric Fluid Mechanics 702

Problems 705

References 706

Chapter 17 | Cloud Physics 708

17.1 Equilibrium of Water Droplets in the Atmosphere 708

17.2 Cloud and Fog Formation 719

17.3 Growth Rate of Individual Cloud Droplets 723

17.4 Growth of a Droplet Population 726

17.5 Cloud Condensation Nuclei 730

17.6 Cloud Processing of Aerosols 736

17.7 Other Forms of Water in the Atmosphere 743

Appendix 17 Extended Köhler Theory 751

17A.1 Modified Form of Köhler Theory for a Soluble Trace Gas 751

17A.2 Modified Form of Köhler Theory for a Slightly Soluble Substance 754

17A.3 Modified Form of Köhler Theory for a Surface-Active Solute 755

17A.4 Examples 756

Problems 759

References 760

Chapter 18 | Atmospheric Diffusion 763

18.1 Eulerian Approach 763

18.2 Lagrangian Approach 766

18.3 Comparison of Eulerian and Lagrangian Approaches 767

18.4 Equations Governing the Mean Concentration of Species in Turbulence 767

18.5 Solution of the Atmospheric Diffusion Equation for an Instantaneous Source 771

18.6 Mean Concentration from Continuous Sources 772

18.7 Statistical Theory of Turbulent Diffusion 778

18.8 Summary of Atmospheric Diffusion Theories 783

18.9 Analytical Solutions for Atmospheric Diffusion: the Gaussian Plume Equation and Others 784

18.10 Dispersion Parameters in Gaussian Models 791

18.11 Plume Rise 796

18.12 Functional Forms of Mean Windspeed and Eddy Diffusivities 798

18.13 Solutions of the Steady-State Atmospheric Diffusion Equation 803

Appendix 18.1 Further Solutions of Atmospheric Diffusion Problems 807

18A.1 Solution of (18.29)-(18.31) 807

18A.2 Solution of (18.50) and (18.51) 809

18A.3 Solution of...