Daniel J Jacob

Introduction to Atmospheric Chemistry

• Gebundenes Buch

Produktbeschreibung

"I can actually imagine a rigorous and challenging undergraduate course making it through this whole text in one semester, which is not the case for its competitors. The problem sets are excellent . . . truly unique." --Hiram Levy, Princeton University

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Produktdetails

• Verlag: Princeton University Press
• Seitenzahl: 280
• Erscheinungstermin: 10. Januar 2000
• Englisch
• Abmessung: 242mm x 162mm x 22mm
• Gewicht: 499g
• ISBN-13: 9780691001852
• ISBN-10: 0691001855
• Artikelnr.: 21863045

Autorenporträt

Daniel J. Jacob is the Gordon McKay Professor of Atmospheric Chemistry and Environmental Engineering at Harvard University. He has taught the undergraduate atmospheric chemistry course at Harvard since 1992. He has published over 100 research papers in atmospheric chemistry journals.

Inhaltsangabe

Preface xi
1 - Measures of Atmospheric Composition 3
1.1 Mixing Ratio 3
1.2 Number Density 4
1.3 Partial Pressure 8
Further Reading 11
Problems 11
1.1 Fog Formation 11
1.2 Phase Partitioning of Water in Cloud 11
1.3 The Ozone Layer 11
2 - Atmospheric Pressure 14
2.1 Measuring Atmospheric Pressure 14
2.2 Mass of the Atmosphere 14
2.3 Vertical Profiles of Pressure and Temperature 16
2.4 Barometric Law 18
2.5 The Sea-Breeze Circulation 21
Problems 22
2.1 Scale Height of the Martian Atmosphere 22
2.2 Scale Height and Atmospheric Mass 22
3 - Simple Models 24
3.1 One-Box Model 25
3.1.1 Concept of Lifetime 25
3.1.2 Mass Balance Equation 27
3.2 Multibox Models 30
3.3 Puff Models 33
Problems 36
3.1 Atmospheric Steady State 36
3.2 Ventilation of Pollution from the United States 37
3.3 Stratosphere- Troposphere Exchange 37
3.4 Interhemispheric Exchange 39
3.5 Long Range Transport of Acidity 39
3.6 Box versus Column Model for an Urban Airshed 40
3.7 The Montreal Protocol 40
4 - Atmospheric Transport 42
4.1 Geostrophic Flow 42
4.1.1 Coriolis Force 42
4.1.2 Geostrophic Balance 46
4.2 The General Circulation 48
4.3 Vertical Transport 53
4.3.1 Buoyancy 53
4.3.2 Atmospheric Stability 55
4.3.3 Adiabatic Lapse Rate 56
4.3.4 Latent Heat Release from Cloud Formation 58
4.3.5 Atmospheric Lapse Rate 60
4.4 Turbulence 63
4.4.1 Description of Turbulence 64
4.4.2 Turbulent Flux 64
4.4.3 Parameterization of Turbulence 67
4.4.4 Time Scales for Vertical Transport 70
Further Readinng 71
Problems 71
4.1 Dilution of Power Plant Plumes 71
4.2 Short Questions on Atmospheric Transport 72
4.3 Seasonal Motion of the ITCZ 73
4.4 A Simple Boundary Layer Model 74
4.5 Breaking a Nightime Inversion 74
4.6 Wet Convection 75
4.7 Scavenging of Water in a Thunderstorm 76
4.8 Global Source of Methane 76
4.9 Role of Molecular Diffusion in Atmosheric Transport 77
4.10 Vertical Transport Near the Surface 78
5 - The Continuity Equation 79
5.1 Eulerian Form 79
5.1.1 Derivation 79
5.1.2 Discretization 81
5.2 Lagrangian Form 84
Further Reading 85
Problems 85
5.1 Turbulent Diffusion Coefficient 85
6 - Geochemical Cycles 87
6.1 Geochemical Cycling of Elements 87
6.2 Early Evolution of the Atmosphere 89
6.3 The Nitrogen Cycle 90
6.4 The Oxygen Cycle 94
6.5 The Carbon Cycle 97
6.5.1 Mass Balance of Atmospheric CO2 97
6 5.2 Carbonate Chemistry in the Ocean 97
6.5.3 Uptake of CO2 by the Ocean 100
6 5.4 Uptake of CO2 by the Terrestrial Biosphere 104
6 5.5 Box Model of the Carbon Cycle 105
Further Reading 107
Problems 107
6.1 Short Questions on the Oxygen Cycle 107
6.2 Short Questions on the Carbon Cycle 108
6.3 Atmospheric Residence Time of Helium 108
6.4 Methyl Bromide 109
6.5 Global Fertilization of the Biosphere 111
6.6 Ocean pH 111
6.7 Cycling of CO2 with the Terrestrial Biosphere 112
6.8 Sinks of Atmospheric CO2 Deduced from Changes in Atmospheric O2 113
6.9 Fossil Fuel CO2 Neutralization by Marine CaCO3 113
7 - The Greenhouse Effect 115
7.1 Radiation 118
7.2 Effective Temperature of the Earth 121
7.2.1 Solar and Terrestrial Emission Spectra 121
7.2.2 Radiative Balance of the Earth 122
7.3 Absorption of Radiation by the Atmosphere 126
7.3.1 Spectroscopy of Gas Molecules 126
7.3.2 A Simple Greenhouse Model 128
7.3.3 Interpretation of the Terrestrial Radiation Spectrum 131
7.4 Radiative Forcing 133
7.4.1 Definition of Radiative Forcing 133
7.4.2 Application 135
7.4.3 Radiative Forcing and Surface Temperature 137
7.5 Water Vapor and Cloud Feedbacks 138
7.5.1 Water Vapor 138
7.5.2 Clouds 140
7.6 Optical Depth 140
Further Reading 142
Problems 142
7.1 Climate Response to Changes in Ozone 142
7.2 Interpretation of the Terrestrial Radiation Spectrum 143
7.3 Jupiter and Mars 144
7.4 The "Faint Sun " Problem 144
7.5 Planetary Skin 145
7.6 Absorption in the Atmospheric Window 145
8 - Aerosols 146
8.1 Sources and Sinks of Aerosols 146
8.2 Radiative Effects 148
8.2.1 Scattering of Radiation 148
8.2.2 Visibility Reduction 150
8.2.3 Perturbation to Climate 151
Further Reading 154
Problems 155
8.1 Residence Times of Aerosols 155
8.2 Aerosols and Radiation 155
9 - Chemical Kinetics 157
9.1 Rate Expressions for Gas-Phase Reactions 157
9.1.1 Bimolecular Reactions 157
9.1.2 Three-Body Reactions 158
9.2 Reverse Reactions and Chemical Equilibria 159
9.3 Photolysis 160
9.4 Radical-Assisted Reaction Chains 161
Further Reading 163
10 - Stratospheric Ozone 164
10.1 Chapman Mechanism 164
10.1.1 The Mechanism 164
10.1.2 Steady-State Solution 166
10.2 Catalytic Loss Cycles 171
10.2.1 Hydrogen Oxide Radicals (HOx) 171
10.2.2 Nitrogen Oxide Radicals (NOx)) 172
10.2.3 Chlorine Radicals (CIOx) 177
10.3 Polar Ozone Loss 179
10.3.1 Mechanism for Ozone Loss 181
10.3.2 PSC Formation 183
10.3.3 Chronology of the Ozone Hole 185
Problems 191
10.1 Shape of the Ozone Layer 191
10.2 The Chapman Mechanism and Steady State 191
10.3 The Detailed Chapman Mechanism 192
10.4 HOx-Catalyzed Ozone Loss 193
10.5 Chlorine Chemistry at Midlatitudes 193
10.6 Partitioning of Cly 195
10.7 Bromine-Catalyzed Ozone Loss 196
10.8 Limitation of Antarctic Ozone Depletion 197
10.9 Fixing the Ozone Hole 198
10.10 PSC Formation 199
11 - Oxidizing Power of the Troposphere 200
11.1 The Hydroxyl Radical 201
11.1.1 Tropospheric Production of OH 201
11.1.2 Global Mean OH Concentration 203
11.2 Global Budgets of CO and Methane 205
11.3 Cycling of HOx and Production of Ozone 207
11.3.1 The OH Titration Problem 207
11.3.2 CO Oxidation Mechanism 207
11.3.3 Methane Oxidation Mechanism 210
11.4 Global Budget of Nitrogen Oxides 212
11.5 Global Budget of Tropospheric Ozone 215
11.6 Anthropogenic Influence on Ozone and OH 216
Further Reading 219
Problems 219
11.1 Sources of CO 219
11.2 Sources of Tropospheric Ozone 220
11.3 Oxidizing Power of the Atmosphere 221
11.4 OH Concentrations in the Past 223
11.5 Acetone in the Upper Troposphere 223
11.6 Transport, Rainout, and Chemistry in the Marine
Upper Troposphere 225
11.7 Bromine Chemistry in the Troposphere 227
11.8 Nighttime Oxidation of NOx 228
11.9 Peroxyacetylnitrate (PAN) as a Reservoir for NOx 229
12 - Ozone Air Pollution 231
12.1 Air Pollution and Ozone 231
12.2 Ozone Formation and Control Strategies 233
12.3 Ozone Production Efficiency 240
Further Reading 242
Problems 242
12.1 NOx- and Hydrocarbon-Limited Regimes for Ozone Production 242
12.2 Ozone Titration in a Fresh Plume 243
13 - Acid Rain 245
13.1 Chemical Composition of Precipitation 245
13.1.1 Natural Precipitation 245
13.1.2 Precipitation over North America 246
13.2 Sources of Acids: Sulfur Chemistry 249
13.3 Effects of Acid Rain 250
13.4 Emission Trends 252
Problems 253
13.1 What Goes Up Must Come Down 253
13.2 The True Acidity of Rain 253
13.3 Aqueous-Phase Oxidation of SO2 by Ozone 253
13.4 The Acid Fog Problem 254
13.5 Acid Rain: The Preindustrial Atmosphere
Numerical Solutions to Problems 257
Appendix. Physical Data and Units 259
Index 261