ALBERT

Note: Contents Volume 5 RADAR MST and ST Radars and Wind Profilers / R.F. Woodman Precipitation Radar / S.E. Yuter Synthetic Aperture Radar (Land Surface Applications) / R.K. Vincent RADIATION (SOLAR) / Q. Fu RADIATIVE TRANSFER Absorption and Thermal Emission / R. Goody, H. Hu Cloud-Radiative Processes / Q. Fu Non-Local Thermodynamic Equilibrium / F.W. Taylor, M. Lopez-Puertas Scattering / M. Mishchenko, L. Travis, A. Lacis RADIOACTIVITY Cosmogenic Radionuclides / D. Lal RADIOSONDES / W.F. Dabberdt, R. Shellhorn, H. Cole, A. Paukkunen, J. Horhammer, V. Antikainen RAINBOWS (See OPTICS, ATMOSPHERIC: Optical Phenomena) REFLECTANCE AND ALBEDO, SURFACE / J.A. Coakley ROSSBY WAVES / P.B. Rhines SATELLITE REMOTE SENSING Aerosol Measurements / Y.J. Kaufman, D. Tanre Cloud Properties / P. Yang, B.A. Baum GPS Meteorology / S.B. Healy Precipitation / Guosheng Liu Surface Wind / W.T. Liu Temperature Soundings / A. Dudhia TOMS Ozone / R.S. Stolarski, R.D. McPeters Water Vapor / J.E. Harries Wind, Middle Atmosphere / P.B. Hays, W.R. Skinner SATELLITES Orbits / S.Q. Kidder Research (Atmospheric Science) / M.D. King, D.D. Herring SEA ICE / W.F. Weeks SEVERE STORMS / C.A. Doswell III SNOW (SURFACE) / M. Sturm SOLAR TERRESTRIAL INTERACTIONS / J.D. Haigh SOLAR WINDS / S.T. Suess, B.T. Tsurutani SOLITARY WAVES / J.P. Boyd SOOT / P. Chylek, S.G. Jennings, R. Pinnick SPECTRAL MODELS / F. Baer STANDARD ATMOSPHERE / W.W. Vaughan STATIC STABILITY / J.A. Young STATIONARY WAVES (OROGRAPHIC AND THERMALLY FORCED) / S. Nigam, E. De Weaver STRATOSPHERE-TROPOSPHERE EXCHANGE Global Aspects / J.R. Holton Local Processes / J.F. Lamarque, P. Hess STRATOSPHERIC CHEMISTRY AND COMPOSITION Overview / J.A. Pyle Halogen Sources, Anthropogenic / A. McCulloch, P.M. Midgley Halogen Sources, Natural / J.H. Butler Halogens / D. Toohey HOx / T.F. Hanisco Hydrogen Budget / J.E. Harries Hydroxyl Radical / D.E. Heard Reactive Nitrogen (NOx and NOy) / Y. Kondo STRATOSPHERIC OZONE RECOVERY / D.J. Hofmann STRATOSPHERIC WATER VAPOR / J.E. Harries SURFACE LAYER MEASUREMENTS OF TURBULENCE / N.O. Jensen SYNOPTIC METEOROLOGY Forecasting / D. Mansfield Weather Maps / R. Reynolds

Note: Contents: Preface. - Acknowledgements. - Publisher's Credits. - Part I Basic Concepts. - Chapter 1 Composition, Structure, and State. - 1.1 Composition of the Atmosphere. - 1.2 Composition of the Ocean. - 1.3 Pressure. - 1.4 Density. - 1.5 Temperature. - 1.6 Kinetic-Molecular Model of the Ideal Gas. - 1.7 Equation of State for Air. - 1.8 Equation of State for Seawater. - 1.9 Compressibility and Expansion Coefficients. - 1.10 Hydrostatic Equilibrium. - Notes. - Problems. - Chapter 2 First and Second Laws of Thermodynamics. - 2.1 Work. - 2.2 Heat. - 2.3 First Law. - 2.4 Applications of the First Law to Ideal Gases. - 2.5 Entropy. - 2.6 Second Law. - 2.7 Equilibrium and the Combined First and Second Laws. - 2.8 Calculation of Thermodynamic Relations. - 2.9 Heat Capacity. - 2.10 Dry Adiabatic Processes in the Atmosphere. - 2.11 Adiabatic Processes in the Ocean. - Notes. - Problems. - Chapter 3 Transfer Processes. - 3.1 Time-dependent Thermodynamics. - 3.2 Radiant Energy. - 3.3 Radiative Transfer. - 3.4 Diffusive Transfer Processes. - 3.5 Turbulence and Turbulent Transport. - 3.6 Time-dependent Equations for the Ocean and Atmosphere. - Notes. - Problems. - Chapter 4 Thermodynamics of Water. - 4.1 Molecular Structure and Properties of Water. - 4.2 Thermodynamic Degrees of Freedom. - 4.3 Phase Equilibria. - 4.4 Atmospheric Humidity Variables. - 4.5 Colligative Properties of Water Solutions. - 4.6 Simple Eutectics. - Notes. - Problems. - Chapter 5 Nucleation and Diffusional Growth. - 5.1 Surface Tension. - 5.2 Nucleation of the Liquid Phase. - 5.3 Nucleation of the Ice Phase. - 5.4 Diffusional Growth of Cloud Drops. - 5.5 Ice Crystal Morphology and Growth. - 5.6 Formation of the Initial Sea Ice Cover. - 5.7 Formation of Sea Ice Transition and Columnar Zones. - Notes. - Problems. - Part II Applications. - Chapter 6 Moist Thermodynamic Processes in the Atmosphere. - 6.1 Combined First and Second Laws. - 6.2 Isobaric Cooling. - 6.3 Cooling and Moistening by Evaporation of Water. - 6.4 Saturation by Adiabatic, Isobaric Mixing. - 6.5 Saturated Adiabatic Cooling. - 6.6 The Ice Phase. - 6.7 Conserved Moist Thermodynamic Variables. - 6.8 Aerological Diagrams. - Notes. - Problems. - Chapter 7 Static Stability of the Atmosphere and Ocean. - 7.1 Stability Criteria. - 7.2 Stability of a Saturated Atmosphere. - 7.3 Processes Producing Changes in Stability. - Notes. - Problems. - Chapter 8 Cloud Characteristics and Processes. - 8.1 Cloud Classification and Characteristics. - 8.2 Precipitation Processes. - 8.3 Radiative Transfer in a Cloudy Atmosphere. - 8.4 Fogs, Stratus Clouds, and Stratocumulus Clouds. - 8.5 Cumuliform Clouds. - 8.6 Parameterization of Cloud Microphysical Processes. - Notes. - Problems. - Chapter 9 Ocean Surface Exchanges of Heat and Freshwater. -

Note: Contents Volume 4 NOCTILUCENT CLOUDS / G.E. Thomas NORTH ATLANTIC AND ARCTIC OSCILLATION (See CLIMATE VARIABILITY: North Atlantic and Arctic Oscillation) NUMERICAL MODELS Chemistry Models / M.P. Chipperfield Methods / J. Thuburn OBSERVATION PLATFORMS Balloons / J.-P. Pommereau Buoys / J.M. Hemsley Kites / B.B. Balsley Rockets / M.F. Larsen OBSERVATIONS FOR CHEMISTRY (IN SITU) Chemiluminescent Techniques / C.A. Cantrell Gas Chromatography / A.C. Lewis Ozone Sondes / H.G.J. Smit Particles / T. Deshler Resonance Fluorescence / L.M. Avallone Water Vapor Sondes / E. Weinstock, E. Hintsa OBSERVATIONS FOR CHEMISTRY (REMOTE SENSING) IR/FIR / H. Fischer, F. Hase Lidar / G- Vaughan Microwave / J. Waters OCEAN CIRCULATION General Processes / N.C. Wells Surface-Wind-Driven Circulation / P. Bogden, C.A. Edwards Thermohaline Circulation / J.R. Toggweiler, R.M..Key Water Types and Water Masses / W.J. Emery OPERATIONAL METEOROLOGY / J.V. Cortinas Jr, W. Blier OPTICS, ATMOSPHERIC Airglow Instrumentation / M. Conde Optical Phenomena / S.D. Gedzelman Optical Remote Sensing Instruments / G.G. Shepherd OROGRAPHIC EFFECTS Lee Cyclogenesis / C. Schär Mountain Waves and Stratospheric Chemistry / K.S. Carslaw OZONE (See also SATELLITE REMOTE SENSING: TOMS Ozone) OZONE Ozone as a UV Filter / J.E. Frederick Ozone Depletion / J.A. Pyle Ozone Depletion Potentials / D.J. Wuebbles Photochemistry of Ozone / A.R. Ravishankara Role in Climate / P. Forster Surface Ozone (Human Health) / M. Lippmann Surface Ozone Effects on Vegetation / M.R. Ashmore PALEOCLIMATOLOGY Ice Cores / E.J. Steig Varves / A. Weinheimer, F. Biondi PALMER DROUGHT INDEX / L.C. Nkemdirim PARAMETERIZATION OF PHYSICAL PROCESSES Clouds / C. Jakob, M. Miller Gravity Wave Fluxes / M.J. Alexander Turbulence and Mixing / A. Beljaars PERMAFROST / T.E. Osterkamp, C.R. Burn PLANETARY ATMOSPHERES (See also EVOLUTION OF ATMOSPHERIC OXYGEN; EVOLUTION OF EARTH'S ATMOSPHERE) PLANETARY ATMOSPHERES Jupiter and the Outer Planets / A.P. Showman Mars / R.M. Haberle Venus / P.J. Gierasch, Y.L. Yung POLAR LOWS / I.A. Renfrew POLAR THERMOSPHERE / A.G. Burns, T.L. Killeen PREDICTABILITY AND CHAOS / L.A. Smith QUASI-GEOSTROPHIC THEORY / H.C. Davies, H. Wernli RADAR Cloud Radar / T. Uttal Doppler Radar / R.J. Doviak, M.E. Frazier Doviak Incoherent Scatter Radar / M.P. Sulzer Meteor Radar / N.J. Mitchell

Note: Contents: Preface. - 1. Introduction. - 1.1. Relations among Thermodynamics, Kinetics, and Cloud Microphysics. - 1.2. The Correspondence Principle. - 1.3. Structure of the Book. - 2. Clouds and Their Properties. - 2.1. Cloud Classification. - 2.2. Cloud Regimes and Global Cloud Distribution. - 2.2.1. Large-Scale Condensation in Fronts and Cyclones. - 2.2.2. Sc-St Clouds and Types of Cloud-Topped Boundary Layer. - 2.2.3. Convective Cloudiness in the Intertropical Convergence Zone. - 2.2.4. Orographic Cloudiness. - 2.3. Cloud Microphysical Properties. - 2.4. Size Spectra and Moments. - 2.4.1. Inverse Power Laws. - 2.4.2. Lognormal Distributions. - 2.4.3. Algebraic Distributions. - 2.4.4. Gamma Distributions. - 2.5. Cloud Optical Properties. - Appendix A.2. Evaluation of the Integrals with Lognormal Distribution. - 3. Thermodynamic Relations. - 3.1. Thermodynamic Potentials. - 3.2. Statistical Energy Distributions. - 3.2.1. The Gibbs Distribution. - 3.2.2. The Maxwell Distribution. - 3.2.3. The Boltzmann Distribution. - 3.2.4. Bose–Einstein Statistics. - 3.2.5. Fermi–Dirac Statistics. - 3.3. Phase Rules. - 3.3.1. Bulk Phases. - 3.3.2. Systems with Curved Interfaces. - 3.4. Free Energy and Equations of State. - 3.4.1. An Ideal Gas. - 3.4.2. Free Energy and the van der Waals Equation of State for a Non-Ideal Gas. - 3.5. Thermodynamics of Solutions. - 3.6. General Phase Equilibrium Equation for Solutions. - 3.6.1. General Equilibrium Equation. - 3.6.2. The Gibbs–Duhem Relation. - 3.7. The Clausius–Clapeyron Equation. - 3.7.1. Equilibrium between Liquid and Ice Bulk Phases. - 3.7.2. Equilibrium of a Pure Water Drop with Saturated Vapor. - 3.7.3. Equilibrium of an Ice Crystal with Saturated Vapor. - 3.7.4. Humidity Variables. - 3.8. Phase Equilibrium for a Curved Interface - The Kelvin Equation. - 3.9. Solution Effects and the Köhler Equation. - 3.10. Thermodynamic Properties of Gas Mixtures and Solutions. - 3.10.1. Partial Gas Pressures in a Mixture of Gases. - 3.10.2. Equilibrium of Two Bulk Phases around a Phase Transition Point. - 3.10.3. Raoult’s Law for Solutions. - 3.10.4. Freezing Point Depression and Boiling Point Elevation. - 3.10.5. Relation of Water Activity and Freezing Point Depression. - 3.11. A diabatic Processes. - 3.11.1. Dry Adiabatic Processes. - 3.11.2. Wet Adiabatic Processes. - Appendix A.3. Calculation of Integrals with the Maxwell Distribution. - 4. Properties of Water and Aqueous Solutions. - 4.1. Properties of Water at Low Temperatures and High Pressures. - 4.1.1. Forms of Water at Low Temperatures. - 4.1.2. Forms of Water at High Pressures. - 4.2. Theories of Water. - 4.3. Temperature Ranges in Clouds and Equivalence of Pressure and Solution Effects. - 4.4. Parameterizations of Water and Ice Thermodynamic Properties. - 4.4.1. Saturated Vapor Pressures. - 4.4.2. Heat Capacity of Water and Ice. - 4.4.3. Latent Heats of Phase Transitions. - 4.4.4. Surface Tension between Water and Air or Vapor. - 4.4.5. Surface Tension between Ice and Water or Solutions. - 4.4.6. Surface Tension between Ice and Air or Vapor. - 4.4.7 Density of Water. - 4.4.8. Density of Ice. - 4.5. Heat Capacity and Einstein-Debye Thermodynamic Equations of State for Ice. - 4.6. Equations of State for Ice in Terms of Gibbs Free Energy. - 4.7. Generalized Equations of State for Fluid Water. - 4.7.1. Equations of the van der Waals Type and in Terms of Helmholtz Free Energy. - 4.7.2. Equations of State Based on the Concept of the Second Critical Point. - Appendix A.4. Relations among Various Pressure Units. - 5. Diffusion and Coagulation Growth of Drops and Crystals. - 5.1. Diffusional Growth of Individual Drops. - 5.1.1. Diffusional Growth Regime. - 5.1.2. The Kinetic Regime and Kinetic Corrections to the Growth Rate. - 5.1.3. Psychrometric Correction Due to Latent Heat Release. - 5.1.4. Radius Growth Rate. - 5.1.5. Ventilation Corrections. - 5.2. Diffusional Growth of Crystals. - 5.2.1. Mass Growth Rates. - 5.2.2. Axial Growth Rates. - 5.2.3. Ventilation Corrections. - 5.3. Equations for Water and Ice Supersaturations. - 5.3.1. General Form of Equations for Fractional Water Supersaturation. - 5.3.2. Supersaturation Relaxation Times and Their Limits. - 5.3.3. E quation for Water Supersaturation in Terms of Relaxation Times. - 5.3.4. Equivalence of Various Forms of Supersaturation Equations. - 5.3.5. Equation for Fractional Ice Supersaturation. - 5.3.6. Equilibrium Supersaturations over Water and Ice. - Liquid Clouds. - Ice Clouds. - Mixed Phase Clouds. - 5.3.7. A diabatic Lapse Rates with Non zero Supersaturations. - 5.4. The Wegener–Bergeron–Findeisen Process and Cloud Crystallization. - 5.5. Kinetic Equations of Condensation and Deposition in the Adiabatic Process. - 5.5.1. Derivation of the Kinetic Equations. - 5.5.2. Some Properties of Regular Condensation. - 5.5.3. Analytical Solution of the Kinetic Equations of Regular Condensation. - 5.5.4. Equation for the Integral Supersaturation. - 5.6. Kinetic Equations of Coagulation. - 5.6.1. Various Forms of the Coagulation Equation. - 5.6.2. Collection Kernels for Various Coagulation Processes. - Brownian Coagulation. - Gravitational Coagulation. - 5.7. Thermodynamic and Kinetic Equations for Multidimensional Models. - 5.8. Fast Algorithms for Microphysics Modules in Multidimensional Models. - 6. Wet Aerosol Processes. - 6.1. Introduction. - 6.1.1. Empirical Parameterizations of Hygroscopic Growth. - 6.1.2. Empirical Parameterizations of Droplet Activation. - 6.2. Equilibrium Radii. - 6.2.1. Equilibrium Radii at Subsaturation. - 6.2.2. Equilibrium Radii of Interstitial Aerosol in a Cloud. - 6.3. Critical Radius and Supersaturation. - 6.4. Aerosol Size Spectra. - 6.4.1. Lognormal and Inverse Power Law Size Spectra. - 6.4.2. Approximation of the Lognormal Size Spectra by the Inverse Power Law. - 6.4.3. Examples of the Lognormal Size Spectra, Inverse Power Law, and Power Indices. - 6.4.4. Algebraic Approximation of the Lognormal Distribution. - 6.5. Transformation of the Size Spectra of Wet Aerosol at Varying Humidity. - 6.5.1. Arbitrary Initial Spectrum of Dry Aerosol. - 6.5.2. Lognormal Initial Spectrum of Dry Aerosol. - 6.5.3. Inverse Power Law Spectrum. - 6.5.4. Algebraic Size Spectra. - 6.6. CCN Differential Supersaturation Activity Spectrum. - 6.6.1. A rbitrary Dry Aerosol Size Spectrum. - 6.6.2. Lognormal Activity Spectrum. - 6.6.3. Algebraic Activity Spectrum. - 6.7. Droplet Concentration and the Modified Power Law for Drops Activation. - 6.7.1. Lognormal and Algebraic CCN Spectra. - 6.7.2. Modified Power Law for the Drop Concentration. - 6.7.3. Supersaturation Dependence of Power Law Parameters. - Appendix A.6. Solutions of Cubic Equations for Equilibrium and Critical Radii. - 7. Activation of Cloud Condensation Nuclei into Cloud Drops. - 7.1. Introduction. - 7.2. Integral Supersaturation in Liquid Clouds with Drop Activation. - 7.3. Analytical Solutions to the Supersaturation Equation. - 7.4. Analytical Solutions for the Activation Time, Maximum Supersaturation, and Drop Concentration. - 7.5. Calculations of CCN Activation Kinetics. - 7.6. Four Analytical Limits of Solution. - 7.7. Limit #1: Small Vertical Velocity, Diffusional Growth Regime. - 7.7.1. Lower Bound. - 7.7.2. Upper Bound. - 7.7.3. Comparison with Twomey’s Power Law. - 7.8. Limit #2: Small Vertical Velocity, Kinetic Growth Regime. - 7.8.1. Lower Bound. - 7.8.2. Upper Bound. - 7.9. Limit #3: Large Vertical Velocity, Diffusional Growth Regime. - 7.9.1. Lower Bound. - 7.9.2. Upper Bound. - 7.10. Limit #4: Large Vertical Velocity, Kinetic Growth Regime. - 7.10.1. Lower Bound. - 7.10.2. Upper Bound. - 7.11. Interpolation Equations and Comparison with Exact Solutions. - Appendix A.7. Evaluation of the Integrals J2 and J3 for Four Limiting Cases. - 8. Homogeneous Nucleation. - 8.1. Metastable States and Nucleation of a New Phase. - 8.2. Nucleation Rates for Condensation and Deposition. - 8.2.1. Application of Boltzmann Statistics. - 8.2.2. The Fokker–Planck