ALBERT

Note: Contents List of Contributors Preface Acknowledgements 1. Determining Timescales for Groundwater Flow and Solute Transport / Peter G. Cook and John-Karl Bohlke 2. Inorganic Ions as Tracers / Andrew L. Herczeg and W. Mike Edmunds 3. Isotope Engineering - Using Stable Isotopes of the Water Molecule to Solve Practical Problems / Tyler B. Coplen, Andrew L. Herczeg and Chris Barnes 4. Radiocarbon Dating of Groundwater Systems / Robert M. Kalin 5. U-Series Nuclides as Tracers in Groundwater Hydrology / J. Kenneth Osmond and James B. Cowart 6. Radon-222 / L. DeWayne Cecil and Jaromy R. Green 7. Sulphur and Oxygen Isotopes in Sulphate / H. Roy Krouse and Bernhard Mayer 8. Strontium Isotopes / Robert H. McNutt 9. Nitrate Isotopes in Groundwater Systems / Carol Kendall and Ramon Aravena 10. Chlorine-36 / Fred M. Phillips 11. Atmospheric Noble Gases / Martin Stute and Peter Schlosser 12. Noble Gas Radioisotopes: 37Ar, 85 Kr, 39Ar, 81 Kr / Heinz H. Loosli, Bernhard E. Lehmann and William M. Smethie, Jr. 13. 3H and 3He / D. Kip Solomon and Peter G. Cook 14. 4He in Groundwater / D. Kip Solomon 15. Chlorofluorocarbons / L. Niel Plummer and Eurybiades Busenberg 16. δ11 B, Rare Earth Elements, δ 37Cl, 32 Si, 35S, 129I / Avner Vengosh, Arthur J. Spivack, Kevin J. Johannesson, W. Berry Lyons, Tamie R. Weaver, Uwe Morgenstern, Robert L. Michel, June Fabryka-Martin Appendix 1: Stable Isotope Notation and Fractionation Appendix 2: Decay Constants and Half-Lives of Radioactive Isotopes Appendix 3: Solubilities of Environmental Gas Tracers Appendix 4: Liquid and Gas-Phase Diffusion Coefficients Index

Note: Contents: List of contributors. - 1. Lakes, limnology and limnetic ecology: towards a new synthesis. - 2. The origin of lake basins. - 3. The hydrology of lakes. - 4. Chemical processes regulating the composition of lake waters. - 5. Physical properties of water relevant to limnology and limnetic ecology. - 6. The motion of lake waters. - 7. Regulatory impacts of humic substances in lakes. - 8. Sedimentation and lake sediment formation. - 9. Organisation and energetic partitioning of limnetic communities. - 10. Phytoplankton. - 11 Aquatic plants and lake ecosystems. - 12. Benthic invertebrates. - 13. Pelagic microbes - protozoa and the microbial food web. - 14. Zooplankton. - 15. Fish population ecology. - 16. Fish community ecology. - 17. Self-regulation of limnetic ecosystems. - 18. Palaeolimnology. - Index.

Note: Contents: Preface. - 1 Introduction to the atmosphere. - Weather and climate. - Atmospheric hazards: assault by the elements. - The atmosphere: a part of the earth system. - Earth's four spheres. - Earth's spheres interact. - The carbon cycle. - Composition of the atmosphere. - Major components. - Carbon dioxide. - Variable components. - Ozone depletion - a global issue. - The ozone hole. - Effects of ozone depletion. - Montreal Protocol. - Probing the atmosphere. - Height and structure of the atmosphere. - Pressure changes. - Temperature changes. - Vertical variations in composition. - The ionosphere. - 2 Heating Earth's Surface and Atmosphere. - Earth-Sun Relationships. - Earth's Motions. - The Seasons. - Earth's Orientation. - Solstices and Equinoxes. - Energy, Heat, and Temperature. - Types of Energy. - Heat Energy Versus Temperature. - Mechanisms of Energy Transfer. - Conduction. - Convection. - Radiation. - Laws of Radiation. - The Fate of Incoming Solar Radiation. - Reflection and Scattering. - Absorption by Earth's Surface and Atmosphere. - Radiation Emitted by Earth. - Heating the Atmosphere. - The "Greenhouse Effect". - Role of Clouds in Heating Earth. - Heat Budget. - Latitudinal Heat Balance. - 3 Temperature. - For the Record: Air Temperature Data. - Why Temperatures Vary: The Controls of Temperature. - Land and Water. - Ocean Currents. - Altitude. - Geographic Position. - Cloud Cover and Albedo. - World Distribution of Temperatures. - Cycles of Air Temperature. - Daily Temperature Variations. - Magnitude of Daily Temperature Changes. - Annual Temperature Variations. - Temperature Measurement. - Mechanical Thermometers. - Electrical Thermometers. - Instrument Shelters. - Temperature Scales. - Applications of Temperature Data. - Heating Degree-Days. - Cooling Degree-Days. - Growing Degree-Days. - Temperature and Comfort. - 4 Moisture and Atmospheric Stability. - Movement of Water Through the Atmosphere. - Water's Changes of State. - Water in the Atmosphere. - Vapor Pressure and Saturation. - Relative Humidity. - How Relative Humidity Changes. - Natural Change in Relative Humidity. - Dew Point Temperature. - Humidity Measurement. - Adiabatic Temperature Changes. - Adiabatic Cooling and Condensation. - Lifting Processes. - Orographic Lifting. - Frontal Wedging. - Convergence. - Localized Convective Lifting. - Contents. - The Critical Weathermaker: Atmospheric Stability. - Types of Stability. - Stability and Daily Weather. - How Stability Changes. - Temperature Changes and Stability. - Vertical Air Movement and Stability. - 5 Forms of Condensation and Precipitation. - Condensation. - Condensation Aloft and Cloud Formation. - Clouds. - Cloud Classification. - Cloud Descriptions. - Fog. - Fogs Formed by Cooling. - Fogs Formed by Evaporation. - Dew and Frost. - How Precipitation Forms. - Precipitation from Cold Clouds: The Bergeron Process. - Precipitation from Warm Clouds: The Collision-Coalescence Process. - Forms of Precipitation. - Rain. - Snow. - Sleet and Glaze. - Hail. - Rime. - Precipitation Measurement. - Standard Instruments. - Measuring Snowfall. - Measurement Errors. - Precipitation Measurement by Weather Radar. - Intentional Weather Modification. - Cloud Seeding. - Fog and Cloud Dispersal. - Hail Suppression. - Frost Prevention. - Inadvertent Weather Modification: Urban-Induced Precipitation. - 6 Air Pressure and Winds. - Understanding Air Pressure. - Measuring Air Pressure. - Factors Affecting Air Pressure. - Pressure Changes With Altitude. - Factors Affecting Wind. - Pressure-Gradient Force. - Coriolis Force. - Friction. - Winds Aloft and Geostrophic Flow. - Curved Flow and the Gradient Wind. - Surface Winds. - How Winds Generate Vettical Air Motion. - Vertical Airflow Associated with Cyclones and Anticyclones. - Factors That Promote Vertical Airflow. - Wind Measurement. - 7 Circulation of the Atmosphere. - Scales of Atmospheric Motion. - Large- and Small-Scale Circulation. - Structure of Wind Patterns. - Local Winds. - Land and Sea Breezes. - Mountain and Valley Breezes. - Chinook (Foehn) Winds. - Katabatic (Fall) Winds. - Country Breeze. - Global Circulation. - Single-Cell Circulation Model. - Three-Cell Circulation Model. - Observed Distribution of Pressure and Winds. - Idealized Zonal Pressure Belts. - Semipermanent Pressure Systems: The Real World. - Monsoons. - The Asian Monsoon. - The North American Monsoon. - The Westerlies. - Why Westerlies?. - Jet Streams. - Origin of the Midlatitude Jet Stream. - Subtropical Jet Stream. - Waves in the Westerlies. - Westerlies and Earth's Heat Budget. - Global Winds and Ocean Currents. - The Importance of Ocean Currents. - Ocean Currents and Upwelling. - El Niño and La Niña. - Global Distribution of Precipitation. - Zonal Distribution of Precipitation. - Distribution of Precipitation Over the Continents. - Precipitation Regimes on a Hypothetical Continent. - 8 Air Masses. - What Is an Air Mass?. - Source Regions. - Classifying Air Masses. - Air-Mass Modification. - Properties of North American Air Masses. - Continental Polar (cP) and Continental Arctic (cA) Air Masses. - Lake-Effect Snow: Cold Air Over Warm Water. - Maritime Polar (mP) Air Masses. - Maritime Tropical (mT) Air Masses. - Continental Tropical (eT) Air Masses. - 9 Weather Patterns. - Polar-Front Theory. - Fronts. - Warm Fronts. - Cold Fronts. - Stationary Fronts. - Occluded Fronts. - Drylines. - Life Cycle of a Midlatitude Cyclone. - Formation: The Clash of Two Air Masses. - Development of Cyclonic Flow. - Occlusion: The Beginning of the End. - Idealized Weather of a Midlatitude Cyclone. - Cyclogenesis. - Cyclonic and Anticyclonic Circulation. - Divergence and Convergence Aloft. - Traveling Cyclones. - Patterns of Movement. - Anticyclonic Weather and Blocking Highs. - Case Study of a Midlatitude Cyclone. - Violent Spring Weather. - Weather in Peoria. - 10 Thunderstorms and Tornadoes. - What's in a Name?. - Thunderstorms. - Air-Mass Thunderstorms. - Stages of Development. - Occurrence. - Severe Thunderstorms. - Supercell Thunderstorms. - Squall Lines and Mesoscale Convective Complexes. - Lightning and Thunder. - What Causes Lightning?. - The Lightning Stroke. - Thunder. - Tornadoes. - The Development and Occurrence of Tornadoes. - Tornado Development. - Tornado Climatology. - Profile of a Tornado. - Tornado Destruction. - Tornado Forecasting. - Tornado Watches and Warnings. - Doppler Radar. - 11 Hurricanes. - Profile of a Hurricane. - Hurricane Formation and Decay. - Hurricane Formation. - Hurricane Decay. - Hurricane Destruction . - Storm Surge. - Wind Damage. - Inland Flooding. - Detecting and Tracking Hurricanes. - The Role of Satellites. - Aircraft Reconnaissance. - Radar and Data Buoys. - Hurricane Watches and Warnings. - 12 Weather Analysis and Forecasting. - The Weather Business: A Brief Overview. - Weather Analysis. - Gathering Data. - Weather Maps: Pictures of the Atmosphere. - Weather Forecasting. - Synoptic Weather Forecasting. - Numerical Weather Prediction. - Statistical Methods. - Techniques Used in Short-Range Forecasting. - Long-Range Forecasts. - Forecast Accuracy. - Tools in Weather Forecasting. - Satellites in Weather Forecasting. - What Weather Satellites Reveal. - Measurement by Satellite. - Weather Forecasting and Upper-Level Flow. - The Winter of 1977. - 13 Air Pollution. - A Brief Historical Perspective. - Air Pollution: Not a new Problem. - Some Historic Episodes. - Sources and Types of Air Pollution. - Primary Pollutants. - Secondary Pollutants. - Trends in Air Quality. - Meteorological Factors Affecting Air Pollution. - Wind as a Factor. - The Role of Atmospheric Stability. - Acid Precipitation. - Extent and Potency of Acid Precip

Note: Contents: Foreword. - Series Preface. - Preface to the Second Edition. - Preface to the First Edition. - Part 1 Introduction. - 1 Modeling Dynamic Systems. - 1.1 Model Components. - 1.2 Dynamic Modeling as a Skill and Art. - 1.3 Modeling in STELLA. - 1.4 Principles of Modeling. - Part 2 Some General Methods for Modeling. - 2 Four-Model Set. - 2.1 Stimulus-Response Model. - 2.2 Self-Referencing Model. - 2.3 Goal-Seeking Model. - 2.4 Goal-Setting Model. - 2.5 Examples. - 2.5.1 Exponential Decay of a Stock. - 2.5.2 Newtonian Cooling. - 3 Gradual Development of a Dynamic Model. - 3.1 Modeling Industrialization for a Simple Agrarian Society. - 3.2 Impacts of Per Capita Food Consumption on Population Growth. - 3.3 Adding Agriculture. - 3.4 Adding Industry. - 4 Two Independent Variables. - 4.1 Population Cohorts. - 4.1.1 Basic Cohort Model. - 4.1.2 Population Cohort Array. - 4.1.3 U.S. Population Growth. - 4.2 River Toxins. - 5 Randomness. - 5.1 Flipping a Coin. - 5.2 Intoxication Model. - 6 Positive and Negative Feedback. - 6.1 The Basic Model. - 6.2 Positive Feedback with Fixed Points. - 6.3 Elaborations. - 7 Derivatives and Lags. - 7.1 Introduction. - 7.2 Applications of Derivatives and Lags. - 7.2.1 Simple Population Model. - 7.2.2 Two-Population Model. - Part 3 Chemistry Models. - 8 The Law of Mass Action. - 8.1 Breakdown of Nitrogen Dioxide into Nitrogen Oxide and Oxygen. - 8.2 Stratospheric Ozone Depletion. - 9 Chance-Cleland Model for Enzyme-Substrate Interaction. - 10 The Olsen Oscillator. - Part 4 Genetics Models. - 11 Mating of Alleles. - 11.1 Heterozygosity and Disease Resistance. - 11.2 The Mating of Two Alleles into a Genotype: Proving the Hardy-Weinberg Law. - 12 Natural Selection and Mutation. - 13 Artificial Worms. - Part 5 Ecological Models. - 14 Robin Population. - 15 Two-Stage Insect Model. - 16 The Zebra Mussel. - 17 Single Cell Forest. - 18 Predator-Prey Models. - 18.1 Basic Model of Predator-Prey Interactions. - 18.2 Spatial Predator-Prey Model. - 19 Epidemic Modeling. - 20 Reestablishment of Wolves. - 21 Lyme Disease. - 22 Tragedy of the Commons. - Part 6 Economic Models. - 23 Introduction to Modeling Economic Processes. - 24 The Competitive Firm. - 25 The Monopolistic Firm. - 25.1 Basic Model. - 25.2 Taxing Monopolies. - 26 Competitive Equilibrium. - 27 Substitution. - 27.1 Isoquants. - 27.2 Finding the Profit-Maximizing Output Level and Input Combinations. - 28 Time Value. - 29 Opportunity Cost. - 30 Optimal Tree Cutting. - 31 Fisheries Reserve Model. - 32 Dynamic Scarcity. - 32.1 Competitive Scarcity. - 32.2 Monopoly Scarcity. - 33 Market Game. - 34 Pig Cycle. - Part 7 Engineering Models. - 35 The Assembly Line. - 35.1 Basic Model. - 35.2 Car Assembly Line. - 36 Models of Gravity and Acceleration. - 36.1 Falling Rock. - 36.2 Projectile Motion. - 36.3 Mass-Damper-Spring. - 36.4 Mechanical Amplifier. - 37 Chaos. - 37.1 A New Paradigm. - 37.2 Jenson Chaos. - 37.3 Lorenz Chaos. - 37.4 Two-Well Chaos. - Part 8 Conclusion. - 38 Beginning a Dialog. - Appendixes. - A1 System Requirements. - A1.1 Macintosh. - A1.2 Windows. - A2 Quick Help Guide. - A2.1 Overview of the STELLA(r) Operating Environment. - A2.2 Drawing an Inflow to a Stock. - A2.3 Drawing an Outflow from a Stock. - A2.4 Replacing a Cloud with a Stock. - A2.5 Bending Flow Pipes. - A2.6 Repositioning Flow Pipes. - A2.7 Reversing Direction of a Flow. - A2.8 Flow Define Dialog-Builtins. - A2.9 Moving Variable Names. - A2.10 Drawing Connectors. - A2.11 Defining Graphs and Tables. - A2.12 Dynamite Operations on Graphs and Tables. - References. - Index.

Note: Contents: ACKNOWLEDGEMENTS. - GENERAL PART. - Introduction. - Area covered. - Abbreviations, scale bars and arrows. - Material examined. - General structure of the podocopid Ostracoda. - Carapace. - Appendages. - Exo- and endoskeleton. - Respiration and blood circulation. - Digestive and nervous systems, eyes and excretory glands. - Reproduction. - Reproductive organs. - Structure of the sperm. - Reproductive modes. - The biological species concept and clonal taxonomy. - Development. - Ecology. - Terminology. - Life histories. - Food and prédation. - Dispersal abilities. - Fossil record. - The utility of the Ostracoda in (palaeo)ecology and evolution. - Ostracon, IRGO, CYPRIS, ISO, and EOM. - The Index and Bibliography of Nonmarine Ostracoda. - NODE - Nonmarine Ostracod Distribution in Europe. - Practical methods. - Previous faunistic synopses and checklists. Numbers of species recorded. - Classification of the Ostracoda. - Diagnosis of the Podocopida. - Evolutionary origin of non-marine Ostracoda. - Classification of the Podocopida. - SYSTEMATIC RECORD OF SPECIES. - Superfamily DARWINULOIDEA Brady &Norman, 1889. - Family Darwinulidae Brady & Norman, 1889. - Genus Darwinula Brady & Robertson, 1885. - 1. Darwinula stevensoni (Brady & Robertson,1870). - Genus Penthesilenula Rossetti & Martens, 1998. - 1. Penthesilenula brasiliensls (Pinto & Kotzian, 1961). - Superfamily CYPRIDOIDEA s. str. Baird, 1845. - Family Candonidae Kaufmann, 1900. - Subfamily Candoninae Kaufmann, 1900. - Genus Paracandona Hartwig, 1899. - 1. Paracandona euplectella (Robertson, 1889). - Genus Nannocandona Ekman, 1914. - 1. Nannocandona faba Ekman, 1914. - Genus Candona s. str. Baird, 1845. - 1. Candona Candida (O.F. Müller, 1776). - 2. Candona weltneri Hartwig, 1899. - 3. Candona sanociensis Sywula, 1971. - 4. Candona improvisa Ostermeyer, 1937. - 5. Candona neglecta Sars, 1887. - 6. Candona lindneri Petkovski, 1969. - 7. Candona meerfeldiana Scharf, 1983. - 8. Candona muelleri Hartwig, 1899. - 9. Candona angulata Müller, 1900. - Genus Fabaeformiscandona Krstic, 1972. - 1. Fabaeformiscandona fabaeformis (Fischer, 1851). - 2. Fabaeformiscandona holzkampfi (Hartwig, 1900). - 3. Fabaeformiscandona alexandri (Sywula, 1981). - 4. Fabaeformiscandona fragilis (Hartwig, 1898). - 5. Fabaeformiscandona angusta (Ostermeyer, 1937). - 6. Fabaeformiscandona tyrolensis (Löffler, 1963) nov. comb. - 7. Fabaeformiscandona brisiaca (Klie, 1938). - 8. Fabaeformiscandona fabella (Nüchterlein, 1969). - 9. Fabaeformiscandona balatonica (Daday, 1894). - 10. Fabaeformiscandona acuminata (Fischer, 1851). - 11. Fabaeformiscandona caudata (Kaufmann, 1900). - 12. Fabaeformiscandona siliquosa (Brady, 1910). - 13. Fabaeformiscandona tricicatricosa(Diebel & Pietrzeniuk, 1969). - 14. Fabaeformiscandona loz.eki (Absolon, 1973) nov. comb. - 15. Fabaeformiscandona levanderi (Hirschmann, 1912). - 16. Fabaeformiscandona hyalina (Brady & Robertson, 1870). - 17. Fabaeformiscandona protzi (Hartwig, 1898). - 18. Fabaeformiscandona brevicornis (Klie, 1925). - 19. Fabaeformiscandona wegelini (Petkovski, 1962). - 20. Fabaeformiscandona latens (Klie, 1940). - 21. Fabaeformiscandona breuili (Paris, 1920) nov. comb. - 22. Fabaeformiscandona bilohata (Klie, 1938). - 23. Fabaeformiscandona bilobatoides (Löffler, 1961). - Genus Schellencandona Meisch, 1996. - 1. Schellencandona schellenhergi (Klie, 1934). - 2. Schellencandona insueta (Klie, 1938). - 3. Schellencandona belgica (Klie, 1937). - 4. Schellencandona triquetra (Klie, 1936). - Genus Pseudocandona Kaufmann, 1900. - 1. Pseudocandona zschokkei (Wolf, 1920). - 2. Pseudocandona marchica (Hartwig, 1899). - 3. Pseudocandona rostrata (Brady & Norman, 1889). - 4. Pseudocandona sarsi (Hartwig, 1899). - 5. Pseudocandona hartwigi (G.W. Müller, 1900). - 6. Pseudocandona lobipes (Hartwig, 1900). - 7. Pseudocandona stagnalis (Sars, 1890). - 8. Pseudocandona semicognita (Schäfer, 1934). - 9. Pseudocandona eremita (Vejdovsky, 1882). - 10. Pseudocandona szoecsi (Farkas, 1958). - 11. Pseudocandona insculpta (G.W. Müller, 1900). - 12. Pseudocandona compressa (Koch, 1838). - 13. Pseudocandona sucki (Hartwig, 1901). - 14. Pseudocandona pratensis (Hartwig, 1901). - 15. Pseudocandona albicans (Brady, 1864). - Genus Cryptocandona Kaufmann, 1900. - 1. Cryptocandona vavrai Kaufmann, 1900. - 2. Cryptocandona kieferi (Klie, 1938). - 3. Cryptocandona reducta (Alm, 1914). - 4. Cryptocandona phreaticola (Klie, 1927). - 5. Cryptocandona leruthi (Klie, 1936). - 6. Cryptocandona dudichi (Klie, 1930). - Genus Mixtacandona Klie, 1938. - 1. Mixtacandona laisi (Klie, 1938). - 2. Mixtacandona transleithanica (Löffler, 1960). - 3. Mixtacandona spandli Rogulj & Danielopol, 1993. - Genus Candonopsis Vavra, 1891. - 1. Candonopsis kingsleii (Brady & Robertson, 1870). - 2. Candonopsis scourfieldi Brady, 1910. - Subfamily Cyclocypridinae Kaufmann, 1900. - Genus Cypria Zenker, 1854. - 1. Cypria exsculpta (Fischer, 1855). - 2. Cypria ophtalmica (Jurine, 1820). - 3. Cypria subsalsa Redeke, 1936. - 4. Cypria sywulae nom. nov. - 5. Cypria reptans Bronshtein, 1928. - Genus Physocypria Vavra, 1897. - 1. Physocypria kraepelini G.W. Müller, 1903. - Genus Cyclocypris Brady & Norman, 1889. - 1. Cyclocypris globosa (Sars, 1863). - 2. Cyclocypris serena (Koch, 1838). - 3. Cyclocypris laevis (O.F. Müller, 1776). - 4. Cyclocypris ovum (Jurine, 1820). - 5. Cyclocypris helocrenica Fuhrmann & Pietrzeniuk, 1990. - Family Ilyocyprididae Kaufmann, 1900. - Subfamily Ilyocypridinae Kaufmann, 1900. - Genus Ilyocypris Brady & Norman, 1889. - 1. Ilyocypris gibba (Ramdohr, 1808). - 2. Ilyocypris monstrifica (Norman, 1862). - 3. Ilyocypris decipiens Masi, 1905. - 4. Ilyocypris bradyi Sars, 1890. - 5. Ilyocypris inermis Kaufmann, 1900. - 6. Ilyocypris lacustris Kaufmann, 1900. - 7. Ilyocypris getica Masi, 1906. - Family Notodromadidae Kaufmann, 1900. - Subfamily Notodromadinae Kaufmann, 1900. - Genus Notodromas Lilljeborg, 1853. - 1. Notodromas monacha (O.F. Müller, 1776). - 2. Notodromas persica Gurney, 1921. - Subfamily Cyproidinae Hartmann, 1963. - Genus Cyprois Zenker, 1854. - 1. Cyprois marginata (Straus, 1821). - Family Cyprididae Baird, 1845. - Subfamily Cypridinae Baird, 1845. - Genus Cypris O.F. Müller, 1776. - 1. Cypris pubera O.F. Müller, 1776. - 2. Cypris bispinosa Lucas, 1849. - 3. Cypris striata (Jurine, 1820). - Subfamily Eucypridinae Bronshtein, 1947. - Genus Eucypris Vâvra, 1891. - 1. Eucypris virens (Jurine, 1820). - 2. Eucypris kerkyrensis Stephanides, 1937. - 3. Eucypris moravica Jancaffk, 1947. - 4. Eucypris lilljeborgi (G.W. Müller, 1900). - 5. Eucypris elliptica (Baird, 1846). - 6. Eucypris crassa (O.F. Müller, 1785). - 7. Eucypris anglica Fox, 1967. - 8. Eucypris pigra (Fischer, 1851). - Genus Koencypris n. gen. - 1. Koencypris ornata (O.F. Müller, 1776). - Genus Prionocypris Brady & Norman, 1896. - 1. Prionocypris zenkeri (Chyzer & Toth, 1858). - Genus Tonnacypris Diebel & Pietrzeniuk, 1975. - 1. Tonnacypris lutaria (Koch, 1838). - Genus Trajancypris Martens, 1989. - 1. Trajancypris serrata (G.W. Müller, 1900). - 2. Trajancypris clavata (Baird, 1838). - 3. Trajancypris laevis (G.W. Müller, 1900). - Subfamily Cypricercinae McKenzie, 1971. - Genus Bradleycypris McKenzie,1982. - 1. Bradleycypris obliqua (Brady, 1868). - Genus Bradleystrandesia Broodbakker, 1983. - 1. Bradleystrandesia fuscata (Jurine, 1820). - 2. Bradleystrandesia reticulata (Zaddach, 1844). - 3. Bradleystrandesia hirsuta (Fischer, 1851). - Subfamily Herpetocypridinae Kaufmann, 1900. - Genus Herpetocypris Brady & Norman, 1889. - 1. Herpetocypris reptans (Baird, 1835). - 2. Herpetocypris brevicaudata Kaufmann, 1900. - 3. Herpetocypris chevreuxi (Sars, 1896) 4. Herpetocypris helenae G.W. Müller, 1908. - 5. Herpetocypris interm

Note: Contents List of Acronyms List of Symbols Foreword Preface Prologue Chapter 1 Introduction to Ocean Dynamics 1.1 Types, Advantages, and Limitations of Ocean Models 1.2 Recent Examples 1.3 Governing Equations 1.4 Vorticity Conservation 1.5 Nondimensional Numbers and Scales of Motion 1.6 Geostrophic Flow and Thermal Wind 1.7 Inertial Motions 1.8 Ekman Layers 1.9 Sverdrup Transport 1.10 Western Boundary Intensification (Stommel Solution) 1.11 Gyre Scale Circulation (Munk Solution) 1.12 Barotropic Currents over Topography 1.13 Baroclinic Transport over Topography 1.14 Coastal Upwelling and Fronts 1.15 Mesoscale Eddies and Variability 1.16 Thermohaline Circulation and Box (Reservoir) Models 1.17 Numerical Models Chapter 2 Introduction to Numerical Solutions 2.1 Introduction 2.1.1 Architecture 2.1.2 Computational Errors 2.2 Ordinary Differential Equations 2.2.1 Runge-Kutta Method 2.3 Partial.Differential Equations 2.3.1 Consistency, Convergence, and Stability 2.3.2 Elliptic, Hyperbolic, and Parabolic Systems 2.4 Elliptic Equations and Steady-State Problems 2.4.1 Direct Solvers 2.4.2 Iterative Solvers and Relaxation Methods 2.4.3 Preconditioned Conjugate Gradient Method 2.4.4 Multigrid Methods 2.4.5 Pseudo-transient Method 2.5 Time Dependent Problems 2.5.1 Advection Equation and Hyperbolic Systems 2.5.2 Diffusion Equation and Parabolic Systems 2.6 Finite-Difference (Grid Point) Methods 2.6.1 Staggered Grids 2.6.2 Time Differencing and Filtering 2.6.3 Computational Grids 2.7 Spectral (Spectral Transform) Methods 2.8 Finite-Element Methods 2.8.1 Spectral Element Approach 2.9 Parameterization of Subgrid Scale Processes 2.10 Lateral Open Boundary Conditions 2.11 Computational Issues 2.12 Examples 2.12.1 Inertial Oscillations 2.12.2 Thermohaline Circulation 2.12.3 Normal Modes 2.12.4 Gyre Scale Circulation 2.12.5 Advection Problems 2.12.6 M.I.T. Nonhydrostatic Global Model Chapter 3 Equatorial Dynamics and Reduced Gravity Models Solutions 3.1 Oceanic Dynamical Response to Forcing 3.2 Governing Equations 3.3 Equatorial Waves 3.3.1 Kelvin Waves 3.3.2 Yanai Waves 3.3.3 Rossby Waves 3.3.4 Inertia-Gravity (Poincare) Waves 3.4 Equatorial Currents 3.5 Reduced Gravity Model of Equatorial Processes Chapter 4 Midlatitude Dynamics and Quasi-Geostrophic Models 4.1 Linear Motions 4.1.1 Inertia-Gravity (Sverdrup/Poincare) Waves 4.1.2 Kelvin Waves 298 4.1.3 Planetary Ross by Waves 4.1.4 Topographic Rossby Waves 4.2 Continuous Stratification 4.3 Geostrophic Adjustment and Instabilities 4.3.1 Geostrophic Adjustment 4.3.2 Instabilities 4.4 Spinup 4.5 Quasi-Geostrophic Models 4.5.1 Governing Equations 4.5.2 Applications Chapter 5 High-Latitude Dynamics and Sea-Ice Models 5.1 Salient Features of Ice Cover 5.2 Momentum Equations for Sea Ice 5.3 Constitutive Law for Sea Ice (Ice Rheology) 5.3.1 Viscous-Plastic Ice Rheology 5.3.2 Elastic-Viscous-Plastic Ice Rheology 5.4 Continuity Equations for Sea Ice 5.5 Response of Sea Ice to Storm Passage 5.6 Numerics 5.6.1 Governing Equations in Orthogonal Curvilinear Coordinates 5.6.2 Solution Technique Chapter 6 Tides and Tidal Modeling 6.1 Description of Tides 6.2 Formulation: Tidal Potential 6.3 Body, Load, Atmospheric, and Radiational Tides 6.3.1 Body (Solid Earth) Tides 6.3.2 Load Tides 6.3.3 Atmospheric Tides 6.3.4 Radiational Tides 6.4 Dynamical Theory of Tides: Laplace Tidal Equations 6.5 Equilibrium Theory of Tides 6.6 Tidal Analysis: Orthotides 6.7 Tidal Currents 6.8 Global Tidal Models 6.9 Regional Tidal Models 6.10 Geophysical Implications 6.10.1 Tidal Dissipation and LOD 6.10.2 Tidal Energetics 6.11 Changes in Earth's Rotation 6.12 Baroclinic (Internal) Tides 6.13 Long-Period Tides 6.14 Shallow Water Tides and Residual Currents 6.15 Summary Chapter 7 Coastal Dynamics and Barotropic Models 7.1 Wind- and Buoyancy-Driven Currents 7.2 Tidal Motions 7.3 Continental Shelf Waves 7.4 Modeling Shelf Circulation 7.5 Barotropic Models 7.5.1 Coastal Ocean Response to Wind Forcing 7.5.2 Storm Surges and Storm Surge Modeling 7.5.3 Response to Pressure Forcing Chapter 8 Data and Data Processing 8.1 In Situ Observational Data 8.1.1 XBT, CTD, CM, ADCP, and Drifter Data 8.1.2 Historical Hydrographic Data 8.1.3 Historical Marine Surface Data 8.2 Remotely Sensed Data 8.2.1 Sea Surface Temperature from IR Sensors 8.2.2 Sea Surface Winds from Microwave Sensors 8.2.3 Chlorophyll and Optical Clarity from Color Sensors 8.2.4 Sea Surface Height from Satellite Altimetry 8.3 NWP Products 8.4 Preprocessing of Observational Data and Postprocessing of Model Output 8.4.1 Graphics and Visualization of Model Output 8.4.2 Analyses Chapter 9 Sigma-Coordinate Regional and Coastal Models 9.1 Introduction 9.2 Governing Equations 9.3 Vertical Mixing 9.4 Boundary Conditions 9.5 Mode Splitting 9.6 Numerics 9.6.1 Vertical Direction 9.6.2 Horizontal Direction 9.7 Numerical Problems 9.8 Applications 9.9 Code Structure Chapter 10 Multilevel Basin Scale and Global Models 10.1 Introduction 10.2 Governing Equations 10.3 Isopycnal Diffusion 10.4 Architecture and Other Model Features 10.5 Applications 10.6 Hybrid s-Coordinate Models 10.7 Regional z-Level Models Chapter 11 Layered and Isopycnal Models 11.1 Layered Models 11.2 Isopycnal Models Chapter 12 Ice-Ocean Coupled Models 12.1 Sea-Ice Models 12.2 Coupled Ice-Ocean Models Chapter 13 Ocean-Atmosphere Coupled Models 13.1 Coupling between the Ocean and the Atmosphere 13.2 Coupled Ocean-Atmosphere General Circulation Models 13.3 Regional Coupled Ocean-Atmosphere Models Chapter 14 Data Assimilation and Nowcasts/ Forecasts 14.1 Introduction 14.2 Direct Insertion 14.3 Nudging 14.4 Statistical Assimilation Schemes 14.4.1 Kalman Filter 14.4.2 Reduced State Space Kalman Filters 14.4.3 Optimal Interpolation (OI) Scheme 14.5 Variational Methods 14.5.1 Adjoint Models 14.6 Predictability of Nonlinear Systems-Low Order Paradigms 14.7 Nowcasts/Forecasts in the Gulf of Mexico Appendix A Equations of State A.1 Equation of State for the Ocean A.2 Equation of State for the Atmosphere Appendix B Wavelet Transforms B.1 Introduction B.1.1 Theory B.1.2 Continuous Wavelet Transforms (CWT) B.1.3 Discrete Wavelet Transforms (DWT) B.2 Examples B.3 Wavelet Transforms and Stochastic Processes B.4 Two-Dimensional Wavelet Transforms B.5 Cross Wavelet Transforms (CrWT) B.6 Error Analysis Appendix C Empirical Orthogonal Functions and Empirical Normal Modes C.1 Empirical Orthogonal Functions C.1.1 Complex EOFs C.1.2 Singular Spectrum Analysis C.1.3 Extended EOFs C.1.4 Coupled Pattern Analysis C.2 Empirical Normal Modes Appendix D Units and Constants D.1 Useful Quantities D.1.1 SI (International System of Units) Units and Conventions D.1.2 Useful Conversion Factors D.1.3 Useful Universal Constants D.1.4 Useful Geodetic Constants D.1.5 Useful Physical Constants D.1.6 Useful Dynamical Quantities D.2 Important Scales and Quantities D.2.1 Length Scales D.2.2 Timescales D.2.3 Velocity Scales D.2.4 Nondimensional Quantities D.3 Useful Websites References Biographies Index

Note: CONTENTS: 1 Concepts and Foundations of Remote Sensing. - 1.1 Introduction. - 1.2 Energy Sources and Radiation Principles. - 1.3 Energy Interactions in the Atmosphere. - 1.4 EnergyJnteractions with Earth Surface Features. - 1.5 Data Acquisition and Interpretation. - 1.6 Reference Data. - 1.7 The Global Positioning System. - 1.8 An Ideal Remote Sensing System. - 1.9 Characteristics of Real Remote Sensing Systems. - 1.10 Successful Application of Remote Sensing. - 1.11 Land and Geographic Information Systems. - 1.12 Organization of the Book. - Selected Bibliography. - 2 Elements of Photographic Systems. - 2.1 Introduction. - 2.2 Early History of Aerial Photography. - 2.3 Basic Negative-to-Positive Photographic Sequence. - 2.4 Film Exposure 2.5 Film Density and Characteristic Curves. - 2.6 Spectral Sensitivity of Black and White Films. - 2.7 Color Film. - 2.8 Color Infrared Film. - 2.9 Filters. - 2.10 Aerial Film Cameras. - 2.11 Film Resolution. - 2.12 Electronic Imaging. - 2.13 Aerial Videography. - 2.14 Multiband Imaging. - 2.15 Conclusion. - Selected Bibliography. - 3 Basic Principles of Photogrammetry. - 3.1 Introduction. - 3.2 Basic Geometric Characteristics of Aerial Photographs. - 3.3 Photographic Scale. - 3.4 Ground Coverage of Aerial Photographs. - 3.5 Area Measurement. - 3.6 Relief Displacement of Vertical Features. - 3.7 Image Parallax. - 3.8 Ground Control for Aerial Photography. - 3.9 Mapping with Aerial Photographs. - 3.10 Flight Planning. - 3.11 Conclusion. - Selected Bibliography. - 4 Introduction to Visual Image Interpretation. - 4.1 Introduction. - 4.2 Fundamentals of Visual Image Interpretation. - 4.3 Basic Visual Image Interpretation Equipment. - 4.4 Land Use/Land Cover Mapping. - 4.5 Geologic and Soil Mapping. - 4.6 Agricultural Applications. - 4.7 Forestry Applications. - 4.8 Rangeland Applications. - 4.9 Water Resource Applications. - 4.10 Urban and Regional Planning Applications. - 4.11 Wetland Mapping. - 4.12 Wildlife Ecology Applications. - 4.13 Archaeological Applications. - 4.14 Environmental Assessment. - 4.15 Principles of Landform Identification and Evaluation. - Selected Bibliography. - 5 Multispectral, Thermal, and Hyperspectral Sensing. - 5.1 Introduction. - 5.2 Across-Track Scanning. - 5.3 Along-Track Scanning. - 5.4 Operating Principles of Across-Track Multispectral Scanners. - 5.5 Example Along-Track Multispectral Scanner and Data. - 5.6 Across-Track Thermal Scanning. - 5.7 Thermal Radiation Principles. - 5.8 Interpreting Thermal Scanner Imagery. - 5.9 Geometric Characteristics of Across-Track Scanner Imagery. - 5.10 Geometric Characteristics of Along-Track Scanner- Imagery. - 5.11 Radiometric Calibration of Thermal Scanners. - 5.12 Temperature Mapping with Thermal Scanner Data. - 5.13 FLIR Systems. - 5.14 Hyperspectral Sensing. - 5.15 Conclusion. - Selected Bibliography. - 6 Earth Resource Satellites Operating in the Optical Spectrum. - 6.1 Introduction. - 6.2 Early History of Space Imaging. - 6.3 Landsat Satellite Program Overview. - 6.4 Landsat-1,-2, and-3. - 6.5 Landsat-4 and -5. - 6.6 Landsat-6 Planned Mission. - 6.7 Landsat-7. - 6.8 Landsat Image Interpretation. - 6.9 New Millennium Program. - 6.10 SPOT Satellite Program. - 6.11 SPOT-1,-2, and-3. - 6.12 SPOT-4. - 6.13 SPOT-5. - 6.14 SPOT Image Interpretation. - 6.15 Other Moderate Resolution Land Satellites. - 6.16 High Resolution Land Satellites. - 6.17 Hyperspectral Satellite Systems. - 6.18 Meteorological Satellites. - 6.19 Ocean Monitoring Satellites. - 6.20 Earth Observing System. - 6.21 Space Station Remote Sensing. - Selected Bibliography. - 7 Digital Image Processing. - 7.1 Introduction. - 7.2 Image Rectification and Restoration. - 7.3 Image Enhancement. - 7.4 Contrast Manipulation. - 7.5 Spatial Feature Manipulation. - 7.6 Multi-Image Manipulation. - 7.7 Image Classification. - 7.8 Supervised Classification. - 7.9 The Classification Stage. - 7.10 The Training Stage. - 7.11 Unsupervised Classification. - 7.12 Hybrid Classification. - 7.13 Classification of Mixed Pixels. - 7.14 The Output Stage. - 7.15 Postclassification Smoothing. - 7.16 Classification Accuracy Assessment. - 7.17 Data Merging and GIS Integration. - 7.18 Hyperspectral Image Analysis. - 7.19 Biophysical Modeling. - 7.20 Scale Effects. - 7.21 Image Transmission and Compression. - 7.22 Conclusion. - Selected Bibliography. - 8 Microwave Sensing. - 8.1 Introduction. - 8.2 Radar Development. - 8.3 Side Looking Radar System Operation. - 8.4 Synthetic Aperture Radar. - 8.5 Geometric Characteristics of Side-Looking Radar Imagery. - 8.6 Transmission Characteristics of Radar Signals. - 8.7 Other Radar Image Characteristics. - 8.8 Radar Image Interpretation. - 8.9 Radar Remote Sensing from Space. - 8.10 Seasat-1. - 8.11 Shuttle Imaging Radar. - 8.12 Almaz-1. - 8.13 ERS-1, ERS-2, and Envisat-1. - 8.14 JERS-1 and ALOS. - 8.15 Radarsat. - 8.16 LightSAR. - 8.17 Spaceborne Radar System Summary. - 8.18 Interferometric Radar. - 8.19 Planetary Exploration. - 8.20 Passive Microwave Sensing. - 8.21 Lidar. - Selected Bibliography. - Appendix. - Remote Sensing Data Sources. - Remote Sensing Periodicals. - Index.

Note: Contents Foreword Preface Summary for Policymakers Synthesis Report Question 1 Question 2 Question 3 Question 4 Question 5 Question 6 Question 7 Question 8 Question 9 Working Group Summaries Working Group I: The Scientific Basis Working Group II: Impacts, Adaptation, and Vulnerability Working Group III: Mitigation Annexes A. Authors and Expert Reviewers B. Glossary of Terms C. Acronyms, Abbreviations, and Units D. Scientific, Technical, and Socio-Economic Questions Selected by the Panel E. List of Major IPCC Reports