ALBERT

Note: Contents: 1 Global Distribution of Lakes / M. MEYBECK. - 1 Introduction. - 2 Background Material and Approaches to Global Lake Census. - 2.1 Data Used. - 2.2 Approaches to Global Lake Census. - 3 General Laws of Lake Distribution. - 3.1 Lake Density . - 3.2 Limnic Ratio. - 4 Distribution of Lakes of Tectonic Origin. - 5 Lakes of Glacial Origin. - 5.1 Lake Densities. - 5.2 Global Deglaciated Area. - 5.3 Total Number of Glacial Lakes. - 6 Fluvial Lakes. - 7 Global Distribution of Crater Lakes. - 8 Global Distribution of Saline Lakes. - 8.1 Coastal Lagoons. - 8.2 Salinized Lakes due to Evaporation. - 9 Global Lake Distribution. - 9.1 Extrapolation Approach. - 9.2 Lake Type Approach. - 9.3 Climatic Typology Approach. - 9.4 Lake Distribution in Endorheic Areas. - 9.5 Global Dissolved Salt Distribution in Lakes. - 10 Major Changes in Global Lake Distribution in the Geological Past. - 10.1 Lake Ages. - 10.2 Historical Changes. - 10.3 Postglacial Changes. - 11 Discussion and Conclusions. - References. - 2 Hydrological Processes and the Water Budget of Lakes / T. C. WINTER. - 1 Introduction. - 2 Hydrological System with Regard to Lakes. - 2.1 Interaction of Lakes with Atmospheric Water. - 2.2 Interaction of Lakes with Surface Water. - 2.3 Interaction of Lakes with Subsurface Water. - 2.4 Change in Lake Volume. - 3 Summary. - References. - 3 Hydrological and Thermal Response of Lakes to Climate: Description and Modeling / S. W. HOSTETLER. - 1 Introduction. - 2 Hydrological Response. - 3 The Hydrological Budget. - 4 Hydrological Models. - 5 Thermal Response. - 5.1 Energy Budget and Energy Budget Models. - 5.2 Models and Modeling. - 6 Use of Models to Link Lakes with Climate Change. - 7 Input Data Sets. - 8 Sample Applications. - 9 Summary. - References. - 4 Mixing Mechanisms in Lakes / D. M. IMBODEN and A. WÜEST. - 1 Transport and Mixing. - 2 Lakes as Physical Systems. - 3 Fluid Dynamics: Mathematical Description of Advection and Diffusion. - 3.1 Equations of Fluid Motion. - 3.2 Turbulence, Reynolds' Stress, and Eddy Diffusion. - 3.3 Vertical Momentum Equation. - 3.4 Nonlocal Diffusion and Transilient Mixing. - 4 Density and Stability of Water Column. - 4.1 Equation of State of Water. - 4.2 Potential Temperature and Local Vertical Stability. - 5 Energy Fluxes: Driving Forces Behind Transport and Mixing. - 5.1 Thermal Energy. - 5.2 Potential Energy. - 5.3 Kinetic Energy. - 5.4 Turbulent Kinetic Energy Balance in Stratified Water. - 5.5 Internal Turbulent Energy Fluxes: Turbulence Cascade. - 6 Mixing Processes in Lakes. - 6.1 Waves and Mixing. - 6.2 Mixing in the Surface Layer. - 6.3 Diapycnal Mixing. - 6.4 Boundary Mixing. - 6.5 Double Diffusion. - 6.6 Isopycnal Mixing. - 7 Mixing and Its Ecological Relevance. - 7.1 Time Scales of Mixing. - 7.2 Reactive Species and Patchiness. - 7.3 Mixing and Growth: The Search for an Ecological Steering Factor. - References. - 5 Stable Isotopes of Fresh and Saline Lakes / J. R. GAT. - 1 Introduction. - 1.1 Isotope Separatio During Evaporation. - 2 Small-Area Lakes. - 2.1 Seasonal and Annual Changes. - 2.2 Deep Freshwater Lakes. - 2.3 Transient Surface-Water Bodies. - 3 Interactive and Feedback Systems. - 3.1 Network of Surface-Water Bodies. - 3.2 Recycling of Reevaporated Moisture into the Atmosphere. - 3.3 Large Lakes. - 3.4 Large-Area Lakes with Restricted Circulation. - 4 Saline Lakes. - 4.1 Isotope Hydrology of Large Salt Lakes. - 4.2 Ephemeral Salt Lakes and Sabkhas. - 5 Isotopie Paleolimnology. - 6 Conclusions: From Lakes to Oceans. - References. - 6 Exchange of Chemicals Between the Atmosphere and Lakes / P. VLAHOS, D. MACKAY, S. J. EISENREICH, and KC. HORNBUCKLE. - 1 Introduction. - 2 Air-Water Partitioning Equilibria. - 3 Diffusion Between Water and Air. - 4 Volatilization and Absorption: Double-Resistance Approach. - 5 Factors Affecting Mass-Transfer Coefficients. - 6 Partitioning of Chemical to Paniculate Matter in Air and Water. - 6.1 Air. - 6.2 Water. - 7 Atmospheric Deposition Processes. - 7.1 Dry Deposition. - 7.2 Wet Deposition. - 8 Specimen Calculation. - 8.1 Step 1: Physicochemical Properties. - 8.2 Step 2: Mass-Transfer Coefficients. - 8.3 Step 3: Sorption in Air and Water. - 8.4 Step 4: Equilibrium Status. - 8.5 Step 5: Volatilization and Deposition Rates. - 9 Role of Air-Water Exchange in Lake Mass Balances. - 10 Case Studies. - 10.1 Mass Balance on Siskiwit Lake, Isle Royale. - 10.2 Mass Balance on Lake Superior. - 10.3 Air-Water Exchange in Green Bay, Lake Michigan. - 10.4 Air-Water Exchange in Lake Superior. - 11 Conclusions. - References. - 7 Atmospheric Depositions: Impact of Acids on Lakes / W. STUMM and J. SCHNOOR. - Abstract. - 1 Introduction: Anthropogenic Generation of Acidity. - 1.1 Genesis of Acid Precipitation. - 2 Acidity and Alkalinity: Neutralizing Capacities. - 2.1 Transfer of Acidity (or Alkalinity) from Pollution Through the Atmosphere to Ecosystems. - 3 Acidification of Aquatic and Terrestrial Ecosystems. - 3.1 Disturbance of H+ Balance from Temporal or Spatial Decoupling of the Production and Mineralization of the Biomass. - 3.2 In Situ H+ Ion Neutralization in Lakes. - 3.3 Krug and Frink Revisited. - 4 Brønsted Acids and Lewis Acids: Pollution by Heavy Metals, as Influenced by Acidity. - 4.1 Cycling of Metals. - 4.2 Pb in Soils. - 5 Impact of Acidity on Ecology in Watersheds. - 5.1 Soils. - 5.2 Lakes. - 5.3 Nitrogen Saturation of Forests. - 6 Critical Loads. - 6.1 Critical Load Maps. - 6.2 Models for Critical Load Evaluation. - 7 Case Studies. - 7.1 Chemical Weathering of Crystalline Rocks in the Catchment Area of Acidic Ticino Lakes, Switzerland. - 7.2 Watershed Manipulation Project at Bear Brooks, Maine. - 8 Summary. - References. - 8 Redox-Driven Cycling of Trace Elements in Lakes / J. HAMILTON-TAYLOR and W. DAVISON. - 1 Introduction. - 2 Major Biogeochemical Cycles and Pathways. - 3 Iron and Manganese. - 3.1 Transformations and Cycling. - 3.2 Iron and Manganese Compounds as Carrier Phases. - 4 Sediment-Water Interface. - 4.1 Diffusive Flux from Sediments. - 4.2 Evidence of Little or No Diffusive Efflux from Sediments. - 4.3 Transient Remobilization. - 4.4 Diffusive Flux into Sediments. - 5 Pathways Involving Redox Reactions Directly: Case Studies. - 5.1 Arsenic. - 5.2 Chromium. - 5.3 239,240Pu. - 5.4 Selenium 6 Pathways Involving Redox Reactions Indirectly: Case Studies. - 6.1 137Cs. - 6.2 Stable Pb, 210Pb, and 210Po. - 6.3 Zinc. - 7 Summary and Conclusions. - References. - 9 Comparative Geochemistry of Marine Saline Lakes / F. T. MACKENZIE, S. VINK, R. WOLLAST, and L. CHOU. - 1 Introduction. - 2 General Characteristics of Marine Saline Lakes. - 3 Comparative Sediment-Pore-Water Reactions. - 3.1 Mangrove Lake, Bermuda. - 3.2 Solar Lake, Sinai. - 4 Conclusions. - References. - 10 Organic Matter Accumulation Records in Lake Sediments / P. A. MEYERS and R. ISHIWATARI. - 1 Introduction. - 1.1 Significance of Organic Matter in Lake Sediments. - 1.2 Origins of Organic Matter to Lake Sediments. - 1.3 Alterations of Organic Matter During Deposition. - 1.4 Similarities and Differences Between Organic Matter in Sediments of Lakes and Oceans. - 1.5 Dating of Lake-Sediment Records. - 2 Indicators of Sources and Alterations of Total Organic Matter in Lake Sediments. - 2.1 Source Information Preserved in C/N Ratios of Sedimentary Organic Matter. - 2.2 Source Information from Carbon-Stable Isotopic Compositions. - 2.3 Source Information from Nitrogen-Stable Isotopic Compositions. - 3 Origin and Alterations of Humic Substances. - 4 Sources and Alterations of Lipid Biomarkers. - 4.1 Alteration of Lipids During Deposition. - 4.2 Changes in Sources vs Selective Diagenesis. - 4.3 Effects of Sediment Grain Size on Geolipid Compositions. - 4.4 Source Records of Alkanes in Lake Sediments. - 4.5 Preserv

Note: Contents: Abstract. - Introduction. - Bunger Hills-Obruchev Hills area. - Metamorphic rocks. - Pyroxene-quartz-feldspar gneiss. - Mafic granulite. - Ultramafic rocks. - Garnet-quartz-feldspar gneiss. - Aluminous metasediments. - Quartzite. - Calc-silicate rocks and marble. - Igneous rocks. - Mafic to felsic plutonic rocks. - Felsic dykes and minor intrusions. - Mafic dykes. - Rapakivi granite and felsic volcanics. - Denman Glacier Area. - Metamorphic rocks. - Felsic orthogneiss. - Mafic rocks. - Ultramafic rocks. - Garnet-quartz-feldspar gneiss. - Metasediments. - Igneous rocks. - Mafic to felsic plutonic rocks. - Felsic dykes and minor intrusions. - Mafic dykes. - Mount Amundsen and Mount Sandow. - Sandow Group. - Sediments. - Metabasalt. - Structural Geology. - Bunger Hills area. - D1 deformation. - D2 deformation. - D3 deformation. - D4 deformation. - Denman Glacier area and Mounts Amundsen and Sandow. - Metamorphism. - Bunger Hills area. - Peak metamorphism. - Retrograde metamorphism. - Denman Glacier area. - Discussion. - Geological history of the Bunger Hills area. - Regional correlations. - Gondwana reconstruction and tectonic synthesis. - Gondwana correlations. - Acknowledgements. - References. - Appendix: Chemical analyses of rock samples rom the Bunger Hills and Denman Glacier areas. - Analytical methods. - Precision and accuracy.

Note: Contents: Figures. - Tables. - Preface. - Illustrations. - 1. Introduction. - 1.1 Background. - 1.2 Scope of the text. - 1.3 World vegetation types. - 1.3.1 Vegetation formations and zones. - 1.3.2 Zonobiomes. - 1.3.3 Exoclimates. - 1.3.4 The Canadian vegetation classification system. - 1.3.5 Ecozones. - 1.3.6 Floristic realms. - 1.3.7 Plant species nomenclature. - 1.4 Soil classification and soil systems. - 1.5 Climatic parameters. - 1.5.1 The role of climate. - 1.5.2 Moisture indices. - 1.5.3 Climate diagrams. - 1.6 Plant strategies. - 1.6.1 Competition. - 1.6.2 Hydrature and moisture regulation. - 1.6.3 Life forms. - 1.6.4 Leaf morphology and adaptation. - 1.7 Biomass and net primary productivity. - 2. Tundra 2.1 Tundra distribution. - 2.2 Climate. - 2.3 Soils. - 2.4 Tundra in North America. - 2.4.1 Ecoclimatic sub-provinces and regions. - 2.4.2 High and mid-Arctic. - 2.4.3 Low Arctic. - 2.5 Tundra in other Northern Hemisphere locations. - 2.5.1 Arctic Tundra. - 2.5.2 Typical Tundra. - 2.5.3 Southern Tundra. - 2.5.4 Tundra on Arctic Islands. - 2.6 Tundea in the Southern Hemisphere. - 2.6.1 The Antarctic Subregion. - 2.6.2 The Sub-Antarctic Subregion. - 2.7 Alpine Tundra. - 2.7.1 Temperate-latitude alpine Tundra. - 2.7.2 Low-latitude (equatorial) alpine Tundra. - 2.8 Primary production and phytomass in Tundra. - 3. Forest-Tundra or Boreal-Tundra Ecotone. - 3.1 Definitions. - 3.2 Distribution. - 3.3 Climate. - 3.4 Soils. - 3.5 Forest-Tundra in Canada. - 3.5.1 Ecoclimatic sub-provinces. - 3.5.2 The shrub subzone (Northern Forest-Tundra). - 3.5.3 The forest subzone (Southern Forest Tundra). - 3.6 Eurasian Forest-Tundra. - 3.7 Primary production and phytomass in forest-Tundra. - 4. Boreal Forest (Taiga) and Mixed Forest Transition. - 4.1 Distribution. - 4.2 Climate. - 4.3 Soils. - 4.4 Boreal forest in North America. - 4.4.1 Open Lichen Woodland. - 4.4.2 Northern Coniferous Forest. - 4.4.3 Mixed-Forest (Boreal-Broadleaf ecotone). - 4.4.4 Mixed-Forest transition to grassland (Northern Mixedwoods). - 4.5 Eurasian Boreal. - 4.5.1 The European Boreal. - 4.5.2 The Siberian Boreal. - 4.5.3 Northwest Pacific Fringe Boreal. - 4.6 Primary production and phytomass in boreal forest. - 5. Prairie (Steppe). - 5.1 Distribution. - 5.2 Climate. - 5.2.1 North America. - 5.2.2 Climate in Eurasia and elsewhere. - 5.3 Soils. - 5.4 Prairie in North America. - 5.4.1 The Canadian Prairie. - 5.4.2 Prairie in the USA. - 5.5. Eurasian Steppe. - 5.6 Southern Hemisphere Grasslands. - 5.6.1 The High Veldt. - 5.6.2 The Pampas/Campos Grasslands. - 5.7 Primary production and biomass. - 6. Cordilleran Environments in Western North America. - 6.1 Canada's Cordilleran ecoclimatic provinces. - 6.1.1 Distribution. - 6.1.2 Climate. - 6.1.3 Soils. - 6.1.4 Pacific Coastal Mesothermal Forest. - 6.1.5 Pacific Coastal Subalpine Forest. - 6.1.6 Cordilleran Forest Region. - 6.1.7 Cordilleran Cold Steppe and Savanna Forst. - 6.1.8 Canadian Cordilleran Subalpine Forest. - 6.1.9 Alpine Tundra and Boreal Forest. - 6.2 The Cordilleran Region in the USA. - 6.2.1 Distribution. - 6.2.2 Northwest Coast Conifer-Hardwood Forests. - 6.2.3 Montane Pine Forests. - 6.2.4 Sagebrush and Grasslands. - 6.2.5 Interior Hemlock-Douglas-Fir-Larch. - 6.2.6 Subalpine Forest. - 6.3 Primary Production and Phytomass. - 7. Temperate Deciduous Forests. - 7.1 Distribution. - 7.2 Climate. - 7.3 Soils. - 7.4 Temperate Deciduous Forest in North America. - 7.4.1 Canada. - 7.4.2 United States of America. - 7.4.3 Southern Mexico and South America. - 7.5 Europe. - 7.5.1 Atlantic Deciduous Forest. - 7.5.2 Central European Deciduous Forest. - 7.5.3 East European Deciduous Forest. - 7.6 Asia. - 7.7 Southern Hemisphere. - 7.8 Primary Production and Phytomass. - 8. Wetlands. - 8.1 Introduction. - 8.2 Climate. - 8.3 Soils. - 8.4 Canadian Wetland Classification. - 8.4.1 Canadian Wetland Classification System. - 8.4.2 Wetland classes. - 8.4.3 Wetland forms and types. - 8.5 Canadian Wetlands. - 8.5.1 Arctic Wetlands. - 8.5.2 Subarctic Wetlands. - 8.5.3 Boreal Wetlands. - 8.5.4 Prairie Wetlands. - 8.5.5 Temperate Wetlands. - 8.5.6 Oceanic Wetlands. - 8.5.7 Mountain Wetlands. - 8.6 Wetlands in the USA. - 8.7 Eurasian Wetlands. - 8.7.1 European Wetlands. - 8.7.2 Asian Wetlands. - 8.8 Central and South American Wetlands. - 8.9 African Wetlands. - 8.10 Austromalesian and Pacific Wetlands. - 8.11 Phytomass and Primary Production. - 9. Conclusion. - Appendix: Biomials and their local names as used in the text. - Bibliography. - Index.

Note: CONTENTS Preface List of Contributors Introduction 1. Predicting the Hydrological Effects of Climate Change / J.A.A. Jones Section I Sensitivity of the Global Hydrosphere Section Summary 2. An Introduction to Global Water Dynamics / I. Kayane 3. Modelling the Biospheric Aspects of the Hydrological Cycle: Upscaling Processes and Downscaling Weather Data / B. Bass, N. Akkur, J. Russo and J. Zack 4. Trends in Historical Steamflow Records / F.H.S. Chiew and T.A. McMahon Section II Regional Implications of Global Warming Section Summary 5. Hydrology of Northern North America under Global Warming / M.-K. Woo 6. Current Evidence on the Likely Impact of Global Warming on Hydrological Regimes in Europe / J.A.A. Jones 7. The Impact of Climatic Warming on Hydrological Regimes in China: An Overview / L. Changming and F. Guobin Section. Ill Precipitation Change and Variability Section Summary 8. The Influence of Topography, Season and Circulation on Spatial Patterns of Daily Precipitation / P.J. Robinson 9. Use of Artificial Neural Networks in Precipitation Forecasting / H.-T. Kung, L.Yu. Lin and S. Malasri 10. Generation of Sequences of Air Temperature and Precipitation for Estimation of the Hydrological Cycle in Changing Climatic Conditions in Poland / M. Gutry-Korycka and P. Werner 11. Some Aspects of Climatic Fluctuation at Four Stations on the Tibetan Plateau during the Last 40 Years / M. Yoshino 12. The Influences of the North Atlantic Oscillation, the El Niiio/Southern Oscillation and the Quasi-Biennial Oscillation on Winter Precipitation in Ireland / S. Daultrey Section IV Impacts on Snow, Ice and Meltwaters Section Summary 13. Runoff Formation and Discharge Modelling of a Glacierized Basin in the Tianshan Mountains / K. Ersi, S. Yafeng, A. Ohmura and H. Lang 14. Impact of Future Climate Change on Glacier Runoff and the Possibilities for Artificially Increasing Melt Water Runoff in the Aral Sea Basin / A.N. Krenke and G.N. Kravchenko 15. Glaciers and Snowcover in Central Asia as Indicators of Climate Change in the Earth-Ocean-Atmosphere System / V.B. Aizen and E.M. Aizen 16. Global Warming and the Trend toward Dryness in the Frigid High Mountains and Plateau of Western China / L.-S. Zhang Section V The Water Balance and Changing Regional Resources Section Summary 17. A Method to Assess the Effects of Climatic Warming on the Water Balance of Mountainous Regions / C. Liu and M.-K. Woo 18. Sensitivity Analyses for the Impact of Global Warming on Water Resources in Wales / C.P. Holt and J.A.A. Jones 19. Potential Hydrological Responses to Climate Change in Australia / F.H.S. Chiew, Q.J. Wang, T.A. McMahon, B.C. Bates and P.H. Whetton 20. Dynamics of Stage Fluctuation in Yangzhouyongcuo Lake, Tibetan Plateau / T. Liu 21. Derivation of Surface Temperature, Albedo, and Radiative Fluxes over the Tibetan Plateau Based on Satellite Measurement / L. Shi 22. Climatic Warming and its Impact on the Water Resources of the Yalong River, China / D. Yuren and H. Yuguang 23. The Probable Impact of Global Change on the Water Resources of Patagonia, Argentina / R.M. Quintela, O.E. Scarpati, L.B. Spescha and AD. Capriolo 24. Long Term Trends in the Water Balance of Central Japan / K. Mori Conclusions 25. The Impact of Global Warming on Regional Hydrology and Future Research Priorities / J.A.A. Jones Index

Note: Zugl.: Bremen, Univ., Diss., 1995

Note: CONTENTS: 1. Introduction. - 1.1 Scope of Aquatic Chemistry. - 1.2 The Solvent Water. - 1.3 Solute Species. - Suggested Readings. - Appendix 1.1: Some Useful Quantities, Units, Conversion Factors, Constants, and Relationships. - 2. Chemical Thermodynamics and Kinetics. - 2.1 Introduction. - 2.2 Chemical Thermodynamic Principles. - 2.3 Systems of Variable Composition: Chemical Thermodynamics. - 2.4 Gibbs Energy and Systems of Variable Chemical Composition. - 2.5 Chemical Potentials of Pure Phases and Solutions. - 2.6 Chemical Potentials of Aqueous Electrolytes. - 2.7 The Equilibrium Constant. - 2.8 The Gibbs Energy of a System. - 2.9 Driving Force for Chemical Reactions. - 2.10 Temperature and Pressure Effects on Equilibrium. - 2.11 Equilibrium Tools. - 2.12 Kinetics and Thermodynamics: Time and Reaction Advancement. - 2.13 Rate and Mechanism. - 2.14 Concentration Versus Time. - 2.15 Theory of Elementary Processes. - 2.16 Elementary Reactions and ACT. - 2.17 Equilibrium Versus Steady State in Flow Systems. - Suggested Readings. - Problems. - Answers to Problems. - 3. Acids and Bases. - 3.1 Introduction. - 3.2 The Nature of Acids and Bases. - 3.3 The Strength of an Acid or Base. - 3.4 Activity and pH Scales. - 3.5 Equilibrium Calculations. - 3.6 pH as a Master Variable; Equilibrium Calculations Using a Graphical Approach. - 3.7 Ionization Fractions of Acids, Bases, and Ampholytes. - 3.8 Titration of Acids and Bases. - 3.9 Buffer Intensity and Neutralizing Capacity. - 3.10 Organic Acids. - Suggested Readings. - Problems. - Answers to Problems. - 4. Dissolved Carbon Dioxide. - 4.1 Introduction. - 4.2 Dissolved Carbonate Equilibria (Closed System). - 4.3 Aqueous Carbonate System Open to the Atmosphere. - 4.4 Alkalinity and Acidity, Neutralizing Capacities. - 4.5 Alkalinity Changes. - 4.6 Analytical Considerations: Gran Plots. - 4.7 Equilibrium with Solid Carbonates. - 4.8 Kinetic Considerations. - 4.9 Carbon Isotopes and Isotope Fractionation. - Suggested Readings. - Problems. - Answers to Problems. - 5. Atmosphere-Water Interactions. - 5.1 Introduction. - 5.2 Anthropogenic Generation of Acidity in the Atmosphere. - 5.3 Gas-Water Partitioning: Henry's Law. - 5.4 Gas-Water Equilibria in Closed and Open Systems. - 5.5 Washout of Pollutants from the Atmosphere. - 5.6 Fog. - 5.7 Aerosols . - 5.8 Acid Rain - Acid Lakes. - 5.9 The Volatility of Organic Substances. - 5.10 Gas Transfer Across Water-Gas Interface. - Suggested Readings. - Problems. - Answers to Problems. - 6. Metal Ions in Aqueous Solution: Aspects of Coordination Chemistry. - 6.1 Introduction. - 6.2 Protons and Metal Ions. - 6.3 Hydrolysis of Metal Ions. - 6.4 Solubility and Hydrolysis: Solid Hydroxides and Metal Oxides. - 6.5 Chelates. - 6.6 Metal Ions and Ligands: Classification of Metals. - 6.7 Speciation in Fresh Waters. - 6.8 Seawater Speciation. - 6.9 Kinetics of Complex Formation. - Suggested Readings. - Problems. - Answers to Problems. - Appendix 6.1: Stability Constants. - Appendix 6.2: The Various Scales for Equilibrium Constants, Activity Coefficients, and pH. - 7. Precipitation and Dissolution. - 7.1 Introduction. - 7.2 The Solubility of Oxides and Hydroxides. - 7.3 Complex Formation and Solubility of (Hydr)oxides. - 7.4 Carbonates. - 7.5 The Stability of Hydroxides, Carbonates, and Hydroxide Carbonates. - 7.6 Sulfides and Phosphates. - 7.7 The Phase Rule: Components, Phases, and Degrees of Freedom. - 7.8 Solubility of Fine Particles. - 7.9 Solid Solutions. - Suggested Readings. - Problems. - Answers to Problems. - 8. Oxidation and Reduction; Equilibria and Microbial Mediation. - 8.1 Introduction. - 8.2 Redox Equilibria and the Electron Activity. - 8.3 The Electrode Potential: The Nernst Equation and the Electrochemical Cell. - 8.4 p[Epsilon]-pH, Potential-pH Diagrams. - 8.5 Redox Conditions in Natural Waters. - 8.6 Effect of Complex Formers on the Redox Potential. - 8.7 Measuring the Redox Potential in Natural Waters. - 8.8 The Potentiometric Determination of Individual Solutes. - Suggested Readings. - Problems. - Answers to Problems. - Appendix 8.1: Activity Ratio Diagrams for Redox Systems. - 9. The Solid-Solution Interface. - 9.1 Introduction. - 9.2 Adsorption. - 9.3 Adsorption Isotherms. - 9.4 Hydrous Oxide Surfaces; Reactions with H+, OH-, Metal Ions, and Ligands. - 9.5 Surface Charge and the Electric Double Layer. - 9.6 Correcting Surface Complex Formation Constants for Surface Charge. - 9.7 Sorption of Hydrophobic Substances on Organic Carbon-Bearing Particles. - 9.8 Ion Exchange. - 9.9 Transport of (Ad)sorbable Constituents in Groundwater and Soil Systems. - Suggested Readings. - Problems. - Appendix 9.1: The Gouy-Chapman Theory. - Appendix 9.2: Contact Angle, Adhesion and Cohesion, the Oil-Water Interface. - 10. Trace Metals: Cycling, Regulation, and Biological Role. - 10.1 Introduction: Global Cycling of Metals. - 10.2 Analytical Approaches to Chemical Speciation. - 10.3 Classification of Metal Ions and the Inorganic Chemistry of Life. - 10.4 Organometallic and Organometalloidal Compounds. - 10.5 Bioavailability and Toxicity. - 10.6 Metal Ions as Micronutrients. - 10.7 The Interaction of Trace Metals with Phytoplankton at the Molecular Level. - 10.8 Regulation of Trace Elements by the Solid-Water Interface in Surface Waters. - 10.9 Regulation of Dissolved Heavy Metals in Rivers, Lakes, and Oceans. - 10.10 Quality Criteria in Fresh Waters: Some Aspects. - Suggested Readings. - 11. Kinetics of Redox Processes. - 11 1 Introduction. - 11.2 How Good an Oxidant Is O2?. - 11.3 Can p[Epsilon] Be Defined for a Nonequilibrium System?. - 11.4 Kinetics of Redox Processes: Case Studies. - 11.5 Oxidants Used in Water and Waste Technology: A Few Case Studies. - 11.6 Linear Free Energy Relations (LFERs). - 11.7 The Marcus Theory of Outer-Sphere Electron Transfer: An Introduction. - 11.8 Nucleophile-Electrophile Interactions and Redox Reactions Involving Organic Substances. - 11.9 Corrosion of Metals as an Electrochemical Process. - Suggested Readings. - 12. Photochemical Processes. - 12.1 Introduction. - 12.2 Absorption of Light. - 12.3 Photoreactants. - 12.4 Photoredox Reactions: Photolysis of Transition Metal Complexes. - 12.5 Photochemical Reactions in Atmospheric Waters: Role of Dissolved Iron Species. - 12.6 Heterogeneous Photochemistry. - 12.7 Semiconducting Minerals. - Suggested Readings. - 13. Kinetics at the Solid-Water Interface: Adsorption, Dissolution of Minerals, Nucleation, and Crystal Growth. - 13.1 Introduction. - 13.2 Kinetics of Adsorption. - 13.3 Surface-Controlled Dissolution of Oxide Minerals: An Introduction to Weathering. - 13.4 Simple Rate Laws in Dissolution. - 13.5 Rates of CaCO3 Dissolution (and of CaCO3 Crystal Growth). - 13.6 Inhibition of Dissolution. - 13.7 Nucleation and Crystal Growth. - Suggested Readings. - 14. Particle-Particle Interaction: Colloids, Coagulation, and Filtration. - 14.1 Colloids. - 14.2 Particle Size Distribution. - 14.3 Surface Charge of Colloids. - 14.4 Colloid Stability: Qualitative Considerations. - 14.5 Effects of Surface Speciation on Colloid Stability. - 14.6 Some Water-Technological Considerations in Coagulation, Filtration, and Flotation. - 14.7 Filtration Compared with Coagulation. - 14.8 Transport in Aggregation and Deposition. - Suggested Readings. - Appendix 14.1: A Physical Model (DLVO) for Colloid Stability. - 15. Regulation of the Chemical Composition of Natural Waters. - 15.1 Introduction. - 15.2 Weathering and the Proton Balance. - 15.3 Isothermal Evaporation. - 15.4 Buffering. - 15.5 Interactions Between Organisms and Abiotic Environment: Redfield Stoichiometry. - 15.6 The Oceans: Relative Constancy of the Composition and Chemical Equilibria. - 15.7 Constancy of Composition: Steady State. - 15.8 Hydrothermal Vents. - 15.9 The Sediment-Water Interface. - 15.10 Biological Regulation of the Composition. - 15.11 Global Cycling: The Interdependence of Biogeochemical Cycles. - 15.12 The Carbon Cycle. - 15.13 Nitrogen Cycles:

Note: Contents Editor's note Acknowledgements page xu Notes on translations and definitions Abstract Preface Introduction 1 Geocryology as part of planetary cryology 2 Frozen rocks as natural-historical geological formations 3 History of research of the zone of permafrost and the frozen materials composing this zone 4 Structure, problems and scientific themes of geocryology 5 Methodological basis of geocryology I Thermal-physical, physico-chemical and mechanical processes in freezing, frozen and thawing ground and their manifestation in the permafrost regions 1 Thermal-physical processes in freezing and thawing ground 1.1 Heat transfer and temperature field in ground 1.2 Freezing (crystallization) of water and melting of ice in the ground 1.3 Sublimation and desublimation of moisture in frozen rocks 1.4 Freezing and thawing of ground 1.5 Methods for solving soil freezing (thawing) problems and approximate formulae for freezing and thawing depth calculations 2 Water transfer and ice formation in soils 2.1 Nature and mechanism of moisture migration in soils 2.2 Water transfer and ice formation in frozen soil 2.3 Water transfer and ice formation in freezing and thawing soils 3 Physico-chemical and mechanical processes in freezing and thawing ground 3.1 Chemical reactions and processes in freezing and thawing soils 3.2 Physico-chemical and mechanical processes in freezing and thawing soils 3.3 Physical-mechanical processes in frozen soils caused by changes in temperature 3.4 Physical and chemical processes in frozen soils caused by an external load 4 Structure and texture of freezing and thawing soils 4.1 Thermal-physical and physical-mechanical conditions of development of migrational-segregated ice interlayers 4.2 Basic types of cryogenic structure 4.3 Formation of structure in freezing and thawing soils 4.4 Structural associations and types of contact in frozen soils 5 Cryogenic geological processes and phenomena 5.1 Classification of processes and phenomena 5.2 Frost heaving of soils 5.3 Frost cracking (fissuring) and polygonal formations, surface and underground 5.4 Thermokarst 5.5 Slope processes and phenomena 5.6 Processes and effects associated with the activity of water, glaciers and other geological agents II Composition, cryogenic structure and properties of frozen rocks 6 Formation of sedimentary materials in the permafrost regions (cryolithogenesis) 6.1 Sediment genesis in the permafrost regions 6.2 Transformation of loose deposits of the permafrost regions into rock 6.3 Formation of useful mineral deposits at different stages of cryogenesis 7 Composition and structure of frozen earth materials 7.1 Characteristics of organic, mineral and chemical composition of frozen earth materials 7.2 Unfrozen water and ice in ground 7.3 Textural characteristics of the frozen material 7.4 Microstructure of frozen soils 8 Properties of frozen soils 8.1 Physical properties of the frozen materials 8.2 Thermal-physical properties of rocks 8.3 Moisture exchange properties of soils 8.4 Mechanical properties of frozen ground 9 Characteristics of the basic genetic types of frozen ground 9.1 Features of the cryogenic types of frozen strata 9.2 Composition and cryogenic structure of the principal geologic-genetic types of sedimentary materials in the permafrost regions 9.3 Natural ice as a monomineral rock III Principles of the formation and development of the frozen strata and layers of seasonal freezing and thawing 10 Thermodynamic and climatic conditions for formation of the frozen layers 10.1 Energy balance of the Earth 10.2 Thermodynamic conditions for development of seasonally and perennially frozen ground 10.3 Frozen ground as a result of zonation of thermal- and mass-exchange processes on the Earth's surface and in the atmosphere 11 Seasonal freezing and thawing of ground 11.1 Formation of the layer of seasonal freezing and thawing of soil 11.2 Types of seasonal freezing and thawing of the ground 11.3 The influence oflandscape-climatic factors on the temperature regime and depth of seasonal freezing and thawing of the ground 12 Development of the temperature regime and the thickness of the permafrost 12.1 Present-day knowledge of the development of permafrost 12.2 The effect of boundary conditions on the permafrost thickness and temperature regime 12.3 Dependence of the permafrost thickness and temperature regime on geological factors and processes 13 Taliks and groundwater in the permafrost zone 13.1 The types and formation of taliks in the permafrost zone 13.2 Groundwater of the permafrost regions 13.3 Interaction of groundwater with the permafrost and types of cryohydrogeological structures IV Regional features and evolution of permafrost 14 Permafrost evolution in the Earth's history 14.1 History of the development of permafrost and its distribution on the planet 14.2 Reasons for the development and evolution of permafrost in the Earth's history 14.3 The history of geocryological development and the main stages of permafrost formation on the territory of the former USSR in the Late Cenozoic 15 Zonal and regional features of present-day geocryological conditions in the territories of the former USSR 15.1 Distribution of permafrost and spatial variations of its mean annual temperature 15.2 Structure of the permafrost and spatial variability of its thickness 15.3 Distribution of main types of seasonal ground thawing and freezing 16 Principles and methods for regional geocryological investigations 16.1 Geocryological survey as the basis for regional investigation of the seasonally and perennially freezing zones 16.2 The methods and carrying-out of geocryological surveys 16.3 Classification and regionalization in the course of geocryological survey 16.4 Regionalization in geocryological mapping V Rational use of frozen ground and environmental protection in the course of economic development of the permafrost regions 17 The effect of different types of development on the natural geocryological environment 17.1 The basic principles of rational use of frozen ground in the course of the economic development of the permafrost regions 17.2 Regional environmental change in the course of development of extensive areas within the permafrost zone 17.3 Economic development of the permafrost regions with various kinds of construction 17.4 Development in the permafrost regions for the mining industry and underground engineering 17.5 Types of agrobiological development in the permafrost regions 18 Ensuring the stability of engineering structures in the permafrost regions 18.1 Principles of construction on permafrost (bases and foundations) 18.2 Methods of amelioration of frozen ground for foundations 18.3 Principles of foundation design and selection of type of foundation for construction on permafrost 18.4 Normative documents for engineering design and construction in the permafrost regions 19 Engineering geology in support of design, construction and operation of structures in the permafrost regions 19.1 Engineering-geological survey in the permafrost regions 19.2 Forecasting change in the geocryological conditions in the course of development 19.3 Principles and methods of the control of cryogenic processes 19.4 The basis of the rational use and protection of the geological environment in the permafrost regions References Index

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: Preface. - Acknowledgments. - Chapter 1 Data Acquisition and Recording. - 1.1 Introduction. - 1.2 Basic sampling requirements. - 1.2.1 Sampling interval. - 1.2.2 Sampling duration. - 1.2.3 Sampling accuracy. - 1.2.4 Burst sampling versus continuous sampling. - 1.2.5 Regularly versus irregularly sampled data. - 1.2.6 Independent realizations. - 1.3 Temperature. - 1.3.1 Mercury thermometers. - 1.3.2 The mechanical bathythermograph (MBT). - 1.3.3 Resistance thermometers (expendable bathythermograph: XBT). - 1.3.4 Salinity/conductivity-temperature-depth profilers. - 1.3.5 Dynamic response of temperature sensors 19 1.3.6 Response times of CTD systems. - 1.3.7 Temperature calibration of STD/CTD profilers. - 1.3.8 Sea surface temperature. - 1.3.9 The modern digital thermometer. - 1.3.10 Potential temperature and density. - 1.4 Salinity. - 1.4.1 Salinity and electrical conductivity. - 1.4.2 The practical salinity scale. - 1.4.3 Nonconductive methods. - 1.5 Depth or pressure. - 1.5.1 Hydrostatic pressure. - 1.5.2 Free-fall velocity. - 1.5.3 Echo sounding. - 1.5.4 Other depth sounding methods. - 1.6 Sea-level measurement. - 1.6.1 Tide and pressure gauges. - 1.6.2 Satellite altimetry. - 1.6.3 Inverted echo sounder (IES). - 1.6.4 Wave height and direction. - 1.7 Eulerian currents. - 1.7.1 Early current meter technology. - 1.7.2 Rotor-type current meters. - 1.7.3 Nonmechanical current meters. - 1.7.4 Profiling acoustic Doppler current meters (ADCM). - 1.7.5 Comparisons of current meters. - 1.7.6 Electromagnetic methods. - 1.7.7 Other methods of current measurement. - 1.7.8 Mooring logistics. - 1.7.9 Acoustic releases. - 1.8 Lagrangian current measurements. - 1.8.1 Drift cards and bottles. - 1.8.2 Modern drifters. - 1.8.3 Processing satellite-tracked drifter data. - 1.8.4 Drifter response. - 1.8.5 Other types of surface drifters. - 1.8.6 Subsurface floats. - 1.8.7 Surface displacements in satellite imagery. - 1.9 Wind. - 1.10 Precipitation. - 1.11 Chemical tracers. - 1.11.1 Conventional tracers. - 1.11.2 Light attenuation and scattering. - 1.11.3 Oxygen isotope: δ18O. - 1.11.4 Helium-3; helium/heat ratio. - 1.12 Transient chemical tracers. - 1.12.1 Tritium. - 1.12.2 Radiocarbon. - 1.12.3 Chlorofluorocarbons. - 1.12.4 Radon-222. - 1.12.5 Sulfur hexachloride. - 1.12.6 Strontium-90. - Chapter 2 Data Processing and Presentation. - 2.1 Introduction. - 2.2 Calibration. - 2.3 Interpolation. - 2.4 Data presentation. - 2.4.1 Introduction. - 2.4.2 Vertical profiles. - 2.4.3 Vertical sections. - 2.4.4 Horizontal maps. - 2.4.5 Map projections. - 2.4.6 Characteristic or property versus property diagrams. - 2.4.7 Time-series presentation. - 2.4.8 Histograms. - 2.4.9 New directions in graphical presentation. - Chapter 3 Statistical Methods and Error Handling. - 3.1 Introduction. - 3.2 Sample distributions. - 3.3 Probability. - 3.3.1 Cumulative probability functions. - 3.4 Moments and expected values. - 3.4.1 Unbiased estimators and moments. - 3.4.2 Moment generating functions. - 3.5 Common probability density functions. - 3.6 Central limit theorem. - 3.7 Estimation. - 3.8 Confidence intervals. - 3.8.1 Confidence interval for μ (σ known) 3.8.2 Confidence interval for μ (σ unknown) 3.8.3 Confidence interval for σ^2. - 3.8.4 Goodness-of-fit test. - 3.9 Selecting the sample size. - 3.10 Confidence intervals for altimeter bias estimates. - 3.11 Estimation methods. - 3.11.1 Minimum variance unbiased estimation. - 3.11.2 Method of moments. - 3.11.3 Maximum likelihood. - 3.12 Linear estimation (regression). - 3.12.1 Method of least squares. - 3.12.2 Standard error of the estimate. - 3.12.3 Multivariate regression. - 3.12.4 A computational example of matrix regression. - 3.12.5 Polynomial curve fitting with least squares. - 3.12.6 Relationship between least-squares and maximum likelihood. - 3.13 Relationship between regression and correlation. - 3.13.1 The effects of random errors on correlation. - 3.13.2 The maximum likelihood correlation estimator. - 3.13.3 Correlation and regression: cause and effect. - 3.14 Hypothesis testing. - 3.14.1 Significance levels and confidence intervals for correlation. - 3.14.2 Analysis of variance and the F-distribution. - 3.15 Effective degrees of freedom. - 3.1 5.1 Trend estimates and the integral time scale. - 3.16 Editing and despiking techniques: the nature of errors. - 3.16.1 Identifying and removing errors. - 3.16.2 Propagation of error. - 3.16.3 Dealing with numbers: the statistics of roundoff. - 3.16.4 Gauss-Markov theorem. - 3.17 Interpolation: filling the data gaps. - 3.17.1 Equally and unequally spaced data. - 3.17.2 Interpolation methods. - 3.17.3 Interpolating gappy records: practical examples. - 3.18 Covariance and the covariance matrix. - 3.18.1 Covariance and structure functions. - 3.18.2 A computational example. - 3.18.3 Multivariate distributions. - 3.19 Bootstrap and jackknife methods. - 3.19.1 Bootstrap method. - 3.19.2 Jackknife method. - Chapter 4 The Spatial Analyses of Data Fields. - 4.1 Traditional block and bulk averaging. - 4.2 Objective analysis. - 4.2.1 Objective mapping: examples. - 4.3 Empirical orthogonal functions. - 4.3.1 Principal axes of a single vector time series (scatter plot). - 4.3.2 EOF computation using the scatter matrix method. - 4.3.3 EOF computation using singular value decomposition. - 4.3.4 An example: deep currents near a mid-ocean ridge. - 4.3.S Interpretation of EOFs. - 4.3.6 Variations on conventional EOF analysis. - 4.4 Normal mode analysis. - 4.4.1 Vertical normal modes. - 4.4.2 An example: normal modes of semidiurnal frequency. - 4.4.3 Coastal-trapped waves (CTWs). - 4.5 Inverse methods. - 4.5.1 General inverse theory. - 4.5.2 Inverse theory and absolute currents. - 4.5.3 The IWEX internal wave problem. - 4.5.4 Summary of inverse methods. - Chapter 5 Time-series Analysis Methods. - 5.1 Basic concepts. - 5.2 Stochastic processes and stationarity. - 5.3 Correlation functions. - 5.4 Fourier analysis. - 5.4.1 Mathematical formulation. - 5.4.2 Discrete time series. - 5.4.3 A computational example. - 5.4.4 Fourier analysis for specified frequencies. - 5.4.5 The fast Fourier transform. - 5.5 Harmonic analysis. - 5.5.1 A least-squares method. - 5.5.2 A computational example. - 5.5.3 Harmonic analysis of tides. - 5.5.4 Choice of constituents. - 5.5.5 A computational example for tides. - 5.5.6 Complex demodulation. - 5.6 Spectral analysis. - 5.6.1 Spectra of deterministic and stochastic processes. - 5.6.2 Spectra of discrete series. - 5.6.3 Conventional spectral methods. - 5.6.4 Spectra of vector series. - 5.6.5 Effect of sampling on spectral estimates. - 5.6.6 Smoothing spectral estimates (windowing). - 5.6.7 Smoothing spectra in the frequency domain. - 5.6.8 Confidence intervals on spectra. - 5.6.9 Zero-padding and prewhitening. - 5.6.10 Spectral analysis of unevenly spaced time series. - 5.6.11 General spectral bandwidth and Q of the system. - 5.6.12 Summary of the standard spectral analysis approach. - 5.7 Spectral analysis (parametric methods). - 5.7.1 Some basic concepts. - 5.7.2 Autoregressive power spectral estimation. - 5.7.3 Maximum likelihood spectral estimation. - 5.8 Cross-spectral analysis. - 5.8.1 Cross-correlation functions. - 5.8.2 Cross-covariance method. - 5.8.3 Fourier transform method. - 5.8.4 Phase and cross-amplitude functions. - 5.8.S Coincident and quadrature spectra. - 5.8.6 Coherence spectrum (coherency). - 5.8.7 Frequency response of a linear system. - 5.8.8 Rotary cross-spectral analysis. - 5.9 Wavelet analysis. - 5.9.1 The wavelet transform. - 5.9.2 Wavelet algorithms. - 5.9.3 Oceanographic examples. - 5.9.4 The S-transformation. - 5.9.5 The multiple filter technique. - 5.10 Digital filters. - 5.10.1 Introduction. - 5.10.2 Basic concepts. - 5.10.3 Ideal filters. -

Note: Contents Preface Acknowledgements Chapter 1. Recognition of paleosols Traces of life Soil horizons Soil structure What else could it be? Chapter 2. Alteration of paleosols after burial Burial decomposition of organic matter Burial gleization of organic matter Burial reddening of iron oxides and hydroxides Cementation of primary porosity Compaction Illitization of smectite Coalification of peat Kerogen maturation and cracking Recrystallization of carbonate Metamorphism Common patterns of alteration Chapter 3. Interpretation of paleosols Wetland paleosols of coal measures Aridland paleosols of calcareous red beds Paleosols at major geological unconformities Many influences on soils Chapter 4. Colour photographs Root traces Other biogenic traces Soil horizons Soil structures Soil microfabric Formation of paleosols Classification of paleosols Burial alteration of paleosols Chapter 5. Methods in palaeopedology Field documentation and sampling Petrographic thin sections Mineral determination by X-ray diffraction Bulk density determination Bulk chemical analysis Palaeopedology itself References Glossary Index