Aquatic chemistry is becoming both a rewarding and substantial area of inquiry and is drawing many prominent scientists to its fold. Its literature has changed from a compilation of compositional tables to studies of the chemical reactions occurring within the aquatic environments. But more than this is the recognition that human society in part is determining the nature of aquatic systems. Since rivers deliver to the world ocean most of its dissolved and particulate components, the interactions of these two sets of waters determine the vitality of our coastal waters. This significant vol ume provides not only an introduction to the dynamics of aquatic chem istries but also identifies those materials that jeopardize the resources of both the marine and fluvial domains. Its very title provides its emphasis but clearly not its breadth in considering natural processes. The book will be of great value to those environmental scientists who are dedicated to keeping the resources of the hydrosphere renewable. As the size of the world population becomes larger in the near future and as the uses of materials and energy show parallel increases, the rivers and oceans must be considered as a resource to accept some of the wastes of society. The ability of these waters and the sediments below them to accommodate wastes must be assessed continually. The key questions relate to the capacities of aqueous systems to carry one or more pollutants.
Inhalt
A Introduction.- 1 Environmental Pollution.- 2 Sources, Pathways and Reservoirs.- 3 Aquatic Ecosystems.- B Toxic Metals.- 1 Metals.- 1.1 Classification of the Elements.- 1.2 Classification of Metals.- 1.3 Trace Metal Species in Aquatic Systems.- 2 Trace Metals and Organic Life.- 2.1 Trace Elements Essential to Human Life.- 2.2 Deficiency and Oversupply.- 2.3 Metal Toxicity.- 2.4 Health Hazard Due to Certain Trace Elements.- 2.5 Accumulation of Toxic Substances in the Aquatic Food Chain.- 2.6 Catastrophic Episodes of Metal Poisonings.- 2.6.1 Mercury Poisoning.- 2.6.2 Cadmium Poisoning.- 2.6.3 Lead Poisoning.- 2.6.4 Chromium Poisoning.- 2.6.5 Arsenic Poisoning.- 2.7 Recent Studies on Metal Intoxication.- 3 Water Quality Criteria: Standards.- 3.1 Introduction.- 3.2 Criteria Development.- 3.3 Water Quality Criteria.- 4 The Sources of Metal Pollution.- 4.1 Geologic Weathering.- 4.2 Mining Effluents.- 4.3 Industrial Effluents.- 4.4 Domestic Effluents and Urban Stormwater Runoff.- 4.4.1 Domestic Effluents.- 4.4.2 Urban Storm Water Runoff.- 4.4.3 Spoil Heaps.- 4.5 Metal Inputs from Rural Areas.- 4.6 Atmospheric Sources.- 4.7 Special Sources.- 4.8 Multi-Source Effects.- 5 Metal Analysis.- 5.1 Media of Pollution Assessment.- 5.2 Sampling and Analytic Methods.- 5.2.1 Sampling.- 5.2.2 Analytic Methods.- C Metal Concentrations in River, Lake, and Ocean Waters.- 1 Distribution of Major Ions.- 1.1 Natural Salt Concentrations.- 1.2 Man-Made Contamination.- 2 Chemical Conditions for Trace Metals in Natural Waters.- 2.1 Chemical Speciation in Freshwater and Seawater.- 2.1.1 Analysis of Trace Metal Speciation.- 2.1.2 Freshwater/Seawater Model.- 2.2 Redox Conditions in Natural Waters.- 3 Trace Metals in Seawater.- 3.1 Natural Distribution.- 3.2 Man-Made Effects.- 3.2.1 Atmospheric Input of Metals.- 3.2.2 Metal Input from Sewage Effluents.- 4 Trace Metals in Inland Waters.- 4.1 Natural Contents.- 4.2 Metal Pollution in River Water: Regional Examples.- 4.2.1 Heavy Metal Pollution in United States Water Systems.- 4.2.2 Metal Pollution in Inland and Coastal Waters of Great Britain.- 4.2.3 Heavy Metals in River Water of the Federal Republic of Germany.- 4.2.4 Metals in Waters of the People's Republic of China.- 4.2.5 Heavy Metals in River Water of the U.S.S.R.- 4.2.6 Heavy Metals in Waters of Japan.- 4.3 Metal Transport in Freshwater Systems.- 4.3.1 Water Discharge and Metal Transport.- 4.3.2 Annual Cycles of Metal Transport.- D Metal Pollution Assessment from Sediment Analysis.- 1 Introduction.- 1.1 Soluble/Solid Equilibrium.- 1.2 Surface Samples and Sediment Cores.- 2 Metal Investigations on Aquatic Sediments.- 2.1 Sampling and Storage.- 2.1.1 Soils and Sediments.- 2.1.2 Grab and Sore Samplers.- 2.1.3 Bottom Sediment Traps.- 2.1.4 Suspended Materials.- 2.1.5 Recovery of Pore Waters.- 2.1.6 Storage.- 2.2 The Mechanical Sediment Analysis.- 2.3 Mineralogical Analysis.- 2.4 Chemical Analysis of Nutrient Components (C-N-P).- 2.4.1 Determinations of Oxidizable Matter (Organic Carbon) by the Chromic Acid Method.- 2.4.2 Determination of Kjeldahl Nitrogen.- 2.4.3 Determination of Total Phosphorus.- 2.5 Sediment Digestion in Metal Analysis.- 2.5.1 Hydrofluoric Acid Decomposition.- 2.5.2 Hydrochloric-Nitric Acid (Aqua Regia) Decomposition or Digestion by Nitric Acid.- 2.5.3 Lithium Metaborate Fusion (with Simultaneous Determination of Silica).- 2.5.4 Transfer of Solid Suspensions into Graphite Cuvettes.- 3 Geochemical Reconnaissance of Aquatic Sediments.- 4 Grain-Size Effects.- 4.1 Grain-Size Dependencies of Trace Metal Concentrations.- 4.2 Reduction of Grain-Size Effects.- 4.2.1 Extrapolation from Grain-Size Distribution.- 4.2.2 Metal Concentrations vs Surface Area.- 4.2.3 Separation of Clay/Silt and Fine Sand Fractions by Sieving.- 4.2.4 Separation of the Pelitic Fraction (< 2 ?m) in Settling Tubes.- 4.2.5 Treatment with Dilute Acids (Hydrochloric Acid, Nitric Acid).- 4.2.6 Mineral Separation: Quartz Correction Method.- 4.2.7 Comparison with "Conservative" Elements.- 4.2.8 The Relative Atomic Variations of Elements.- 5 Factors Controlling the Distribution of Metals in Aquatic Sediments.- 6 Natural Metal Content-Civilizational Accumulation.- 6.1 Average Shale: Global Standard Value.- 6.2 Fossil Lake Sediments: Standards Regarding Environmental Data.- 6.3 Fossil Fluviatile Deposits: Regional Influences.- 6.4 Short, Dated Sediment Cores: 200 Years of Industrial Development.- 6.5 Recent Lake Deposits in Relatively Unpolluted Areas.- 6.6 Metals in Suspended Matter: Background Values in Storm Water.- 6.7 Background Values and Nonpoint Sources.- 7 Lake Sediments as Indicators of Heavy Metal Pollution.- 7.1 Interference: Geochemical Background and Man's Impact.- 7.2 Metal Pollution in Lake Sediments (Examples).- 7.3 Metal Contamination Recorded in Dated Sedimentary Cores.- 7.4 Mercury Poisoning of Lakes.- 7.4.1 Sources of Mercury Pollution.- 7.4.2 Swedish Lakes.- 7.4.3 Canadian Lakes: Clay Lake.- 7.4.4 Laurentian Great Lakes.- 8 Metal Pollution in River Sediments.- 8.1 Geochemical Reconnaissance of Mercury.- 8.2 Stream Sediments: a Response to Environmental Contamination.- 8.3 Heavy Metal Enrichment of River Sediments by Man-Made Influences.- 9 Assessing Metal Pollution in the Sea by Sediment Study.- 9.1 Mercury Contamination-Forms of Metal Enrichment in Coastal Sediments.- 9.1.1 Minamata-Industrial Metal Contamination in Japanese Coastal Waters.- 9.1.2 Firth of Clyde-Sewage Sludge Disposal.- 9.1.3 Southern Californian Coast-Sewer Outfalls and Atmospheric Influences.- 9.1.4 New Haven-Unregulated Effluent Discharge.- 9.2 Marine Waste Deposits in the New York Metropolitan Region.- 9.3 Industrial Effluents in New Bedford Harbor, Mass.- 9.4 Heavy Metal Enrichment in the North Sea, Baltic Sea, and Mediterranean Sea.- 9.4.1 Metal Pollution in the Mediterranean Sea.- 9.4.2 Metal Pollution in the North Sea.- 9.4.3 Metal Contamination of the Baltic Sea.- 9.4.4 Other Restricted Basins-Fjords.- 9.5 Heavy Metal in Estuarine Sediments.- 9.5.1 The Estuarine Environment.- 9.5.2 The Rhine Estuary.- 9.5.3 The Elbe Estuary.- 9.5.4 Mixing Processes.- E Metal Transfer Between Solid and Aqueous Phases.- 1 Residence Times of Metals in Aquatic Systems.- 2 Types of Metal Association in Sediments.- 2.1 Classification of Chemical Phases in Sediment.- 2.2 Heavy Metals in Detrital Minerals.- 2.3 Heavy Metal Precipitation.- 2.3.1 Hydroxides.- 2.3.2 Sulfides.- 2.3.3 Carbonates.- 2.4 Cation Exchange and Adsorption.- 2.5 Sorption onto Clay Minerals.- 2.6 Sorption and Copr…