Proceedings of the NATO Advanced Study Institute, Ankara, Turkey, from 5 to 16 August 2002
Our desire to understand the global carbon cycle and its link to the climate system represents a huge challenge. These overarching questions have driven a great deal of scientific endeavour in recent years: What are the basic oceanic mechanisms which control the oceanic carbon reservoirs and the partitioning of carbon between ocean and atmosphere? How do these mechanisms depend on the state of the climate system and how does the carbon cycle feed back on climate? What is the current rate at which fossil fuel carbon dioxide is absorbed by the oceans and how might this change in the future? To begin to answer these questions we must first understand the distribution of carbon in the ocean, its partitioning between different ocean reservoirs (the "solubility" and "biological" pumps of carbon), the mechanisms controlling these reservoirs, and the relationship of the significant physical and biological processes to the physical environment. The recent surveys from the JGOFS and WOCE (Joint Global Ocean Flux Study and World Ocean Circulation Ex periment) programs have given us a first truly global survey of the physical and biogeochemical properties of the ocean. These new, high quality data provide the opportunity to better quantify the present oceans reservoirs of carbon and the changes due to fossil fuel burning. In addition, diverse process studies and time-series observations have clearly revealed the complexity of interactions between nutrient cycles, ecosystems, the carbon-cycle and the physical envi ronment.
-Preface. List of Contributors. -1. Ocean carbonate chemistry: the aquatic chemistry fundamentals; J.W. Murray. -2. A primer on dissolved organic material and heterotrophic prokaryotes in the ocean; D.L. Kirchman. -3. Modelling the response of the biological pump to climate change; T.R. Anderson, I.J. Totterdell. -4. The dynamics of the marine nitrogen cycle and its influence on atmospheric CO2 variations; N. Gruber. -5. Exploration of biogeochemical temporal variability; T.D. Dickey. -6. Remote sensing of the ocean from space; G.K. Korotaev. -7. Mechanisms controlling the air-sea flux of CO2 in the North Atlantic; M. Follows, R.G. Williams. -8. The role of the oceans in the global carbon cycle: an overview; I. Marinov, J.L. Sarmiento. -9. Ocean carbon cycle in a changing climate: climate change detection; R.J. Matear. -10. Glacial-interglacial CO2 variations; H. Gildor. -11. Data assimilation into marine carbon models; R.J. Matear.
Our desire to understand the global carbon cycle and its link to the climate system represents a huge challenge. These overarching questions have driven a great deal of scientific endeavour in recent years: What are the basic oceanic mechanisms which control the oceanic carbon reservoirs and the partitioning of carbon between ocean and atmosphere? How do these mechanisms depend on the state of the climate system and how does the carbon cycle feed back on climate? What is the current rate at which fossil fuel carbon dioxide is absorbed by the oceans and how might this change in the future? To begin to answer these questions we must first understand the distribution of carbon in the ocean, its partitioning between different ocean reservoirs (the "solubility" and "biological" pumps of carbon), the mechanisms controlling these reservoirs, and the relationship of the significant physical and biological processes to the physical environment. The recent surveys from the JGOFS and WOCE (Joint Global Ocean Flux Study and World Ocean Circulation Ex periment) programs have given us a first truly global survey of the physical and biogeochemical properties of the ocean. These new, high quality data provide the opportunity to better quantify the present oceans reservoirs of carbon and the changes due to fossil fuel burning. In addition, diverse process studies and time-series observations have clearly revealed the complexity of interactions between nutrient cycles, ecosystems, the carbon-cycle and the physical envi ronment.
1. Ocean carbonate chemistry: the aquatic chemistry fundamentals.- 2. A primer on dissolved organic material and heterotrophic prokaryotes in the ocean.- 3. Modelling the response of the biological pump to climate change.- 4. The dynamics of the marine nitrogen cycle and its influence on atmospheric CO2 variations.- 5. Exploration of biogeochemical temporal variability.- 6. Remote sensing of the ocean from space.- 7. Mechanisms controlling the air-sea flux of CO2 in the North Atlantic.- 8. The role of the oceans in the global carbon cycle: an overview.- 9. Ocean carbon cycle in a changing climate: climate change detection.- 10. Glacial-interglacial CO2 variations.- 11. Data assimilation into marine carbon models.
Inhaltsverzeichnis
-Preface. List of Contributors. -1. Ocean carbonate chemistry: the aquatic chemistry fundamentals; J.W. Murray. -2. A primer on dissolved organic material and heterotrophic prokaryotes in the ocean; D.L. Kirchman. -3. Modelling the response of the biological pump to climate change; T.R. Anderson, I.J. Totterdell. -4. The dynamics of the marine nitrogen cycle and its influence on atmospheric CO2 variations; N. Gruber. -5. Exploration of biogeochemical temporal variability; T.D. Dickey. -6. Remote sensing of the ocean from space; G.K. Korotaev. -7. Mechanisms controlling the air-sea flux of CO2 in the North Atlantic; M. Follows, R.G. Williams. -8. The role of the oceans in the global carbon cycle: an overview; I. Marinov, J.L. Sarmiento. -9. Ocean carbon cycle in a changing climate: climate change detection; R.J. Matear. -10. Glacial-interglacial CO2 variations; H. Gildor. -11. Data assimilation into marine carbon models; R.J. Matear.
Klappentext
Our desire to understand the global carbon cycle and its link to the climate system represents a huge challenge. These overarching questions have driven a great deal of scientific endeavour in recent years: What are the basic oceanic mechanisms which control the oceanic carbon reservoirs and the partitioning of carbon between ocean and atmosphere? How do these mechanisms depend on the state of the climate system and how does the carbon cycle feed back on climate? What is the current rate at which fossil fuel carbon dioxide is absorbed by the oceans and how might this change in the future? To begin to answer these questions we must first understand the distribution of carbon in the ocean, its partitioning between different ocean reservoirs (the "solubility" and "biological" pumps of carbon), the mechanisms controlling these reservoirs, and the relationship of the significant physical and biological processes to the physical environment. The recent surveys from the JGOFS and WOCE (Joint Global Ocean Flux Study and World Ocean Circulation Ex periment) programs have given us a first truly global survey of the physical and biogeochemical properties of the ocean. These new, high quality data provide the opportunity to better quantify the present oceans reservoirs of carbon and the changes due to fossil fuel burning. In addition, diverse process studies and time-series observations have clearly revealed the complexity of interactions between nutrient cycles, ecosystems, the carbon-cycle and the physical envi ronment.
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