The Carbon Cycle

Leading scientists describe how we can reduce CO2 emissions; for graduate students and researchers.

T. M. L. Wigley (Edited by), D. S. Schimel (Edited by)

9780521018623, Cambridge University Press

Paperback, published 22 August 2005

312 pages, 114 b/w illus. 36 tables
28.6 x 22.2 x 2.3 cm, 1.042 kg

'… covers the topic superbly … the book is a 'must-buy' for libraries. But it is more important than that … fodder for graduate courses, and for anyone interested in the future of the planet … the story it tells is vital to us all.' Euan Nisbet, Geological Magazine

Reducing carbon dioxide (CO2) emissions is imperative to stabilizing our future climate. Our ability to reduce these emissions combined with an understanding of how much fossil-fuel-derived CO2 the oceans and plants can absorb is central to mitigating climate change. In The Carbon Cycle, leading scientists examine how atmospheric carbon dioxide concentrations have changed in the past and how this may affect the concentrations in the future. They look at the carbon budget and the 'missing sink' for carbon dioxide. They offer approaches to modeling the carbon cycle, providing mathematical tools for predicting future levels of carbon dioxide. This comprehensive text incorporates findings from the recent IPCC reports. New insights, and a convergence of ideas and views across several disciplines make this book an important contribution to the global change literature. It will be an invaluable resource for students and researchers working in the field.

Preface
Acknowledgements
Part I. Introduction: 1. Introduction
2. Excerpts from 1994 and 1995 IPCC Reports
Part II. The Missing Carbon Sink: 3. Carbon dioxide emissions from fossil fuel consumption and cement manufacture, 1751-1991 and an estimate of their isotopic composition and latitudinal distribution
5. Emissions of carbon from land-use change
6. The CO2 fertilizing effect: relevance to the global carbon cycle
7. Soils and the global carbon cycle
8. Grasslands and the global carbon cycle: modeling the effects of climate change
9. Constraints on the atmospheric carbon budget from spatial distributions of CO2
10. Estimating air-sea exchanges of CO2 from pCO2 gradients: assessment of uncertainties
11. Atmospheric oxygen measurements and the carbon cycle
a strategy for estimating the potential soil carbon storage due to CO2 fertilization
Part III. Paleo-CO2 Variations: 12. Isotope and carbon cycle inferences
13. Shallow water carbonate deposition and its effect on the carbon cycle
Part IV. Modeling CO2 Changes: 14. Future fossil fuel carbon emissions without policy intervention: a review
15. The future role of reforestation in reducing the buildup of atmospheric CO2
16. Simple ocean carbon cycle models
17. Very high-resolution estimates of global ocean circulation, suitable for carbon cycle modeling
18. Effects of ocean circulation change on atmospheric CO2
19. Box models of the terrestrial biosphere
20. Impacts of climate and CO2 on the terrestrial carbon cycle
21. Stabilization of CO2 concentration levels
Part V. Appendix 1. Organizing committee
Appendix 2. Working group members
Appendix 3. Reviewers.

Subject Areas: Atmospheric physics [PHVJ]