Book contents
- Frontmatter
- Contents
- Preface
- List of Contributors
- Acknowledgments
- 1 Overview of climate modeling
- 2 Climate-change modeling: a brief history of the theory and recent twenty-first-century ensemble simulations
- 3 Energy-balance climate models
- 4 Intrinsic climatic variability: an essay on modes and mechanisms of oceanic and atmospheric fluid dynamics
- 5 The radiative forcing due to clouds and water vapor
- 6 A model study of the effect of Pinatubo volcanic aerosols on stratospheric temperatures
- 7 Unresolved issues in atmospheric solar absorption
- 8 Cloud feedbacks
- 9 Water-vapor feedback
- 10 Water-vapor observations
- 11 New frontiers in remote sensing of aerosols and their radiative forcing of climate
- 12 Cloud–climate feedback: lessons learned from two El Niño events
- 13 Runaway greenhouses and runaway glaciations: how stable is Earth's climate?
- Glossary
- Plate section
8 - Cloud feedbacks
Published online by Cambridge University Press: 12 August 2009
- Frontmatter
- Contents
- Preface
- List of Contributors
- Acknowledgments
- 1 Overview of climate modeling
- 2 Climate-change modeling: a brief history of the theory and recent twenty-first-century ensemble simulations
- 3 Energy-balance climate models
- 4 Intrinsic climatic variability: an essay on modes and mechanisms of oceanic and atmospheric fluid dynamics
- 5 The radiative forcing due to clouds and water vapor
- 6 A model study of the effect of Pinatubo volcanic aerosols on stratospheric temperatures
- 7 Unresolved issues in atmospheric solar absorption
- 8 Cloud feedbacks
- 9 Water-vapor feedback
- 10 Water-vapor observations
- 11 New frontiers in remote sensing of aerosols and their radiative forcing of climate
- 12 Cloud–climate feedback: lessons learned from two El Niño events
- 13 Runaway greenhouses and runaway glaciations: how stable is Earth's climate?
- Glossary
- Plate section
Summary
Introduction
As discussed in Chapter 1, climate feedbacks are an integral aspect of the climate system. This chapter investigates the importance of cloud feedbacks. Although many of the best-known early climate models used prescribed clouds (e.g., Manabe and Bryan, 1969), the importance of potential changes in cloudiness for the problem of climate change has been recognized as a key factor since the 1970s (e.g., Arakawa, 1975; Charney et al., 1979). In particular, it is now widely appreciated that “cloud feedback” is a key source of uncertainty limiting the reliability of simulations of anthropogenic climate change (e.g., Houghton et al., 1990).
Nevertheless the whole concept of cloud feedback continues to be obscure, in part because the term “cloud feedback” is often used without being properly defined at all, and is rarely given a definition precise enough to show how it can be quantitatively measured. Further confusion arises from the fact that there are in fact many types of cloud feedbacks (e.g., Schneider, 1972; Schlesinger, 1985; 1988; 1989; Wielicki et al., 1995). In addition, it is widely perceived that existing atmospheric general circulation models (AGCMs) are incapable of making quantitatively realistic simulations of cloudiness.
The purposes of this chapter are to give a definition of cloud feedback, to discuss some particular types of cloud feedback, and to assess the prospects for simulations of cloud feedback on anthropogenic climate change.
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- Frontiers of Climate Modeling , pp. 217 - 250Publisher: Cambridge University PressPrint publication year: 2006
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