Book contents
- Frontmatter
- Contents
- List of figures
- List of SI unit prefixes
- List of chemical symbols
- Preface to the First Edition
- Preface to the Second Edition
- Preface to the Third Edition
- 1 Global warming and climate change
- 2 The greenhouse effect
- 3 The greenhouse gases
- 4 Climates of the past
- 5 Modelling the climate
- 6 Climate change in the twenty-first century and beyond
- 7 The impacts of climate change
- 8 Why should we be concerned?
- 9 Weighing the uncertainty
- 10 A strategy for action to slow and stabilise climate change
- 11 Energy and transport for the future
- 12 The global village
- Glossary
- Index
2 - The greenhouse effect
- Frontmatter
- Contents
- List of figures
- List of SI unit prefixes
- List of chemical symbols
- Preface to the First Edition
- Preface to the Second Edition
- Preface to the Third Edition
- 1 Global warming and climate change
- 2 The greenhouse effect
- 3 The greenhouse gases
- 4 Climates of the past
- 5 Modelling the climate
- 6 Climate change in the twenty-first century and beyond
- 7 The impacts of climate change
- 8 Why should we be concerned?
- 9 Weighing the uncertainty
- 10 A strategy for action to slow and stabilise climate change
- 11 Energy and transport for the future
- 12 The global village
- Glossary
- Index
Summary
The basic principle of Global warming can be understood by considering the radiation energy from the Sun that warms the Earth's surface and the Thermal radiation from the Earth and the Atmosphere that is radiated out to space. On average these two radiation streams must balance. If the balance is disturbed (for instance by an increase in atmospheric Carbon dioxide) it can be restored by an increase in the Earth's surface temperature.
How the Earth keeps warm
To explain the processes that warm the Earth and its Atmosphere, I will begin with a very simplified Earth. Suppose we could, all of a sudden, remove from the Atmosphere all the clouds, the water vapour, the Carbon dioxide and all the other minor gases and the dust, leaving an Atmosphere of nitrogen and oxygen only. Everything else remains the same. What, under these conditions, would happen to the atmospheric temperature?
The calculation is an easy one, involving a relatively simple radiation balance. Radiant energy from the Sun falls on a surface of one square metre in area outside the Atmosphere and directly facing the Sun at a rate of about 1370 Watts – about the power radiated by a reasonably sized domestic electric fire. However, few parts of the Earth's surface face the Sun directly and in any case for half the time they are pointing away from the Sun at night, so that the average energy falling on one square metre of a level surface outside the Atmosphere is only one-quarter of this or about 343 Watts.
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- Information
- Global WarmingThe Complete Briefing, pp. 14 - 27Publisher: Cambridge University PressPrint publication year: 2004