Synopses & Reviews
A complete revision of Goody's classic 1964 work, this volume offers a systematic discussion of atmospheric radiation processes that today are at the center of worldwide study and concern. It deals with the ways in which incident solar radiation is transformed into scattered and thermal radiation, and the thermodynamic consequences for the Earth's gaseous envelope, identifying aspects of the interaction between radiation and atmospheric motions as the central theme for atmospheric radiation studies. As a complete treatment of physical and mathematical foundations, the text assumes no prior knowledge of atmospheric physics. The theoretical discussion is systematic, and can therefore be applied with minor extension to any planetary atmosphere.
Review
"This is a much-improved volume that builds on the successful style of the original while presenting an impressive array of new material." --Science
"A classic in the field . . . An excellent text for the advanced student and highly useful reference for the researcher." --Bulletin American Meteorological Society
Synopsis
This volume brings together prominent voices on competence, governance, and entrepreneurship to advance and stimulate economic strategy research. By pooling and mobilizing intellectual resources of both competence and governance perspectives, the contributions show that an innovative joint
venture between these two main perspectives can lead to a new avenue of future research on strategic issues such as 'corporate growth', 'interfirm cooperation', and 'corporate entrepreneurship.'
Table of Contents
1. Introduction
1.1. The Nature of the Problem
1.2. The Thermal Structure of the Atmosphere
1.3. The Chemical Composition of the Atmosphere
2. Theory of Radiative Transfer
2.1. Definitions
2.2. Thermal Emission
2.3. The Integral Equations
2.4. Approximate Methods for Thermal Radiation
3. Vibration-Rotation Spectra of Gaseous Molecules
3.1. Introduction
3.2. Vibration-Rotation Spectra
3.3. The Shape of a Spectral Line
3.4. Collision-Induced and Polymer Spectra
3.5. Overview
4. Band Models
4.1. Introduction
4.2. Isolated Lines
4.3. Distributed Line Intensities
4.4. The Effect of Overlap
4.5. Regular Models
4.6. Random Models
4.7. Generalized Transmission Functions
4.8. K-Distributions
4.9. Models of Complete Bands
5. Absorption by Atmospheric Gases
5.1. Introduction
5.2. Nitrogen
5.3. Oxygen
5.4. Water Vapor
5.5. Carbon Dioxide
5.6. Ozone
5.7. Nitrous Oxide, Carbon Monoxide and Methane
6. Radiation Calculations in a Clear Atmosphere
6.1. Introduction
6.2. Transmission Through a Nonhomogeneous Atmosphere
6.3. Topics Concerning Heating Rates
6.4. Approximate Methods
6.5. The Inverse Problem for Thermal Radiation
7. Extinction by Molecules and Droplets
7.1. The Problem in Terms of the Electromagnetic Theory
7.2. Scattering Functions
7.3. Rayleigh's Solution for Small Particles
7.4. Large Particles
7.5. Geometric Optics
7.6. The Mie Theory
7.7. Nonspherical Particles
8. Radiative Transfer in a Scattering Atmosphere
8.1. Introduction
8.2. Integro-Differential Equation
8.3. Interaction Principle
8.4. Miscellaneous Methods
8.5. Numerical Results
8.6. Applications
9. Atmospheres in Radiative Equilibrium
9.1. Introduction
9.2. An Elementary Solution
9.3. Non-Grey Atmospheres
9.4. The Troposphere and Stratosphere
9.5. The Runaway Greenhouse
10. Evolution of a Thermal Disturbance
10.1. Introduction
10.2. The Radiation Eigenvalue Problem
10.3. Numerical Results
10.4. Planetary-Scale Relaxation
10.5. The Newtonian Cooling Approximation
10.6. Solar Radiation in the Middle Atmosphere