Book contents
- Frontmatter
- Contents
- Acknowledgments
- 1 Introduction
- 2 Electromagnetic-wave propagation
- 3 The absorption of light
- 4 Specular reflection
- 5 Single-particle scattering: perfect spheres
- 6 Single-particle scattering: irregular particles
- 7 Propagation in a nonuniform medium: the equation of radiative transfer
- 8 The bidirectional reflectance of a semiinfinite medium
- 9 The bidirectional reflectance in other geometries
- 10 Other quantities related to reflectance, integrated reflectances, planetary photometry, reflectances of mixtures
- 11 Reflectance spectroscopy
- 12 Photometric effects of large-scale roughness
- 13 Effects of thermal emission
- 14 Polarization
- Appendix A A brief review of vector calculus
- Appendix B Functions of a complex variable
- Appendix C The wave equation in spherical coordinates
- Appendix D Table of symbols
- Bibliography
- Index
14 - Polarization
Published online by Cambridge University Press: 04 October 2009
- Frontmatter
- Contents
- Acknowledgments
- 1 Introduction
- 2 Electromagnetic-wave propagation
- 3 The absorption of light
- 4 Specular reflection
- 5 Single-particle scattering: perfect spheres
- 6 Single-particle scattering: irregular particles
- 7 Propagation in a nonuniform medium: the equation of radiative transfer
- 8 The bidirectional reflectance of a semiinfinite medium
- 9 The bidirectional reflectance in other geometries
- 10 Other quantities related to reflectance, integrated reflectances, planetary photometry, reflectances of mixtures
- 11 Reflectance spectroscopy
- 12 Photometric effects of large-scale roughness
- 13 Effects of thermal emission
- 14 Polarization
- Appendix A A brief review of vector calculus
- Appendix B Functions of a complex variable
- Appendix C The wave equation in spherical coordinates
- Appendix D Table of symbols
- Bibliography
- Index
Summary
Introduction
In the equations for the reflectance and emissivity of a particulate medium developed in Chapters 7–12 it has been assumed that polarization can be neglected. For irregular particles that are large compared with the wavelength of the observation, this assumption is justified on the grounds that the light scattered by such particles is only weakly polarized. However, the polarization of the light scattered by a medium does contain information about the medium and thus is a useful tool for remote sensing. One of the advantages of using polarization is that it does not require absolute calibration of the detector, but only a measurement of the ratio of two radiances.
The discovery that sunlight scattered from a planetary regolith was polarized was made as early as 1811 by Arago, who noticed that moonlight was partially linearly polarized and that the dark lunar maria were more strongly polarized than the lighter highlands. Subsequent observations of planetary polarization were made by several persons, including Lord Rosse in Ireland. However, the quantitative measurement of polarization from bodies of the solar system was placed on a firm foundation in the 1920s by the classical studies of Lyot (1929). This work was later continued by Dollfus (1956) and his colleagues.
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- Theory of Reflectance and Emittance Spectroscopy , pp. 386 - 412Publisher: Cambridge University PressPrint publication year: 1993