- \n
- To understand how electro-magnetic radiation interacts with the Earth’s atmosphere and the consequences of this interaction for remote sensing<\/li>\n
- To understand the different types of atmospheric scatter, atmospheric absorption processes, and atmospheric refraction<\/li>\n<\/ul>\n
\nAll radiation used for remote sensing passes through the atmosphere before and after it has interacted with the Earth’s surface. The atmosphere alters the radiation’s frequency, intensity, and direction. In reality, of course, atmospheric effects on remotely sensed imagery are complex and diverse. Radiance measured by an air- or space-borne sensor is affected by numerous factors, not solely diffuse sky irradiance between the sensor and the target on the Earth’s surface. The atmosphere mainly affects the visible and infra-red wavelengths and has more minor effects on the microwave wavelength. There are three physical processes involved:<\/p>\n
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- scattering<\/i>, which changes the direction and intensity of radiation (see illustration below).<\/li>\n
- absorption<\/i>, in which incident radiation is retained by constituent parts of the atmosphere, thereby reducing its intensity.<\/li>\n
- refraction<\/i>, which changes the direction of radiation as it passes through the atmosphere (see illustration below).<\/li>\n<\/ul>\n
![](\"http:\/\/generic.wordpress.soton.ac.uk\/rs4eo\/wp-content\/uploads\/sites\/106\/2016\/08\/3.6-300x249.jpg\")
<\/p>\nAtmospheric Refraction<\/p>\n
![](\"http:\/\/generic.wordpress.soton.ac.uk\/rs4eo\/wp-content\/uploads\/sites\/106\/2016\/08\/3.7.jpg\")
<\/p>\nAtmospheric Scattering<\/p>\n
Scattering<\/strong><\/p>\n
Scattering is the redirection of electromagnetic radiation by particles suspended in the atmosphere. The amount of scattering which takes place depends on the size of the atmospheric particles, the abundance of these particles, the wavelength of the electromagnetic radiation, and the depth of the atmosphere. There are four main types of scattering:<\/p>\n
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- Rayleigh scattering<\/li>\n
- Mie Scattering<\/li>\n
- Non-selective scattering<\/li>\n
- Raman scattering<\/li>\n<\/ul>\n
Rayleigh scattering<\/i> was discovered by Lord Rayleigh in the 1890s, for which he received the Nobel Prize in Physics in 1904. This type of scattering is caused by gases in the upper atmosphere, more specifically by particles that are smaller than the wavelength of the radiation. As shown by the equation below, the degree of scattering (\u03a4 in the equation below) is inversely proportional to the fourth power of wavelength (\u03bb in the equation below).<\/p>\n
![](\"http:\/\/generic.wordpress.soton.ac.uk\/rs4eo\/wp-content\/uploads\/sites\/106\/2016\/08\/3.8.gif\")
<\/p>\nAs shown in the diagram below, what this means is that Rayleigh scattering is much greater for shorter wavelengths compared to longer wavelengths.<\/p>\n
![](\"http:\/\/generic.wordpress.soton.ac.uk\/rs4eo\/wp-content\/uploads\/sites\/106\/2016\/08\/3.9.jpg\")
<\/p>\n
\nActivity<\/strong><\/p>\n
On a cloud-free day, to an observer on the ground, the sky appears blue.<\/p>\n
![](\"http:\/\/generic.wordpress.soton.ac.uk\/rs4eo\/wp-content\/uploads\/sites\/106\/2016\/08\/3.10.jpg\")
<\/p>\nGiven what you know about atmospheric scattering, why is the sky blue (a question often also asked by young children!)?<\/p>\n
\r\n
- absorption<\/i>, in which incident radiation is retained by constituent parts of the atmosphere, thereby reducing its intensity.<\/li>\n
- scattering<\/i>, which changes the direction and intensity of radiation (see illustration below).<\/li>\n