Editing Optics (section)

=====Natural light=====
[[File:CircularPolarizer.jpg|right|thumb|upright=1.8|The effects of a [[photographic filter#Polarizer|polarising filter]] on the sky in a photograph. Left picture is taken without polariser. For the right picture, filter was adjusted to eliminate certain polarisations of the scattered blue light from the sky.]]
Most sources of electromagnetic radiation contain a large number of atoms or molecules that emit light. The orientation of the electric fields produced by these emitters may not be [[statistical correlation|correlated]], in which case the light is said to be ''unpolarised''. If there is partial correlation between the emitters, the light is ''partially polarised''. If the polarisation is consistent across the spectrum of the source, partially polarised light can be described as a superposition of a completely unpolarised component, and a completely polarised one. One may then describe the light in terms of the [[degree of polarisation]], and the parameters of the polarisation ellipse.{{sfnp|Hecht|2017|p=336}}

Light reflected by shiny transparent materials is partly or fully polarised, except when the light is normal (perpendicular) to the surface. It was this effect that allowed the mathematician Étienne-Louis Malus to make the measurements that allowed for his development of the first mathematical models for polarised light. Polarisation occurs when light is scattered in the [[earth's atmosphere|atmosphere]]. The scattered light produces the brightness and colour in clear [[sky|skies]]. This partial polarisation of scattered light can be taken advantage of using polarising filters to darken the sky in [[science of photography|photographs]]. Optical polarisation is principally of importance in [[chemistry]] due to [[circular dichroism]] and optical rotation (''circular birefringence'') exhibited by [[optical activity|optically active]] ([[chirality (chemistry)|chiral]]) [[molecules]].{{sfnp|Hecht|2017|pp=353–356}}