Editing Polarization (waves) (section)

==== Birefringence ====
{{Main|Birefringence}}

In a [[birefringent]] substance, electromagnetic waves of different polarizations travel at different speeds ([[phase velocity|phase velocities]]).  As a result, when unpolarized waves travel through a plate of birefringent material, one polarization component has a shorter wavelength than the other, resulting in a [[phase difference]] between the components which increases the further the waves travel through the material.  The Jones matrix is a [[unitary matrix]]: {{math|1= {{abs|''g''{{sub|1}}}} = {{abs|''g''{{sub|2}}}} = 1}}. Media termed diattenuating (or ''[[dichroic]]'' in the sense of polarization), in which only the amplitudes of the two polarizations are affected differentially, may be described using a [[Hermitian matrix]] (generally multiplied by a common phase factor). In fact, since {{em|any}} matrix may be written as the product of unitary and positive Hermitian matrices, light propagation through any sequence of polarization-dependent optical components can be written as the product of these two basic types of transformations.

[[File:Birefringence Stress Plastic.JPG|thumb|Color pattern of a plastic box showing [[Birefringence#Stress induced birefringence|stress-induced birefringence]] when placed in between two crossed [[polarizer]]s.]]
In birefringent media there is no attenuation, but two modes accrue a differential phase delay. Well known manifestations of linear birefringence (that is, in which the basis polarizations are orthogonal linear polarizations) appear in optical [[wave plate]]s/retarders and many crystals. If linearly polarized light passes through a birefringent material, its state of polarization will generally change, {{em|unless}} its polarization direction is identical to one of those basis polarizations. Since the phase shift, and thus the change in polarization state, is usually wavelength-dependent, such objects viewed under white light in between two polarizers may give rise to colorful effects, as seen in the accompanying photograph.

Circular birefringence is also termed [[optical activity]], especially in [[chiral]] fluids, or [[Faraday rotation]], when due to the presence of a magnetic field along the direction of propagation. When linearly polarized light is passed through such an object, it will exit still linearly polarized, but with the axis of polarization rotated. A combination of linear and circular birefringence will have as basis polarizations two orthogonal elliptical polarizations; however, the term "elliptical birefringence" is rarely used.

[[File:Birefringence.svg|thumb|upright=1.1|left|Paths taken by vectors in the Poincaré sphere under birefringence. The propagation modes (rotation axes) are shown with red, blue, and yellow lines, the initial vectors by thick black lines, and the paths they take by colored ellipses (which represent circles in three dimensions).]]

One can visualize the case of linear birefringence (with two orthogonal linear propagation modes) with an incoming wave linearly polarized at a 45° angle to those modes. As a differential phase starts to accrue, the polarization becomes elliptical, eventually changing to purely circular polarization (90° phase difference), then to elliptical and eventually linear polarization (180° phase) perpendicular to the original polarization, then through circular again (270° phase), then elliptical with the original azimuth angle, and finally back to the original linearly polarized state (360° phase) where the cycle begins anew. In general the situation is more complicated and can be characterized as a [[coordinate rotation|rotation]] in the Poincaré sphere about the axis defined by the propagation modes. Examples for linear (blue), circular (red), and elliptical (yellow) [[birefringence]] are shown in the figure on the left. The total intensity and degree of polarization are unaffected. If the path length in the birefringent medium is sufficient, the two polarization components of a collimated beam (or [[Ray (optics)|ray]]) can exit the material with a positional offset, even though their final propagation directions will be the same (assuming the entrance face and exit face are parallel). This is commonly viewed using [[calcite]] [[crystal]]s, which present the viewer with two slightly offset images, in opposite polarizations, of an object behind the crystal. It was this effect that provided the first discovery of polarization, by [[Erasmus Bartholinus]] in 1669.