Skip to main contentdfsdf

Debbie Foster's List: Polarization

    • Absorption Filters

       

      Absorption filters work by reducing the incident light through absorption of  specific wavelengths. Absorption filters are commonly made from pigmented  gelatin or dyed glass. The spectral performance of an absorption filter is a  function of the quantity of the dye present in the glass or gelatin matrix and  the physical thickness of the filter itself.

       

      Absorption filters are used to generate special effects in numerous  photography applications and are extensively used in the cinema industry.  Absorption filters are also found in traffic signals and on boats, aircrafts and  vehicles as directional signals.

       

      Dichroic Filters

       

      Dichroic filters are far more capable and precise in their ability to  obstruct unwanted wavelengths when compared to glass and gel absorption filters.  Multi-layered thin film coatings are used for the manufacture of dichroic  filters. These coatings are built up onto optical-grade glass using vacuum  deposition.

       

      Dichroic filters are widely used in a number of applications such as specific  filtration for photography and optical microscopy. Dichroic filters are used  instead of absorption filters for high quality color enlarges to fine tune the  light color transmitted through the color transparency or negative.

       

      Interference Filters

       

      Interference filters differs from absorption filters. Rather than absorbing,  interference filters reflect and destructively interfere with unwanted  wavelength.

       

      Modern interference filters are formed after the Fabry-Perot interferometer  designed in the late 1800s by Alfred Perot and Charles Fabry. Interference  filters are manufactured with a number of layers of thin films applied to a flat  optically transparent glass surface.

       

      Successive layers of dielectric materials are used to produce modern  interference filters. The thickness of the dielectric materials ranges from 1/4  to 1/2 of the targeted wavelength. The dielectric materials are coated onto a  flat optical glass of a polymer surface under vacuum conditions.

       

      Light which is incident on the multilayered dielectric surface is either  passes through the filter with constructive reinforcement or reflected and  decreases in magnitude by destructive interference.

    • Birefringence of crystals can modify  the Polarization State of light which is very useful in many applications. This  type of optical components are called birefringent wave plates or retardation  plates (or just wave plates or retarders for short).   

      The velocities of the extraordinary and  ordinary rays through the birefringent materials vary inversely with their  refractive indices. The difference in velocities gives rise to a phase  difference when the two beams recombine. In the case of an incident linearly  polarized beam this is given by a=2pd(ne-no)/l(a-phase difference; d-thickness of waveplate; ne,  no-refractive indices of extraordinary and ordinary rays  respectively; l-wavelength). At any specific wavelength the phase difference is governed  by the thickness of the waveplate.   

      Red Optronics provides the following  waveplates: octadic-wave (l/8), quarter-wave (l/4), half-wave (l/2) and full-wave (l) plates. 

      Half Wave Plate  

      The half wave plate can be used to  rotate the polarization state of a plane polarized light as shown in Figure  1.  

      Suppose a plane-polarized wave is  normally incident on a wave plate, and the plane of polarization is at an angle  q with respect to the fast axis, as shown. After passing through the plate, the  original plane wave has been rotated through an angle 2q

       

      A half-wave plate is very handy in  rotating the plane of polarization from a polarized laser to any other desired  plane (especially if the laser is too large to rotate).  Most large ion  lasers are vertically polarized.  To obtain horizontal polarization, simply  place a half-wave plate in the beam with its fast (or slow) axis 45° to the  vertical.  The l/2 plates can also change left circularly polarized light into right  circularly polarized light or vice versa.  The thickness of half waveplate  is such that the phase difference is 1/2 wavelength (l/2, Zero order) or certain multiple of  1/2-wavelength [(2n+1)l/2, multiple order].

       

      Quarter Wave Plate

       

      Quarter wave plate are used to turn  plane-polarized light into circularly polarized light and vice versa. To do this, we must orient  the wave plate so that equal amounts of fast and slow waves are excited. We may  do this by orienting an incident plane-polarized wave at 45° to the fast (or  slow) axis, as shown in Figure 2. When a l/4 plate is double passed, i.e., by  mirror reflection, it acts as a l/2 plate and rotates the plane of polarization to a certain  angle, i.e., 90°.   This scheme is widely used in isolators,  Q-switches, etc.

       

      The thickness of the quarter waveplate  is such that the phase difference is 1/4 wavelength (l/4, Zero order) or certain multiple of  1/4-wavelength [(2n+1)l/4, multiple order].

    • One of the rays travels with the same velocity in every direction through the  crystal and is termed the ordinary ray. The other ray travels with a  velocity that is dependent upon the propagation direction within the crystal.  This light ray is termed the extraordinary ray. The distance of  separation between the ordinary and extraordinary ray increases with increasing  crystal thickness. The two independent refractive indices of anisotropic  crystals are quantified in terms of their birefringence, a measure of the  difference in refractive index. Thus, the birefringence (B, often termed  d, or D) of a  crystal is defined as:
1 - 4 of 4
20 items/page
List Comments (0)