Difference between revisions of "Double Refraction"

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When a ray of light enters the gemstone, the atomic structure allows only those rays vibrating in two specific directions to continue.<br />
 
When a ray of light enters the gemstone, the atomic structure allows only those rays vibrating in two specific directions to continue.<br />
These two rays vibrate in planes that are mutually perpendicular and are therefore polarized. Both these rays travel at different speeds inside the gemstone and thus will refact at different angles.
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These two rays vibrate in planes that are mutually perpendicular and are therefore polarized. Both these rays travel at different speeds inside the gemstone and thus will refract at different angles.
  
 
The strength of DR (Double Refraction) varies with direction and we measure the maximum DR (Δ).<br />
 
The strength of DR (Double Refraction) varies with direction and we measure the maximum DR (Δ).<br />
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The maximum RI difference between these two rays is named "double refraction", often indicated by the symbol "Δ" (Greek letter delta). This maximum birefringence is largest when light enters the gemstone at an angle perpendicular to the optic axis.
 
The maximum RI difference between these two rays is named "double refraction", often indicated by the symbol "Δ" (Greek letter delta). This maximum birefringence is largest when light enters the gemstone at an angle perpendicular to the optic axis.
  
In faceted stones, a strong birefingence may result in visual doubling of facets, which is in a large number of zircons. Although the DR is at its maximum when viewed in the direction perpendicular to the optic axis, no doubling of facets will be seen in that direction due to superimposition.
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In faceted stones, a strong birefringence may result in visual doubling of facets, which is in a large number of zircons. Although the DR is at its maximum when viewed in the direction perpendicular to the optic axis, no doubling of facets will be seen in that direction due to superimposition.
  
 
Gemstones belonging to the cubic crystal system and amorphous gems have only one RI and therefore do not show birefringence; all other gemstones do.<br />
 
Gemstones belonging to the cubic crystal system and amorphous gems have only one RI and therefore do not show birefringence; all other gemstones do.<br />
 
Uniaxial stones (those crystallizing in the trigonal, hexagonal and tetragonal systems) will show two readings and have one optic axis.<br />
 
Uniaxial stones (those crystallizing in the trigonal, hexagonal and tetragonal systems) will show two readings and have one optic axis.<br />
 
Biaxial gemstones (orthorhombic, monoclinic and triclinic systems) have two directions in which the incident light will react as if it were isotropic and therefore will have two optic axes.
 
Biaxial gemstones (orthorhombic, monoclinic and triclinic systems) have two directions in which the incident light will react as if it were isotropic and therefore will have two optic axes.

Revision as of 18:36, 20 November 2006

Incident ray separated into an ordinary ray (ω) and an extra-ordinary ray (ε)

Some gemstones have more than one refractive index (RI) because these stones belong to crystal systems (anistropic) that have atomic structures which cause an incident ray of light to be resolved (split) into two separate rays. This phenomenon is named "birefringence".

When a ray of light enters the gemstone, the atomic structure allows only those rays vibrating in two specific directions to continue.
These two rays vibrate in planes that are mutually perpendicular and are therefore polarized. Both these rays travel at different speeds inside the gemstone and thus will refract at different angles.

The strength of DR (Double Refraction) varies with direction and we measure the maximum DR (Δ).
These maximum values differ from one gemstone to another. For instance:

  • Strong DR - zircon (0.059)
  • Medium DR - tourmaline (0.020)
  • Low DR - quartz (0.009)


In uniaxial gemstones, one ray will vibrate in the direction perpendicular to the optic axis and will obey Snell's Law (one can calculate its angle of refraction). This ray is named the ordinary ray (usually indicated with ω). The other ray will vibrate in the direction of the optic axis and does not obey Snell's Law (i.e. the angle of refraction will vary). That ray is named the extra-ordinary ray (indicated by ε).

The maximum RI difference between these two rays is named "double refraction", often indicated by the symbol "Δ" (Greek letter delta). This maximum birefringence is largest when light enters the gemstone at an angle perpendicular to the optic axis.

In faceted stones, a strong birefringence may result in visual doubling of facets, which is in a large number of zircons. Although the DR is at its maximum when viewed in the direction perpendicular to the optic axis, no doubling of facets will be seen in that direction due to superimposition.

Gemstones belonging to the cubic crystal system and amorphous gems have only one RI and therefore do not show birefringence; all other gemstones do.
Uniaxial stones (those crystallizing in the trigonal, hexagonal and tetragonal systems) will show two readings and have one optic axis.
Biaxial gemstones (orthorhombic, monoclinic and triclinic systems) have two directions in which the incident light will react as if it were isotropic and therefore will have two optic axes.