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Cutting facets: SiC has a higher index than C!
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Cutting facets: I don't expect Wikipedia to have a "specialized machines" article soon, but maybe "goniometer"?
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Thus, although [[cubic zirconia]] and [[quartz|rock crystal]] may look similar to [[diamond]], and all can be cut in a round brilliant cut, the angles must be different to produce the same [[optics|optical]] effects. Additionally, as diamond has a refractive index significantly higher than most other natural transparent stones, it can have a much greater sparkle than other materials.
Thus, although [[cubic zirconia]] and [[quartz|rock crystal]] may look similar to [[diamond]], and all can be cut in a round brilliant cut, the angles must be different to produce the same [[optics|optical]] effects. Additionally, as diamond has a refractive index significantly higher than most other natural transparent stones, it can have a much greater sparkle than other materials.


While some facets can be cut by [[cleavage (crystal)|cleavage]], [[specialised machines]] are used for cutting arbitrary facets. These consist of two main features:
While some facets can be cut by [[cleavage (crystal)|cleavage]], specialised machines are used for cutting arbitrary facets. These consist of two main features:
*a flat [[abrasive]], usually diamond dust of precise size bonded onto a metal disk (called 'laps') or carried by an oily fluid on a smooth metal or ceramic disk, and
*a flat [[abrasive]], usually diamond dust of precise size bonded onto a metal disk (called 'laps') or carried by an oily fluid on a smooth metal or ceramic disk, and
*a system for holding a stone onto the disk at a precise angle and position.
*a system ([[goniometer]]) for holding a stone onto the disk at a precise angle and position.


This usually requires the stone to be attached to a holder or dop, which is then placed in an indexed vice. This allows progressively finer abrasives to be used without disrupting the orientation of the stone. The final abrasive must be smaller than the [[wavelength]] of light, so that the scratches it creates are invisible. Modern machines tend to have indexed gears for moving the stone, so that rotating the stone to cut the next facet can be more precisely controlled.
This usually requires the stone to be attached to a holder or dop, which is then placed in an indexed vice. This allows progressively finer abrasives to be used without disrupting the orientation of the stone. The final abrasive must be smaller than the [[wavelength]] of light, so that the scratches it creates are invisible. Modern machines tend to have indexed gears for moving the stone, so that rotating the stone to cut the next facet can be more precisely controlled.

Revision as of 06:14, 2 February 2007

A cut ruby, with facets visible.

Facets are flat faces on geometric shapes. The organization of naturally occurring facets was key to early developments in crystallography, since they reflect the underlying symmetry of the crystal structure. Gemstones commonly have facets cut into them in order to improve their appearance.

Of the many hundreds of facet arrangements that have been used, the most famous is probably the round brilliant cut, used for diamond and many colored gemstones. This arrangement of 57 facets was calculated by Marcel Tolkowsky in 1919. Slight improvements have been made since then, including the addition of a 58th facet (a culet) on the bottom of the stone. Since this is calculated to show maximum brilliance, round diamonds are rarely cut in any other arrangement, although recently the Princess cut is becoming popular. Other cuts, including "rose" cuts, are most typically found in antique jewelry. See diamond cuts for an in-depth discussion and diagrams of various shapes and ways of cutting faceted stones.

Cutting facets

The art of cutting a gem with facets is a very precise activity. The aim with a faceted cut is to produce an article that sparkles with internally reflected light, and that shows off the "fire" of the stone. Accordingly, only transparent or translucent stones are usually faceted.

The angles between each facet are precisely calculated. As the aim is to maximise the effect of the internal reflections, these angles depend on the refractive index of the material. This means that although the name and general shape of a particular cut may be the same between different materials, the actual angles will be slightly different, for the maximum effect.

Thus, although cubic zirconia and rock crystal may look similar to diamond, and all can be cut in a round brilliant cut, the angles must be different to produce the same optical effects. Additionally, as diamond has a refractive index significantly higher than most other natural transparent stones, it can have a much greater sparkle than other materials.

While some facets can be cut by cleavage, specialised machines are used for cutting arbitrary facets. These consist of two main features:

  • a flat abrasive, usually diamond dust of precise size bonded onto a metal disk (called 'laps') or carried by an oily fluid on a smooth metal or ceramic disk, and
  • a system (goniometer) for holding a stone onto the disk at a precise angle and position.

This usually requires the stone to be attached to a holder or dop, which is then placed in an indexed vice. This allows progressively finer abrasives to be used without disrupting the orientation of the stone. The final abrasive must be smaller than the wavelength of light, so that the scratches it creates are invisible. Modern machines tend to have indexed gears for moving the stone, so that rotating the stone to cut the next facet can be more precisely controlled.

An older machine called the jamb peg faceting machine used wooden dop sticks of precise length. By placing one end into one of many precisely located holes in the jamb peg, the other end, with the stone, could be precisely placed onto the lap. These machines took considerable skill to use effectively.

Much less commonly, faceters use cylindrical machines, which leave concave facets. This technique is most noticeably used around the gem's girdle.