Difference between revisions of "Diamond"

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[[media:download_file_409.pdf|Natural and Simulated Diamonds]]
 
[[media:download_file_409.pdf|Natural and Simulated Diamonds]]
 
== Additional Images ==
 
 
<gallery>
 
File:diamondswkp.jpg|Diamonds
 
File:DiamondcutWK.jpg|Diamond cuts
 
File:diamondunitcellWK.jpg|Diamond unit cell
 
</gallery>
 
  
 
==Resources and Citations==
 
==Resources and Citations==

Latest revision as of 13:46, 13 October 2024

Moth brooch
MFA# 2007.631

Description

Diamond ring
Diamonds
Diamond cuts
Diamond unit cell

A stable, extremely hard, crystalline form of Carbon that occurs naturally. Diamonds were known to man prior to 800 BCE from alluvial deposits found in India, Sumatra, and Borneo. They were discovered in Brazil in 1725, in South Africa in 1867, and in Arkansas in 1906. The finest grade diamonds are transparent, brilliant stones that are used as gems; these are primarily mined from the kimberlite pipes in South Africa, and glacial tills of Zaire and Brazil. The largest diamond in the world, the Cullinan diamond, was found in 1905 in South Africa. Named for Sir Thomas Cullinan, it has since been cut into 9 large stones, the largest of which, Great Star of Africa (530.2 carat), is set in the British royal scepter. Diamonds with some imperfections are classified as industrial grade and are used for cutting tools and delicate instruments. These are primarily mined in Australia, Brazil, and South Africa. Abrasive pastes are made from small, imperfectly crystallized pieces called Bort (rounded with no distinct cleavage), Ballas, and Carbonado (black diamond, usually granular with no distinct cleavage). Synthetic diamonds, produced using high heat and pressure, are also used as abrasives. Imitation diamonds have been made from lead glass (Paste diamond), quartz rock crystal (Rhinestone), cubic zirconia, synthetic Rutile, and synthetic Spinel.

Properties of Natural and Simulated Diamonds

Gem Source Composition Common dates of use Mohs' hardness Refractive index Specific gravity Dispersion Crystal indices Fluorescence Optical Other
Corundum natural or synthetic Al2O3 1900-
1947
9 epsilon = 1.757-1.768;
omega = 1.765-1.776
3.96-
4.05
0.018 hexagonal crystal system with tabular, prismatic or pyramidal crystals; fracture =
conchoidal
orange to red; heat treated stones may fluoresce green marked dichroism natural inclusions minerals and fluid are common; synthetic may have gas bubbles and curved striae; low thermal conductivity
Cubic zirconia synthetic ZrSiO4 1976 -
present
8.5 2.15-2.18 5.6-6.0 0.06 fracture = conchoidal yellow fluorescence in shortwave UV usually no inclusions; low thermal conductivity
Diamond natural C 1476 -
present
10 2.4175 3.51-
3.53
0.044 cubic crystal system; perfect cleavage in four directions. may fluoresce pale colors in longwave UV; may phosphoresce Numerous inclusions; trigonal on surface; very high thermal conductivity
Garnet synthetic YAG/GGG 1970-
1976
8.25/7.0 1.87/1.97 4.6/7.0 0.028/
0.045
cubic crystal system isotropic turns brown in UV light; low thermal conductivity
Moissanite synthetic silicon carbide 1998 -
present
8.5-8.25 2.65-2.69 3.22 0.104 may have pale fluorescence strongly birefringent; anisotropic may have brown tint; resistant to heat; inclusions occur as fine white tubes; high thermal conductivity
Paste diamond synthetic high lead glass 1700 -
present
5.0-6.0 1.67 2.4-4.2 >0.02 highly refractive low thermal conductivity; used since 1700
Quartz natural SiO2 7 epsilon = 1.553;
omega = 1.544
2.65-
2.66
trigonal crystal system; low birefringence;
fracture = conchoidal
low birefringence heat treatments may bleach stones; low thermal conductivity; low thermal expansion;
Rutile synthetic TiO2 1947-
1955
6 2.6-2.9 4.25 0.33 doubly refractive may have yellow tint; low thermal conductivity
Spinel natural or synthetic MgAl2O4 1920-
1947
8 1.715-1.725 3.5-4.1 0.02 isometric crystal system; fracture = conchoidal natural fluoresces red in longwave; synthetic may fluoresce in
shortwave
anisotropic Natural stone has octahedral inclusions; may have fingerprint patterns; low thermal conductivity
Strontium titantate synthetic SrTiO3 1955-
1970
5.5 2.41 5.13 0.19 low thermal conductivity
Tourmaline natural aluminum borosilicate 7-7.5 epsilon = 1.610-1.650;
omega = 1.635-1.675
2.9-3.2 hexagonal, prismatic crystals; fracture = conchoidal little fluorescence pleochroic; high birefringence inclusions include gas or liquid pockets and color zoning; develops electrical charge when heated
Zircon natural ZrSiO4 6.0 - 7.5 epsilon = 1.968-2.015;
omega = 1.923-1.960
4.6-4.7 0.039 tetragonal system with square prismatic crystals; brittle; fracture = uneven some show dull yellow color; some may phosphoresce pleochroic; high birefringence heating brown zircon crystals produces strong colors (blue, green, red, etc.) that fade slowly with time or with UV exposure; low thermal
conductivity

Synonyms and Related Terms

bort; carbonado; ballas; Cullinan diamond; Great Star of Africa; adamas (ancient Greek); diamant (Ces., Dan., Fr., Ned., Sven.); Diamant (Deut.); diamante (Esp., It., Port.); diament (Pol.)

Risks

Raman (RASMIN)

DiamondRS.jpg

Raman (RRUFF)

Diamond Raman RRUFF R150089.png

  • No significant hazards.

Physical and Chemical Properties

  • Hardest natural material.
  • Cubic crystal system.
  • Perfect cleavage in four directions.
  • Luster = greasy to adamantine.
  • Streak = colorless.
  • Fluorescence: natural diamonds may fluoresce blue (type I) or orange (type II). Irradiated diamonds have a strong orange fluorescence in both LW and SW, Synthetic diamonds range from inert to strong orange fluorescence; some may phosphoresce.
  • Birefringence = none
Mohs Hardness 10
Melting Point 3700 C
Boiling Point 4200 C
Density 3.51-3.53 g/ml
Refractive Index 2.417-2.4195
Dispersion 0.044 (moderate fire)

For easy print and to download

Properties of Common Abrasives

Properties of Common Gemstones

Natural and Simulated Diamonds

Resources and Citations

  • Gem Identification Lab Manual, Gemological Institute of America, 2016. (fluorescence information)
  • Mineralogy Database: Diamond
  • Jack Odgen, Jewellery of the Ancient World, Rizzoli International Publications Inc., New York City, 1982
  • R.F.Symmes, T.T.Harding, Paul Taylor, Rocks, Fossils and Gems, DK Publishing, Inc., New York City, 1997
  • Encyclopedia Britannica, http://www.britannica.com Comment: "diamond" [Accessed March 4, 2002].
  • Website: http://www.geo.utexas.edu/courses/347k/redesign/gem_notes/Diamond/diamond_triple_frame.htm (fluorescence information)
  • Wikipedia: http://en.wikipedia.org/wiki/Diamond (Accessed Mar. 1, 2006) (synonyms)
  • Yasukazu Suwa, Gemstones: Quality and Value, Volume 1, Sekai Bunka Publishing Inc., Tokyo, 1999 Comment: RI=2.417; Specific gravity=3.52;
  • Michael O'Donoghue and Louise Joyner, Identification of Gemstones, Butterworth-Heinemann, Oxford, 2003 Comment: RI=2.417; Specific gravity=3.52; dispersion=0.44
  • Van Nostrand's Scientific Encyclopedia, Douglas M. Considine (ed.), Van Nostrand Reinhold, New York, 1976
  • The American Heritage Dictionary or Encarta, via Microsoft Bookshelf 98, Microsoft Corp., 1998
  • G.S.Brady, Materials Handbook, McGraw-Hill Book Co., New York, 1971
  • Michael McCann, Artist Beware, Watson-Guptill Publications, New York City, 1979
  • R.M.Organ, Design for Scientific Conservation of Antiquities, Smithsonian Institution, Washington DC, 1968
  • Thomas B. Brill, Light Its Interaction with Art and Antiquities, Plenum Press, New York City, 1980
  • CRC Handbook of Chemistry and Physics, Robert Weast (ed.), CRC Press, Boca Raton, Florida, v. 61, 1980 Comment: density=3.01-3.52