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Title: Nickeline  
Author: World Heritage Encyclopedia
Language: English
Subject: Sulfide minerals, Polonide, WikiProject Rocks and minerals/Worklist, Nickel, Magnesium polonide
Collection: Arsenide Minerals, Hexagonal Minerals, Nickel Minerals
Publisher: World Heritage Encyclopedia


Category Arsenide mineral
(repeating unit)
nickel arsenide (NiAs)
Strunz classification 02.CC.05
Crystal symmetry Hexagonal (6/m 2/m 2/m)
Unit cell a = 3.602 Å, c = 5.009 Å Z=2
Color Pale copper red with blackish tarnish. white with strong yellowish pink hue on polished section strongly anisotorpic
Crystal habit Massive columnar to reniform, rarely as distorted, horizontally striated, {1011} terminated crystals
Crystal system Hexagonal dihexagonal dipyramidal
Twinning On {1011} producing fourlings
Cleavage {1010} Imperfect, {0001} Imperfect
Fracture Conchoidal
Tenacity Brittle
Mohs scale hardness 5 - 5.5
Luster metallic
Streak brownish black
Specific gravity 7.8
Pleochroism Strong (reflected light)
Fusibility 2
Other characteristics garlic odor on heating
References [1][2][3]

Nickeline or niccolite is a mineral consisting of nickel arsenide (NiAs) containing 43.9% nickel and 56.1% arsenic.

Small quantities of sulfur, iron and cobalt are usually present, and sometimes the arsenic is largely replaced by antimony. This last forms an isomorphous series with breithauptite (nickel antimonide).


  • Etymology and history 1
  • Preparation of NiAs 2
  • Occurrence 3
  • Crystal structure 4
  • Economic Importance 5
  • References 6

Etymology and history

When, in the medieval German Erzgebirge, or Ore Mountains, a red mineral resembling copper-ore was found, the miners looking for copper could extract none from it, as it contains none; worse yet, the ore also sickened them. They blamed a mischievous sprite of German mythology, Nickel (similar to Old Nick) for besetting the copper (German: Kupfer): the mischievous Kupfernickel.[4] This German equivalent of "copper-nickel" was used as early as 1694 (other old German synonyms are Rotnickelkies and Arsennickel).

In 1751, Baron Axel Fredrik Cronstedt was attempting to extract copper from kupfernickel mineral, and obtained instead a white metal that he called after the spirit, nickel.[5] In modern German, Kupfernickel and Kupfer-Nickel designates the alloy Cupronickel.

The names subsequently given to the ore, nickeline from F. S. Beudant, 1832, and niccolite, from J. D. Dana, 1868, refer to the presence of nickel; in Latin, niccolum.

In 1971, the International Mineralogical Association recommended use of the name nickeline rather than niccolite.[6]

Preparation of NiAs

The main compound within nickeline, nickel arsenide (NiAs), can be prepared by direct combination of the elements:

Ni(s) + As(s) → NiAs(s)[7]


Nickeline is formed by hydrothermal modification of ultramafic rocks and associated ore deposits, and may be formed by replacement of nickel-copper bearing sulfides (replacing pentlandite, and in association with copper arsenic sulfides), or via metasomatism of sulfide-free ultramafic rocks, where metasomatic fluids introduce sulfur, carbonate, and arsenic. This typically results in mineral assemblaged including millerite, heazelwoodite and metamorphic pentlandite-pyrite via sulfidation and associated arsenopyrite-nickeline-breithauptite.

Associated minerals include: arsenopyrite, barite, silver, cobaltite, pyrrhotite, pentlandite, chalcopyrite, breithauptite and maucherite. Nickeline alters to annabergite (a coating of green nickel arsenate) on exposure to moist air.

Most of these minerals can be found in the areas surrounding Sudbury and Cobalt, Ontario. Other localities include the eastern flank of the Widgiemooltha Dome, Western Australia, from altered pentlndite-pyrite-pyrrhotite assemblages within the Mariners, Redross and Miitel nickel mines where nickeline is produced by regional Au-As-Ag-bearing alteration and carbonate metasomatism. Other occurrences include within similarly modified nickel mines of the Kambalda area.

Crystal structure

The unit cell of nickeline is used the prototype of a class of solids with similar crystal structures. Compounds adopting the NiAs structure are generally the chalcogenides, arsenides, antimonides and bismuthides of transition metals. Members of this group include cobalt(II) sulfide and iron(II) sulfide.

The unit cell of nickel arsenide

The following are the members of the nickeline group:[8]

  • Achavalite: iron selenide, FeSe
  • Breithauptite: nickel antimonide, NiSb
  • Freboldite: cobalt selenide, CoSe
  • Imgreite: nickel telluride, NiTe
  • Langistite: cobalt nickel arsenide, (Co,Ni)As
  • Nickeline: nickel arsenide, NiAs
  • Pyrrhotite: iron sulfide Fe1-xS
  • Sederholmite: nickel selenide, NiSe
  • Stumpflite: platinum antimonide bismuthide, Pt(Sb,Bi)
  • Sudburyite: palladium nickel antimonide, (Pd,Ni)Sb
  • Troilite: iron sulfide, FeS

Economic Importance

Nickeline is rarely used as a source of nickel due to the presence of arsenic, which is deleterious to most smelting and milling techniques. When nickel sulfide ore deposits have been altered to produce nickeline, often the presence of arsenic renders the ore uneconomic when concentrations of As reach several hundred parts per million. However, arsenic bearing nickel ore may be treated by blending with 'clean' ore sources, to produce a blended feedstock which the mill and smelter can handle with acceptable recovery.

The primary problem for treating nickeline in conventionally constructed nickel mills is the specific gravity of nickeline versus that of pentlandite. This renders the ore difficult to treat via the froth flotation technique. Within the smelter itself, the nickeline contributes to high arsenic contents which require additional reagents and fluxes to strip from the nickel metal.


  1. ^ Handbook of Mineralogy
  2. ^
  3. ^ Webmineral data
  4. ^ Chambers Twentieth Century Dictionary, p888, W&R Chambers Ltd, 1977.
  5. ^  
  6. ^ "International Mineralogical Association: Commission on New Minerals and Mineral Names" (PDF). Mineralogical Magazine 38: 104. 1971. 
  7. ^ Shriver and Atkins. Inorganic Chemistry (Fifth Edition). W. H. Freeman and Company, New York, 2010, pp 383.
  8. ^ Mineral Galleries
  • Dana's Manual of Mineralogy ISBN 0-471-03288-3
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