Grokhovskyite

Where it forms, where it's found

Geological setting: small sulfide inclusions (up to 50–80 µm) in Ni-rich iron (kamacite) seem to form due to high-temperature (>1000 °C) separation of Fe-Cr sulfide liquid, which is locally enriched in Cu, from Fe-Ni metal melt.
Type locality: Uakit iron meteorite
Baunt District
Buryatia
Russia
55.4964°, 113.5631°

4recorded occurrences

Source · OpenStreetMap

Physical

Hardness: 1Talc
2Gypsum
3Calcite
4Fluorite
5Apatite
6Orthoclase
7Quartz
8Topaz
9Corundum
10Diamond
Transparency: Opaque
Colour: yellow–brown
Streak: black
Tenacity: brittle
Cleavage: None Observed
Density: 4.599 g/cm³

Optical

Pleochroism: Weak
from gray to light gray.
Optical colour: gray to light gray color with yellow tint in reflected light
Anisotropism: weak to medium
Bireflectance: weak to medium
Tropism: Anisotropic
Reflectance R%: (30.16,29.51) 470, (31.53,31.32) 546, (31.90,31.52) 589, (32.36,31.82) 650
UV response: none

Reflected-light panel

R̄ 31.5 %anisotropic · dual curve

Specimen sRGB 204, 141, 75

White reference100 % reflector under same lamp

R₁ R₂

Wavelength550 nm · R 31.6 %Stage rotation0°

Mode

Bireflectance: weak to medium
Anisotropism: weak to medium
Reflected colour: gray to light gray color with yellow tint in reflected light

Crystallography

Crystal system: Trigonal
Space group: R3m
Cell parameters: a = 3.4794(8) Å · c = 18.702(4) Å
Type-locality form: The grain sizes of this mineral are usually less than 5 μm, and the biggest detected crystals are 10 × 5 μm in size. the mineral forms elongated splintered crystals, or, rarely, needle-shaped grains in daubréelite.

Crystal structure

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
16SSulfur Sulfur 2 32.060 64.120
35.69%
29CuCopper Copper 1 63.546 63.546
35.37%
24CrChromium Chromium 1 51.996 51.996
28.94%
Total 179.662 100.00%
Mass share = atoms × atomic mass ÷ molar mass × 100
From IMA formula

Mass composition breakdown
Element	Atoms	At. mass g/mol	Mass g/mol	Mass share
16SSulfur	Sulfur	2	32.060	64.120	35.69%
29CuCopper	Copper	1	63.546	63.546	35.37%
24CrChromium	Chromium	1	51.996	51.996	28.94%
	Total	179.662	100.00%

Synonyms

Grokhovskyiet

In other languages

German: Grokhovskyit · IMA 2019-065

Classification

Strunz

10th ed.

2.CA.25

2Sulfides and SulfosaltsClass
2.CMetal Sulfides, M: S = 1: 1 (and similar)Division
2.CAWith CuGroup
2.CA.25GrokhovskyiteSpecies

Literature, links & citation

Citations

2018Sharygin, V. (2018) Phase CuCrS2 in iron meteorite Uakit (IIAB), Buryatia: preliminary data. IX Russian Young Scientists Conference “Minerals: structure, properties, investigation methods”, Ekaterinburg, Russia: 229.
2019Bevan, Alex W. R., Downes, Peter J., Henry, Dermot A., Verrall, Michael, Haines, Peter W. (2019) The Gove relict iron meteorite from Arnhem Land, Northern Territory, Australia. Meteoritics & Planetary Science, 54 (8) 1710-1719 doi:10.1111/maps.13307DOI: 10.1111/maps.13307
2020Sharygin, Victor V. (2020) CuCrS2 Phase in Uakit Iron Meteorite (IIAB), Buryatia, Russia: Preliminary Data. In Springer Proceedings in Earth and Environmental Sciences. Springer International Publishing. p.229-236. doi:10.1007/978-3-030-00925-0_34DOI: 10.1007/978-3-030-00925-0_34
2020Miyawaki, Ritsuro, Hatert, Frédéric, Pasero, Marco, Mills, Stuart J. (2020) IMA Commission on New Minerals, Nomenclature and Classification (CNMNC) - Newsletter 52. European Journal of Mineralogy, 32 (1) 1-11 doi:10.5194/ejm-32-1-2020 DOI: 10.5194/ejm-32-1-2020
2022(2022) Grokhovskyite. Handbook of Mineralogy. Mineralogical Society of America

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Grokhovskyite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/grokhovskyite-53721},
  note      = {Accessed 2026-05-11}
}