Wenjiite

Ti10SixPy; x>y, 6≤(x+y)≤7
IMA status
  • Approved
IMA symbol
Wnj
Also known as
  • IMA2019-107c
  • Wenjiiet

Where it forms, where it's found

Geological setting

In corundum from a podiform chromitite.

Type locality
Orebody CR-11
  1. Kangjinla Cr deposit
  2. Luobusha ophiolite ("Luobusa ophiolite")
  3. Qusum Co. (Qusong Co.)
  4. Shannan Prefecture (Lhokha Prefecture
  5. Lhoka Prefecture)
  6. Tibet
  7. China

29.1833°, 92.3000°

3recorded occurrences
Source · OpenStreetMap

Physical

Hardness
123456789106.5/ 10 MOHS
  1. 1Talc
  2. 2Gypsum
  3. 3Calcite
  4. 4Fluorite
  5. 5Apatite
  6. 6Orthoclase
  7. 7Quartz
  8. 8Topaz
  9. 9Corundum
  10. 10Diamond
Colour
Silver gray (synthetic)
Density
4.762 g/cm³

Crystallography

Crystal system
Hexagonal
Space group
P63/mcm
Cell parameters
a = 7.30(10) Å · c = 5.09(10) Å
Z
1
Twinning

Not noted in type material, but it has been noted in synthetic material.

Type-locality form

With kangjinlaite in a spheroid 20 μm across enclosed in corundum; as an overgrowth up to 20 μm thick around a jingsuiite grain; a platelet in a lamellar intergrowth with jingsuiite, khamrabaevite-osbornite and deltalumite; and as two grains up to 20 μm in the longest dimension with other minerals.

Synonyms

  • IMA2019-107c
  • Wenjiiet

In other languages

German
IMA 2019-107c · Wenjiit

Classification

Strunz
10th ed.

1.B0

  • 1ElementsClass
  • 1.BMetallic Carbides, Silicides, Nitrides, Phosphides and HydridesDivision
  • 1.B0— unnamed intermediate level —Group
  • 1.B0WenjiiteSpecies

Group, growth & confusion

Commonly confused with
2 minerals

Literature, links & citation

Citations
  1. 1955Krikorian, O.H. (1955) High temperature studies: I. Reactions of the Refractory Silicides with Carbon and with Nitrogen. II. Thermodynamic Properties of the Carbides. III. Heat of Formation of the 3πu State of C2 from Graphite. Lawrence Berkeley National Radiation Laboratory. Ph.D. Thesis.
  2. 2004Frommeyer, G., Rosenkranz, R. (2004) Structures and properties of the refractory silicides Ti5Si3 and TiSi2 and Ti-Si-(Al) eutectic alloys. In: Senkov, O.N.; Miracle, D.B.; Firstov, S.A. Metallic Materials with High Structural Efficiency, NATO Science Series, Series II: Mathematics, Physics and Chemistry, 146, 287-308.
  3. 2021Miyawaki, Ritsuro, Hatert, Frédéric, Pasero, Marco, Mills, Stuart J. (2021) IMA Commission on New Minerals, Nomenclature and Classification (CNMNC) – Newsletter 61. European Journal of Mineralogy, 33 (3) 299-304 doi:10.5194/ejm-33-299-2021 DOI: 10.5194/ejm-33-299-2021
  4. 2022(2022) Wenjiite. Handbook of Mineralogy. Mineralogical Society of America
  5. 2023Xiong, Fahui, Xu, Xiangzhen, Mugnaioli, Enrico, Gemmi, Mauro, Wirth, Richard, Yang, Jingsui, Grew, Edward S. (2023) Wenjiite, Ti10(Si,P,☐)7, and kangjinlaite, Ti11(Si,P)10, new minerals in the ternary Ti-P-Si system from the Luobusa ophiolite, Tibet, China. American Mineralogist, 108 (1) 197-210 doi:10.2138/am-2022-8226DOI: 10.2138/am-2022-8226
Cite this entry
@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Wenjiite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/wenjiite-55445},
  note      = {Accessed 2026-05-11}
}