Graeserite

Where it forms, where it's found

In hydrothermal veins in a two-mica paragneiss.

Metamorphosed Precambrian calc-silicate gneissic rock in the footwall of a Zn-Fe-Mn orebody (Sterling Hill, NJ).

Gorb

Lärchultini
Binn
Goms
Valais
Switzerland

46.3638°, 8.2280°

3recorded occurrences

Source · OpenStreetMap

Safety & handling

Physical

Hardness: 1Talc
2Gypsum
3Calcite
4Fluorite
5Apatite
6Orthoclase
7Quartz
8Topaz
9Corundum
10Diamond
Lustre: Metallic
Transparency: Opaque
Colour: Black
Streak: Black
Tenacity: malleable
Cleavage: Distinct/Good
Moderate on (100).
Fracture: Conchoidal
Density: 4.56 g/cm³

Optical

Pleochroism: Non-pleochroic
Optical colour: Grayish white.
Bireflectance: None.
Internal reflections: None.
Tropism: Anisotropic
Reflectance R%: (20.1,20.8) 460, (19.6,20.3) 480, (18.7,19.3) 540, (18.2,18.9) 580, (17.5,18.1) 660
Notes: A full-spectrum reflectance plot given in Krzemnicki and Reusser (1998).

Reflected-light panel

R̄ 18.8 %anisotropic · dual curve

Specimen sRGB 156, 111, 63

White reference100 % reflector under same lamp

R₁ R₂

Wavelength550 nm · R 18.6 %Stage rotation0°

Mode

Bireflectance: None.
Reflected colour: Grayish white.
Internal reflections: None.

Crystallography

Crystal system: Monoclinic
Space group: C2/m
Cell parameters: a = 5.0225(7) Å · b = 14.3114(18) Å · c = 7.1743(9) Å
Cell angles: β = 104.878(3) °
Ratio a:b:c: 1 : 2.849 : 1.428
Unit cell volume: 498.39 Å³
Twinning: Common, parallel to c axis.
Type-locality form: Needle-shaped (<10 µm thick, up to 5 mm long). Occasionally, occurs in radial aggregates.
Comment: example, Biagoni et al. (2020)

Crystal structure

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
8OOxygen Oxygen 14 15.999 223.986
33.59%
26FeIron Iron 4 55.845 223.380
33.50%
22TiTitanium Titanium 3 47.867 143.601
21.53%
33AsArsenic Arsenic 1 74.922 74.922
11.23%
1HHydrogen Hydrogen 1 1.008 1.008
0.15%
Total 666.897 100.00%
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
8OOxygen	Oxygen	14	15.999	223.986	33.59%
26FeIron	Iron	4	55.845	223.380	33.50%
22TiTitanium	Titanium	3	47.867	143.601	21.53%
33AsArsenic	Arsenic	1	74.922	74.922	11.23%
1HHydrogen	Hydrogen	1	1.008	1.008	0.15%
	Total	666.897	100.00%

Synonyms

Graeseriet
IMA1996-010

In other languages

German: Graeserit · IMA 1996-010
Italian: Graeserite
Chinese: 砷铁钛矿

Classification

Strunz

10th ed.

4.JB.55

4OxidesClass
4.JArsenites, antimonites, bismuthites, sulfites, selenites, tellurites; iodatesDivision
4.JBArsenites, antimonites, bismuthites; with additional anions, without H₂OGroup
4.JB.55GraeseriteSpecies

Literature, links & citation

Citations

1998Krzemnicki, M.S. and Reusser, E. (1998) Graeserite, Fe4Ti3AsO13(OH), a new mineral species of the derbylite group from the Monte Leone Nappe, Binntal region, Western Alps, Switzerland. The Canadian Mineralogist: 36: 1083–1088.
1998Berlepsch, P. and Armbruster, T. (1998) The crystal structure of Pb²⁺–bearing graeserite, Pb_0.14(Fe,Ti)₇AsO_12+x(OH)_2–x, a mineral of the derbylite group. Schweizerische Mineralogische und Petrographische Mitteilungen: 78: 1–9.
2006Verbeek, E., Orosz, J., and Nikischer, T. (2006) Graeserite: a second world occurrence from Sterling Hill, Ogdensburg, New Jersey. Mineral News: 22(9): 8-9.
2020Biagioni, Cristian, Bonaccorsi, Elena, Perchiazzi, Natale, Hålenius, Ulf, Zaccarini, Federica (2020) Derbylite and graeserite from the Monte Arsiccio mine, Apuan Alps, Tuscany, Italy: occurrence and crystal-chemistry. Mineralogical Magazine, 84 (5) 766-777 doi:10.1180/mgm.2020.67DOI: 10.1180/mgm.2020.67
2022(2022) Graeserite. Handbook of Mineralogy. Mineralogical Society of America

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Graeserite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/graeserite-6977},
  note      = {Accessed 2026-05-11}
}