Lawrencite

Where it forms, where it's found

Iron meteorite.

Fissures in iron meteorites; sublimation product in volcanic fumaroles.

Tazewell meteorite

Claiborne County
Tennessee
USA

36.4333°, -83.7500°

29recorded occurrences

Source · OpenStreetMap

Physical

Transparency: Translucent
Colour: White (unoxidized) · green to brown (oxidized)
Cleavage: Perfect
On (0001) ?
Density: 3.16 g/cm³

Optical

Optical type: Uniaxial (-)
Refractive index: 1.576
Surface relief: Moderate
Principal indices: n_ω 1.576 · n_ε 1.576

Michel-Lévy diagramhighlighted lineδ = 0.0000

Attainable Michel-Lévy rangeΔ ∈ [0, t·δ_max]0 nm1st order

Δ = 0Δ_max

Section thickness10 μmStage rotation0°

Thin-section mosaic70 grains · random 3D orientations

PPL

pleochroism per grain

XPL

independent extinctions · rotate the stage

Interference simulatorsingle grain · PPL ↔ XPL

PPL

pleochroism only · colour blends on rotation

XPL

interference colour · extinct every 90°

Retardation0 nm

Order1st order

XPL colour

Crystallography

Crystal system: Trigonal
Space group: R-3m
Cell parameters: a = 3.58 Å · c = 17.57 Å
Z: 3
Morphology: Crystals are thin hexagonal plates (0001) (artificial). Massive only in natural material.

Crystal structure

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
17ClChlorine Chlorine 2 35.450 70.900
55.94%
26FeIron Iron 1 55.845 55.845
44.06%
Total 126.745 100.00%
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
17ClChlorine	Chlorine	2	35.450	70.900	55.94%
26FeIron	Iron	1	55.845	55.845	44.06%
	Total	126.745	100.00%

Synonyms

Chlorure de fer
Eisenchlorür
Ferro muriato
Lawrenciet

In other languages

German: Lawrencit
Italian: Lawrencite · Malattia da Lawrencite

Classification

Strunz

10th ed.

3.AB.20

3HalidesClass
3.ASimple halides, without H₂ODivision
3.ABM:X = 1:2Group
3.AB.20LawrenciteSpecies

Dana

8th ed.

09.02.03.01

09Normal HalidesClass
09.02AX₂Type
09.02.03— unnamed intermediate level —Group
09.02.03.01LawrenciteSpecies

CIM

—

8.11.10

8Halides - Fluorides, Chlorides, Bromides and Iodides; also Fluoborates and FluosilicatesClass
8.11Halides of Fe and NiGroup
8.11.10LawrenciteSpecies

Group, growth & confusion

3 members

2 minerals

Literature, links & citation

Citations

1845Jackson, C.T. (1845) Remarks on the Alabama meteoric iron, with a chemical analysis of the drops of green liquid which exude from it. American Journal of Science: 48: 146.
1845Hayes, A.A. (1845) Letter from Mr A.A. Hayes on the same subject, with remarks on the origin of the chlorine found in the Alabama Iron, and a description of new methods employed in the analysis of meteoric irons. American Journal of Science: 48: 153.
1855Smith, J.L. (1855) Memoir on Meteorites - A description of five new meteoric irons, with some theoretical considerations on the origin of Meteorites based on their physical and chemical properties. American Journal of Science: 19: 153-163 (159).
1877Smith, J.L. (1877) Examination of the Waconda meteoric stone, Bates County meteoric iron and Rockingham County meteoric iron. American Journal of Science: 13: 211-214.
1877Daubrée, G.A. (1877) Observations sur la structure intérieure d'une des masses de fer natif d'Ovifak. Comptes Rendus Hebdomadaires des Séances de l’Académie des Sciences: 84: 66-70.

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Lawrencite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/lawrencite-2351},
  note      = {Accessed 2026-05-11}
}