Emmonsite

Where it forms, where it's found

Geological setting: Oxidized zones of tellurium-bearing ore bodies.
Type locality: Tombstone
Tombstone Mining District
Cochise County
Arizona
USA
31.7128°, -110.0669°

37recorded occurrences

Source · OpenStreetMap

Physical

Hardness: 1Talc
2Gypsum
3Calcite
4Fluorite
5Apatite
6Orthoclase
7Quartz
8Topaz
9Corundum
10Diamond
Lustre: Vitreous
Transparency: Translucent
Colour: Yellowish-green · light yellow-green in transmitted light.
Cleavage: Perfect
On (010), perfect plus 2 unequal cleavages inclined relative to it, making plane angles of 85° and 95° in (010).
Density: 4.52 g/cm³

Optical

Optical type: Biaxial (-) · 2V measured = 23° · 2V calc = 28 – 48°
Refractive index: 1.962 – 2.12
Surface relief: Very high
Principal indices: n_α 1.962 · n_β 2.09 · n_γ 2.1 – 2.12
Pleochroism: Weak
Dispersion: relatively strong r > v

Michel-Lévy diagramhighlighted lineδ = 0.1480

Attainable Michel-Lévy rangeΔ ∈ [0, t·δ_max]1480 nm3rd 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°

Retardation1480 nm

Order3rd order

XPL colour

Crystallography

Crystal system: Triclinic
Space group: #2
Cell parameters: a = 7.90(1) Å · b = 8.00(1) Å · c = 7.62(1) Å
Cell angles: α = 96.73 ° · β = 95 ° · γ = 84.47 °
Ratio a:b:c: 1 : 1.013 : 0.965
Z: 2
Morphology: Radially-configured or lichen-like groups of rough, acicular crystals; druses of thin scales; compact microcrystalline masses. Fibrous crusts with a small botryoidal surface to isolated globular aggregates.
Twinning: Observed in microscopic crystals (Goldfield, Nevada).

Crystal structure

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
52TeTellurium Tellurium 3 127.600 382.800
56.75%
8OOxygen Oxygen 11 15.999 175.989
26.09%
26FeIron Iron 2 55.845 111.690
16.56%
1HHydrogen Hydrogen 4 1.008 4.032
0.60%
Total 674.511 100.00%
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
52TeTellurium	Tellurium	3	127.600	382.800	56.75%
8OOxygen	Oxygen	11	15.999	175.989	26.09%
26FeIron	Iron	2	55.845	111.690	16.56%
1HHydrogen	Hydrogen	4	1.008	4.032	0.60%
	Total	674.511	100.00%

Synonyms

Durdenite
Emmonsiet
Emmonsite (of Hillebrand)

In other languages

French: emmonsite
German: Emmonsit
Spanish: Emmonsita
Italian: Emmonsite
Chinese: 碲铁石

Classification

Strunz

10th ed.

4.JM.10

4OxidesClass
4.JArsenites, antimonites, bismuthites, sulfites, selenites, tellurites; iodatesDivision
4.JMTellurites without additional anions, with H₂OGroup
4.JM.10EmmonsiteSpecies

Dana

8th ed.

34.03.03.01

34Selenites, Tellurites and SulfitesClass
34.03A₂(XO₃)₃·xH₂OType
34.03.03— unnamed intermediate level —Group
34.03.03.01EmmonsiteSpecies

CIM

—

28.3.21

28Selenites, Selenates, Tellurites, and TelluratesClass
28.3TelluritesGroup
28.3.21EmmonsiteSpecies

Literature, links & citation

Citations

—Proceedings of the Colorado Scientific Society: 2: 45-46.
1885Hillebrand, W.F. (1885) Emmonsite, a ferric tellurite. Proceedings of the Colorado Scientific Society: 2: 20-23.
1890Dana, E.S, Wells, H.L. (1890) On some selenium and tellurium minerals from Honduras. American Journal of Science: 40: 78-82 (as Durdenite).
1904Schaller in: Hillebrand, W.F. (1904) Emmonsite (?) from a new locality. American Journal of Science: 18: 433-434.
1921Larsen, Esper S. (1921) The microscopic determination of the nonopaque minerals. Bulletin 679. US Geological Survey doi:10.3133/b679 DOI: 10.3133/b679

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Emmonsite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/emmonsite-1377},
  note      = {Accessed 2026-05-11}
}