Crocoite

History

Grind crocoite to a powder and it turns the orange of saffron threads. That likeness gave the mineral its name. The French mineralogist François Sulpice Beudant coined crocoise in 1832, from the Greek krokos — saffron — for the colour. The word was soon altered to crocoisite, then settled as crocoite.

The mineral was found long before it had that name. It came from the Beresof mines, near Yekaterinburg in the Ural Mountains of Russia. In 1763, the Russian scholar Mikhail Lomonosov recognised it as a red lead ore. Johann Gottlob Lehmann knew the same orange-red stone from that field. In 1766 he described it as Nova Minera Plumbi — a new lead ore. Across Europe it became known as Siberian red lead.

The early names all pointed at the two things anyone could see: lead and the colour red. Werner called it Rothes bleierz — red lead ore — in 1774; Jean-Baptiste Macquart wrote Plomb rouge, red lead, in 1789.

Then a chemist took the stone apart. Louis-Nicolas Vauquelin received samples of the Siberian ore and, in 1797, found a new metallic element hiding inside it. He produced an orange oxide from the crocoite, then heated it with charcoal to isolate the metal itself. He named the element chromium, from the Greek chroma — colour — because its compounds came in so many vivid shades. Martin Klaproth reached the same discovery independently. Crocoite had given the world a new element.

After chromium was announced, the mineral picked up names built on the metal. René Just Haüy called it Plomb chromaté — chromated lead — in 1801, and Johann Hausmann coined Kallochrom in 1813. Beudant's crocoise of 1832 eventually won out. Later writers offered rivals that did not last: Breithaupt's Krokoit in 1841, Shepard's Beresofite in 1844, and Lehmannite, named for Lehmann by Henry Brooke and William Miller in 1852.

The most celebrated crocoite came much later, and from the other side of the world. The Adelaide mine at Dundas, in western Tasmania, is described as probably the prime source of crocoite in the world. Its long, blade-like scarlet crystals are prized by collectors, and the mineral is the official mineral emblem of Tasmania.

Industrial & practical applications

Crocoite has almost no industrial use today. It is lead chromate, and its composition is identical to the artificial product chrome yellow once used as a paint pigment. But that pigment is made synthetically, not mined from crocoite. Chromium for industry now comes from chromite, a far more common ore that displaced crocoite as the metal's main source. Because the mineral carries both lead and hexavalent chromium, it is also toxic, which rules out everyday handling.

What demand exists is from collectors. Crocoite's long, blade-like scarlet crystals make it one of the most prized specimens a cabinet can hold. The Adelaide mine at Dundas, Tasmania, is regarded as probably the prime source in the world. Beyond the specimen trade, the mineral has no current commercial application.

Where it forms, where it's found

Geological setting: Uncommon secondary mineral in lead deposits associated with chromium-bearing rocks.
Type locality: Tsvetnoi Mine
Uspenskaya Hill
Berezovsk deposit
Beryozovsky
Sverdlovsk Oblast
Russia

81recorded occurrences

Source · OpenStreetMap

Safety & handling

Physical

Hardness: 1Talc
2Gypsum
3Calcite
4Fluorite
5Apatite
6Orthoclase
7Quartz
8Topaz
9Corundum
10Diamond
Lustre: Adamantine · vitreous
Transparency: Transparent · Translucent
Colour: Orange · red · yellow · orange-red in transmitted light.
Streak: Yellow-orange
Tenacity: brittle
Cleavage: Poor/Indistinct
Distinct on (110), indistinct on (001) and (100).
Fracture: Conchoidal
Density: 5.97 g/cm³

Optical

Optical type: Biaxial (+) · 2V measured = 57° · 2V calc = 54°
Refractive index: 2.29 – 2.66
Surface relief: Very high
Principal indices: n_α 2.29 · n_β 2.36 · n_γ 2.66
Pleochroism: Weak
X = Red-orange Y = Red-orange Z = Blood red
Dispersion: very strong r > v inclined
Extinction: Y = b; Z ∧ c = 5.5°.
UV response: Not fluorescent in UV.

Michel-Lévy diagramhighlighted lineδ = 0.3700

Attainable Michel-Lévy rangeΔ ∈ [0, t·δ_max]3700 nm7th 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°

Retardation3700 nm

Order7th order

XPL colour

Crystallography

Crystal system: Monoclinic
Cell parameters: a = 7.12 Å · b = 7.421 Å · c = 6.80 Å
Cell angles: β = 102.41 °
Ratio a:b:c: 1 : 1.042 : 0.955
Z: 4
Morphology: Crystals commonly prismatic [001] to acicular crystals with nearly square outline; elongated parallel to [_101]; pseudo-octahedral at times, with (111) (111), or acute rhombohedral with (110) {_h0l}. Faces usually smooth and brilliant; (110) commonly striated [001], and the steep orthodomes rounded or distorted. Crystals are often cavernous or hollow. Massive; imperfectly columnar to granular. Forms include: a(100), b(010), c(001), α(310), d(210), g(320), m(110), ζ(350), f(120), h(101), ρ(502), n(401), χ(801), k(101), x(301), l(401), ε(501), θ(601), w(012), z(011), y(021), t(111), π(221), ϑ(331), s(441), λ(112), γ(223), v(111), e{11.1.1}, ψ(911), G(812), N(711), η(412), q{12.4.1}, L{2.1.10}, g(841), Q(953), H(435), δ{11.10.1}, p{_1_3.1.5}, τ(911), r(612), A(511), R{_1_8.4.1}, ξ(411), β(312), φ(311), F(621), Y(931), B(521), u(211), E(328), o{_8.7.10}, M{6.10.9}, σ(352), i(123), μ(154}, D(265). Also an additional couple dozen probable forms.
Comment: Space group P21/n.

Crystal structure

Chemical composition

Constituent elements: Mass composition breakdown
Element Atoms At. mass g/mol Mass g/mol Mass share
82PbLead Lead 1 207.200 207.200
64.11%
8OOxygen Oxygen 4 15.999 63.996
19.80%
24CrChromium Chromium 1 51.996 51.996
16.09%
Total 323.192 100.00%
Mass share = atoms × atomic mass ÷ molar mass × 100
From IMA formula
Impurities: Zn
S

Mass composition breakdown
Element	Atoms	At. mass g/mol	Mass g/mol	Mass share
82PbLead	Lead	1	207.200	207.200	64.11%
8OOxygen	Oxygen	4	15.999	63.996	19.80%
24CrChromium	Chromium	1	51.996	51.996	16.09%
	Total	323.192	100.00%

Synonyms

Beresofite (of Shepard)
Beresowite (of Shepard)
Bleichromat
Bleiischer Chromspath
Callochrome
Chromate of lead
Chrombleispath
Chromsaures Blei
Crocoise
Crocoisit
Crocoisita
Crocoisite
Kallochrom
Kollochrom
Krokoisit
Lehmannit (nach Brooke)
Lehmannita
Lehmannite (of Brooke)
Minera plumbi rubra
Minera spathiforma rubra
Minerai de plomb rouge
Nova minera plumbi
Plomb chromaté
Plombe rouge de Sibérie
Red lead ore
Red lead-ore from Beresov
Rotbleierz
Rothes Bleierz

In other languages

French: Beresofite · Crocoïse · Crocoïte · Lehmannite (of Brooke) · Minerai de plomb rouge · Plomb chromaté · Plombe rouge de Sibérie
German: Krokoit · Rotbleierz
Spanish: crocoíta
Italian: Crocoite
Portuguese: crocoíta · Crocoíte
Japanese: 紅鉛鉱
Chinese: 铬铅矿
Simplified Chinese: 铬铅矿
Traditional Chinese: 鉻鉛礦
Russian: Красная свинцовая руда · Крокоит
Arabic: كروكوئيت

Classification

Strunz

10th ed.

7.FA.20

7SulfatesClass
7.FChromatesDivision
7.FAWithout additional anionsGroup
7.FA.20CrocoiteSpecies

Dana

8th ed.

35.03.01.01

35Anhydrous ChromatesClass
35.03AXO₄Type
35.03.01— unnamed intermediate level —Group
35.03.01.01CrocoiteSpecies

CIM

—

27.2.5

27Sulphites, Chromates, Molybdates and TungstatesClass
27.2ChromatesGroup
27.2.5CrocoiteSpecies

Group, growth & confusion

3 members

1 mineral

PhoenicochroitePb₂O(CrO₄)
Mineral
—

Literature, links & citation

Citations

1763Lomonossow, Michail Wassiljewitsch (1763) Erste Grundlagen Der Metallurgie Oder Des Huttenwesens.
1766Lehmann, Johann G. (1766) De nova mineral plumbi specie crystallina rubra. Novi Commentarii Academiae Petropolitanae, 12, 356. [as Nova minera Plumbi].
1767Lehmann, Johann G. (1767) Nachricht von einem neu endechten Bleyerze. Neues Hamburg Magazin: 7: 336-348.
1771Pallas, Peter Simon (1771) Reise durch verschiedene Provinzen des russischen Reichs. St. Petersburg, Imperial Academy of Sciences, 2, 235. [as Minerai de plomb rouge].
1774Werner, Abraham Gottlieb (1774) Von den äusserlichen Kennzeichen der Fossilien. Leipzig, 296. [as Rotbleierz and Rothes Bleierz].

Cite this entry

@misc{mineral2026,
  author    = {Mineral Index editorial board},
  title     = {Crocoite — Mineral Index},
  year      = {2026},
  url       = {https://mineralindex.org/minerals/crocoite-1157},
  note      = {Accessed 2026-05-11}
}