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sulfate mineral

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Also known as: sulphate mineral
Sulfate also spelled:
Sulphate
Related Topics:
gypsum
alum
alunite
chalcanthite
anhydrite

sulfate mineral, any naturally occurring salt of sulfuric acid. About 200 distinct kinds of sulfates are recorded in mineralogical literature, but most of them are of rare and local occurrence. Abundant deposits of sulfate minerals, such as barite and celestite, are exploited for the preparation of metal salts. Many beds of sulfate minerals are mined for fertilizer and salt preparations, and beds of pure gypsum are mined for the preparation of plaster of paris.

Sulfate minerals
name colour lustre Mohs hardness specific gravity
alum colourless; white vitreous 2–2½ 1.8
alunite white; grayish, yellowish, reddish, reddish brown vitreous 3½–4 2.6–2.9
alunogen white; yellowish or reddish vitreous to silky 1½–2 1.8
anglesite colourless to white; often tinted gray, yellow, green, or blue adamantine to resinous or vitreous 2½–3 6.4
anhydrite colourless to bluish or violet vitreous to pearly 3.0
antlerite emerald to blackish green; light green vitreous 3.9
barite colourless to white; also variable vitreous to resinous 3–3½ 4.5
botryogen light to dark orange red vitreous 2–2½ 2.1
brochantite emerald to blackish green; light green vitreous 3½–4 4.0
caledonite deep verdigris green or bluish green resinous 2½–3 5.8
celestite pale blue; white, reddish, greenish, brownish vitreous 3–3½ 4.0
chalcanthite various shades of blue vitreous 2.3
coquimbite pale violet to deep purple vitreous 2.1
epsomite colourless; aggregates are white vitreous; silky to earthy (fibrous) 2–2½ 1.7
glauberite gray; yellowish vitreous to slightly waxy 2½–3 2.75–2.85
gypsum colourless; white, gray, brownish, yellowish (massive) subvitreous 2 (a hardness standard) 2.3
halotrichite colourless to white vitreous 1.5 1.7 (pick) to 1.9 (halo)
jarosite ochre yellow to dark brown subadamantine to vitreous; resinous on fracture 2½–3½ 2.9–3.3
kainite colourless; gray, blue, violet, yellowish, reddish vitreous 2½–3 2.2
kieserite colourless; grayish white, yellowish vitreous 3.5 2.6
linarite deep azure blue vitreous to subadamantine 2.5 5.3
mirabilite colourless to white vitreous 1½–2 1.5
plumbojarosite golden brown to dark brown dull to glistening or silky soft 3.7
polyhalite colourless; white or gray; often salmon pink from included iron oxide vitreous to resinous 3.5 2.8
thenardite colourless; reddish, grayish, yellowish, or yellow brown vitreous to resinous 2½–3 2.7
name habit fracture or cleavage refractive indices crystal system
alum columnar or granular massive conchoidal fracture n = 1.453–1.466 isometric
alunite granular to dense massive conchoidal fracture omega = 1.572
epsilon = 1.592
hexagonal
alunogen fibrous masses and crusts one perfect cleavage alpha = 1.459–1.475
beta = 1.461–1.478
gamma = 1.884–1.931
triclinic
anglesite granular to compact massive; tabular or prismatic crystals one good, one distinct cleavage alpha = 1.868–1.913
beta = 1.873–1.918
gamma = 1.884–1.931
orthorhombic
anhydrite granular or fibrous massive; concretionary (tripestone) two perfect, one good cleavage alpha = 1.567–1.580
beta = 1.572–1.586
gamma = 1.610–1.625
orthorhombic
antlerite thick tabular crystals one perfect cleavage alpha = 1.726
beta = 1.738
gamma = 1.789
orthorhombic
barite usually in tabular crystals; rosettes (desert roses); massive one perfect, one good cleavage alpha = 1.633–1.648
beta = 1.634–1.649
gamma = 1.645–1.661
orthorhombic
botryogen reniform, botryoidal, or globular aggregates one perfect, one good cleavage alpha = 1.523
beta = 1.530
gamma = 1.582
monoclinic
brochantite prismatic to hairlike crystal and crystal aggregates; granular massive; crusts one perfect cleavage alpha = 1.728
beta = 1.771
gamma = 1.800
monoclinic
caledonite coating of small elongated crystals one perfect cleavage alpha = 1.815–1.821
beta = 1.863–1.869
gamma = 1.906–1.912
orthorhombic
celestite tabular crystals; fibrous massive one perfect, one good cleavage alpha = 1.618–1.632
beta = 1.620–1.634
gamma = 1.627–1.642
orthorhombic
chalcanthite short prismatic crystals; granular masses; stalactites and reniform masses conchoidal fracture alpha = 1.514
beta = 1.537
gamma = 1.543
triclinic
coquimbite prismatic and pyramidal crystals; granular massive omega = 1.536
epsilon = 1.572
hexagonal
epsomite fibrous or hairlike crusts; woolly efflorescences one perfect cleavage alpha = 1.430–1.440
beta = 1.452–1.462
gamma = 1.457–1.469
orthorhombic
glauberite tabular, dipyramidal, or prismatic crystals one perfect cleavage alpha = 1.515
beta = 1.535
gamma = 1.536
monoclinic
gypsum elongated tabular crystals (some 5 ft long; others twisted or bent); granular or fibrous masses; rosettes one perfect cleavage alpha = 1.515–1.523
beta = 1.516–1.526
gamma = 1.524–1.532
monoclinic
halotrichite aggregates of hairlike crystals conchoidal fracture alpha = 1.475–1.480
beta = 1.480–1.486
gamma = 1.483–1.490
monoclinic
jarosite minute crystals; crusts; granular or fibrous massive one distinct cleavage omega = 1.82
epsilon = 1.715
hexagonal
kainite granular massive; crystalline coatings one perfect cleavage alpha = 1.494
beta = 1.505
gamma = 1.516
monoclinic
kieserite granular massive, intergrown with other salts two perfect cleavages alpha = 1.520
beta = 1.533
gamma = 1.584
monoclinic
linarite elongated tabular crystals, either singly or in groups one perfect cleavage; conchoidal fracture alpha = 1.809
beta = 1.839
gamma = 1.859
monoclinic
mirabilite short prisms; lathlike or tabular crystals; crusts or fibrous masses; granular massive one perfect cleavage alpha = 1.391–1.397
beta = 1.393–1.410
gamma = 1.395–1.411
monoclinic
plumbojarosite crusts, lumps, compact masses of microscopic hexagonal plates one fair cleavage omega = 1.875
epsilon = 1.786
hexagonal
polyhalite fibrous to foliated massive one perfect cleavage alpha = 1.547
beta = 1.560
gamma = 1.567
triclinic
thenardite rather large crystals; crusts, efflorescences one perfect, one fair cleavage alpha = 1.464–1.471
beta = 1.473–1.477
gamma = 1.481–1.485
orthorhombic

All sulfates possess an atomic structure based on discrete insular sulfate (SO42-) tetrahedra, i.e., ions in which four oxygen atoms are symmetrically distributed at the corners of a tetrahedron with the sulfur atom in the centre. These tetrahedral groups do not polymerize, and the sulfate group behaves as a single negatively charged molecule, or complex. Thus, sulfates are distinct from the silicates and borates, which link together into chains, rings, sheets, or frameworks.

Basalt sample returned by Apollo 15, from near a long sinous lunar valley called Hadley Rille.  Measured at 3.3 years old.
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Sulfate minerals can be found in at least four kinds: as late oxidation products of preexisting sulfide ores, as evaporite deposits, in circulatory solutions, and in deposits formed by hot water or volcanic gases. Many sulfate minerals occur as basic hydrates of iron, cobalt, nickel, zinc, and copper at or near the source of preexisting primary sulfides. The sulfide minerals, through exposure to weathering and circulating water, have undergone oxidation in which the sulfide ion is converted to sulfate and the metal ion also is changed to some higher valence state. Noteworthy beds of such oxidation products occur in desert regions, such as Chuquicamata, Chile, where brightly coloured basic copper and ferric iron sulfates have accumulated. The sulfate anions generated by oxidation processes may also react with calcium carbonate rocks to form gypsum, CaSO4·2H2O. Sulfates formed by the oxidation of primary sulfides include antlerite [Cu3(SO4)(OH)4], brochantite [Cu4(SO4)(OH)6], chalcanthite [Cu2+(SO4)·5Η2Ο], anglesite (PbSO4), and plumbojarosite [PbFe3+6(SO4)4(OH)12].

Soluble alkali and alkaline-earth sulfates crystallize upon evaporation of sulfate-rich brines and trapped oceanic salt solutions. Such brines can form economically important deposits of sulfate, halide, and borate minerals in thick parallel beds, as the potash deposits at Stassfurt, Ger., and the southwestern United States. Many of the sulfate minerals are salts of more than one metal, such as polyhalite, which is a combination of potassium, calcium, and magnesium sulfates.

Sulfate minerals common in evaporite deposits include anhydrite, gypsum, thenardite (Na2SO4), epsomite (MgSO4·7H2O), glauberite [Na2Ca(SO4)2], kainite (MgSO4·KCl·3H2O), kieserite (MgSO4·H2O), mirabilite (Na2SO4·10H2O), and polyhalite [K2Ca2Mg(SO4)4·2H2O].

Groundwater carrying sulfate anions reacts with calcium ions in muds, clays, and limestones to form beds of gypsum. The massive material is called alabaster or plaster of paris (originally found in the clays and muds of the Paris basin). If such beds become deeply buried or metamorphosed (altered by heat and pressure), anhydrite may form by dehydration of the gypsum.

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Numerous sulfates, usually simple, are formed directly from hot aqueous solutions associated with fumarolic (volcanic gas) vents and late-stage fissure systems in ore deposits. Noteworthy examples include anhydrite, barite, and celestine.

This article was most recently revised and updated by John P. Rafferty.