(Redirected from Ultramafic)'Ultramafic' (or ultrabasic) rocks are
igneous and meta-igneous rocks with very low
silica content (less than 45%), generally >18%
MgO, high
FeO, low
potassium, and are composed of usually greater than 90%
mafic minerals (dark colored, high
magnesium and
iron content). The
Earth's mantle is considered to be composed of ultramafic rocks.
Intrusive ultramafic rocks
Classification diagram for ultramafic rocks. Green area represents typical mantle peridotite.
Intrusive ultramafic rocks are often found in large, layered
ultramafic intrusions where differentiated rock types often occur in layers
[1]. Such
cumulate rock types do not represent the chemistry of the magma from which they crystallized. The ultramafic intrusives include the
dunites,
peridotites and
pyroxenites. Other rare varietis include
troctolite which has a greater percentage of calcic plagioclase. These grade into the
anorthosites.
Gabbro and
norite often occur in the upper portions of the layered ultramafic sequences.
Hornblendite and, rarely phlogopitite are also found.
Volcanic ultramafic rocks
Volcanic ultramafic rocks are rare outside of the
Archaean and are essentially restricted to the
Neoproterozoic or earlier, although some
boninite lavas currently erupted within back-arc basins (Manus Trough, Philippines) verge on being ultramafic. Subvolcanic ultramafic rocks and dykes persist longer, but are also rare. Many of the lavas being produced on
Io may be ultramafic, as evidenced by their temperatures which are higher than terrestrial
mafic eruptions.
Examples include
komatiite[2] and
picritic basalt. Komatiites can be host to ore deposits of nickel
[3].
Ultrapotassic ultramafic rocks
Technically
ultrapotassic rocks and
melilitic rocks are considered a separate group, based on melting model criteria, but there are ultrapotassic and highly silica-under-saturated rocks with >18% MgO. which can be considered "ultramafic".
Ultrapotassic, ultramafic igneous rocks such as
lamprophyre,
lamproite and
kimberlite are known to have reached the surface of the Earth. Although no modern eruptions have been observed, analogues are preserved.
Most of these rocks occur as
dykes,
diatremes,
lopoliths or
laccoliths, and very rarely, intrusions. Most kimberlite and lampproite occurrences occur as
volcanic and subvolcanic diatremes and
maars; lavas are virtually unknown.
Vents of Proterozoic lamproite (
Argyle diamond mine), and Cenozoic lamproite (Gaussberg, Antarctica) are known, as are vents of Devonian lamprophyre (Scotland). Kimberlite pipes in Canada, Russia and South Africa have incompletely-preserved tephra and agglomerate facies.
These are generally
diatreme events and as such are not lava flows although
tephra and ash deposits are partially preserved. These represent low-volume volatile melts and attain their ultramafic chemistry via a different process to typical ultramafic rocks.
Carbonatites are rare high
carbonate, low silica igneous rocks.
Metamorphic ultramafic rocks
Metamorphism of ultramafic rocks in the presence of water and/or carbon dioxide results in two main classes of metamorphic ultramafic rock;
talc carbonate and
serpentinite.
Talc carbonation reactions occur in ultramafic rocks at lower
greenschist through to
granulite facies metamorphism when the rock in question is subjected to metamorphism and the metamorphic fluid has more than 10% molar proportion of
carbon dioxide.
When the metamorphic fluids in contact with the ultramafic rock have less than 10% CO2 the metamorphic reactions favor serpentnitisation reactions, resulting in
chlorite-
serpentine-
amphibole type assemblages.
Distribution in space and time
The majority of ultramafic rocks are exposed in
orogenic belts, and predominate in
Archaean and
Proterozoic terranes. Ultramafic magmas in the
Phanerozoic are rarer, and there are very few recognised true ultramafic lavas in the Phanerozoic.
Many surface exposures of ultramafic rocks occur in
ophiolite complexes where deep mantle-derived rocks have been
obducted onto
continental crust along and above
subduction zones.
Ultramafic rocks and the regolith
Where ultramafic rocks (in particular, the types which have low amounts of nutrient elements such as
calcium,
potassium and
phosphorus) are exposed on the surface, the high metal content of the rocks creates unique vegetation. Examples are the ultramafic woodlands and ultramafic barrens of the
Appalachian mountains and piedmont, the "wet maquis" of the
New Caledonia rain forests, and the ultramafic forests of
Mount Kinabalu and other peaks in
Sabah,
Malaysia. Vegetation is typically stunted, and is sometimes home to
endemic species adapted to the metallic soils.
Often thick,
magnesite-
calcrete caprock, clayey
laterite and
duricrust forms over ultramafic rocks in tropical and subtropical environments. Particular floral assemblages associated with highly
nickeliferous ultramafic rocks are indicative tools for
mineral exploration.
Weathered ultramafic rocks may form
lateritic nickel ore deposits[4][5]
See also
★ Ultramafic rock types:
Peridotite,
dunite,
gabbro,
norite,
essexite
★
Cumulate rocks and rock types:
chromitite,
magnetitite,
anorthosite
★ Ultramafic-associated ore deposits:
Lateritic nickel ore deposits,
kambalda type komatiitic nickel ore deposits,
diamond
★
Kimberlite,
lamproite,
lamprophyre
★
Ophiolite
★
Ultramafic to mafic layered intrusions
★
Igneous differentiation,
fractional crystallisation
References
1. Ballhaus, C.G. & Glikson, A.Y., 1995, Petrology of layered mafic-ultramafic intrusions of the Giles Complex, western Musgrave Block, central Australia. AGSO Journal, 16/1&2: 69-90.
2. Hill R.E.T, Barnes S.J., Gole M.J., and Dowling S.E., 1990. Physical volcanology of komatiites; A field guide to the komatiites of the Norseman-Wiluna Greenstone Belt, Eastern Goldfields Province, Yilgarn Block, Western Australia., Geological Society of Australia. ISBN 0-909869-55-3
3. Lesher, C.M., Arndt, N.T., and Groves, D.I., 1984, Genesis of komatiite-associated nickel sulphide deposits at Kambalda, Western Australia: A distal volcanic model, in Buchanan, D.L., and Jones, M.J. (Editors), Sulphide Deposits in Mafic and Ultramafic Rocks, Institution of Mining and Metallurgy, London, p. 70-80.
4. Golightly, J.P. (1981): Nickeliferous Laterite Deposits. Economic Geology 75, 710-735
5. Schellmann, W. (1983): Geochemical principles of lateritic nickel ore formation. Proceedings of the 2. International Seminar on Lateritisation Processes, Sao Paulo, 119-135
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