Restite



Restite is the residual material left at the site of melting during the in place production of granite through intense metamorphism.

Generally, restite is composed of a predominance of feldspar. When chunks of restite are caught up within the granite it is known as a restite inclusion or enclave.

S-type restite reactions

Restite in S-type granites is produced from the melting, within the crust, of a typical metamorphic mineral assemblage of high-pressure sedimentary origin; 

 biotite + cordierite + residual feldspars

The melt reaction produces a granitic melt and solid orthopyroxene and cordierite.

Cordierite in restite inclusions is unstable at low pressures; this reverts to Al-rich muscovite-feldspar-quartz.

If the restite minerals are carried with the magma, as the minerals become thermo-barometrically unstable during ascent, they will react back with the magma to form biotite from orthopyroxene, and feldspar or mica from cordierite. These reactions also involve consumption of significant quantities of water, and hence, will preclude the generation of a hydrothermal solution.

I-type restite reactions

Restite reactions in I-type granites are essentially similar, but due to the mafic and granitic source rocks, the restite assemblage is predisposed to produce an orthopyroxene + hornblende and plagioclase upon ascent, resorbing water and precluding generation of hydrothermal solutions.

Porphyry copper deposits are generally associated with I-type granites which are not restite mediated.

Importance of restite

Restite is an important constituent in igneous differentiation processes.

Restite acts as a form of buffer within magma, acting as a reservoir primarily of water and water-adsorbent minerals, which may prevent or retard a granitic magma from attaining water mineral redox buffer except in this case it is a mineral-water exchange.

This process occurs by hornblende, which may adsorb up to 5% H2O, and by conversion of pyroxene to hornblende during melting or fractionation at temperatures below the pyroxene stability field. This process is envisaged as, for instance, pyroxene-bearing restite inclusions 'soaking up' water and being converted to hydrous hornblende-bearing inclusions.

Secondly, restite acts as a compositional buffer, providing elements to the surrounding magma as it is melted and ground up by erosive forces within the ascending magma. Restite can, in large enough amounts, retard the compositional changes of a magma either via providing more reagents or physically trapping crystals within the magma.

Generally, restite is not present within magmas in large amounts and thus the effects of the above processes are not usually profound. However, it is likely that, particularly for S-type granite which is formed by wholesale anatexis (melting) of metasedimentary rocks, restite mediated melting and fractionation is crucial to the composition and behaviour of these magmas.

In magmas which do not have a restite component, such as most M-type granites, some A-type granites, and most basaltic magmas, it is much easier for these magmas to achieve more dramatic fractional crystallization effects.

See also

References

  • White, A.J.R., 2001. Water, Restite and Granite Mineralisation, Australian Journal of Earth Sciences, 48, pp 551-555.
 
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