The genetic association of adakites and Cu-Au ore deposits

Adakites may form by partial melting of either the subducting oceanic lithosphere or the lower part of the continental crust. These two magma types can be discriminated geochemically using a combination of La/Yb, Sr/Y ratios, MgO and Na 2 O contents, and Sr-Nd isotopes. Given that the basaltic crust...

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Bibliographic Details
Published in:International Geology Review 2011-04, Vol.53 (5-6), p.691-703
Main Authors: Sun, Weidong, Zhang, Hong, Ling, Ming-Xing, Ding, Xing, Chung, Sun-Lin, Zhou, Jibin, Yang, Xiao-Yong, Fan, Weiming
Format: Article
Language:English
Subjects:
adakite
Copper
Crystallization
Crystals
Cu-Au ore deposit
Deposits
Differentiation
Geology
Isotopes
Lava
Melting
Mineralization
oxides
Reviews
slab melting
subduction
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Summary:Adakites may form by partial melting of either the subducting oceanic lithosphere or the lower part of the continental crust. These two magma types can be discriminated geochemically using a combination of La/Yb, Sr/Y ratios, MgO and Na 2 O contents, and Sr-Nd isotopes. Given that the basaltic crust has Cu concentrations more than two times higher than the lower continental crust and the mantle wedge, 'primitive' adakites produced by oceanic slab melting should contain significantly higher Cu contents than adakites derived from the continental crust, as well as normal arc andesites. A globally compiled dataset shows that Cu concentrations in adakites are generally lower than that in normal arc rocks. We attribute this low copper content to loss of magmatic fluids as a result of sulphate reduction during adakitic magma differentiation, in turn induced by the crystallization of Fe-Ti oxides, essential to mineralization. Therefore, the underflow of oceanic-slab-derived adakites that can release larger amounts of Cu (presumably Au as well) by crystal fractionation leads to higher potential for Cu-Au mineralization along convergent margins, usually associated with ridge subduction. Such basaltic slab melts initially have considerably higher Cu contents and thus play a crucial role particularly in the relatively closed magma system responsible for generating porphyry Cu deposits.
ISSN:0020-6814
1938-2839
DOI:10.1080/00206814.2010.507362