TY - JOUR
T1 - Are A-type granites the high-temperature felsic granites? Evidence from fractionated granites of the Wangrah Suite
AU - King, P. L.
AU - Chappell, B. W.
AU - Allen, C. M.
AU - White, A. J.R.
PY - 2001
Y1 - 2001
N2 - A-type granites are a minor, but distinctive, component of the granites of the Lachlan Fold Belt of southeastern Australia. They are felsic rocks with SiO2 contents ranging from 69.7 to 77.1%, with an average of 73.8% (55 analyses). When unfractionated, as evidenced by high Ba contents, they are distinguished from felsic l-type granites by a greater abundance of high-field-strength elements, such as Zr. The Wangrah Suite contains a diverse association of A-type granites, comprising four main units with coherent geochemical trends overall, but with textural variation from equigranular through to porphyritic. The least felsic granites from the suite (Danswell Creek Granite ∼70% SiO2) have compositional features that suggest that they represent parental magma compositions. The most felsic granites (Dunskeig Granite ∼76% SiO2) were derived from such compositions by fractional crystallisation. The Wangrah Suite granites were emplaced at shallow levels (∼200 MPa), at high zircon saturation temperatures (>830°C) and relatively low water activity. The chemical composition of the Wangrah granites cannot be easily related to the adjacent mafic magmas. The compositionally variable Wangrah Suite differs from the homogeneous A-type suites, such as the Gabo Suite to the southeast. Its variability is probably related to the efficiency of fractional crystallisation and emplacement along a major fault at shallow levels. We favour a single-stage petrogenetic scheme where the A-type magmas were produced by high-temperature, partial melting of quartzo-feldspathic crustal rocks. The relatively refractory nature of the source rocks may have been due to limited H2O content, relatively low fo2 and relatively high (TiO2 + FeOtotal)/MgO.
AB - A-type granites are a minor, but distinctive, component of the granites of the Lachlan Fold Belt of southeastern Australia. They are felsic rocks with SiO2 contents ranging from 69.7 to 77.1%, with an average of 73.8% (55 analyses). When unfractionated, as evidenced by high Ba contents, they are distinguished from felsic l-type granites by a greater abundance of high-field-strength elements, such as Zr. The Wangrah Suite contains a diverse association of A-type granites, comprising four main units with coherent geochemical trends overall, but with textural variation from equigranular through to porphyritic. The least felsic granites from the suite (Danswell Creek Granite ∼70% SiO2) have compositional features that suggest that they represent parental magma compositions. The most felsic granites (Dunskeig Granite ∼76% SiO2) were derived from such compositions by fractional crystallisation. The Wangrah Suite granites were emplaced at shallow levels (∼200 MPa), at high zircon saturation temperatures (>830°C) and relatively low water activity. The chemical composition of the Wangrah granites cannot be easily related to the adjacent mafic magmas. The compositionally variable Wangrah Suite differs from the homogeneous A-type suites, such as the Gabo Suite to the southeast. Its variability is probably related to the efficiency of fractional crystallisation and emplacement along a major fault at shallow levels. We favour a single-stage petrogenetic scheme where the A-type magmas were produced by high-temperature, partial melting of quartzo-feldspathic crustal rocks. The relatively refractory nature of the source rocks may have been due to limited H2O content, relatively low fo2 and relatively high (TiO2 + FeOtotal)/MgO.
KW - A-type granite
KW - Lachlan Fold Belt
KW - Wangrah Suite
KW - Zircon saturation temperature
UR - http://www.scopus.com/inward/record.url?scp=0034902729&partnerID=8YFLogxK
U2 - 10.1046/j.1440-0952.2001.00881.x
DO - 10.1046/j.1440-0952.2001.00881.x
M3 - Article
SN - 0812-0099
VL - 48
SP - 501
EP - 514
JO - Australian Journal of Earth Sciences
JF - Australian Journal of Earth Sciences
IS - 4
ER -