CIG   05423
CENTRO DE INVESTIGACIONES GEOLOGICAS
Unidad Ejecutora - UE
artículos
Título:
Payenia volcanic province, southern Mendoza, Argentina:
Autor/es:
SOAGER, N.; HOLM, P. M.; LLAMBÍAS, E. J.
Revista:
CHEMICAL GEOLOGY
Editorial:
ELSEVIER SCIENCE BV
Referencias:
Lugar: Amsterdam; Año: 2013 vol. 349 p. 36 - 53
ISSN:
0009-2541
Resumen:
The Pleistocene to Holocene Payenia volcanic province is a backarc region of 60,000 km2 in Mendoza, Argentina,
which is dominated by transitional to alkaline basalts and trachybasalts. We present major and trace element
compositions of 139 rocks from this area of which the majority are basaltic rocks with 4 to 12 wt.% MgO and
44 to 50 wt.% SiO2. The southern Payenia province is dominated by intraplate basalts and the trace element patterns
of the Río Colorado and Payún Matrú lavas suggest little or no influence from subducted slab components.
The mantle source of these rocks is similar to some EM-1 ocean island basalts. In contrast, the magmas from the
northern Payenia province and the Andean retroarc occurrences have received an important input from the
subducting slab and their trace element patterns are transitional between intraplate and arc rocks. These
magmas are mainly derived from another asthenospheric mantle source which may be similar to normal
MORB mantle. The Nevado and Northern Segment basalts have presumably been formed above a shallowly
subducting slab and the progression of volcanism from south to north and northwest along the San Rafael
block likely marks the downwarping of the slab and the end of the shallowsubduction period. The downwarping
slab may have generated an enhanced mantle upwelling of both the intraplate and the MORB-like mantle
sources.
In samples from almost all parts of the Payenia province and in particular many Nevado, Llancanelo and older
Payún Matrú basalts, trace element variations suggest a significant contribution from lower crustal melts,
possibly up to 70% in the most extreme cases. The contaminating lower crustal rocks must have been depleted
mafic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.2 in Mendoza, Argentina,
which is dominated by transitional to alkaline basalts and trachybasalts. We present major and trace element
compositions of 139 rocks from this area of which the majority are basaltic rocks with 4 to 12 wt.% MgO and
44 to 50 wt.% SiO2. The southern Payenia province is dominated by intraplate basalts and the trace element patterns
of the Río Colorado and Payún Matrú lavas suggest little or no influence from subducted slab components.
The mantle source of these rocks is similar to some EM-1 ocean island basalts. In contrast, the magmas from the
northern Payenia province and the Andean retroarc occurrences have received an important input from the
subducting slab and their trace element patterns are transitional between intraplate and arc rocks. These
magmas are mainly derived from another asthenospheric mantle source which may be similar to normal
MORB mantle. The Nevado and Northern Segment basalts have presumably been formed above a shallowly
subducting slab and the progression of volcanism from south to north and northwest along the San Rafael
block likely marks the downwarping of the slab and the end of the shallowsubduction period. The downwarping
slab may have generated an enhanced mantle upwelling of both the intraplate and the MORB-like mantle
sources.
In samples from almost all parts of the Payenia province and in particular many Nevado, Llancanelo and older
Payún Matrú basalts, trace element variations suggest a significant contribution from lower crustal melts,
possibly up to 70% in the most extreme cases. The contaminating lower crustal rocks must have been depleted
mafic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.2. The southern Payenia province is dominated by intraplate basalts and the trace element patterns
of the Río Colorado and Payún Matrú lavas suggest little or no influence from subducted slab components.
The mantle source of these rocks is similar to some EM-1 ocean island basalts. In contrast, the magmas from the
northern Payenia province and the Andean retroarc occurrences have received an important input from the
subducting slab and their trace element patterns are transitional between intraplate and arc rocks. These
magmas are mainly derived from another asthenospheric mantle source which may be similar to normal
MORB mantle. The Nevado and Northern Segment basalts have presumably been formed above a shallowly
subducting slab and the progression of volcanism from south to north and northwest along the San Rafael
block likely marks the downwarping of the slab and the end of the shallowsubduction period. The downwarping
slab may have generated an enhanced mantle upwelling of both the intraplate and the MORB-like mantle
sources.
In samples from almost all parts of the Payenia province and in particular many Nevado, Llancanelo and older
Payún Matrú basalts, trace element variations suggest a significant contribution from lower crustal melts,
possibly up to 70% in the most extreme cases. The contaminating lower crustal rocks must have been depleted
mafic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.fluence from subducted slab components.
The mantle source of these rocks is similar to some EM-1 ocean island basalts. In contrast, the magmas from the
northern Payenia province and the Andean retroarc occurrences have received an important input from the
subducting slab and their trace element patterns are transitional between intraplate and arc rocks. These
magmas are mainly derived from another asthenospheric mantle source which may be similar to normal
MORB mantle. The Nevado and Northern Segment basalts have presumably been formed above a shallowly
subducting slab and the progression of volcanism from south to north and northwest along the San Rafael
block likely marks the downwarping of the slab and the end of the shallowsubduction period. The downwarping
slab may have generated an enhanced mantle upwelling of both the intraplate and the MORB-like mantle
sources.
In samples from almost all parts of the Payenia province and in particular many Nevado, Llancanelo and older
Payún Matrú basalts, trace element variations suggest a significant contribution from lower crustal melts,
possibly up to 70% in the most extreme cases. The contaminating lower crustal rocks must have been depleted
mafic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.ficant contribution from lower crustal melts,
possibly up to 70% in the most extreme cases. The contaminating lower crustal rocks must have been depleted
mafic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.fic rocks with a plagioclase component. The extensive melting of lower crust is probably related to the
low thickness of the lithospheric mantle and preheating of the lower crust by earlier Mio-Pliocene volcanism.
Rare earth element modelling of mantle melting calls for enriched source compositions and a beginning of
melting within the garnet stability field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.field for all Payenia basalts. The Río Colorado and Payún Matrú basalts indicate
high solidus pressures around 3?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.?3.1 GPa which requires either a thermal or compositional mantle
anomaly. The model suggests a thinner lithosphere in the western Payenia region compared to the eastern.