TY - JOUR
T1 - Recycling and hybridization of incremental episodes of magma intrusions
T2 - Pinheiro Machado Complex, Southeastern Dom Feliciano Belt, Brazil
AU - Loureiro, Paula O.
AU - Koester, Edinei
AU - Weinberg, Roberto F.
AU - Lenz, Cristine
AU - Porcher, Carla C.
AU - Ramos, Rodrigo C.
AU - Vieira, Daniel T.
AU - Bastos, Vivianne A.
AU - Knijnik, Daniel
AU - Pimentel, Márcio M.
PY - 2021/1
Y1 - 2021/1
N2 - The Pinheiro Machado Complex extends for over 10,000 km2 as part of the Brasiliano-age Dom Feliciano Belt in Rio Grande do Sul, Brazil. In the Monte Bonito region, the complex is exposed in three quarries, which record multiple and complex magmatic structures revealing competing magmatic processes. Older magmatic rocks are eroded by younger ones, evidenced by several stages of disaggregation of magmatic xenoliths into fragments and schlieren, and by their deformation by ductile dragging. Hybridization is evidenced by mafic microgranular enclaves in granitic rocks close to contacts with diorite intrusions, and by diffuse, gradational boundaries between different magma mafic and felsic batches. Syenogranites represent the latest magma intrusion episode and recycle host mushes and rocks intruded earlier. In this process, zircons were recycled forming antecrysts. Finally, as the body evolved, some rocks underwent anatexis evidenced by patchy leucosomes with peritectic hornblende and/or titanite or magnetite, sometimes forming stictolithic or fleck texture. U–Pb SHRIMP ages obtained for zircons from an early diorite and a late-intrusive magnetite granite yielded crystallization ages of 616 ± 3 Ma and 608 ± 4 Ma, respectively. High U zircon rims yield Concordia ages around 600 Ma in both rock types, which can be related to crystallization of highly fractionated melts, late anatexis evidenced for example by fleck texture in rocks of both stages, or Pb loss. Thus, the geology and magma crystallization ages obtained for the Monte Bonito region of the Pinheiro Machado Complex indicate that batholith growth was punctuated by intervals of melt influx separated by periods of relative quiescence. The magmatic structures resulted from a variety of recycling and hybridization processes, that evolved as a function of changing rheological contrasts between intruding magmas and previously intruded batches at different stages of crystallization.
AB - The Pinheiro Machado Complex extends for over 10,000 km2 as part of the Brasiliano-age Dom Feliciano Belt in Rio Grande do Sul, Brazil. In the Monte Bonito region, the complex is exposed in three quarries, which record multiple and complex magmatic structures revealing competing magmatic processes. Older magmatic rocks are eroded by younger ones, evidenced by several stages of disaggregation of magmatic xenoliths into fragments and schlieren, and by their deformation by ductile dragging. Hybridization is evidenced by mafic microgranular enclaves in granitic rocks close to contacts with diorite intrusions, and by diffuse, gradational boundaries between different magma mafic and felsic batches. Syenogranites represent the latest magma intrusion episode and recycle host mushes and rocks intruded earlier. In this process, zircons were recycled forming antecrysts. Finally, as the body evolved, some rocks underwent anatexis evidenced by patchy leucosomes with peritectic hornblende and/or titanite or magnetite, sometimes forming stictolithic or fleck texture. U–Pb SHRIMP ages obtained for zircons from an early diorite and a late-intrusive magnetite granite yielded crystallization ages of 616 ± 3 Ma and 608 ± 4 Ma, respectively. High U zircon rims yield Concordia ages around 600 Ma in both rock types, which can be related to crystallization of highly fractionated melts, late anatexis evidenced for example by fleck texture in rocks of both stages, or Pb loss. Thus, the geology and magma crystallization ages obtained for the Monte Bonito region of the Pinheiro Machado Complex indicate that batholith growth was punctuated by intervals of melt influx separated by periods of relative quiescence. The magmatic structures resulted from a variety of recycling and hybridization processes, that evolved as a function of changing rheological contrasts between intruding magmas and previously intruded batches at different stages of crystallization.
KW - Dom Feliciano Belt
KW - Hybridization
KW - Long-lived batholiths
KW - Magmatic recycling
KW - Pinheiro Machado Complex
KW - Water-fluxed melting
UR - http://www.scopus.com/inward/record.url?scp=85095806577&partnerID=8YFLogxK
U2 - 10.1016/j.jsames.2020.102922
DO - 10.1016/j.jsames.2020.102922
M3 - Article
AN - SCOPUS:85095806577
SN - 0895-9811
VL - 105
JO - Journal of South American Earth Sciences
JF - Journal of South American Earth Sciences
M1 - 102922
ER -