Geophysical evidence of pre-sag rifting and post-rifting fault reactivation in the Parnaíba basin, Brazil

David Lopes De Castro,Francisco Hilário Bezerra,Roberta Mary Vidotti,Reinhardt Adolfo Fuck

doi:10.5194/se-7-529-2016

David Lopes De Castro, Francisco Hilário Bezerra + Show 2 more

Open Access

https://doi.org/10.5194/se-7-529-2016

Copy DOI

Abstract

Abstract. This study investigated the rifting mechanism that preceded the prolonged subsidence of the Paleozoic Parnaíba basin in Brazil and shed light on the tectonic evolution of this large cratonic basin in the South American platform. From the analysis of aeromagnetic, aerogravity, seismic reflection and borehole data, we concluded the following: (1) large pseudo-gravity and gravity lows mimic graben structures but are associated with linear supracrustal strips in the basement. (2) Seismic data indicate that 120–200 km wide and up to 300 km long rift zones occur in other parts of the basins. These rift zones mark the early stage of the 3.5 km thick sag basin. (3) The rifting phase occurred in the early Paleozoic and had a subsidence rate of 47 m Myr−1. (4) This rifting phase was followed by a long period of sag basin subsidence at a rate of 9.5 m Myr−1 between the Silurian and the late Cretaceous, during which rift faults propagated and influenced deposition. These data interpretations support the following succession of events: (1) after the Brasiliano orogeny (740–580 Ma), brittle reactivation of ductile basement shear zones led to normal and dextral oblique-slip faulting concentrated along the Transbrasiliano Lineament, a continental-scale shear zone that marks the boundary between basement crustal blocks. (2) The post-orogenic tectonic brittle reactivation of the ductile basement shear zones led to normal faulting associated with dextral oblique-slip crustal extension. In the west, pure-shear extension induced the formation of rift zones that crosscut metamorphic foliations and shear zones within the Parnaíba block. (3) The rift faults experienced multiple reactivation phases. (4) Similar processes may have occurred in coeval basins in the Laurentia and Central African blocks of Gondwana.

Highlights

The transition between the late Neoproterozoic and early Cambrian was marked by the final assembly of West Gondwana via closure of the Brasiliano/Pan-African ocean basins, amalgamation of cratonic fragments and incorporation of accretionary complexes into mobile belts (Dalziel, 1997; Oliveira and Mohriak, 2003; Cordani et al, 2013)
Paleozoic cratonic basins formed on the failed rifts and occupied large regions of North America, Africa and South America (Hartley and Allen, 1994; Armitage and Allen, 2010)
Its history of long-term accumulation of terrestrial and shallow-water marine sediments started following the final assembly of the Amazon– West African block in an overall collisional scenario involving the Araguaia and Transbrasiliano megashear zones

Summary

Introduction

The transition between the late Neoproterozoic and early Cambrian was marked by the final assembly of West Gondwana via closure of the Brasiliano/Pan-African ocean basins, amalgamation of cratonic fragments and incorporation of accretionary complexes into mobile belts (Dalziel, 1997; Oliveira and Mohriak, 2003; Cordani et al, 2013). During the late Cambrian–early Ordovician, changes in the stress state of the continental lithosphere caused crustal extension and rifting, which were occasionally accompanied by abundant intrusions (Stampfli et al, 2013). The rifting and magmatic episodes occurred primarily along regional lithospheric anisotropies in West Gondwana and Laurentia, and these episodes did not result in continental breakup. Paleozoic cratonic basins formed on the failed rifts and occupied large regions of North America (e.g., the Michigan, Illinois and Hudson Bay basins), Africa (e.g., the Congo, Chad and Taoudeni basins) and South America (e.g., the Amazonas, Parecis, Paraná and Parnaíba basins) (Hartley and Allen, 1994; Armitage and Allen, 2010)

Objectives

Discussion

Conclusion