Abstract
The central Australian Musgrave Province at the junction of the South, North and West Australian cratons has undergone and continues to retain evidence of significant whole-of-crust, and most likely ‘whole-of-lithosphere’ tectono-magmatic processes. The area is known for some of the largest geophysical anomalies related to significant Moho offsets of up to 15 km, which resulted from repeated intracratonic reworking since the Neoproterozoic. New magnetotelluric (MT) data have been collected across the Musgrave Province in Western Australia and South Australia as part of the Australian Lithospheric Architecture Magnetotelluric Project (AusLAMP). Station spacing was sim 50,hbox {km} between 96 sites over an area of 500 × 700 km. Long-period MT impedance and tipper data over a bandwidth of 8 s to 10,000 s period have been inverted using a smooth 3D inverse algorithm. The 3D model shows two predominant resistivity trends. There are deep (>65,hbox {km}) north–south mantle conductors that we infer to be related to the Palaeo- to Mesoproterozoic north-trending arc-related rocks that experienced ultra-high temperature metamorphism and widespread magmatism during the Mesoproterozoic Musgravian Orogeny. These conductors are preserved in the crust south of the Musgrave Province. The upper mantle also contains a localised resistive zone that possibly represents generation of mafic- to ultramafic magmas during the c. 1090–1040 Ma Giles Event. The crust (<65,hbox {km} depth) contains strong east–west crustal conductors interpreted to reflect the east–west structural grain that initiated during the c. 1090–1040 Ma Giles Event and overprinted the older N–S-oriented mantle anomalies. These E–W crustal conductors coincide with magnetic anomalies that represent crustal-scale structures, and high gravity anomalies associated with significant Moho offsets resulting from further reactivation during the c. 630–520 Ma Petermann and c. 450–300 Ma Alice Springs orogenies.
Highlights
Tectonothermal events leave an imprint in the lithospheric architecture and the electrical resistivity structure measured today is a result of the cumulative fertilising and depleting effects of all events (Unsworth 2010; Selway 2014)
Subsequent multiple overprinting with the intrusions of the giant layered mafic-ultramafic intrusions of the Giles Event (Smithies et al 2011) and of the Warakurna Large Igneous Province (Alghamdi et al 2018) and again localisation of deformation during the amagmatic Petermann and Alice Springs orogenies further complicates the unravelling of the Musgrave Province (Raimondo et al 2010)
This paper presents the results of this study of the Musgrave Province and shows new lithospheric-scale 3D MT data across this intracontinental deformation zone
Summary
Tectonothermal events leave an imprint in the lithospheric architecture and the electrical resistivity structure measured today is a result of the cumulative fertilising and depleting effects of all events (Unsworth 2010; Selway 2014). Understanding the cause of the MT response is important in interpreting the MT data as well as how this response changes over time and with successive deformation. The Musgrave Province in central Australia is a worthy area to evaluate the use of 3D AusLAMP MT in understanding geological processes. The geological history of the Musgrave Province involves c. The range of geological processes recognised in the Musgrave Province provides ample possibilities for leaving behind signatures of tectonomagmatic events in the lithosphere. A full 3D image of the lithosphere beneath the Musgrave Province will add an important dataset to help constrain the evolution of the Musgrave Province
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