Abstract
The Congo Basin (CB) occupies a large part of the Congo Craton, which formed from the amalgamation of different cratonic blocks of Archean age. It records the history of deposition of up to 1 Gyr of sediments, one of the longest geological records on Earth above a crystalline basement. It is considered as a typical intracratonic basin, with its slow and long-lived subsidence history and the largely unknown formation mechanisms. In this study, we analyze the gravity field in the central area of the CB, applying two different methodologies to investigate the depth of the crystalline rock basement and crustal structures. The crustal contribution to the gravity observations is determined in one case by a data driven approach, while in the other using an isostatic compensation model that includes the effect of the rigidity of the lithosphere. Both methods are constrained by density measurements from rock samples/boreholes and interpretations of the reflection seismic profiles, crossing the CB. The results obtained are quite consistent with the aeromagnetic anomalies, showing structural highs and lows, NW-SE trending, matching the axial magnetic zone. The maximum basement depth is between 10 and 18 km, depending on the gravity method and assumptions used. Furthermore, we could identify several small basins that from the interpolation of seismic profiles are not clearly resolved, such as Busira (7–9 km deep), Lokoro (10.5–12 km deep), and Salonga basins (10–11.5 km deep), in the northwestern, southeastern, and central sector of the CB, respectively. The analysis of the gravity anomalies mainly related to the crystalline crust supposes the presence of high-density bodies located in the southern part of the CB that we interpreted as related to the extensional phases that initiated the subsidence of the basin.
| Original language | English |
|---|---|
| Article number | 103611 |
| Pages (from-to) | 1-22 |
| Number of pages | 22 |
| Journal | Global and Planetary Change |
| Volume | 205 |
| DOIs | |
| Publication status | Published - Oct 2021 |
Bibliographical note
Funding Information:A PhD grant to author Francesca Maddaloni was provided by Regione Friuli Venezia Giulia (Italy) through a European Social Fund (FSE) 50% cofounded fellowship. Magdala Tesauro acknowledges the grant “INTRAcratonic basins TECTOnic evolution: The Congo Basin (INTRA-TECTO)”. We acknowledge the RMCA for the availability of seismic and geological data. Aeromagnetic data have been processed by M. Evraerts. We are grateful to Dr. Alberto Pastorutti and Tommaso Pivetta for helpful discussions, assistance in program coding and informatics system management. The comments of three anonymous reviewers have significantly improved a previous version of the manuscript.
Funding Information:
A PhD grant to author Francesca Maddaloni was provided by Regione Friuli Venezia Giulia (Italy) through a European Social Fund (FSE) 50% cofounded fellowship. Magdala Tesauro acknowledges the grant ?INTRAcratonic basins TECTOnic evolution: The Congo Basin (INTRA-TECTO)?. We acknowledge the RMCA for the availability of seismic and geological data. Aeromagnetic data have been processed by M. Evraerts. We are grateful to Dr. Alberto Pastorutti and Tommaso Pivetta for helpful discussions, assistance in program coding and informatics system management. The comments of three anonymous reviewers have significantly improved a previous version of the manuscript.
Publisher Copyright:
© 2021 Elsevier B.V.
Keywords
- Congo basin
- Gravity effect of sediments
- Gravity residuals
- Regression analysis