The Congo basin (CB) is an intracratonic basin that occupies a large part of the Congo Craton (1.2
million km2) covering approximately 10% of the continent [1]. It contains up to 9 km of
sedimentary rocks from the Mesoproterozoic until Cenozoic age. The formation of the CB started
with a rifting phase during Mesoproterozoic with the amalgamation of the Rodinia supercontinent
(1.2 Gyr). Afterwards, the main episodes of subsidence occurred during the subsequent
Neoproterozoic post-rift phases, which were followed by phases of compression at the end of the
Permian and during the Early Jurassic age and other sedimentation episodes during Upper
Cretaceous and Cenozoic [2].
We reconstruct the stratigraphy and tectonic evolution of the basin by analyzing seismic reflection
profiles. Furthermore, we estimated the velocity, density, and thickness of the sedimentary layers
in order to calculate their gravity effect. Afterwards, we calculate the gravity disturbance and
Bouguer anomalies using a combined satellite and terrestrial data gravity model. The gravity
disturbance obtained from the EIGEN-6C4 gravity model [3] shows two types of anomalies. One
with a long wavelength (~50 mGal) that covers the entire area of the Congo basin and a second
one with a short wavelength (~130 mGal), having a NW-SE trend, which corresponds to the main
depocenters of sediments detected by the interpretation of seismic reflection profiles. These
results have been used as input parameters for 3D numerical simulations to test the main
mechanisms of formation and evolution of the CB. For this aim, we used the thermomechanical
I3ELVIS code [4] to simulate the initial rift phase. The numerical tests have been conducted
considering a sub-circular weak zone in the central part of the cratonic lithosphere [2] and
applying a velocity of 2.5 cm/yr in two orthogonal directions (NS and EW), to test the hypothesis of
the formation of a multi extensional rift in a cratonic area. We repeated these numerical tests by
increasing the size of the weak zone and varying its lithospheric thickness. The results of these first
numerical experiments show the formation of a circular basin in the central part of the cratonic
lithosphere, in response to extensional stress, inducing the uplift of the asthenosphere.
[1] Kadima, et al. (2011), Structure and geological history of the Congo Basin: an integrated interpretation of gravity, magnetic and reflection seismic data,
doi:10.1111/j.1365-2117.2011.00500.x.
[2] De Wit, et al. (2008), Restoring Pan-African-Brasiliano connections: more Gondwana control,
less Trans-Atlantic corruption, doi:10.1144/SP294.20
[3] Förste et al. (2014) EIGEN-6C4 The latest combined global gravity field model including GOCE
data up to degree and order 2190 of GFZ Potsdam and GRGS Toulouse; doi:
10.5880/ICGEM.2015.1, 2014
[4] Gerya (2009), Introduction to numerical geodynamic modelling, Cambridge University Press