The exhumation along the Kenyase and Ketesso shear zones in the Sefwi terrane, West African Craton: a numerical study

High-grade (amphibolite–granulite facies) tectono-metamorphic domains in the Sefwi terrane of Ghana are separated from adjacent lower-grade (greenschist facies) greenstone belts by two main shear zones. The high-grade rocks presumably exhumed along the sinistral shear zones during the D2 ENE-WSW transtension (~2073 Ma). To better understand the role boundary conditions and the spatial relationship of faults play in the exhumation of partially molten lower crust in the Sefwi terrane, ten 3D thermomechanical models have been constructed. The results show that the normal component of velocity boundary conditions mainly controls the exhumation (8–10 km) of the lower crust along pre-existing faults, while the exhumation in the relay zones between faults is controlled by the obliquity between the applied extensional velocity vector and the vertical wall on which it is applied. The strike of the exhumation belt made of partially molten lower crust rocks in the relay zone is sub-orthogonal to the horizontal maximum stretching axis. The isostatic compensation from low-density upper mantle to overlying crust (thinning) is higher under transtension than under extension. The lower crust exhumation influenced by inherited shear zones (ductile) can be used to better understand the loci of the high-grade rocks in the Sefwi terrane. We suggest that the Kukuom-Juaboso domain composed of amphibolite–migmatite facies rocks probably resulted from the concentration of partially molten rocks in the relay zone between the Ketesso and Kenyase shear zones during the D2 ENE-WSW transtension. The two shear zones probably underwent two main stages for growth and maturation from the D1 to D2 phases. The regional exhumation of the high-grade rocks in the Sefwi terrane probably occurred within < 5 Ma.

[1]  Louis Moresi,et al.  Numerical investigation of 2D convection with extremely large viscosity variations , 1995 .

[2]  T. Gerya,et al.  Transient hot channels: Perpetrating and regurgitating ultrahigh-pressure, high-temperature crust–mantle associations in collision belts , 2008 .

[3]  O. Vanderhaeghe Melt segragation, pervasive melt migration and magma mobility in the continental crust: the structural record from pores to orogens , 2001 .

[4]  C. Teyssier,et al.  The role of partial melting and extensional strain rates in the development of metamorphic core complexes , 2009 .

[5]  L. Montési,et al.  Strain weakening enables continental plate tectonics , 2013 .

[6]  Soumyajit Mukherjee,et al.  Using Graph Theory to Represent Brittle Plane Networks , 2019, Developments in Structural Geology and Tectonics.

[7]  Hans Muhlhaus,et al.  A Lagrangian integration point finite element method for large deformation modeling of viscoelastic geomaterials , 2003 .

[8]  J. Brun,et al.  Thermomechanical modeling of extensional gneiss domes , 2004 .

[9]  C. Guerrot,et al.  The paleoproterozoic Ghanaian province: Geodynamic model and ore controls, including regional stress modeling , 2006 .

[10]  James P. Evans,et al.  Growth, linkage, and termination processes of a 10-km-long strike-slip fault in jointed granite: the Gemini fault zone, Sierra Nevada, California , 2002 .

[11]  D. Peacock,et al.  Active relay ramps and normal fault propagation on Kilauea Volcano, Hawaii , 2002 .

[12]  M. Jessell,et al.  Petrological and geochronological constraints on lower crust exhumation during Paleoproterozoic (Eburnean) orogeny, NW Ghana, West African Craton , 2015 .

[13]  D. Davis,et al.  Reassessment of Proterozoic granitoid ages in Ghana on the basis of U/Pb zircon and monazite dating , 1992 .

[14]  M. Jessell,et al.  The geophysical signatures of the West African Craton , 2016 .

[15]  R. Parker,et al.  Isostatic compensation on a continental scale: local versus regional mechanisms , 1977 .

[16]  H. Koyi,et al.  Centrifuge modelling of the evolution of low-angle detachment faults from high-angle normal faults , 2001 .

[17]  H. Rollinson Archaean crustal evolution in West Africa: A new synthesis of the Archaean geology in Sierra Leone, Liberia, Guinea and Ivory Coast , 2016 .

[18]  Patience A. Cowie,et al.  Physical explanation for the displacement-length relationship of faults using a post-yield fracture mechanics model , 1992 .

[19]  Giorgio Ranalli,et al.  Rheology of the earth , 1987 .

[20]  S. Mukherjee,et al.  Brittle Shear Tectonics in a Narrow Continental Rift: Asymmetric Nonvolcanic Barmer Basin (Rajasthan, India) , 2017, The Journal of Geology.

[21]  S. Mukherjee Locating center of gravity in geological contexts , 2018, International Journal of Earth Sciences.

[22]  K. Mulchrone,et al.  Estimating the viscosity and Prandtl number of the Tso Morari crystalline gneiss dome, Indian western Himalaya , 2012, International Journal of Earth Sciences.

[23]  I. Moretti,et al.  Rifting through a stack of inhomogeneous thrusts (the dipping pie concept) , 2004 .

[24]  S. Mukherjee Shear heating by translational brittle reverse faulting along a single, sharp and straight fault plane , 2017, Journal of Earth System Science.

[25]  A. Nicol,et al.  Segmentation and growth of an obliquely reactivated normal fault , 2012 .

[26]  P. Williams,et al.  Transpression (or transtension) zones of triclinic symmetry: natural example and theoretical modelling , 1998, Geological Society, London, Special Publications.

[27]  R. Schultz,et al.  Displacement and interaction of normal fault segments branched at depth : Implications for fault growth and potential earthquake rupture size , 2008 .

[28]  J. Ganne,et al.  Thermo-mechanical modeling of lower crust exhumation—Constraints from the metamorphic record of the Palaeoproterozoic Eburnean orogeny, West African Craton , 2014 .

[29]  J. Brun,et al.  Dynamics and structural development of metamorphic core complexes , 2008 .

[30]  Roland Martin,et al.  3-D numerical modelling of the influence of pre-existing faults and boundary conditions on the distribution of deformation: Example of North-Western Ghana , 2016 .

[31]  S. Mukherjee,et al.  Tectonic Inheritance in Continental Rifts and Passive Margins , 2015 .

[32]  B. Tikoff,et al.  Extended models of transpression and transtension, and application to tectonic settings , 1998, Geological Society, London, Special Publications.

[33]  S. Mukherjee Channel flow extrusion model to constrain dynamic viscosity and Prandtl number of the Higher Himalayan Shear Zone , 2013, International Journal of Earth Sciences.

[34]  G. Schreurs,et al.  Analogue modelling of intraplate strike-slip tectonics: A review and new experimental results , 2012 .

[35]  J. Daniel,et al.  Fault reactivation control on normal fault growth: an experimental study , 2005 .

[36]  M. Jessell,et al.  Crustal-scale transcurrent shearing in the Paleoproterozoic Sefwi-Sunyani-Comoé region, West Africa , 2012 .

[37]  M. Batist,et al.  Fault linkage in continental rifts: structure and evolution of a large relay ramp in Zavarotny; Lake Baikal (Russia) , 2006 .

[38]  Xiaojun Feng,et al.  Statistical petrology reveals a link between supercontinents cycle and mantle global climate , 2016 .

[39]  Cheng‐Horng Lin Thermal modeling of continental subduction and exhumation constrained by heat flow and seismicity in Taiwan , 2000 .

[40]  Christopher H. Scholz,et al.  A model of normal fault interaction based on observations and theory , 2000 .

[41]  John H. Spang,et al.  Influence of layering and boundary conditions on fault-bend and fault-propagation folding , 1991 .

[42]  D. Sanderson,et al.  Fault damage zones , 2004 .

[43]  S. Mukherjee Airy’s isostatic model: a proposal for a realistic case , 2017, Arabian Journal of Geosciences.

[44]  M. Jessell,et al.  Juvenile Paleoproterozoic crust evolution during the Eburnean orogeny (~2.2-2.0Ga), western Burkina Faso , 2011 .

[45]  Louis Moresi,et al.  Computational approaches to studying non-linear dynamics of the crust and mantle , 2007 .

[46]  J. Malavieille,et al.  Extensional tectonics, basement uplift and Stephano-Permian collapse basin in a late Variscan metamorphic core complex (Montagne Noire, Southern Massif Central) , 1990 .

[47]  G. Abers,et al.  Mantle compensation of active metamorphic core complexes at Woodlark rift in Papua New Guinea , 2002, Nature.

[48]  John H. Spang,et al.  Influence of layering and boundary conditions on fault-bend and fault-propagation folding : Bull Geol Soc AmV103, N8, Aug 1991, P1059–1072 , 1992 .

[49]  C. Morley,et al.  Activation of rift oblique and rift parallel pre-existing fabrics during extension and their effect on deformation style: examples from the rifts of Thailand , 2004 .

[50]  M. Jessell,et al.  Modern-style plate subduction preserved in the Palaeoproterozoic West African craton , 2012 .

[51]  D. Sanderson,et al.  Reactivated strike–slip faults: examples from north Cornwall, UK , 2001 .

[52]  Tobias Keller,et al.  Numerical modelling of magma dynamics coupled to tectonic deformation of lithosphere and crust , 2013 .

[53]  J. Brun,et al.  Analogue modeling of detachment fault systems and core complexes , 1994 .

[54]  Lawrence W. Teufel,et al.  Hydraulic-fracture propagation in layered rock: experimental studies of fracture containment , 1984 .

[55]  G. B. Piccardo Evolution of the lithospheric mantle during passive rifting: Inferences from the Alpine–Apennine orogenic peridotites , 2016 .

[56]  Zoe K. Shipton,et al.  A review of recent developments concerning the structure, mechanics and fluid flow properties of fault zones , 2010 .

[57]  S. Mukherjee Moment of inertia for rock blocks subject to bookshelf faulting with geologically plausible density distributions , 2018, Journal of Earth System Science.

[58]  Jerico Revote,et al.  Styles of rifting and fault spacing in numerical models of crustal extension , 2015 .

[59]  D. C. Drucker,et al.  Soil mechanics and plastic analysis or limit design , 1952 .

[60]  Roland Martin,et al.  Effect of strain-weakening on Oligocene–Miocene self-organization of the Australian-Pacific plate boundary fault in southern New Zealand: Insights from numerical modelling , 2016 .