Sophie Pan , John Naliboff, Rebecca E. Bell, Christopher Aiden-Lee Jackson 

Continental extension is primarily accommodated by the evolution of normal fault networks. Rifts are shaped by complex tectonic processes and it has historically been difficult to determine the key rift controls using only observations from natural rifts. Here, we use 3D thermo-mechanical, high-resolution (<650 m) forward models of continental extension to investigate how fault network patterns vary as a function of key rift parameters, including extension rate, the magnitude of strain weakening, and the distribution and magnitude of initial crustal damage. We quantitatively compare modelled fault networks with observations of fault patterns in natural rift, finding key similarities in their along-strike variability and scaling distributions. We show that fault-accommodated strain summed across the entire 160 x 160 km study area increases linearly with time. We find that large faults do not abide by power-law scaling as they are limited by an upper finite characteristic, ω0. Fault weakening, and the spatial distribution of initial plastic strain blocks, exert a key control on fault characteristics. We show that off-fault (i.e. non-fault extracted) deformation accounts for 30-70% of the total extensional strain, depending on the rift parameters. As fault population statistics produce distinct characteristics for our investigated rift parameters, further numerical and observational data may enable the future reconstruction of key rifting parameters through observational data alone.