Using core complex geometry to constrain fault strength

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  • E. Choi, University of Memphis
  • ,
  • W.R. Buck, Columbia University
  • ,
  • L.L. Lavier, University of Texas at Austin
  • ,
  • Kenni Dinesen Petersen, Danmark
We present the first model results showing that some core complex detachment faults are strong and that their strength has to be in a narrow range to allow certain extensional structures to develop. The structures we simulate are kilometer-scale "rider blocks" that are particularly well observed on some oceanic core complexes as well as continental metamorphic core complexes. Previous numerical simulations of lithospheric extension produced the large-offset, core complex-forming, normal faults only when the faults were weaker than a given threshold. However, our new, high-resolution simulations indicate that rider blocks only result when the faults are stronger than a given level. A narrow range of fault weakening, relative to intact surrounding rock, allows for a consecutive series of rider blocks to emerge in a core complex-like geometry. Our results show that rider blocks develop when the dominant form of weakening is by reduction of fault cohesion while faults that weaken primarily by friction reduction do not form distinct rider blocks.
OriginalsprogEngelsk
TidsskriftGeophysical Research Letters
Vol/bind40
Nummer15
Sider (fra-til)3863-3867
Antal sider5
ISSN0094-8276
DOI
StatusUdgivet - 16 aug. 2013

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