Dependence of active normal fault dips on lower-crustal flow regimes

doi:10.1144/gsjgs.155.2.0233

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Journal of the Geological Society; 1998; v. 155; issue.2; p. 233-253;
DOI: 10.1144/gsjgs.155.2.0233
© 1998 Geological Society of London

Article

Dependence of active normal fault dips on lower-crustal flow regimes

R.O.B. WESTAWAY

16 Neville Square, Durham DH1 3PY, UK

Two key questions are raised by the presence in the Basin andRange Province of subhorizontal normal faults, which were activein and around the Miocene. First, how did they develop, whentheir existence seems to be precluded by elementary rock-mechanicsarguments? Second, if they did slip in the recent geologicalpast, why do normal faults now active in the brittle upper crusthave steeper dips, both in the western USA and elsewhere? Onemay now answer both questions, by considering the stress fieldin regions where the isostatic response during extension involveshorizontal flow in the plastic lower crust. This stress tensorwill have inclined principal axes, making it possible for normalfaults to form with either very steep or subhorizontal dipsdepending on the sense of flow. This can be controlled by environmentalconditions, which influence rates of hanging-wall sedimentationand footwall erosion and thus determine lateral variations inlithostatic pressure in the lower crust. Regional-scale lateralvariations in the geothermal gradient caused by subduction canalso influence lower-crustal flow regimes in adjacent zonesof continental extension, enabling extension to occur on low-anglenormal faults dipping away from the active continental margin.

Keywords: Basin and Range Province, Aegean Sea, normal faults, lower crust, isostasy.

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