Progressive Strain Localisation in the Growth of Normal Fault Systems.



Bailey, W.R., Bonson, C., Childs, C., Imber, J., Manzocchi, T., Meyer, V.1, Nell, P., Nicol, A.2, Strand, J., Walsh, J.J., & Watterson, J.
1 - Institut de Physics du Globe, 4 Place Jussieu, Case 89 - Tectonique - Tour 24, 75252 PARIS cedex 05
2 - Institute of Geological & Nuclear Sciences, P.O. Box 30368, Lower Hutt, New Zealand

Abstract - The growth of normal fault arrays is most conveniently examined in basins where sedimentation rates were higher than fault displacement rates. In these basins fault growth histories are recorded by thickness and displacement variations within syn-faulting sequences and can be reconstructed using displacement backstripping methods. Using data from the Inner Moray Firth, a sub-basin of the North Sea, and from the Timor Sea, offshore Australia, we outline the principal characteristics of the growth history of normal fault systems.

The growth of normal fault systems in the Inner Moray Firth and in the Timor Sea has several features in common:
(i) Fault displacement rates correlate with fault size, where size is measured in terms of either displacement or length.
(ii) Large faults have higher displacement rates than smaller faults throughout the growth of the fault system.
(iii) Smaller faults have higher mortality rates and large faults grow at their expense.
(iv) Fault size populations vary from continuous power-law distributions at earlier stages of growth, through to non-power-law distributions as the system matures. As a fault system evolves, large faults progressively dominate, with small faults occupying a size range that is progressively distinct from that of the large faults.
(v) The progressive localisation of displacement and strain onto large faults, is accompanied by an increase in the connectivity of large faults, at the scale of observation.

These characteristic features of fault system growth support the case for the existence of long-range correlations between different faults within a system throughout its growth. Because of the pronounced geometric controls, in particular fault connectivity, demonstrated by the overall growth of these systems, we attribute the preferential growth of larger faults also to geometric factors (i.e. fault size, connectivity, orientation), rather than to differences between the fault rock mechanical properties of individual faults. The outstanding feature of the growth of fault systems is the progressive localisation of strain and displacements, onto fewer and larger faults.

Abstract of talk given to:

Tectonic Studies Group Annual Meeting, Tectonic Studies Group, University of Manchester, January 2000