The relationship between displacement and length of faults
The relationship between displacement and length of faults
The relationship between maximum displacement (dmax) and fault length (L) has been studied extensively, mainly in attempts to understand how fault geometry varies over different length scales. Individual data sets are sampled over limited length scales, and values of dmax and L are generally poorly correlated, thus relationships are usually postulated on the basis of combining different data sets. There are problems in sampling both dmax and L in a consistent manner over these different length scales, especially where different data collection methods are used (e.g., field and seismic reflection data).
Failure to resolve low-displacement tips and damage zones leads to underestimates of L, and exclusion of fault drag leads to underestimates of dmax. Measurement of non-central fault traces leads to underestimates of both dmax and L and an underestimate of dmax/L. In this paper, we examine factors that control the measured displacement–fault length relationships of natural faults. We suggest that there may be systematic differences between the dmax/L ratios where length is measured parallel or normal to the displacement vector, and where the growth histories of individual faults vary due to the nature and number of slip events, linkage, and reactivation. Controlling factors also include material properties and fault types. It is explained how each controlling factor contributes to the dmax/L ratio and should be considered in the statistical analysis of fault data
fault length, maximum displacement, linkage, propagation, scaling, damage, reactivation
317-334
Sanderson, David J.
5653bc11-b905-4985-8c16-c655b2170ba9
Kim, Young-Seog
63f4740a-5cc1-4d29-a6ca-40cebad2c7a3
January 2005
Sanderson, David J.
5653bc11-b905-4985-8c16-c655b2170ba9
Kim, Young-Seog
63f4740a-5cc1-4d29-a6ca-40cebad2c7a3
Sanderson, David J. and Kim, Young-Seog
(2005)
The relationship between displacement and length of faults.
Earth-Science Reviews, 68 (3-4), .
(doi:10.1016/j.earscirev.2004.06.003).
Abstract
The relationship between maximum displacement (dmax) and fault length (L) has been studied extensively, mainly in attempts to understand how fault geometry varies over different length scales. Individual data sets are sampled over limited length scales, and values of dmax and L are generally poorly correlated, thus relationships are usually postulated on the basis of combining different data sets. There are problems in sampling both dmax and L in a consistent manner over these different length scales, especially where different data collection methods are used (e.g., field and seismic reflection data).
Failure to resolve low-displacement tips and damage zones leads to underestimates of L, and exclusion of fault drag leads to underestimates of dmax. Measurement of non-central fault traces leads to underestimates of both dmax and L and an underestimate of dmax/L. In this paper, we examine factors that control the measured displacement–fault length relationships of natural faults. We suggest that there may be systematic differences between the dmax/L ratios where length is measured parallel or normal to the displacement vector, and where the growth histories of individual faults vary due to the nature and number of slip events, linkage, and reactivation. Controlling factors also include material properties and fault types. It is explained how each controlling factor contributes to the dmax/L ratio and should be considered in the statistical analysis of fault data
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Published date: January 2005
Keywords:
fault length, maximum displacement, linkage, propagation, scaling, damage, reactivation
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Local EPrints ID: 52991
URI: http://eprints.soton.ac.uk/id/eprint/52991
ISSN: 0012-8252
PURE UUID: 8e377439-639a-44c0-927b-fbd3acdce9e6
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Date deposited: 17 Jul 2008
Last modified: 16 Mar 2024 03:57
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Author:
Young-Seog Kim
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