Ts. Buddin et al., A SENSITIVITY ANALYSIS OF 3-DIMENSIONAL RESTORATION TECHNIQUES USING VERTICAL AND INCLINED SHEAR CONSTRUCTIONS, Tectonophysics, 269(1-2), 1997, pp. 33-50
The restoration of cross sections in extensional settings is commonly
carried out with simple shear constructions which use either vertical
or inclined shear geometrical construction techniques. These technique
s assume plane strain and that the X and Z principal finite strain axe
s are contained within the plane of the cross-section. In 2-dimensiona
l balanced cross sections the displacement vector is, of necessity, as
sumed to be in the plane of the section. In 3-dimensional restoration
the main components are the horizontal displacement vector (heave), th
e deformation plane that contains the X and Z principal strain axes in
plane strain deformation and the vertical/inclined shear angle (shear
pins) parallel to which the hanging wall deforms during translation.
During 3-dimensional restoration it is possible to vary the orientatio
n of the displacement vector and shear pins in both azimuth and plunge
. We can therefore test the sensitivity of artificial models, or natur
al examples, to variation in restoring parameters. The examples used h
ere show that restorations are extremely sensitive to the shear angle
chosen for the hanging wall, and in the case of an oblique ramp model
and a natural fault example, to the movement direction assumed for the
restoration. Using map view visualisation of faulted hanging-wall sur
faces it is possible to obtain a good estimate of the original slip ve
ctor which would not be apparent from 2-D sections by matching hanging
-wall and footwall cut-offs. Using this 3-D approach it is possible to
minimise errors in restoration which result from erroneous restoring
slip vectors. Any information on the angle of simple shear deformation
of the hanging wall during deformation should be used when restoring
the 3-D surface or cross-section.