1 Introduction
The geometry of microstructures is an
important source of information on the development of mylonite zones and
on the kinematics and dynamics of flow in them. Shear band cleavage is
an important as a commonly used shear-sense indicator in mylonites, although
its development is incompletely understood. Two types of shear band cleavage
are distinguished in the literature: S-C-type and S-C'-type cleavage
(Berthé
et al. 1979a, b)
(Figure 1).
In our experiment we focused on the development of S-C' type cleavage
(Figure 2),
which
is common in micaceous mylonites: S (cleavage) planes represent a
penetratively developed foliation and spaced C'-type shear bands are oblique
to shear zone boundaries and to the S-planes
(White
1979b, Platt and Vissers 1980) (Figure
1).
The angle between shear bands and the shear zone margin is 15-35o
(Dennis and Secor 1987, Passchier
1991b, Blenkinsop and Treloar 1995).
Normally, only one set of shear bands is developed, with a sense of slip
synthetic to the shear-sense of bulk flow. The shear bands may be composed
of the same mineralogy as the rest of the rock
(e.g.
Gapais and White 1982)
or they may show compositional changes typical of retrograde metamorphic
reactions (e.g. McCaig 1987,
Norrell et
al. 1989) or of the concentration
of less soluble material by mass transfer.
S-C'-type shear band cleavage seems
to develop late during shear zone activity after a strong mineral preferred
orientation has already been established, and probably represents an energetically
favourable flow partitioning in strongly anisotropic materials (Platt and
Vissers 1980, Platt 1984,
Dennis
and Secor 1987,
Passchier 1991b).
The
initiation mechanism of shear bands is related to the amplification of
perturbations in the planar anisotropy of a foliated host rock (Cobbold
et al. 1971, Cobbold 1976)
and a response to hardening of deforming mylonites
(e.g. White et al. 1980,
Passchier 1986).
In order to increase understanding
of shear band cleavage development, we experimentally modelled the development
S-C' type cleavage and the influence of the S-C' cleavage geometry on flow
behaviour. We carried out experiments in paraffin wax, an organic material
with non-Newtonian rheology in which shear bands can develop. Experiments
were carried out in a circular shear rig that has the advantage that very
high strain could be obtained. Moreover, the deformation process can be
observed and monitored in transmitted light down to the scale of individual
grains.
