4.2  ·  Foliations  95
                 ing or micro-shear zone development, and the new folia-  importance at deeper crustal levels since large volumes
                 tion follows the axial planes of folds, or the shear zones  of fluid would necessarily have to flux through the rock
                 (Hobbs et al. 1982; Fig. 4.31b). Mawer and Williams (1991)  to remove material in solution (Engelder 1984; Bhagat and
                 describe a situation where fold hinges develop in a con-  Marshak 1990), However, Goldstein et al. (1998) argue that
                 tinuous foliation deformed in non-coaxial progressive  in accretionary complexes large volumes of water are pass-
                 deformation; new micas overgrow newly formed fold  ing through the rocks and that in such settings large vol-
                 hinges, these become unrecognisable and a mixed folia-  ume losses are to be expected. The difficulty is that vol-
                 tion is formed with an orientation oblique to the XY-plane  ume loss during foliation development can rarely be di-
                 of tectonic strain (Fig. 4.31b; Mawer and Williams 1991).  rectly measured in deformed rocks (Sect. 9.2). Well-pre-
                 Even ordinary slaty cleavage normally replaces a diagenetic
                 foliation and is therefore not necessarily exactly parallel
                 to the XY-plane of tectonic strain (Figs. B.4.5, 4.31a,
                 ×Video B.4.5). In most of the cases mentioned above, the
                 foliation is oblique to the XY-plane of tectonic strain, ex-
                 cept in the case of very high strain values.
                   Some foliations are active as fold limbs or micro-shear
                 zones. These ‘active foliations’ will never be parallel to tec-
                 tonic strain axes, unless they become passive by rotation.
                 Examples are some constrictional crenulation cleavages
                 (Rajlich 1991), and shear band cleavages (Sect. 5.6.3). Care
                 is needed even in assessment of apparently ‘passive’
                 foliations because foliation planes, once formed, are eas-
                 ily mobilised as planes of shear movement (Bell 1986). In
                 many practical examples there is evidence of such ‘reac-
                 tivation’, resulting in shear movement along foliation
                 planes during deformation post-dating their formation.
                   Finally, there are ‘oblique foliations’ (Box 4.2; Figs. 5.10,
                 5.30), which represent only the last part of the tectonic
                 strain. These foliations are not normally parallel to the
                 XY-plane of tectonic strain (Fig. 4.31c; Ree 1991) but form
                 wherever some process such as recrystallisation or grain
                 boundary sliding resets the shape of elongated grains
                 formed by dislocation creep. As a result, the foliation will
                 only represent the last part of the deformation history
                 (Box 4.2; Fig. 4.31c).
                 4.2.9.3
                 Foliations, Strain and Volume Change

                 It is presently unclear to what extent solution transfer as-
                 sociated with foliation development leads to bulk volume  Fig. 4.32. Two end-member models of crenulation cleavage develop-
                                                               ment in plane strain. The onset of crenulation cleavage development
                 change. Shortening values normal to the foliation up to
                                                               is shown in the squares at left. Schematic enlargements of an aggre-
                 70% are mentioned in the literature, but most observa-  gate of four quartz grains (white), a pyrite cube (black) and a passive
                 tions are in the range of 30% (Gray 1979; Southwick 1987).  marker circle are given. Deformed situations in cleavage domains (CD
                 Bulk volume loss of up to 80% has been reported, espe-  grey) and microlithons (ML white) are shown in rectangles at right.
                 cially for slaty cleavage development at very low- and low-  Local strain and volume loss in both situations are indicated schema-
                                                               tically (not to scale) by the elliptical shape of the deformed marker
                 grade metamorphic conditions (Ramsay and Wood 1973;  circle and the outline of the original circle. a Significant volume loss in
                 Wright and Platt 1982; Etheridge et al. 1983; Beutner and
                                                               cleavage domains while microlithons are undeformed. Quartz grains
                 Charles 1985; Ellis 1986; Wright and Henderson 1992;  are partly dissolved in cleavage domains but no fibres form near the
                 Goldstein et al. 1995, 1998). On the other hand, many stud-  quartz or pyrite grains. b Volume-constant deformation where vol-
                 ies concluded that little or no significant bulk volume  ume loss in cleavage domains is compensated by volume increase of
                 change accompanied cleavage formation (Waldron and  microlithons. Quartz grains are partly dissolved in cleavage domains
                 Sandiford 1988; Wintsch et al. 1991; Tan et al. 1995; Saha  but have fibrous overgrowths in cleavage domains and microlithons
                                                               (vertical striping); fibres also occur next to pyrite cubes. If no pyrite
                 1998; Davidson et al. 1998). On theoretical grounds, bulk  cubes or similar objects are present, and if overgrowths on quartz are
                 volume loss on a large scale is expected to be of minor  not clear, situations a and b are difficult to distinguish