Structure The generalised structure

Structure The generalised structure of the Lower Ordovician sediments within the Bendigo Goldfield is that of regular, close spaced folding with extensive local reverse faulting related to the compression event generating the folding. Within the confines of the Bendigo Goldfield, mineralisation is known to occur through at least 3.2 km of the stratigraphic succession.
The main characteristics of folds at Bendigo are their regular frequency, continuity along strike, and their strong structural control of gold-quartz mineralisation. Some folds are continuous for up to 25 km along strike and mining has traced individual anticlines to as deep as 1.6 km. Wavelengths vary from up to 300 m whilst amplitudes vary from 250 m to 600 m.

Folds plunge 5o-10o south at the southern end of the field and 5o-15o north at the northern end producing a broad domal structure in the centre of the goldfield. Local variations in fold plunge give rise to smaller dome and basin structures along the strike of individual anticlines.

Chevron folding (interlimb angles of < 40o) is apparently restricted to the mineralised portion of the Bendigo Goldfield with folding to the east and west more open in character. This variation is important in developing and understanding the mineralisation controls.

Several classes of faults occur in the area, most of which, with the exception of the Whitelaw and Sebastian faults, have small displacements. The Whitelaw and Sebastian Faults are steeply west-dipping reverse faults with a strike fault component and a displacement of at least 1,500 m.

The three main types of minor faults are bedding-plane faults (backs), break faults and oblique-faults (crosscourses) all of which may host quartz-gold mineralisation.

Bedding-plane faults are reverse dip-slip faults confined to single bedding planes. They are characterised by the presence of 1 cm to 200 cm of laminated quartz associated with black carbonaceous pug. The laminated quartz is so characteristic that the term ‘bedded vein’ is usually synonymous with the term ‘bedding-plane fault’. Some bedded veins, however, are not accompanied by pug and show only small displacements parallel to bedding.

Break fault is the general term used to describe reverse faults striking sub-parallel to bedding but truncate bedding when viewed in cross section.

Break faults form as limb thrusts by reactivation of bedding plane faults which then truncate the anticlinal hinge zone. The faults have limited vertical continuity but may extend along strike for several kilometres. The faults may be either east or west dipping, repeat at regular intervals with depth and are the major structural control to mineralisation in the Bendigo Goldfield.

Oblique faults cut across the regional structural trend and were termed ‘crosscourses’ by miners because the faults crossed the reefs displacing them horizontally..

A well-developed cleavage (S1) has developed during folding and is most strongly developed in fold hinges. Cleavage occurs in two main forms dependent on host lithology. In pelitic rocks the closely spaced (sub-millimetre scale) slaty cleavage is parallel to the fold axial surface.

Cleavage in sandstones develops as a more widely spaced differentiated solution cleavage and is best developed at fold hinges as convergent fans. Cleavage lamellae are separated by up to several centimetres and are commonly refracted across bedding contacts between sandstone and shales.