School of Physical Sciences

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This collection contains Honours, Masters and Ph.D by coursework theses from University of Adelaide postgraduate students within the School of Physical Sciences. The material has been approved as making a significant contribution to knowledge.

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Browsing School of Physical Sciences by Author "Anderson, J. A."

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    Structural and strain analysis of the nose of the Myponga-Little Gorge inlier, Fleurieu Peninsula, South Australia
    (1975) Anderson, J. A.; School of Physical Sciences
    The Myponga-Little Gorge Inlier is the core of a regional reclined fold, which is delineated by the stratigraphy of the Adelaidean cover and by detailed structural analysis. The regional fold formation occurred during the F1 phase of the Palaeozoic Delamerian Orogeny. The regional fold axis is orientated with a shallow southeast plunge which is perpendicular to the regional trend. Although the fold closure is to the southwest, brittle thrusting disrupts the nose of the inlier. Planar zones of extensive phyllonitization and foliation development in basement lithologies adjacent to the overturned basement-cover contact, are interpreted as zones of simple shear. Formation of these zones is considered contemporaneous with the development of an elongation lineation, which is reflected by deformed pebbles and elastic grains in the basal conglomeratic sandstone . A quantitative strain analysis of the conglomerate is discussed. Deformation paths interpreted from the variation of finite strains suggest prolate strains have developed from less significant oblate strains. This is inconsistent with the plane strains inferred by the proposed simple shear model. Two possible explanations are considered likely: a) As Rf/Ø diagram analysis suggests that only one deformation has been imposed on an initial sedimentary fabric, the finite strain variation may not represent a true deformation path, which is a result of two deformations. Therefore plane strain and the simple shear model may be valid. b) The estimates of prolate strains may be realistic, in which case, the simple shear model is invalid. The F2 phase of the Delamerian Orogeny is represented by a small-scale crenulation cleavage and lineation. Widespread but insignificant conjugate faulting also post-dates the regional fold formation.
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