Abstract
Stratigraphic influence on structural style and strain distribution in deformed sedimentary sequences is well established, in models of 2D mechanical stratigraphy. In this study we attempt to refine existing models of stratigraphic-structure interaction by examining outcrop scale 3D variations in sedimentary architecture and the effects on subsequent deformation. At Monkstone Point, Pembrokeshire, SW Wales, digital mapping and virtual scanline data from a high resolution virtual outcrop have been combined with field observations, sedimentary logs and thin section analysis. Results show that significant variation in strain partitioning is controlled by changes, at a scale of tens of metres, in sedimentary architecture within Upper Carboniferous fluvio-deltaic deposits. Coupled vs uncoupled deformation of the sequence is defined by the composition and lateral continuity of mechanical units and unit interfaces. Where the sedimentary sequence is characterized by gradational changes in composition and grain size, we find that deformation structures are best characterized by patterns of distributed strain. In contrast, distinct compositional changes vertically and in laterally equivalent deposits results in highly partitioned deformation and strain. The mechanical stratigraphy of the study area is inherently 3D in nature, due to lateral and vertical compositional variability. Consideration should be given to 3D variations in mechanical stratigraphy, such as those outlined here, when predicting subsurface deformation in multi-layers.
Highlights
Understanding how deformation processes are impacted by the inherent compositional heterogeneity of the rock volume being deformed is a key question in structural geology
We discuss the findings of our work in the context of understanding 3D mechanical stratigraphy in non-planar multi-layer sedimentary successions, mechanical stratigraphy in contractional settings, and the consequent implications for subsurface prediction of structures
Virtual outcrops were generated of Monkstone Point from 14 Light Detection and Ranging (LiDAR) scans, and by Structure from Motion, using 627 terrestrially acquired digital images
Summary
Understanding how deformation processes are impacted by the inherent compositional heterogeneity of the rock volume being deformed is a key question in structural geology. The complex interplay of stratigraphic heterogeneity and structural mechanisms is well documented at multiple scales of observation and in a range of tectonic settings. Studies have addressed this interaction at thin section Mechanical stratigraphy, or the differences in mechanical properties through a given sequence, has long been known to influence the localisation of strain in contractional settings (Willis, 1893) This concept has been used to explain a range of structural features and patterns, and has been found to influence style of folding Using sedimentary/structural logging, Structure from Motion photogrammetry, compositional analysis of samples and structural measurements we provide a detail analysis of the outcrop and document the extent and localisation of partitioned strain during contractional deformation. We discuss the findings of our work in the context of understanding 3D mechanical stratigraphy in non-planar multi-layer sedimentary successions, mechanical stratigraphy in contractional settings, and the consequent implications for subsurface prediction of structures
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