Your search keyword '"bepress|Physical Sciences and Mathematics|Earth Sciences|Geology"' showing total 2 results

1. Pre-inversion normal fault geometry controls inversion style and magnitude, Farsund Basin, offshore southern Norway

Author

James Norcliffe, Christopher A.-L. Jackson, and Thomas Phillips

Subjects

bepress|Physical Sciences and Mathematics, Stratigraphy, Inversion (geology), bepress|Physical Sciences and Mathematics|Earth Sciences|Tectonics and Structure, Soil Science, bepress|Physical Sciences and Mathematics|Earth Sciences, Geometry, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, Neogene, Unconformity, lcsh:Stratigraphy, Geochemistry and Petrology, Lithosphere, Alpine orogeny, Earth-Surface Processes, lcsh:QE640-699, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geology, Palaeontology, bepress|Physical Sciences and Mathematics|Earth Sciences|Geology, lcsh:QE1-996.5, Anticline, Paleontology, Geology, Cretaceous, EarthArXiv|Physical Sciences and Mathematics, lcsh:Geology, Plate tectonics, Geophysics, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Tectonics and Structure

Abstract

Compressional strains may manifest along pre-existing structures within the lithosphere, far from the plate boundaries along which the causal stress is greatest. The style and magnitude of the related contraction is expressed in different ways, depending on the geometric and mechanical properties of the pre-existing structure. A three-dimensional approach is thus required to understand how compression may be partitioned and expressed along structures in space and time. We here examine how post-rift compressional strains are expressed along the northern margin of the Farsund Basin during Late Cretaceous inversion and Palaeogene–Neogene pulses of uplift. At the largest scale, stress localises along the lithosphere-scale Sorgenfrei-Tornquist Zone, where it is expressed in the upper crust as hangingwall folding, reverse reactivation of the basin-bounding normal fault, and bulk regional uplift. The geometry of the northern margin of the basin varies along strike, with a normal fault system passing eastward into an unfaulted ramp. Late Cretaceous compressive stresses, originating from the convergence between Africa, Iberia, and Europe, selectively reactivated geometrically simple, planar sections of the fault, producing hangingwall anticlines and causing long-wavelength folding of the basin fill. The amplitude of these anticlines decreases upwards due to tightening of pre-existing fault propagation folds at greater depths. In contrast, later Palaeogene–Neogene uplift is accommodated by long-wavelength folding and regional uplift of the entire basin. Subcrop mapping below a major, uplift-related unconformity and borehole-based compaction analysis show that uplift increases to the north and east, with the Sorgenfrei-Tornquist Zone representing a hinge line rather than a focal point to uplift, as was the case during earlier Late Cretaceous compression. We show how compressional stresses may be accommodated by different mechanisms within structurally complex settings. Furthermore, the prior history of a structure may also influence the mechanism and structural style of shortening that it experiences.

Published

2020

2. Mechanical models to estimate the paleostress state from igneous intrusions

Author

Stephens, Tara, Walker, Richard, Healy, David, Bubeck, Alodie, and England, Richard

Subjects

bepress|Physical Sciences and Mathematics, Dike, 010504 meteorology & atmospheric sciences, Stratigraphy, bepress|Physical Sciences and Mathematics|Earth Sciences|Tectonics and Structure, bepress|Physical Sciences and Mathematics|Earth Sciences, Volcanology, Soil Science, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, 010502 geochemistry & geophysics, 01 natural sciences, bepress|Physical Sciences and Mathematics|Earth Sciences|Volcanology, Stress (mechanics), Brittleness, Sill, lcsh:Stratigraphy, Geochemistry and Petrology, Physical Sciences and Mathematics, Thrust fault, Petrology, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Volcanology, 0105 earth and related environmental sciences, Earth-Surface Processes, lcsh:QE640-699, geography, geography.geographical_feature_category, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geology, bepress|Physical Sciences and Mathematics|Earth Sciences|Geology, lcsh:QE1-996.5, Paleontology, Geology, FOS: Earth and related environmental sciences, EarthArXiv|Physical Sciences and Mathematics, lcsh:Geology, Tectonics, Geophysics, Volcano, Shear (geology), EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Tectonics and Structure, Earth Sciences, Tectonics and Structure

Abstract

Dikes and sills represent an important component of the deformation history in volcanic systems, but unlike dikes, sills are typically omitted from traditional paleostress analyses in tectonic studies. The emplacement of sheet intrusions is commonly associated with mode I fracturing in a low deviatoric stress state, where dilation is perpendicular to the fracture plane. Many natural examples of sills and dikes, however, are observed to accommodate minor shear offsets, in addition to a component of dilation. Here we present mechanical models for sills in the San Rafael Subvolcanic Field, Utah, which use field-derived measurements of intrusion attitude and opening angles to constrain the tectonic stress axes during emplacement, and the relative magma pressure for that stress state. The sills display bimodal dips to the NE and SW and consistent vertical opening directions, despite variable sill dips. Based on sill attitude and opening angles, we find that the sills were emplaced during a phase of NE-SW horizontal shortening. Calculated principal stress axes are consistent (within ~ 4°) with paleostress results for penecontemporaneous thrust faults in the area. The models presented here can be applied to any set of dilational structures, including dikes, sills, or hydrous veins, and represent a robust method for characterising the paleostress state in areas where other brittle deformation structures (e.g. faults), are not present.

Published

2018