Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

Poppe, Sam; Galland, Olivier; Winter, Niels J. de; Goderis, Steven; Claeys, Philippe; Debaille, Vinciane; Boulvais, Philippe; Kervyn, Matthieu

doi:10.1029/2019gc008685

Cited by 20 publications

(30 citation statements)

References 101 publications

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“…The low values of thickness-to-length aspect ratios of sheet intrusions have been interpreted as indicators of emplacement as Mode I tensile fractures [2,[17][18][19][20]. In agreement with this model, field observations of sharp intrusion tip geometries have been mostly described for low-viscosity magma [18,[21][22][23]. However, observed tips of high-viscosity magma intrusions exhibit blunt shapes [21,[24][25][26], suggesting another emplacement mechanism than Mode I tensile fracturing [21,24,27].…”

Section: Introductionmentioning

confidence: 53%

Emplacement and Segment Geometry of Large, High-Viscosity Magmatic Sheets

et al. 2021

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Understanding magma transport in sheet intrusions is crucial to interpreting volcanic unrest. Studies of dyke emplacement and geometry focus predominantly on low-viscosity, mafic dykes. Here, we present an in-depth study of two high-viscosity dykes (106 Pa·s) in the Chachahuén volcano, Argentina, the Great Dyke and the Sosa Dyke. To quantify dyke geometries, magma flow indicators, and magma viscosity, we combine photogrammetry, microstructural analysis, igneous petrology, Fourier-Transform-Infrared-Spectroscopy, and Anisotropy of Magnetic Susceptibility (AMS). Our results show that the dykes consist of 3 to 8 mappable segments up to 2 km long. Segments often end in a bifurcation, and segment tips are predominantly oval, but elliptical tips occur in the outermost segments of the Great Dyke. Furthermore, variations in host rocks have no observable impact on dyke geometry. AMS fabrics and other flow indicators in the Sosa Dyke show lateral magma flow in contrast to the vertical flow suggested by the segment geometries. A comparison with segment geometries of low-viscosity dykes shows that our high-viscosity dykes follow the same geometrical trend. In fact, the data compilation supports that dyke segment and tip geometries reflect different stages in dyke emplacement, questioning the current usage for final sheet geometries as proxies for emplacement mechanism.

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Section: Introductionmentioning

confidence: 53%

Emplacement and Segment Geometry of Large, High-Viscosity Magmatic Sheets

et al. 2021

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“…We can consider the potential for post-emplacement overprinting through detailed field-based textural and structural characterisation of the host rock and intrusion [e.g., Bons et al, 2004]. Few studies have focused on syn-emplacement variations in host rock and magma properties, which may cause a transition in the intrusion tip geometry and emplacement mechanism [Poppe et al, 2020]. Tapered through to superelliptical sill segments outcrop in the Neist Point study area, within no correlation between host rock lithology and emplacement mechanism ( Fig.…”

Section: Controls On Sheet Intrusion Tip Geometrymentioning

confidence: 99%

“…An issue that is generally omitted in intrusion growth models, is that magma and host rock properties can change during the lifetime of an intrusive event [Poppe et al, 2020].…”

Section: Introductionmentioning

confidence: 99%

“…Tensile failure is therefore inhibited, and the segment tip may inflate to accommodate the driving pressure, producing a rounded tip geometry [e.g. Cañón-Tapia and Merle].Few studies have documented the presence of tapered and rounded segment geometries in the same study area [exceptions includeBaer, 1991;Kjøll et al, 2019, Poppe et al, 2020 Baer [1991]. suggests that dykes may propagate in a poorly cemented sandstone by a cyclic process of brittle fracture and viscous fingering that depends on the availability of magma-related fluids and local resistance of the host rock to fluidization.…”

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confidence: 99%

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Segment tip geometry of sheet intrusions, II: Field observations of tip geometries and a model for evolving emplacement mechanisms

Stephens¹,

Walker²,

Healy³

et al. 2022

Preprint

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Igneous sheet intrusions are segmented across several orders of magnitude, with segment tip geometry commonly considered indicative of the propagation mechanism (brittle or nonbrittle). Proposed propagation mechanisms are inferred to represent host rock mechanical properties during initial magma emplacement; typically, these models do not account for segment sets that show a range of tip geometries within the same lithology. We present a detailed structural characterization of basaltic sill segments and their associated host rock deformation from the Little Minch Sill Complex, Isle of Skye, UK, and a broader comparison with segment geometries in three additional intrusive suites (Utah, USA; and Mull and Orkney, UK). Each separate host lithology shows multiple tip geometries and styles of host rock deformation, from elastic-brittle fracture, to viscous indentation and fluidisation. We attribute this range of host rock deformations to evolving conditions that occur at the tips both during sheet growth and arrest.

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“…Intrusion segments are generally treated as representing the staged growth of through-going sheets, with isolated segments inferred to represent the earliest stages of the process (Delaney and Pollard, 1981;Baer and Reches, 1987;Rickwood, 1990;Schofield et al, 2012), before linkage to create the sheet-like form of sills, dykes, or inclined sheets. Field-based observations of intrusive segment tips tend to be the lateral edges of the segments as viewed in the axis of bulk magma transport (e.g., Galland et al, 2019), rather than the terminal end tip region at the distal extremities of the segment (e.g., Poppe et al, 2020). In either case, observations of segment tips are of a system that did not grow further than the observed state, and therefore represent the arresting form of segments, rather than the growing form.…”

Section: The Field Record Of Igneous Sheet Intrusionsmentioning

confidence: 99%

Segment tip geometry of sheet intrusions, I: Theory and numerical models for the role of tip shape in controlling propagation pathways.

Walker¹,

Stephens²,

Greenfield³

et al. 2021

Preprint

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This manuscript is submitted to EarthArXiv as a pre-print and has not yet been peer-reviewed. Please note that following peer-review, subsequent versions of this paper may have slightly different content. If accepted for publication, the final version of this pre-print will also be made available. Please feel free to contact the corresponding author directly. We welcome constructive feedback. Title: Segment tip geometry of sheet intrusions, I: Theory and numerical models for the role of tip shape in controlling propagation pathways.

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Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

Cited by 20 publications

References 101 publications

Emplacement and Segment Geometry of Large, High-Viscosity Magmatic Sheets

Emplacement and Segment Geometry of Large, High-Viscosity Magmatic Sheets

Segment tip geometry of sheet intrusions, II: Field observations of tip geometries and a model for evolving emplacement mechanisms

Segment tip geometry of sheet intrusions, I: Theory and numerical models for the role of tip shape in controlling propagation pathways.

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