2020
DOI: 10.1029/2019jb019041
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The Roles of Elastic Properties, Magmatic Pressure, and Tectonic Stress in Saucer‐Shaped Sill Growth

Abstract: Near-surface igneous sills commonly exhibit saucer-like shapes, formed due to interaction with the Earth's surface once some critical sill length is reached relative to its depth. Sill geometry has been strongly linked to the host material conditions, particularly in terms of the elastic properties and shear cohesion of the host rock, operating as primary controls on sill geometry. Here we conduct dynamic numerical simulations for sill growth in the near surface, in which we vary the host rock properties, magm… Show more

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Cited by 15 publications
(28 citation statements)
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“…2018; Burchardt et al 2019], magma driving pressure relative to the tectonic stress [Gill and Walker 2020], depth of emplacement [Gill and Walker 2020], and the remote stress state [e.g. Pollard 1973;Pollard et al 1975;Rubin 1993;Walker and Gill 2020].…”
Section: [E] Brittle Faulting Model [After Pollardmentioning
confidence: 99%
See 1 more Smart Citation
“…2018; Burchardt et al 2019], magma driving pressure relative to the tectonic stress [Gill and Walker 2020], depth of emplacement [Gill and Walker 2020], and the remote stress state [e.g. Pollard 1973;Pollard et al 1975;Rubin 1993;Walker and Gill 2020].…”
Section: [E] Brittle Faulting Model [After Pollardmentioning
confidence: 99%
“…Inflow of pore fluids may cause non-localised inelastic damage in the process zone ahead of the intrusion, which increases the energy required for continued fracture propagation [Rubin 1993;Gudmundsson 2011]. However, the pressure gradient arising from low pressure in the cavity also serves to drive magma flow toward the tip [Gill and Walker 2020]. Importantly in the Barenblatt model, if the magma driving pressure cannot drive further propagation of the fracture plane, it will instead cause inflation and rounding of the magma front, blunting the preserved tip geometry.…”
Section: [E] Brittle Faulting Model [After Pollardmentioning
confidence: 99%
“…Haug et al, 2017, 2018]. Other factors affecting emplacement mechanism include the magma viscosity [Mattsson et al, 2018;Burchardt et al, 2019;Wilson et al, 2019], magma driving pressure relative to the tectonic stress [Gill and Walker, 2020], the depth of emplacement (Gill and Walker, 2020), and the remote stress state [e.g. Pollard 1973;Pollard et al, 1975;Rubin, 1993;Chanceaux and Menand, 2016;Walker and Gill, 2020].…”
Section: Mechanisms Of Segment Propagation and Resulting Geometrymentioning
confidence: 99%
“…However, the pressure gradient arising from low pressure in the cavity also serves to drive magma flow toward the tip [Gill and Walker, 2020]. Importantly in the Barenblatt model, if the magma driving pressure cannot facilitate further propagation of the fracture plane, the driving pressure will instead be accommodated by inflation and rounding of the magma front, without an increase in fracture length.…”
Section: Elastic-brittle Tip-zone Modelsmentioning
confidence: 99%
“…Preserved tips and isolated segments are therefore treated as being representative of the growth stages of sheet development (Magee et al, 2019). This classical model for sheet emplacement has been generally considered as an elastic-brittle process, in which magma pressure in the intrusion performs work on the intrusion walls in a hydraulic fracture (Rubin, 1995;Gill and Walker, 2020). Deformation ahead of the tip occurs as elastic bending of the host rock to accommodate the gradual gradient of the intrusion thickness (Fig.…”
Section: Background: Relating Crack Shape To Stress In the Host Rockmentioning
confidence: 99%