New insights into the mechanics of sill emplacement provided by field observations of the Njardvik Sill, Northeast Iceland

Burchardt, Steffi

doi:10.1016/j.jvolgeores.2008.02.009

Cited by 66 publications

(40 citation statements)

References 44 publications

(66 reference statements)

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“…Table shows the range of values for each parameter in the models and nature, with the associated scaling factor. The scaled Young's modulus considered in our models corresponds to 10 10 Pa, within the range of natural rocks (10 9 –10 10 , Kavanagh et al, ; Table ), while the average intrusion lengths ( H ) before dike to sill rotation in the experiments (~11 cm) corresponds to ~2,200 m in nature, consistently with the length of dikes feeding sills (Burchardt, ; Famin & Michon, ). The lateral compression imposed in the experiments corresponds, scaled, to 10 6 Pa (Table ), thus within the range of compressive stresses in nature (between 10 5 and 10 8 Pa; Menand et al, ).…”

Section: Experimental Methodssupporting

confidence: 69%

“…Natural examples of rigidity contrasts (i.e., stiff layer above a weak one, as imposed in our models) are common in many volcanic areas with alternating soft scoria (or pyroclastic) layers and stiff lava flows, such as in SW Iceland and Tenerife (Gudmundsson, ; Gudmundsson & Løtveit, ). Field observations on the Njardvik Sill (Northeast Iceland; Burchardt, ) show initial sill emplacement when an inclined sheet dipping 46° met the horizontal contact between a rhyolitic intrusion of the Njardvik Silicic Complex and the overlying basaltic lava flows. For the Njardvik Sill, the rigidity contrast between the rhyolitic Njardvik Silicic Complex and the basaltic lava flows (inferred to be E u / E l = 3) might have caused a local stress rotation and the mechanical properties of the interface between rhyolite and basalt might have encouraged stress rotation and the intrusion of the first sill unit of the Njardvik Sill (Burchardt, ).…”

Section: Discussionmentioning

confidence: 99%

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What Controls Sill Formation: An Overview From Analogue Models

2019

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Understanding the mechanisms of shallow magma storage (less than ~10‐km depth) is crucial to defining volcanic plumbing systems and their effect on volcano unrest. Sills are common structures to emplace shallow magma. Many factors may control sill emplacement, but their relative importance has not been evaluated so far. To define a hierarchy among a selection of the proposed factors, we performed analogue models by injecting water at constant flux (magma analogue) within gelatin (crust analogue), investigating the effects of: interface strength and rigidity contrast between layers, density layering, ratio of layer thickness, compressive stresses, magma flow rate, and buoyancy pressure. Our results show that a strong rigidity contrast (i.e., a stiff layer overlying a weak one) and a higher buoyancy pressure are necessary and sufficient conditions for sill emplacement. Low rigidity contrasts require other contributions (weak interface and compressive stress) to develop sills; however, without rigidity contrast sill formation is always inhibited. These experiments suggest that sill emplacement is primarily controlled by rigidity contrasts and magma buoyancy pressure; the second‐order parameters are lateral compression and weak interfaces; the third‐order parameters are the ratio of layer thicknesses, magma flow rate, and density layering. These results are in agreement with field observations in Iceland, Tenerife, Utah, and La Réunion, supporting our proposed hierarchy.

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Section: Experimental Methodssupporting

confidence: 69%

Section: Discussionmentioning

confidence: 99%

What Controls Sill Formation: An Overview From Analogue Models

2019

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“…4a). Lateral injection of magma to build the initial sill may occur along subhorizontal weak planes2425 such as those between lavas and pyroclastic deposits beneath the vent (Supplementary Fig. 3).…”

Section: Resultsmentioning

confidence: 99%

Rapid laccolith intrusion driven by explosive volcanic eruption

Castro¹,

Cordonnier

Schipper

et al. 2016

Nat Commun

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Magmatic intrusions and volcanic eruptions are intimately related phenomena. Shallow magma intrusion builds subsurface reservoirs that are drained by volcanic eruptions. Thus, the long-held view is that intrusions must precede and feed eruptions. Here we show that explosive eruptions can also cause magma intrusion. We provide an account of a rapidly emplaced laccolith during the 2011 rhyolite eruption of Cordón Caulle, Chile. Remote sensing indicates that an intrusion began after eruption onset and caused severe (>200 m) uplift over 1 month. Digital terrain models resolve a laccolith-shaped body ∼0.8 km3. Deformation and conduit flow models indicate laccolith depths of only ∼20–200 m and overpressures (∼1–10 MPa) that likely stemmed from conduit blockage. Our results show that explosive eruptions may rapidly force significant quantities of magma in the crust to build laccoliths. These iconic intrusions can thus be interpreted as eruptive features that pose unique and previously unrecognized volcanic hazards.

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“…Although commonly used, these models have serious limitations: They model simplistic intrusion and fault shapes, such as point source [ Mogi , ; Masterlark , ], tensile [e.g., Okada , ; Amelung et al ., ; Wright et al ., ; Chang et al ., ; Sigmundsson et al ., ], or shear dislocation rectangle [ Okada , ; Shen et al ., ; Gusman et al ., ; Yue et al ., ]. These deformation sources are not representative of the complex shapes of magmatic intrusions or fault planes in nature [e.g., Burchardt , ; Lohr et al ., ; Burchardt et al ., ]. They model static intrusions/fault planes, such that they do not account for the complex magma propagation mechanisms [ Mathieu et al ., ; Abdelmalak et al ., ] or fault mechanics [ Mair and Abe , , ; Brodsky and Lay , ]; It is impossible to quantify the uncertainties of the model results and so to test their robustness. The main reason is that active geological processes occur in the subsurface, so that the results of the modeling cannot be validated by direct observations. …”

Section: Discussionmentioning

confidence: 99%

Application of open‐source photogrammetric software MicMac for monitoring surface deformation in laboratory models

et al. 2016

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Quantifying deformation is essential in modern laboratory models of geological systems. This paper presents a new laboratory monitoring method through the implementation of the open‐source software MicMac, which efficiently implements photogrammetry in Structure‐from‐Motion algorithms. Critical evaluation is provided using results from two example laboratory geodesy scenarios: magma emplacement and strike‐slip faulting. MicMac automatically processes images from synchronized cameras to compute time series of digital elevation models (DEMs) and orthorectified images of model surfaces. MicMac also implements digital image correlation to produce high‐resolution displacements maps. The resolution of DEMs and displacement maps corresponds to the pixel size of the processed images. Using 24 MP cameras, the precision of DEMs and displacements is ~0.05 mm on a 40 × 40 cm surface. Processing displacement maps with Matlab® scripts allows automatic fracture mapping on the monitored surfaces. MicMac also offers the possibility to integrate 3‐D models of excavated structures with the corresponding surface deformation data. The high resolution and high precision of MicMac results and the ability to generate virtual 3‐D models of complex structures make it a very promising tool for quantitative monitoring in laboratory models of geological systems.

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New insights into the mechanics of sill emplacement provided by field observations of the Njardvik Sill, Northeast Iceland

Cited by 66 publications

References 44 publications

What Controls Sill Formation: An Overview From Analogue Models

What Controls Sill Formation: An Overview From Analogue Models

Rapid laccolith intrusion driven by explosive volcanic eruption

Application of open‐source photogrammetric software MicMac for monitoring surface deformation in laboratory models

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