Why Deep-Water Eruptions Are So Different From Subaerial Eruptions

Raymond, Anita; Simmons, Jack M.

doi:10.3389/feart.2018.00198

Cited by 67 publications

(68 citation statements)

References 109 publications

(231 reference statements)

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“…Some rock-types recovered from Resolution-1 have textures that indicate intense material fragmentation (rocks composed of very-fine broken crystals and glassy shards with platy and cuspate shapes), and deposits that commonly contain limestone and sandstones lithics, potentially sourced from the root zone of the MVS diatremes (Figure 12; Figure 13), which maybe represent of fallout material formed by submarine pyroclastic eruptions in the MVS (Bischoff, 2019). Cas and Simmons (2018) suggest that subaqueous effusive eruptions can produce fallout deposits of ash size autoclastic vitric material, similar to typical deposits of subaqueous pyroclastic eruptions. This autoclastic process could explain the large (ca 5 km) seismically detected limits of our ring plain and overspill wedge architectural elements, without necessarily requiring large explosive eruptions, but cannot explain the pit craters excavated into the PrErS horizon.…”

Section: Origin Of the Crater-type Volcanoes In The Mvsmentioning

confidence: 76%

“…Fiske et al, 1998;Bonadonna et al, 2002;White, 2000;Deardoff et al, 2011;Cas and Giordano, 2014; Di Capua and Groppelli, 2016). Rafts of highly vesiculated pumice can travel long distances carried out by currents (Rotella et al, 2013;Cas and Giordano, 2014;Cas and Simmons, 2018). When saturated in water, these fragments sink and can form deposits with size varying from ash to blocks (e.g.…”

Section: Syn-eruptive Architectural Elements: Eruptive Eruption-relamentioning

confidence: 99%

“…). 2 This stratal relationships are commonly observed for deposits formed by explosive eruptions in both subaerial and submarine environments(Cas et al, 1989;White, 1996;White, 2000;Kereszturi and Németh, 2013),3 These textures alone are not diagnose for explosivity, but could also represent submarine auto-brecciation (e.g White and Valentine, 2016;Cas and Simmons, 2018)…”

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confidence: 98%

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Stratigraphy of Architectural Elements of a Buried Monogenetic Volcanic System and Implications for Geoenergy Exploration

Bischoff¹,

Nicol²,

Cole³

et al. 2019

Preprint

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Large volumes of magma emplaced and deposited within sedimentary basins can have an impact on their architectural style and geological evolution. Over the last decade, continuous improvement in techniques such as seismic volcano-stratigraphy and 3D seismic visualization of igneous rocks buried in sedimentary basins has helped increase knowledge about these “volcanic basins”. Here, we unravel the complete architecture of the Maahunui Volcanic System (MVS), a middle Miocene monogenetic volcanic field now buried in the offshore Canterbury Basin, South Island of New Zealand. We show the location, geometry, size, and stratigraphic relationships between 25 main intrusive, eruptive, and sedimentary architectural elements in a comprehensive volcano-stratigraphic framework that explains the evolution of the MVS from emplacement to complete burial. The plumbing system of the MVS comprises of seven main architectural elements, including saucer-shaped sills, dikes and sills swarms, minor stocks and laccoliths, and pre-eruptive strata deformed by intrusions. These endogenous elements occur in five distinctive plumbing-types, controlled by the emplacement depth, and by the geometric relationships between the intrusions and the enclosing strata. The exogenous volcanic architecture is defined by a combination of eruptive and associated sedimentary architectural elements, with minor and localized shallow intrusions. Characteristic volcano-types of the MVS are interpreted as the deep-water equivalents of crater and cone-type volcanoes. Crater-type volcanoes have eight main architectural elements (i.e. root zone, lower and upper diatreme, tephra ring, tephra plain, intra-crater cones, overspill wedge and tephra fallow carpet). Cone-type volcanoes have five main architectural elements (i.e. basal cone, central crater, tephra flank, cone apron and tephra fallout carpet). After volcanism has ceased, the process of degradation and burial of the volcanic edifices produces five main sedimentary architectural elements (i.e. inter-cone plains, epiclastic plumes, canyons and gullies, burial domes and seamount-edge fans). Understanding the relationships between these diverse architectural elements allow us to reconstruct the complete architecture of the MVS, and to recognize the main volcano-stratigraphic trends in the study area. The characterisation of architectural elements of the MVS can be applied to explore opportunities to find valuable geoenergy resources such as oil, gas and geothermal energy with buried and active monogenetic volcanic systems.

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Section: Origin Of the Crater-type Volcanoes In The Mvsmentioning

confidence: 76%

Section: Syn-eruptive Architectural Elements: Eruptive Eruption-relamentioning

confidence: 99%

mentioning

confidence: 98%

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Stratigraphy of Architectural Elements of a Buried Monogenetic Volcanic System and Implications for Geoenergy Exploration

Bischoff¹,

Nicol²,

Cole³

et al. 2019

Preprint

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“…Similar techniques have been, and can be, applied to deposits in the submarine environment to reveal the effect of high hydrostatic pressure from the overlying ocean, which provides a fundamental control on the production of pumiceous clasts (Allen et al 2010;Barker et al 2012;Cas and Giordano 2014;Cas and Simmons 2018;Head and Wilson 2003;Jones et al 2018;Murch et al 2019;Rotella et al 2015;Schipper et al 2010aSchipper et al , 2010bSchipper et al , 2010cVon Lichtan et al 2016;White et al 2015). Explosive fragmentation of magma in conduits is thought to occur at very shallow-depth subaqueous vents or at sufficiently high decompression and strain rates (Cashman and Scheu 2015;Manga et al 2018a).…”

Section: Introductionmentioning

confidence: 99%

Submarine giant pumice: a window into the shallow conduit dynamics of a recent silicic eruption

et al. 2019

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Meter-scale vesicular blocks, termed "giant pumice," are characteristic primary products of many subaqueous silicic eruptions. The size of giant pumices allows us to describe meter-scale variations in textures and geochemistry with implications for shearing processes, ascent dynamics, and thermal histories within submarine conduits prior to eruption. The submarine eruption of Havre volcano, Kermadec Arc, in 2012, produced at least 0.1 km 3 of rhyolitic giant pumice from a single 900-m-deep vent, with blocks up to 10 m in size transported to at least 6 km from source. We sampled and analyzed 29 giant pumices from the 2012 Havre eruption. Geochemical analyses of whole rock and matrix glass show no evidence for geochemical heterogeneities in parental magma; any textural variations can be attributed to crystallization of phenocrysts and microlites, and degassing. Extensive growth of microlites occurred near conduit walls where magma was then mingled with ascending microlite-poor, low viscosity rhyolite. Meter-to micron-scale textural analyses of giant pumices identify diversity throughout an individual block and between the exteriors of individual blocks. We identify evidence for post-disruption vesicle growth during pumice ascent in the water column above the submarine vent. A 2D cumulative strain model with a flared, shallow conduit may explain observed vesicularity contrasts (elongate tube vesicles vs spherical vesicles). Low vesicle number densities in these pumices from this high-intensity silicic eruption demonstrate the effect of hydrostatic pressure above a deep submarine vent in suppressing rapid late-stage bubble nucleation and inhibiting explosive fragmentation in the shallow conduit.

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“…In addition, the dynamics of submarine explosive eruptions may be highly variable: observations at Mata (Tonga Trench) evidence degassing, lava flow emissions, Vulcanian-and Strombolian-like eruptions from the same vent area 11 . Our knowledge on how the deposits of this type of eruptions vary with the distance from the vent, the amount of gas in the emitted magma, the fragmentation mechanisms, the settling times of the pyroclasts, the height of volcanic plumes, and the traveling distance of the generated volcanoclastic flows is, however, poorly constrained 13,14 . Results from theoretical and analogue models show that jets and plumes can raise several hundreds of meters above vents and are, in principle, able to generate gravity currents [2][3][4][5][6][7][8][9][10][11][12][13][14][15] ; however, the results of these models have not been confirmed from field data, with the possible exception represented by nowadays emerged Precambrian pyroclastic deposits 13 .…”

mentioning

confidence: 99%

Deep sea explosive eruptions may be not so different from subaerial eruptions

Iezzi

Lanzafame

Mancini

et al. 2020

Sci Rep

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The dynamics of deep sea explosive eruptions, the dispersion of the pyroclasts, and how submarine eruptions differ from the subaerial ones are still poorly known due to the limited access to sea environments. Here, we analyze two ash layers representative of the proximal and distal deposits of two submarine eruptions from a 500 to 800 m deep cones of the Marsili Seamount (Italy). Fall deposits occur at a distance of more than 1.5 km from the vent, while volcanoclastic flows are close to the flanks of the cone. Ash shows textures indicative of poor magma-water interaction and a gas-rich environment. X-ray microtomography data on ash morphology and bubbles, along with gas solubility and ash dispersion models suggest 200-400 m high eruptive columns and a sea current velocity <5 cm/s. In deep sea environments, Strombolian-like eruptions are similar to the subaerial ones provided that a gas cloud occurs around the vent.

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Why Deep-Water Eruptions Are So Different From Subaerial Eruptions

Cited by 67 publications

References 109 publications

Stratigraphy of Architectural Elements of a Buried Monogenetic Volcanic System and Implications for Geoenergy Exploration

Stratigraphy of Architectural Elements of a Buried Monogenetic Volcanic System and Implications for Geoenergy Exploration

Submarine giant pumice: a window into the shallow conduit dynamics of a recent silicic eruption

Deep sea explosive eruptions may be not so different from subaerial eruptions

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