David W. McGarvie scite author profile

We present field observations from Blzihntlkur, a small volume (<0.l km 3) subglacial rhyolite edifice at the Torf@Skull central volcano, south-central Iceland. Bkihnt]kur was probably emplaced during the last glacial period (ca. 115-11 ka). The characteristics of the deposits suggest that they were formed by an effusive eruption in an exclusively subglacial environment, beneath a glacier >400 m thick. Lithofacies associations attest to complex patterns of volcano-ice interaction. Erosive channels at the base of the subglacial sequence are filled by both eruption-derived material and subglacial till, which show evidence for deposition by flowing meltwater. This suggests that meltwater was able to drain away from the vent area during the eruption. Much of the subglacial volcanic deposits consist of conical-to-irregularly shaped lava lobes typically 5-10 m long, set in poorly sorted breccias with an ash-grade matrix. A gradational lavabreccia contact at the base of lava lobes represents a fossilised fragmentation interface, driven by magma-water interaction as the lava flowed over poorly consolidated, waterlogged debris. Sets of columnar joints on the upper surfaces of lobes are interpreted as ice-contact features. The morphology of the lobes suggests that they chilled within conically shaped subglacial cavities 2-5 m high. Avalanche deposits mantling the flanks of Blzihntikur appear to have been generated by the collapse of lava lobes and surrounding breccia. A variety of deposit characteristics suggests that this occurred both prior to and after quenching of the lava lobes. Collapse events may have occurred when the supporting ice walls were melted back from around the cooling lava lobes and breccias. Much larger lava flows were emplaced in the latter stagEditorial responsibility: W. Hildreth es of the eruption. Columnar joint patterns suggest that these flowed and chilled within subglacial cavities 20 m high and 100-200 m in length. There is little evidence for magma-water interaction at lava flow margins which suggests that these larger cavities were drained of meltwater. As rhyolite magma rose to the base of the glacier, the nature of the subglacial cavity system played an important role in governing the style of eruption and the volcanic facies generated. We present evidence that the cavity system evolved during the eruption, reflecting variations in both melting rate and edifice growth that are best explained by a fluctuating eruption rate.

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The 1875 eruption of Askja volcano, Iceland: combined fractional crystallization and selective contamination in the generation of rhyolitic magma

Macdonald

Sparks

Sigurdsson

et al. 1987

Mineral. mag.

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Major and trace element and Sr, Nd and O isotopic data are presented for ferrobasalts, icelandites, rhyolites, mixed pumices and silicic xenoliths of the 1875 eruption of Askja. Trace element modelling and Sr and Nd data largely confirm previous major element calculations that fractional crystallization was dominant in the generation of the basalt-ferrobasalt-icelandite-rhyolite suite. Relative enrichment in Rb (and Th and U?), depletion in Cs, and low values of 6180/a60, in the rhyolites are not explained by this mechanism alone. The silicic magmas were selectively contaminated by diffusion from partially molten granitic wall rocks, now found as xenoliths in the eruptive products, the process being particularly marked by lower 6180 and Cs/Rb ratios in the rhyolites than in the associated basalts. This is the first record of a combined fractional crystallization-selective contamination process in an Icelandic silicic complex.

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Petrogenetic Evolution of the Torfaj kull Volcanic Complex, Iceland I. Relationship Between the Magma Types

MacDonald

McGarvie

Pinkerton

et al. 1990

Journal of Petrology

105

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An explosive–intrusive subglacial rhyolite eruption at Dalakvísl, Torfajökull, Iceland

et al. 2007

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This paper describes unusual rhyolitic deposits at Dalakvísl, Torfajökull, Iceland that were emplaced during a Quaternary subglacial eruption. Despite its small volume (<0.2 km 3 ), the eruption mechanisms were highly variable and involved both explosive and intrusive phases. The explosive phase involved vesiculation-driven magma fragmentation at the glacier base and generated a pumiceous pyroclastic deposit containing deformed sheets of dense obsidian. Textures suggest that the obsidian was generated by the collapse of partly fragmented foam that was intruding the deposit and water contents indicate quenching at elevated pressures. In contrast, the intrusive phase of the eruption generated vesicle-poor quench hyaloclastites associated with a variety of peperitic lava bodies. The presence of juvenile-rich fluvio-lacustrine sediments is the first documented evidence that meltwater may pond close to the vent during subglacial rhyolite eruptions if the bedrock topography is favourable. In order to explain the variable eruption mechanisms, a conceptual model is presented in which the transition from an explosive to an intrusive eruption was controlled by the space available for fragmentation within the subglacial cavity melted above the vent. When the cavity became completely filled by volcanic deposits, the vent became blocked and rising magma was forced to intrude through poorly consolidated debris. This led to arrested fragmentation and welding of foam domains to form vesicle-poor obsidian lava; the transition to an intrusive eruption has taken place. Although this ventblocking mechanism is particularly relevant to subglacial eruptions, it may also apply to subaerial rhyolitic eruptions, where patterns of explosive and effusive activity cannot be explained by shallow degassing processes alone. Meanwhile, the variable style of a small-volume subglacial rhyolite eruption further highlights the complex processes that mediate volcano-ice interactions.Keywords Volcano-ice interaction . Rhyolite . Obsidian . Pumice . Explosive volcanism . Fragmentation . Subglacial volcanism Subglacial volcanic eruptions are complex events that involve melting and deformation of an ice sheet, quenching and disruption of magma and either drainage or temporary retention of meltwater (e.g. Guðmundsson et al. 1997;Smellie 2000). Significant advances in our understanding of the processes involved have occurred in the last decade, through field studies of ancient deposits (e.g.

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Torfajökull: A volcano dominated by magma mixing

McGarvie

1984

Geol

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David W. McGarvie

Products of an effusive subglacial rhyolite eruption: Bláhnúkur, Torfajökull, Iceland

The 1875 eruption of Askja volcano, Iceland: combined fractional crystallization and selective contamination in the generation of rhyolitic magma

Petrogenetic Evolution of the Torfaj kull Volcanic Complex, Iceland I. Relationship Between the Magma Types

An explosive–intrusive subglacial rhyolite eruption at Dalakvísl, Torfajökull, Iceland

Torfajökull: A volcano dominated by magma mixing

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