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Lava penetrating water: the different behaviours of p?hoehoe and ‘a‘? at the Nesjahraun, Þingvellir, Iceland

Stevenson, John Alexander, Mitchell, Neil Charles, Mochrie, Fiona, Cassidy, Michael and Pinkerton, Harry (2012) Lava penetrating water: the different behaviours of p?hoehoe and ‘a‘? at the Nesjahraun, Þingvellir, Iceland Bulletin of Volcanology, 74, (1), pp. 33-46. (doi:10.1007/s00445-011-0480-1).

Record type: Article

Abstract

The Nesjahraun is a basaltic lava flow erupted from a subaerial fissure, extending NE along the Þingvellir graben from the Hengill central volcano that produced p?hoehoe lava followed by ‘a‘?. The Nesjahraun entered Iceland’s largest lake, Þingvallavatn, along its southern shore during both phases of the eruption and exemplifies lava flowing into water in a lacustrine environment in the absence of powerful wave action. This study combines airborne light detection and ranging, sidescan sonar and Chirp seismic data with field observations to investigate the behaviour of the lava as it entered the water. P?hoehoe sheet lava was formed during the early stages of the eruption. Along the shoreline, stacks of thin (5–20 cm thick), vesicular, flows rest upon and surround low (<5 m) piles of coarse, unconsolidated, variably oxidised spatter. Clefts within the lava run inland from the lake. These are 2–5 m wide, >2 m deep, ?50 m long, spaced ?50 m apart and have sub-horizontal striations on the walls. They likely represent channels or collapsed tubes along which lava was delivered into the water. A circular rootless cone, Eldborg, formed when water infiltrated a lava tube. Offshore from the p?hoehoe lavas, the gradient of the flow surface steepens, suggesting a change in flow regime and the development of a talus ramp. Later, the flow was focused into a channel of ‘a‘? lava, ?200–350 m wide. This split into individual flow lobes 20–50 m wide along the shore. ‘A‘? clinker is exposed on the water’s edge, as well as glassy sand and gravel, which has been locally intruded by small (<1 m), irregularly shaped, lava bodies. The cores of the flow lobes contain coherent, but hackly fractured lava. Mounds consisting predominantly of scoria lapilli and the large paired half-cone of Grámelur were formed in phreatomagmatic explosions. The ‘a‘? flow can be identified underwater over 1 km offshore, and the sidescan data suggest that the flow lobes remained coherent flowing down a gradient of <10°. The Nesjahraun demonstrates that, even in the absence of ocean waves, phreatomagmatic explosions are ubiquitous and that p?hoehoe flows are much more likely to break up on entering the water than ‘a‘? flows, which, with a higher flux and shallow underlying surface gradient, can penetrate water and remain coherent over distances of at least 1 km.

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More information

Published date: 2012
Keywords: LiDAR, Lava, Iceland, P?hoehoe, ‘a‘?, Rootless
Organisations: Geochemistry

Identifiers

Local EPrints ID: 338937
URI: http://eprints.soton.ac.uk/id/eprint/338937
ISSN: 0258-8900
PURE UUID: dd3a44d6-d282-4b5e-83a3-8e3e9c074768

Catalogue record

Date deposited: 17 May 2012 15:17
Last modified: 18 Jul 2017 05:56

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Contributors

Author: John Alexander Stevenson
Author: Neil Charles Mitchell
Author: Fiona Mochrie
Author: Michael Cassidy
Author: Harry Pinkerton

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