Lengths and hazards from channel-fed lava flows on Mauna Loa, Hawai‘i, determined from thermal and downslope modeling with FLOWGO

Rowland, Scott K.; Garbeil, H.; Harris, Andrew

doi:10.1007/s00445-004-0399-x

Cited by 59 publications

(51 citation statements)

References 33 publications

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“…Baloga et al 1995;Harris and Rowland 2001;Harris and Neri 2002;Jurado-Chichay and Rowland 1995;Keszthelyi and Self 1998;Keszthelyi et al 2000;Rowland et al 2003Rowland et al -2005. Effusion rates can also be obtained in this manner by integrating the vertical velocity profile through the entire flow thickness (Dragoni 1989;Dragoni et al 1986;Fink 1993;Oddone 1910;Tallarico and Dragoni 1999;Soule et al 2005).…”

Section: Model-based Measurementsmentioning

confidence: 98%

“…Thus, effusion rate, velocity and volume are important input parameters into lava flow models and simulations, and/or have been the outputs of others (e.g. Costa and Macedonio 2005;Crisci et al 2003Crisci et al , 2004Favalli et al 2005;Glaze and Baloga 2001;Harris and Rowland 2001;Hikada et al 2005;Ishihara et al 1990; Keszthelyi and Self 1998;Keszthelyi et al 2000;Macedonio and Longo 1999;Rowland et al 2004Rowland et al , 2005Wadge et al 1994;Young and Wadge 1990). Finally, by representing material supplied from a deeper source, effusion rates allow constraint of mass flux out of the shallow feeder system, allowing assessment and/or modelling of the mass balance and dynamics of the effusing or extruding system, and of the source depth and conduit geometry (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…They can also be used in predictive models designed to estimate the possible extent, and thus hazard posed by, advancing flows (e.g. Calvari and Pinkerton 1998;Costa and Macedonio 2005;Crisci et al 2003Crisci et al , 2004Favalli et al 2005;Ishihara et al 1990; Rowland et al 2005).…”

Section: Introductionmentioning

confidence: 99%

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Lava effusion rate definition and measurement: a review

2007

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Measurement of effusion rate is a primary objective for studies that model lava flow and magma system dynamics, as well as for monitoring efforts during on-going eruptions. However, its exact definition remains a source of confusion, and problems occur when comparing volume flux values that are averaged over different time periods or spatial scales, or measured using different approaches. Thus our aims are to: (1) define effusion rate terminology; and (2) assess the various measurement methods and their results. We first distinguish between instantaneous effusion rate, and time-averaged discharge rate. Eruption rate is next defined as the total volume of lava emplaced since the beginning of the eruption divided by the time since the eruption began. The ultimate extension of this is mean output rate, this being the final volume of erupted lava divided by total eruption duration. Whether these values are total values, i.e. the flux feeding all flow units across the entire flow field, or local, i.e. the flux feeding a single active unit within a flow field across which many units are active, also needs to be specified. No approach is without its problems, and all can have large error (up to ∼50%). However, good agreement between diverse approaches shows that reliable estimates can be made if each approach is applied carefully and takes into account the caveats we detail here. There are three important factors to consider and state when measuring, giving or using an effusion rate. First, the time-period over which the value was averaged; second, whether the measurement applies to the entire active flow field, or a single lava flow within that field; and third, the measurement technique and its accompanying assumptions.

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Section: Model-based Measurementsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Lava effusion rate definition and measurement: a review

2007

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“…This may result from the fact that this was a compound flow field, which at times was fed by a complex tube system . FLOWGO is a model for channel-fed flow, where the development of tubes or well-insulated flow will mean that the lava will have the potential to travel further before reaching is cooling-limited extent at any given effusion rate (Harris and Rowland Rowland et al 2005). Fits between model simulations and field data for single, channel-fed units active within this eruption are, however, excellent if appropriate insulation conditions are used, and if single channel-fed flow units active within the flow field are considered (Harris et al 2007a).…”

Section: Methods Part Ii: Land Classification Using Satellite Imagerymentioning

confidence: 99%

“…To do this, we used the FLOWGO thermal-rheological input parameters defined for Etna by Harris et al (2007a), coupled with the effusion rate fitting adaptation applied to FLOWGO by Rowland et al (2005). This assumes an initial (at-vent) square channel, of width w and depth d (so that w = d), and iterates on channel depth to obtain the required effusion rate.…”

Section: 3mentioning

confidence: 99%

Hazard assessment at Mount Etna using a hybrid lava flow inundation model and satellite-based land classification

et al. 2011

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Using a lava flow emplacement model and a satellite-based land cover classification, we produce a map to allow assessment of the type and quantity of natural, agricultural and urban land cover at risk from lava flow invasion. The first step is to produce lava effusion rate contours, i.e., lines linking distances down a volcano's flank that a lava flow will likely extend if fed at a given effusion rate from a predetermined vent zone. This involves first identifying a vent mask and then running a downhill flow path model from the edge of every pixel around the vent mask perimeter to the edge of the DEM. To do this, we run a stochastic model whereby the flow path is projected 1,000 times from every pixel around the vent mask perimeter with random noise being added to the DEM with each run so that a slightly different flow path is generated with each run. The FLOWGO lava flow model is then run down each path, at a series of effusion rates, to determine likely run-out distance for channel-fed flow extending down each path. These results are used to plot effusion rate contours. Finally, effusion rate contours are projected onto a land classification map (produced from an ASTER image of Etna) to assess the type and amount of each land cover class falling within each contour. The resulting maps are designed to provide a quick look-up capability to assess the type of land at risk from lava extending from any location at a range of likely effusion rates. For our first (2,000 m) vent zone case used for Etna, we find a total of area of *680 km 2 is at risk from flows fed at 40 m 3 s -1 , of which *6 km 2 is urban, *150 km 2 is agriculture and *270 km 2 is grass/woodland. The model can also be run for specific cases, where we find that Etna's 1669 vent location, if active today, would likely inundate almost 11 km 2 of urban land, as well as 15.6 km 2 of agricultural land, including 9.5 km 2 of olive groves and 5.2 km 2 of vineyards and fruit/nut orchards.

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How and Why Hawaiian Volcanism Has Become Pivotal to Our Understanding of Volcanoes from Their Source to the Surface

Garcia

2015

Geophysical Monograph Series

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Lengths and hazards from channel-fed lava flows on Mauna Loa, Hawai‘i, determined from thermal and downslope modeling with FLOWGO

Cited by 59 publications

References 33 publications

Lava effusion rate definition and measurement: a review

Lava effusion rate definition and measurement: a review

Hazard assessment at Mount Etna using a hybrid lava flow inundation model and satellite-based land classification

How and Why Hawaiian Volcanism Has Become Pivotal to Our Understanding of Volcanoes from Their Source to the Surface

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