2012
DOI: 10.1029/2011jb008904
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Distal deposition of tephra from the Eyjafjallajökull 2010 summit eruption

Abstract: The 2010 Eyjafjallajökull lasted 39 days and had 4 different phases, of which the first and third (14–18 April and 5–6 May) were most intense. Most of this period was dominated by winds with a northerly component that carried tephra toward Europe, where it was deposited in a number of locations and was sampled by rain gauges or buckets, surface swabs, sticky‐tape samples and air filtering. In the UK, tephra was collected from each of the Phases 1–3 with a combined range of latitudes spanning the length of the … Show more

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Cited by 65 publications
(86 citation statements)
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“…Between 3-5 May an increase in seismic activity was followed by a more intense explosive eruptions. The discharge rate increased and was highly variable (Stevenson et al, 2012). Ash production increased and the eruption column altitude was between 4 and 10 km .…”
Section: Case Study: Eyjafjallajökull Eruption During April and May 2010mentioning
confidence: 96%
See 3 more Smart Citations
“…Between 3-5 May an increase in seismic activity was followed by a more intense explosive eruptions. The discharge rate increased and was highly variable (Stevenson et al, 2012). Ash production increased and the eruption column altitude was between 4 and 10 km .…”
Section: Case Study: Eyjafjallajökull Eruption During April and May 2010mentioning
confidence: 96%
“…During this period the injection altitude of the plume is estimated at between 2 and 10 km (Marzano et al, 2011;Stohl et al, 2011) and the wind conditions transported the ash plume in a SE direction, towards Europe (Petersen et al, 2012). This was the most powerful phase of the eruption with the highest mass discharge rate (Stevenson et al, 2012). The majority of the tephra deposited in Europe was produced in this phase (Stevenson et al, 2012).…”
Section: Case Study: Eyjafjallajökull Eruption During April and May 2010mentioning
confidence: 99%
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“…For example, some fallout deposits may fall outside the defined field in Figure 6 if they are poorly-sorted as a result of ash transportation at different levels in the atmosphere with differing wind trajectories, as in the 1991 Pinatubo eruption (Wiesner et al, 2004). Furthermore, aggregation of clasts of varying sizes commonly occurs in plumes from large explosive eruptions, leading to less wellsorted fallout deposits, which are commonly bimodal and contain a fine ash mode derived from aggregation (Carey and Sigurdsson, 1982;Rose and Durant, 2011;Stevenson et al, 2012;Brown et al, 2012). For the volcaniclastic deposits deemed as non-tephra-fallout deposits, this does not necessarily preclude the presence of some primary tephra-fallout grains as these are average values, and the comminution processes occurring in co-ignimbrite plumes, for example, may plot outside our defined tephra-fallout field.…”
Section: Distinguishing Tephra Fallout Deposits From Other Volcaniclamentioning
confidence: 99%