Dynamics of deep-submarine volcanic eruptions

Abstract: Deposits from explosive submarine eruptions have been found in the deep sea, 1–4 km below the surface, with both flow and fall deposits extending several km’s over the seafloor. A model of a turbulent fountain suggests that after rising 10–20 m above the vent, the erupting particle-laden mixture entrains and mixes with sufficient seawater that it becomes denser than seawater. The momentum of the resulting negatively buoyant fountain is only sufficient to carry the material 50–200 m above the seafloor and much … Show more

“…After sufficient mixing, this flow becomes negatively buoyant and behaves as a multiphase fountain, consisting of a size distribution of pyroclasts and warm water, and the subsequent dynamics of the flow will be affected by the conditions of the ambient water column, such as ocean currents (Head & Wilson 2003; Cas & Simmons 2018; Newland et al. 2022).…”

“…We can utilise the model presented in Newland et al. (2022) to calculate the conditions of an eruption column as it transitions to a negatively buoyant flow and, using the framework presented in this paper, we can describe how the magnitude of ocean currents and the size of pyroclasts may affect the eruption dynamics. In figure 12, using similar source conditions as presented in Murch et al.…”

“…The following source conditions were used in the model presented in Newland et al. (2022) to simulate the conditions found at the Havre eruption of 2012 (Murch et al. 2020): vent km, vent m, initial , magma kg m and magma C.…”

“…The release of particle-laden fluid into the environment occurs in many settings, including both subaerial and subaqueous explosive volcanic eruptions (Head & Wilson 2003; Woods 2010; Newland, Mingotti & Woods 2022; Rowell et al. 2022) and tailings discharge from vessels during deep-sea mining (Mingotti & Woods 2020).…”

“…Using similar experimental techniques, Carazzo, Kaminski & Tait (2015) and Newland et al. (2022) investigated the effect of particle-sedimentation in turbulent fountains on the dynamics of volcanic eruption columns.…”

On particle fountains in a crossflow

“…After sufficient mixing, this flow becomes negatively buoyant and behaves as a multiphase fountain, consisting of a size distribution of pyroclasts and warm water, and the subsequent dynamics of the flow will be affected by the conditions of the ambient water column, such as ocean currents (Head & Wilson 2003; Cas & Simmons 2018; Newland et al. 2022).…”

“…We can utilise the model presented in Newland et al. (2022) to calculate the conditions of an eruption column as it transitions to a negatively buoyant flow and, using the framework presented in this paper, we can describe how the magnitude of ocean currents and the size of pyroclasts may affect the eruption dynamics. In figure 12, using similar source conditions as presented in Murch et al.…”

“…The following source conditions were used in the model presented in Newland et al. (2022) to simulate the conditions found at the Havre eruption of 2012 (Murch et al. 2020): vent km, vent m, initial , magma kg m and magma C.…”

“…The release of particle-laden fluid into the environment occurs in many settings, including both subaerial and subaqueous explosive volcanic eruptions (Head & Wilson 2003; Woods 2010; Newland, Mingotti & Woods 2022; Rowell et al. 2022) and tailings discharge from vessels during deep-sea mining (Mingotti & Woods 2020).…”

“…Using similar experimental techniques, Carazzo, Kaminski & Tait (2015) and Newland et al. (2022) investigated the effect of particle-sedimentation in turbulent fountains on the dynamics of volcanic eruption columns.…”

On particle fountains in a crossflow

Influence of Environment on Magma Properties, Eruption Processes, and Deposits

Explosive Eruption Styles, Columns, and Pyroclastic Fallout Deposits