A revisit of the role of gas entrapment on the stability conditions of explosive volcanic columns

Michaud-Dubuy, Audrey; Carazzo, Guillaume; Kaminski, E. C.; Girault, Frédéric

doi:10.1016/j.jvolgeores.2018.05.005

Cited by 14 publications

(13 citation statements)

References 82 publications

(161 reference statements)

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“…All available options were used aside from particle aggregation. Although aggregation is known to be an important process in Sakurajima (Bagheri et al, ; Gilbert & Lane, ) and the total grain size distribution (TGSD) of each eruption is known to impact plume height (Macedonio et al, ; Michaud‐Dubuy et al, ), owing to the lack of concrete data and the large span of the study period, the TGSD used is the one assigned to Sakurajima by Mastin et al (), that is, 0.24, 0.25, 0.2, 0.12, 0.09, 0.0425, 0.0325, 0.0125, 0.0075, and 0.005 for ϕ ranging between −1 and 8 (

ϕ = - \log_{2} false(d false)

in millimeters).…”

Section: Location and Methodologymentioning

confidence: 99%

“…In the calculations here U 0 was based on FPLUME output but the exit velocity at the vent was arbitrarily set at 120 m/s. Finally, the TGSD is known to affect plume height (Michaud‐Dubuy et al, ), but this effect was ignored due to the lack of data. For a more detailed approach on the subject, FPLUME would need to be coupled with a numerical weather prediction model to allow for high‐resolution computational experiments to mirror the controlled nature of analog experiments (e.g., Carazzo et al, ).…”

Section: Plume Regime Separationmentioning

confidence: 99%

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The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

2019

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Volcanic plumes from small and moderate eruptions represent a challenge in the study of plume morphology due to eruption source parameter uncertainties and atmospheric influence. Sakurajima volcano, Japan, features such activity and due to its continuous eruptions in the recent years provides an ideal natural laboratory. A data set of 896 eruptions between 2009 and 2016 with well‐constrained plume heights, estimated erupted mass, and associated atmospheric conditions has been compiled. Plume heights ranged between 1,500 and 5,000 m and mainly developed under stable atmospheric stratification and low background wind speeds. The eruptions presented in the database were used to drive FPLUME, a 1‐D integral volcanic plume model, to study the simulated plume morphology. FPLUME was seen to provide consistent results under stable atmospheric stratification. A method for the real‐time monitoring of erupted mass used in the Sakurajima observatory was seen to provide appropriate first guess estimates for the eruptions, showing agreement with analytical and simulated mass flow rate calculations. Volcanic plumes from Sakurajima show significant influence by the atmospheric environment. The plume scaling parameter (Π) was used to characterize the expected degree of plume bending with results correlating well against modeled plume angles. The vertical wind profile was seen to have a significant impact on the resolved plume. Wind shear characteristics were seen to have a mechanical effect on the plume, aiding or inhibiting bending. Finally, potential issues were identified in simulations under unstable atmospheric conditions as the model either failed to provide a solution or overestimated the plume height.

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ϕ = - \log_{2} false(d false)

in millimeters).…”

Section: Location and Methodologymentioning

confidence: 99%

Section: Plume Regime Separationmentioning

confidence: 99%

The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

2019

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“…We now use the constant value of wind entrainment coefficient β found with our laboratory experiments to parameterize our 1‐D theoretical model (PPM) of explosive volcanic eruption (Michaud‐Dubuy et al, 2018), which is detailed in Appendix A. As described in Michaud‐Dubuy et al (2018), this model takes into account particle sedimentation, modulation of the effective amount of gas in the column (through gas entrapment and open porosity), as well as the variation of the entrainment coefficient α . Our theoretical analysis and laboratory experiments highlight the importance of both Ri 0 and W ∗ , a result consistent with previous studies (Degruyter & Bonadonna, 2013).…”

Section: Volcanological Implicationsmentioning

confidence: 99%

Wind Entrainment in Jets with Reversing Buoyancy: Implications for Volcanic Plumes

2020

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Explosive volcanic eruptions commonly undergo a transition from stable plume to collapsing fountain with associated destructive pyroclastic density currents. A major goal in physical volcanology is to predict quantitatively the limit between the flow regimes as a function of the source and environmental conditions. Atmospheric winds influence the dynamics and stability of the column causing bending and enhancing turbulent air entrainment. However, the predictions made with 1-D models of volcanic plumes accounting for the presence of wind strongly depend on the wind entrainment coefficient , a parameter whose value varies in the literature. Here we present a new theoretical model to identify an analytical criterion for column collapse in windy conditions. We then present new laboratory experiments on turbulent jets with reversing buoyancy rising in a crossflow in order to better constrain. Our results show that a single value of = 0.5 can be used to describe the behavior of laboratory jets with arbitrary buoyancy. The results allow us to parameterize our 1-D model of volcanic plumes PPM and to show the crucial importance of wind gradient and profile on volcanic column dynamics through the use of the 1991 Mt. Hudson eruption as a case study. Finally, we propose a new transition diagram between the stable plume and collapsing fountain regimes, as a function of wind speed and mass discharge rate only, which can be used for the rapid assessment of major hazards during an explosive eruption. Since the 1970s, numerous 1-D, 2-D, and 3-D theoretical models provided a good knowledge of the overall physics of these eruptions and have yielded a better understanding of the conditions leading to column collapse (

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“…The total grain-size distribution (TGSD) is an essential input for models of tephra transport and dispersion in the rising volcanic plume (Michaud-Dubuy et al, 2018) and the spreading umbrella cloud (Macedonio et al, 2005), as it gives the mass percentage of the different particle classes at the source. The TGSD of a given unit is calculated from the grain-size distribution of each individual sample collected in the field for this unit.…”

Section: Grain-size Analysesmentioning

confidence: 99%

“…The value of the exponent D reflects the fragmentation efficiency, and thus quantifies the fraction of fine (D > 3, efficient fragmentation) or coarse (D < 3, poorly efficient fragmentation) particles in the deposit. It has been proven to control the total amount of gas available in the turbulent flow (Kaminski and Jaupart, 1998) hence to affect the maximum column height of sustained Plinian columns (Girault et al, 2014) and collapsing fountains (Michaud-Dubuy et al, 2018). This parameter is thus important to characterize the eruption dynamics.…”

Section: Appendix Amentioning

confidence: 99%

Impact of wind direction variability on hazard assessment in Martinique (Lesser Antilles): The example of the 13.5 ka cal BP Bellefontaine Plinian eruption of Mount Pelée volcano

Michaud-Dubuy

Carazzo

Tait

et al. 2019

Journal of Volcanology and Geothermal Research

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HAL is a multidisciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L'archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d'enseignement et de recherche français ou étrangers, des laboratoires Impact of wind direction variability on hazard assessment in Martinique (Lesser Antilles): the example of the 13.5 ka cal BP

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A revisit of the role of gas entrapment on the stability conditions of explosive volcanic columns

Cited by 14 publications

References 82 publications

The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

Wind Entrainment in Jets with Reversing Buoyancy: Implications for Volcanic Plumes

Impact of wind direction variability on hazard assessment in Martinique (Lesser Antilles): The example of the 13.5 ka cal BP Bellefontaine Plinian eruption of Mount Pelée volcano

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A revisit of the role of gas entrapment on the stability conditions of explosive volcanic columns

Cited by 14 publications

References 82 publications

The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

The Effect of Wind and Atmospheric Stability on the Morphology of Volcanic Plumes From Vulcanian Eruptions

Wind Entrainment in Jets with Reversing Buoyancy: Implications for Volcanic Plumes

Impact of wind direction variability on hazard assessment in Martinique (Lesser Antilles): The example of the 13.5 ka cal BP Bellefontaine Plinian eruption of Mount Pelée volcano

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Product

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Impact of wind direction variability on hazard assessment in Martinique (Lesser Antilles): The example of the 13.5 ka cal BP Bellefontaine Plinian eruption of Mount Pelée volcano