Your search keyword '"ASH AGGREGATES"' showing total 4 results

1. Proximal record of the 273 ka Poris caldera-forming eruption, Las Cañadas, Tenerife.

Author

Smith, Natasha J. and Kokelaar, B. Peter

Subjects

*CALDERAS, *VOLCANIC eruptions, *LITHOFACIES, *ECOLOGICAL succession, *IGNIMBRITE, *VOLCANIC ash, tuff, etc.

Abstract

Lithofacies architecture analysis is applied to the most proximal exposures of the 273 ka Poris Formation, in the Diego Hernandez caldera wall of Las Cañadas. Here, the succession records an opening Plinian phase followed by generation of a pyroclastic density current (PDC) that was partly blocked by near-vent topography. The upper part of the current surmounted the barrier and deposited an ignimbrite veneer. During a hiatus in energetic flow, ash and various ash aggregates were deposited from a hybrid cloud comprising parts of both the Plinian and the co-ignimbrite plumes. Phreatomagmatic explosions then generated currents rich in fine-grained lithics; current waxing with local erosion was followed by pulsing-unsteady waning, recorded in repeated sets of graded tuff. Reversion to magmatic activity was marked by hybrid deposition, as coarse pumice fallout and juvenile ballistics entered pyroclastic currents to form stratified pumice-block tuff. Increasingly energetic flow is recorded in 9 m of mainly massive lapilli tuff that includes evidence of widespread scour and bypass; lithic-rich layers record incremental onset of edifice disruption due to magma withdrawal. Laterally variable stratification and load structures show that the PDC was unsteady and highly non-uniform at times, with locally rapid aggradation of gas-rich ignimbrite. Climactic edifice disruption is marked by a lithic-block layer in erosional contact with the underlying ignimbrite, recording intense pyroclastic current activity and widespread bypass of material to distal volcano slopes. Pumice-block breccia, 10 m thick and with blocks up to 1.2 m in diameter, forms the top of the succession and registers modification of the magmatic plumbing. The timing of collapse to form a major summit depression is uncertain. However, the abrupt termination of the proximal aggradation of coarse breccia, with no record there of any waning-stage pyroclastic currents, suggests subsidence at that time, conceivably with formation of a caldera that contained late-erupted material. [ABSTRACT FROM AUTHOR]

Published

2013

2. Diversity of soluble salt concentrations on volcanic ash aggregates from a variety of eruption types and deposits

Author

Colombier, Mathieu, Mueller, Sebastian B., Kueppers, Ulrich, Scheu, Bettina, Delmelle, Pierre, Cimarelli, Corrado, Cronin, Shane J., Brown, Richard J., Tost, Manuela, and Dingwell, Donald B.

Published

2019

3. Diversity of soluble salt concentrations on volcanic ash aggregates from a variety of eruption types and deposits

Author

UCL - SST/ELI/ELIE - Environmental Sciences, Colombier, Mathieu, Mueller, Sebastian B., Kueppers, Ulrich, Scheu, Bettina, Delmelle, Pierre, Cimarelli, Corrado, Cronin, Shane J., Brown, Richard J., Tost, Manuela, Dingwell, Donald B., UCL - SST/ELI/ELIE - Environmental Sciences, Colombier, Mathieu, Mueller, Sebastian B., Kueppers, Ulrich, Scheu, Bettina, Delmelle, Pierre, Cimarelli, Corrado, Cronin, Shane J., Brown, Richard J., Tost, Manuela, and Dingwell, Donald B.

Abstract

Ash aggregation is a common phenomenon in particle-laden environments of volcanic eruption plumes and pyroclastic density currents.Manyoftheseinitiallyfragileaggregatesgainsufficientmechanicalstrengthtoremainintactafteratmospherictransport and deposition. Several processes contribute to ash aggregate stability, including electrostatic and hydrostatic bonding, ice formation,andcementationbysaltprecipitates.Here,wecompareleachatechemistryfromaggregatesfromavarietyoferuption and sedimentation conditions, ranging from dry magmatic eruptions with immediate deposition, to eruptions through seawater. The leachate data shows that the broad window of opportunity for aggregation and aggregate break-up may be used to qualitatively constrain suspended ash concentration and its temporal evolution. We show that aggregation rate and aggregate stability largelydependontheavailabilityofexternalwaterandsaltsource.Inparticular,highhumidityandextensivesaltprecipitationin seawater environments, such as during the Surtseyan eruptions, promote high aggregation rates and aggregate stability, with accordingly accentuated proximal deposition and aggregate concentration in the deposits. On the other hand, low humidity and salt concentrations during dry magmatic eruptions promote less aggregation and more efficient aggregate break-up, explaining the rarity of aggregates in the deposits. These results have strong implications for the ash budget in volcanic plumes and associated models of plume dispersal and related hazards.

Published

2019

4. Diversity of soluble salt concentrations on volcanic ash aggregates from a variety of eruption types and deposits

Author

Corrado Cimarelli, Donald B. Dingwell, Shane J. Cronin, Manuela Tost, Mathieu Colombier, Pierre Delmelle, Richard J. Brown, Sebastian Mueller, Ulrich Kueppers, Bettina Scheu, and UCL - SST/ELI/ELIE - Environmental Sciences

Subjects

geography, Vulcanian eruption, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, ASH AGGREGATES, Geochemistry, Pyroclastic rock, Humidity, LEACHING, 010502 geochemistry & geophysics, Cementation (geology), PLUME DISPERSAL, 01 natural sciences, Plume, Volcano, 13. Climate action, Geochemistry and Petrology, Seawater, SALT PRECIPITATION, PARTICLE BINDING, Geology, 0105 earth and related environmental sciences, Volcanic ash

Abstract

Ash aggregation is a common phenomenon in particle-laden environments of volcanic eruption plumes and pyroclastic density currents. Many of these initially fragile aggregates gain sufficient mechanical strength to remain intact after atmospheric transport and deposition. Several processes contribute to ash aggregate stability, including electrostatic and hydrostatic bonding, ice formation, and cementation by salt precipitates. Here, we compare leachate chemistry from aggregates from a variety of eruption and sedimentation conditions, ranging from dry magmatic eruptions with immediate deposition, to eruptions through seawater. The leachate data shows that the broad window of opportunity for aggregation and aggregate break-up may be used to qualitatively constrain suspended ash concentration and its temporal evolution. We show that aggregation rate and aggregate stability largely depend on the availability of external water and salt source. In particular, high humidity and extensive salt precipitation in seawater environments, such as during the Surtseyan eruptions, promote high aggregation rates and aggregate stability, with accordingly accentuated proximal deposition and aggregate concentration in the deposits. On the other hand, low humidity and salt concentrations during dry magmatic eruptions promote less aggregation and more efficient aggregate break-up, explaining the rarity of aggregates in the deposits. These results have strong implications for the ash budget in volcanic plumes and associated models of plume dispersal and related hazards.

Published

2019