000 03465nam a2200337Ia 4500
001 24186
041 _aInglés
100 _aKratzmann, David J.
_919439
245 0 _aSimulations of tephra dispersal from the 1991 explosive eruptions of Hudson volcano, Chile
260 _c2010
300 _app. 337-352
500 _aDOI: https://doi.org/10.1016/j.jvolgeores.2009.11.021
520 _aThe 1991 explosive eruptions of Hudson volcano in southern Chile produced 2.7 km3 (dense rock equivalent) of basalt and trachyandesite tephra during the period August 8-15. The initial basaltic phase (phase I, August 8-9) produced a maximum column height of 12 km above sea level (ASL) and tephra fallout was directed to the north and northeast by the prevailing winds. The paroxysmal trachyandesitic phase (phase II, August 12-15) involved at least three separate events with a maximum ~ 18-km-high (ASL) eruption column inferred from satellite temperature data. During the initial 24 h of this phase the plume was advected almost directly south, before swinging towards the east as the wind changed direction. The plume was ultimately directed to the southeast and stayed relatively fixed at this bearing for the remainder of the eruption. These temporal variations in the main dispersal direction during the earlier stages of the phase II eruption produced a much wider overall deposit than would be expected from a plume with a relatively fixed transport direction (e.g., latter stages of phase II). The Lagrangian ash tracking model PUFF was utilized to simulate the 1991 explosive eruptions and was able to successfully reproduce the aerial distribution and temporal evolution of the plumes. The optimal agreement between the observed and simulated plumes occurs when the highest concentration of ash particles coincides with the tropopause, a height that is typically lower than the maximum observed column heights for the 1991 eruptions. Gravitational settling of the laterally spreading umbrella region (e.g., Pinatubo 1991) may result in the concentration of ash at this level. This may account for differences in column height estimates between ground- or satellite-based and lithic-based models. The plume associated with the paroxysmal phase (August 12-15, 1991) produced a multilayered deposit composed of alternating layers of fine ash and pumice lapilli. The highly stratified nature of the fall deposit is likely the result of multiple eruptive events coupled with a time varying wind field. A strongly changing wind direction that occurred during the earlier stages of the paroxysmal eruption could have produced variations in the dominant grain size being deposited between fine ash and pumice lapilli during individual eruptive sequences.
650 _aVOLCANISMO
_966746
650 _aERUPCIONES VOLCANICAS
_947558
650 _aTEFROCRONOLOGIA
_965042
650 _aTEFRA
_965041
650 _a VOLCAN HUDSON
_966473
650 _a CHILE
_95
650 _a REGION 11
_960615
700 _aCarey, Steven N.
_97832
700 _a Fero, Julie
_912449
700 _a Scasso, Roberto A.
_932590
700 _a Naranjo S., José Antonio
_925356
773 _tJournal of Volcanology and Geothermal Research, v.190, n.3-4
856 _uwww.sciencedirect.com/science/article/pii/S0377027309004570
_yUrl Archivo
942 _cARTR
_n0
991 _aAnalíticas
008 220218s9999 xx 000 0 und d
999 _c236518
_d236518