Modeling ash fall distribution from a Yellowstone supereruption
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Reconstructing the plinian and co-ignimbrite sources of large volcanic eruptions: A novel approach for the Campanian Ignimbrite.New Zealand supereruption provides time marker for the Last Glacial Maximum in Antarctica.Geomys tyrioni, a new species of early Pleistocene dwarf pocket gopher from the Meade Basin of southwestern KansasProbing the volcanic-plutonic connection and the genesis of crystal-rich rhyolite in a deeply dissected supervolcano in the Nevada Great Basin: Source of the late Eocene Caetano TuffResurgent Toba—field, chronologic, and model constraints on time scales and mechanisms of resurgence at large calderasDynamics of wind-affected volcanic plumes: The example of the 2011 Cordón Caulle eruption, Chile
P2860
Modeling ash fall distribution from a Yellowstone supereruption
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wetenschappelijk artikel
@nl
наукова стаття, опублікована в серпні 2014
@uk
name
Modeling ash fall distribution from a Yellowstone supereruption
@en
Modeling ash fall distribution from a Yellowstone supereruption
@nl
type
label
Modeling ash fall distribution from a Yellowstone supereruption
@en
Modeling ash fall distribution from a Yellowstone supereruption
@nl
prefLabel
Modeling ash fall distribution from a Yellowstone supereruption
@en
Modeling ash fall distribution from a Yellowstone supereruption
@nl
P2860
P356
P1476
Modeling ash fall distribution from a Yellowstone supereruption
@en
P2093
Larry G. Mastin
P2860
P304
P356
10.1002/2014GC005469
P577
2014-08-01T00:00:00Z