TY - CHAP
T1 - Large ignimbrite eruptions and volcano-tectonic depressions in the Central Andes
T2 - A thermomechanical perspective
AU - De Silva, Shanaka
AU - Zandt, George
AU - Trumbull, Robert
AU - Viramonte, José G.
AU - Salas Álvarez, Guido Edgard
AU - Jiménez, Néstor
PY - 2006
Y1 - 2006
N2 - The Neogene ignimbrite flare-up of the Altiplano Puna Volcanic Complex (APVC) of the Central Andes produced one of the best-preserved large silicic volcanic fields on Earth. At least 15 000 km3 of magma erupted as regional-scale ignimbrites between 10 and 1 Ma, from large complex calderas that are typical volcano-tectonic depressions (VTD). Simple Valles-type calderas are absent. Integration of field, geochronological, petrological, geochemical and geophysical data from the APVC within the geodynamic context of the Central Andes suggests a scenario where elevated mantle power input, subsequent crustal melting and assimilation, and development of a crustal-scale intrusive complex lead to the development of APVC. These processes lead to thermal softening of the sub-APVC crust and eventual mechanical failure of the roofs above batholith-scale magma chambers to trigger the massive eruptions. The APVC ignimbrite flare-up and the resulting VTDs are thus the result of the time-integrated impact of intrusion on the mechanical strength of the crust, and should be considered tectonomagmatic phenomena, rather than purely volcanic features. This model requires a change in paradigm about how the largest explosive eruptions may operate.
AB - The Neogene ignimbrite flare-up of the Altiplano Puna Volcanic Complex (APVC) of the Central Andes produced one of the best-preserved large silicic volcanic fields on Earth. At least 15 000 km3 of magma erupted as regional-scale ignimbrites between 10 and 1 Ma, from large complex calderas that are typical volcano-tectonic depressions (VTD). Simple Valles-type calderas are absent. Integration of field, geochronological, petrological, geochemical and geophysical data from the APVC within the geodynamic context of the Central Andes suggests a scenario where elevated mantle power input, subsequent crustal melting and assimilation, and development of a crustal-scale intrusive complex lead to the development of APVC. These processes lead to thermal softening of the sub-APVC crust and eventual mechanical failure of the roofs above batholith-scale magma chambers to trigger the massive eruptions. The APVC ignimbrite flare-up and the resulting VTDs are thus the result of the time-integrated impact of intrusion on the mechanical strength of the crust, and should be considered tectonomagmatic phenomena, rather than purely volcanic features. This model requires a change in paradigm about how the largest explosive eruptions may operate.
UR - http://www.scopus.com/inward/record.url?scp=33845580244&partnerID=8YFLogxK
U2 - 10.1144/GSL.SP.2006.269.01.04
DO - 10.1144/GSL.SP.2006.269.01.04
M3 - Capítulo
AN - SCOPUS:33845580244
SN - 1862392110
SN - 9781862392113
T3 - Geological Society Special Publication
SP - 47
EP - 63
BT - Mechanisms of Activity and Unrest at Large Calderas
A2 - Troise, C.
A2 - De Natale, G.
A2 - Kilburn, C.R.J.
ER -