The San Pedro and San Pablo volcanoes of northern Chile and their hot avalanche deposits

Abstract

The twin 6000 m volcanoes San Pedro and San Pablo rise 2000 m above the extensive ignimbrite plateau of northern Chile. San Pablo is extinct and quite deeply eroded, San Pedro has an active fumarole and a record of several historic volcanic eruptions. Activity on both has on the whole migrated westwards with time. The volcanoes consist of pyroxene and hornblende andesite lavas with broad aprons of volcaniclastic rocks, including hot avalanche deposits, on their flanks. 30 new chemical analyses show that the composition range of the rocks composing the volcanoes is small, with silica varying between 56 and 66%, significantly higher than that of Quaternary volcanic suites of the western Pacific. The hornblende andesite lavas are very thick (commonly 100 to 200 m) indicating a high viscosity. Where such flows were erupted high on San Pedro, large portions of them collapsed when they became mechanically unstable and the resulting avalanche deposits form an important part of the volcano. Most avalanches took place when the source-lava was still hot, though so viscous that it broke by brittle fracture when it collapsed. The larger blocks have a prismatic jointing normal to their outer surface, showing that they cooled down in place after collapse. Evidence is presented that the mechanism of transport of these hot avalanches is not likely to be different from that of non-volcanic rock avalanches. Pumiceous pyroclastic flows also occur, one on the flanks of San Pedro, while others comprise the ignimbrite plateau. The latter is made up of many pyroclastic flows different from the San Pedro example only in size, and there are good grounds for believing that the ignimbrites likewise originated by eruptions on the andesitic volcanoes. Many of the ignimbrites are rhyolites, much more acidic than the andesite stratovolcanoes and a process of surface transport separation has operated whereby the andesites are concentrated on and near their source, while most of the rhyolites, because of their different style of eruption, have spread widely from it.