The South Spur edifice is the oldest structure found at Lastarria. The Negriales lava field formed later. The five craters of Lastarria proper formed in five different stages. An alternative view holds that Negriales formed before the South Spur, and that the main edifice formed in ten different stages. Block-and-ash flows,
hot avalanches, lava domes, lava flows, and pyroclastic flows have all been involved in the activity of Lastarria. Most deposits on the northern slopes were erupted during the last two stages, with the exception of several exposures of the older stages on the northwestern flank and the western "pink pyroclastic flow" deposit. Overall, later and
Holocene activity at Lastarria was highly
explosive, unlike the more effusive earlier eruptions including the Negriales eruptions.
Potassium–argon dating of Lastarria has yielded ages of 600,000 ± 300,000 and less than 300,000 years ago. The older date refers to the Negriales lava field, which has also been dated at 400,000116,000 ± 26,000 years ago. The South Spur is dated at 150,000 ± 50,000 years ago. The main edifice started forming 260,000 ± 20,000 years ago. One andesite lava flow was dated at 51,000 ± 13,000 years ago by
argon–argon dating. There was then a lull in volcanic activity until the
Holocene. Three
ignimbrites were erupted during the Holocene between 4,850 ± 40 and 2,460 ± 40 years ago and were emplaced around the volcano, in particular north and west of the edifice. Most of the volcano formed post-
glacially.
Holocene explosive eruptions were separated by intervals of about 2,390 - 1,660 years. Three
ignimbrites were erupted during the Holocene between 4,850 ± 40 and 2,460 ± 40 years ago and were emplaced around the volcano, in particular north and west of the edifice. Three
ignimbrites were erupted during the Holocene between 4,850 ± 40 and 2,460 ± 40 years ago and were emplaced around the volcano, in particular north and west of the edifice. The landslide also occurred during the Holocene, 7430 (+136,−156) years before present. The lava dome on the northernmost crater rim is the youngest vent of Lastarria. The youngest dated deposit is 2,460 ± 50/60 years old, but at least one younger pyroclastic flow is present. No historical eruptions are known but
earthquakes have been recorded at the volcano and new sulfur flows were observed in 2019. Noticeable thermal hotspots are visible from
ASTER imagery and are associated with the fumarolic areas. Temperatures observed at the hotspots are around . A potential of
geothermal power at Lastarria was recognized already in 1974. It is considered Argentina's 9th most dangerous volcano out of 38.
Fumarolic activity Lastarria displays vigorous
fumarolic activity on the summit and down the northwestern slopes. Such activity has been observed since the European discovery of Lastarria, in the late 19thcentury. Lastarria is the only volcano in the area with ongoing fumarolic activity. It manifests in fumaroles forming high chimneys, small cones reaching heights of , wide craters, fractures, in a diffuse fashion through pyroclastic deposits, as well as degassing through cracks and fissures on surfaces. Individual fumaroles have been found in the craters, on the crater edges, and on the slopes. A northwest–southeast striking fracture is associated with some of the fumaroles. Four different fumarole fields have been found, one along this fissure on the northwestern slope at altitudes of about , two on the rims of the fourth crater, and one in the fifth crater. The fissure field is the largest, covering a surface area of , while the other fields can be as small as . The alignment of fumarolic vents suggest that their position is controlled by the structure of the volcano. The fumarolic activity has led to the deposition of
borates,
sulfates,
sulfides and
sulfur on Lastarria. Fumarole fields have colours trending from grey to red to yellow-orange to pale yellow with decreasing temperatures, owing to different elements having different volatilities and depositing at different temperatures. The fumaroles release gases with temperatures ranging from .
Carbon dioxide is the most important non-hydrous component of the gases; other components are
hydrogen in variable amounts,
hydrogen chloride,
hydrogen fluoride,
hydrogen sulfide, and variable amounts of
nitrogen and
sulfur dioxide. Additional components are
alkanes,
alkenes,
argon,
carbon monoxide especially in hotter fumaroles,
helium,
methane especially in colder fumaroles, and
oxygen. The composition of the fumaroles indicates that most gases are of magmatic origin with little contribution from the atmosphere. Likewise, most water comes from the magma rather than from precipitation, as indicated by the
oxygen isotope ratios. It is likely that the arid climate of the region reduces the input of meteoric water to the volcanic system. Of five volcanoes analyzed in 2012 (
Lascar, Lastarria,
Ollague,
Putana, and
San Pedro), Lastarria had the highest
flux rates. Individual gas fluxes in tons per day are registered as: The composition of Lastarria's gases has changed over time, with an increase in the magmatic component between 2009 and 2012, which may be due either to different measurement methods or to changes in the volcanic activity at Lastarria. Decreased temperatures have been observed after rainfall. Changes in the hydrothermally active areas have been observed in the 2010s-2020s. The gases of Lastarria come from a geothermal system and, with temperatures ranging from and , supply the colder and hotter fumaroles, respectively. In turn, a magma system at depths of underpins and feeds this geothermal system. During their rise, the gases interact with the rocks of the surrounding country and with
aquifers. Lastarria's exhalations contain numerous volatile elements, like
boron and
chalcophiles.
Arsenic is a harmful pollutant that occurs in above average concentrations in waters of northern Chile. Fumarolic exhalations at Lastarria can reach over of the fumarole sediments and the volcano is considered to be an important source of arsenic of the southern Central Volcanic Zone.
Sulfur The
fumaroles on Lastarria have created widespread deposits of
sulfur. The sulfur has also formed flows, of which the two largest are and long. The longer flow is partly buried by the shorter one and has already lost part of its surface structure. No vents have been found; sulfur flows appear to emerge from the fumarolic terrain. One
andesite lava flow has generated several subsidiary sulfur flows that resemble
pahoehoe flows and have widths of . It is likely that sulfur deposited by fumaroles formed such flows. Some fumaroles currently release centimetre-long sulfur flows. Flows of sulfur are highly fragile constructs that can easily be destroyed. The conditions surrounding the emplacement of the sulfur have caused the sulfur to assume various colours, including black, brown-orange, orange, red, yellow, and yellow-orange. These colours vary along the length of the flows and between various flows, indicating that temperatures varied between one flow and another. Liquid sulfur has different
viscosity and
rheomorphic properties at different temperatures, and some variation occurred at Lastarria's flows as well. Such sulfur flows are rare on
Earth; they may be more common on the
Jupiter moon
Io. On Earth, they have been found at
Kawah Ijen in
Indonesia,
Mount Iō (Shiretoko) in
Japan,
Mauna Loa on
Hawaii,
Momotombo in
Nicaragua, and
Sierra Negra on the
Galapagos Islands. The sulfur flows on Lastarria may be threatened by future
mining efforts in the region.
Ground uplift InSAR observations performed in the years 1998 to 2000 have yielded evidence of a pattern of ground uplift centered between Lastarria and
Cordón del Azufre. This pattern, also known as "Lazufre", covers a surface area of . This uplift appears to be caused by the injection of magma at depth, with a pattern of progressively increasing flux between 2003 and 2006. The source of this uplift appears to lie at depths of , later recalculated at . This uplift may have been ongoing for about 400,000 years and has influenced the final position of lava flows of Lastarria and other volcanoes in the area. Ground uplift has been detected at Lastarria itself, amounting to . The uplifting region has either a surface area of or is wide, smaller than Lazufre. The Lastarria uplift started later than the Lazufre uplift and may be influenced by the latter. Possibly, magma injected into a Lazufre magma chamber is influencing the Lastarria
hydrothermal system, with changes in fumarole output observed in 2006–2012. Modelling indicates that the source of this uplift lies at a depth of about and has the shape of a sphere. Another estimate places the source inside the volcanic edifice and assumes a size of , with the volume increasing by about . Ground uplift is still underway but with a slowdown between 2006 and 2016. At other volcanoes, such uplift has been associated with changes in fumarolic activity or even the start of an eruption. == Threats ==