15 research outputs found
Age and Eruptive Style of Volcanic Rocks Dredged from the Alpha Ridge, Arctic Ocean
The Alpha–Mendeleev ridge complex is a prominent physiographic and
geological feature of the Arctic Amerasia Basin. The Alpha and Mendeleev
ridges are, respectively, the eastern and western components of a continuous
seafloor high that is approximately 2000 km long and 200–400 km wide.
A surge of interest in the tectonic evolution of Arctic submarine features has
led to a wealth of new geophysical data collected from the Alpha Ridge. Current
interpretations of its origin vary but there is compelling evidence that the Alpha Ridge
may have formed as an oceanic plateau during the Late Cretaceous. Geological
samples are rare but most samples recovered indicate a genetic link with the High
Arctic Large Igneous Province (HALIP).
In August 2016, Canada’s Extended Continental Margin-United Nations Convention
on the Law of the Sea Program dredged approximately 100 kg of volcanic rocks from
the Alpha Ridge. The large size and pristine state of the samples enabled the first
comprehensive study of a single eruptive event in the volcanic record of the Alpha
Ridge. The dredge sample is a lapilli tuff containing vitric and basaltic clasts. Textural
evidence and the coexistence of juvenile and cognate clasts suggest a phreatomagmatic
eruption. The vitric fragments consist of sideromelane glass with abundant plagioclase
microlites. Texturally, these basaltic glass lapilli display a fresh glassy core surrounded
by Fe- and Ti-rich zones and a palagonite rim. Major and trace element analyses of
glassy cores indicate remarkably uniform, mildly alkaline basaltic compositions. The plagioclase-bearing glass yielded a 40Ar/39Ar plateau age of 90.40±0.26 Ma (2σ error) which included 89% of 39 Ar
released. We interpret this result to represent the eruption age of the plagioclase microlites
and consequently, of the host basaltic glass lapilli in the tuff. Volatile species analyses by
infrared spectroscopy on the fresh basaltic glass suggests that the melt was effectively
degassed to shallow level. Assuming equilibrium degassing, the homogeneous resulting
values of H2O total in the range 0.1 to 0.19 wt.% (1σ error) indicate subaerial or shallow
eruption (surface to 80 m).
The new 40Ar/39Ar age for the sample is consistent with a 40 Ar/39Ar age of 89±1 Ma
obtained for a sample of tholeiitic basalt dredged from the central part of the
Alpha Ridge, and with the range of ages reported for HALIP igneous rocks exposed
onshore in the Canadian Arctic Archipelago (130-80 Ma). Our new data provide
evidence for local emergence of the Alpha Ridge in the Late Cretaceous. A comparison
the Alpha Ridge and Kerguelen Plateau–Broken Ridge Large Igneous Province (LIP)
provides new insights on the episodic nature of LIP magmatism and variations in
eruptive style through time
The Ilopango Tierra Blanca Joven (TBJ) eruption, El Salvador: volcano-stratigraphy and physical characterization of the major Holocene event of Central America
The Ilopango caldera is the source of the large Tierra Blanca Joven (TBJ) eruption that occurred about 1.5 ka years ago, between ca. AD270 and AD535. The eruption dispersed volcanic ash over much of the present territory of El Salvador, and pyroclastic density currents (PDCs) extended 40 km from the volcano. In this study, we document the physical characteristics of the deposits from all over El Salvador to further constrain the eruption processes and the intensity and magnitude of the different phases of the eruption. The succession of deposits generated by the TBJ eruption is made of 8 units. The eruption started with PDCs of hydromagmatic origin (Unit A0), followed by fallout deposits (Units A and B) that are <15 cm thick and exposed in sections close to the Ilopango caldera (within 10–15 km). The eruption, then, transitioned into a regime that generated further PDCs (Units C–F), these range from dilute to dense and they filled the depressions near the Ilopango caldera with thicknesses up to 70 m. Deposits from the co-ignimbrite plume (Unit G) are the most widespread, the deposits are found in Guatemala, Honduras, Nicaragua, Costa Rica and the Pacific Ocean and cm-thick across El Salvador. Modelling of the deposits suggests that column heights were 29 km and 7 km for the first two fallout phases, and that the co-ignimbrite phoenix plume rose up to 49 km. Volumes estimated for the fallout units are 0.15, 0.8 and 16 km3 dense rock equivalent (DRE) for Unit A, B and G respectively. The PDCs deposits volumes were estimated to be ~0.5, ~3.3, ~0.3 and ~9.1 km3 DRE for Units C, D, E and F, respectively. The combined volume of TBJ deposits is ~30 km3 DRE (~58 km3 bulk rock), indicating that it was one of largest Holocene eruptions from Central America. This eruption occurred while Mayan populations were living in the region and it would have had a significant impact on the areas within tens of kilometres of the vent for many years to decades after the eruption