Your search keyword '"Ukstins, Ingrid A."' showing total 9 results

1. Vikrahraun—the 1961 basaltic lava flow eruption at Askja, Iceland: morphology, geochemistry, and planetary analogs

Author

Blasizzo, Aline Y., Ukstins, Ingrid A., Scheidt, Stephen P., Graettinger, Alison H., Peate, David W., Carley, Tamara L., Moritz, Adam J., and Thines, Jennifer E.

Published

2022

2. Volumetric extrusive rates of silicic supereruptions from the Afro-Arabian large igneous province

Author

Thines, Jennifer E., Ukstins, Ingrid A., Wall, Corey, and Schmitz, Mark

Published

2021

3. Olivine xenocryst diffusion reveals rapid monogenetic basaltic magma ascent following complex storage at Pupuke Maar, Auckland Volcanic Field, New Zealand

Author

Brenna, Marco, Cronin, Shane J., Smith, Ian E.M., Tollan, Peter M.E., Scott, James M., Prior, David J., Bambery, Keith, and Ukstins, Ingrid A.

Published

2018

4. Matching conjugate volcanic rifted margins: 40Ar/ 39Ar chrono-stratigraphy of pre- and syn-rift bimodal flood volcanism in Ethiopia and Yemen

Author

Ukstins, Ingrid A., Renne, Paul R., Wolfenden, Ellen, Baker, Joel, Ayalew, Dereje, and Menzies, Martin

Published

2002

5. The geological history and hazards of a long-lived stratovolcano, Mt. Taranaki, New Zealand.

Author

Cronin, Shane J., Zernack, Anke V., Ukstins, Ingrid A., Turner, Michael B., Torres-Orozco, Rafael, Stewart, Robert B., Smith, Ian E. M., Procter, Jonathan N., Price, Richard, Platz, Thomas, Petterson, Michael, Neall, Vince E., McDonald, Garry S., Lerner, Geoffrey A., Damaschcke, Magret, and Bebbington, Mark S.

Subjects

DEBRIS avalanches, DENSITY currents, PUMICE, MAGMAS, HAZARDS

Abstract

Mt. Taranaki is an andesitic stratovolcano in the western North Island of New Zealand. Its magmas show slab-dehydration signatures and over the last 200 kyr they show gradually increasing incompatible element concentrations. Source basaltic melts from the upper mantle lithosphere pond at the base of the crust (∼25 km), interacting with other stalled melts rich in amphibole. Evolved hydrous magmas rise and pause in the mid crust (14–6 km), before taking separate pathways to eruption. Over 228 tephras erupted over the last 30 kyr display a 1000–1500 yr-periodic cycle with a five-fold variation in eruption frequency. Magmatic supply and/or tectonic regime could control this rate-variability. The volcano has collapsed and re-grown 16 times, producing large (2 to >7.5 km3) debris avalanches. Magma intrusion along N-S striking faults below the edifice are the most likely trigger for its failure. The largest Mt. Taranaki Plinian eruption columns reach ∼27 km high, dispersing 0.1 to 0.6 km3 falls throughout the North Island. Smaller explosive eruptions, or dome-growth and collapse episodes were more frequent. Block-and-ash flows reached up to 13 km from the vent, while the largest pumice pyroclastic density currents travelled >23 km. Mt. Taranaki last erupted in AD1790 and the present annual probability of eruption is 1–1.3%. [ABSTRACT FROM AUTHOR]

Published

2021

6. An (U-Th)/He age for the small Monturaqui impact structure, Chile.

Author

Ukstins, Ingrid A., Wartho, Jo-Anne, Cabrol, Nathalie A., Grin, Edmond A., van Soest, Matthijs C., Biren, Marc B., Hodges, Kip V., and Chong, Guillermo

Subjects

CLASTIC rocks, GEOLOGICAL time scales, BRECCIA, ZIRCON

Abstract

Single-crystal (U-Th)/He dating of 32 apatite and zircon crystals from an impact breccia yielded a weighted mean age of 663 ± 28 ka (n = 3; 4.2 % 2σ uncertainties) for the Monturaqui impact structure, Chile. This ~350 m diameter simple crater preserves a small volume of impactite consisting of polymict breccias that are dominated by reworked target rock clasts. The small size, young age and limited availability of melt material for traditional geochronological techniques made Monturaqui a good test to define the lower limits of the (U-Th)/He system to successfully date impact events. Numerical modeling of 4He loss in apatite and zircon crystals shows that, for even small craters such as Monturaqui, the short-lived compressional stage and shock metamorphic stage can account for the observed partial to full resetting of (U-Th)/He ages in accessory minerals. Despite the distinctly different 4He diffusion parameters of apatite and zircon, the 2σ-overlapping youngest ages are recorded in both populations of minerals, which supports the inference that the weighted mean of the youngest (U-Th)/He population is the age of formation of this impact structure. [ABSTRACT FROM AUTHOR]

Published

2022

7. What triggered the early-stage eruption of the Emeishan large igneous province?

Author

Bei Zhu, Zhaojie Guo, Shaonan Zhang, Ukstins, Ingrid, Wei Du, and Runchao Liu

Subjects

*IGNEOUS provinces, *MANTLE plumes, *PLATE tectonics, *VOLCANIC ash, tuff, etc., *GEOCHEMISTRY, *SUBDUCTION

Abstract

The formation of the Emeishan large igneous province is widely regarded as being related to a mantle plume, but plate tectonics may also have played an important role. We analyzed the regional facies architecture of the early-stage subaqueous volcanic rocks of the central Emeishan large igneous province. The results suggest that these rocks were emplaced in a N-S-striking subaqueous rift, which existed immediately before the onset of volcanism and was persistently maintained during the early eruption stage. By linking this conclusion with the background information indicating that (1) the basaltic geochemistry in this section is indicative of a subcontinental lithospheric mantle source rather than a mantle plume source, and (2) the western Yangtze plate, where the Emeishan large igneous province was developed, was located in the back-arc region of the Permian Paleo-Tethys subduction system, we propose a new view that the early-stage eruptions of the Emeishan large igneous province were triggered by back-arc extension. The dominant functioning of the mantle plume occurred shortly after this process and inherited it, as evidenced by the following: (1) The subaqueous volcanic architecture showing back-arc geochemical affinity is laterally restricted in the presumed rift, but the overlying subaerial lavas showing plumerelated geochemical features overwhelmingly flooded the whole province; (2) vertically, the source of the basaltic component in these intrarift sequences underwent a gradual transition from lithospheric origin to mantle plume origin along the stratigraphic order, as evidenced by an intercalated basaltic succession showing mixed geochemical features from the two contextual origins. [ABSTRACT FROM AUTHOR]

Published

2019

8. Complex decompression and fragmentation of mingled andesite magmas driving multi-phase Plinian eruptions at Mt. Taranaki, New Zealand.

Author

Torres-Orozco, Rafael, Cronin, Shane J., Pardo, Natalia, Kósik, Szabolcs, Ukstins, Ingrid, Heinrich, Mirja, and Lee, Peter D.

Subjects

*ANDESITE, *MAGMAS, *GLASS chemistry, *SHEAR (Mechanics), *CRYSTALLIZATION kinetics, *SUPERSATURATION

Abstract

Estimating the kinetics of andesite magma vesiculation and crystallization inside volcanic plumbing systems is key for unraveling andesite Plinian eruption dynamics. The conduit kinetics provide the necessary input data for estimating the magma flow rates driving magma ascent and the fragmentation mechanisms controlling shifts in eruption explosivity and style. This information is crucial for increasing knowledge on expected hazards and for developing realistic eruption scenarios. In this work, we estimate conduit magma vesiculation and crystallization kinetics during the 3300 cal BP Upper Inglewood Plinian eruptive episode of Mount Taranaki, New Zealand. This episode comprised (i) low-intensity, conduit-opening phases of dome-collapse PDCs; (ii) pre-climactic, highly explosive phases of diverse PDCs, of up to violent 18-km-runout lateral blasts; (iii) climactic phases of steady 22-km-high Plinian eruption columns; and (iv) waning phases of column-collapse PDCs. By employing synchrotron microtomography, combined with mineral/glass chemistry and electron-microscopy, we quantified 3D vesicle and crystal size and shape distributions in juvenile pyroclasts over time, and corresponding number densities ranging from 1.1 × 105 to 2.5 × 106 mm−3 for vesicles, and from 8.0 × 104 to 5.1 × 106 mm−3 for crystals. Our results indicate that tapping of chemically alike yet rheologically contrasting magmas over a multi-phase andesite eruptive episode is linked to: (a) mafic magma recharge and differentiation in multiple storage reservoirs at distinct crustal levels, (b) stepwise to rapid magma decompression while mingling, producing variable pre- and syn -eruptive degassing and crystallization, and (c) syn-eruptive changes in melt viscosity, strain rate, localized shear deformation, and conduit geometry. The earliest and least explosive eruptive phases (≈ 2 × 106 kg s−1) were produced at the slowest rates of magma decompression (0.3–0.6 MPa s−1), ascent (0.01–0.02 m s−1) and strain (< 0.002 s−1), driven by volatile diffusion and exsolution. All subsequent pre-climactic and Plinian phases (4 × 107–1 × 108 kg s−1) were produced at either rapid or intermittent rates of magma decompression (2.0–6.0 MPa s−1), ascent (0.06–0.2 m s−1) and strain (> 0.003–0.010 s−1), powered by combined magma volatile supersaturation and delayed disequilibrium degassing, decompression-induced microlite crystallization and rapid heterogeneous vesiculation kinetics, shear deformation and magma mingling. These processes enabled complex fragmentation mechanisms of the rheologically most homogeneous magmas. • Plinian eruptions linked to rheologically different mingling andesite magmas. • Magma decompression regimes producing variable degassing/crystallization kinetics. • Least explosive eruptions at slowest decompression, ascent and strain rates. • Plinian phases at rapid/intermittent magma decompression, ascent and strain rates. [ABSTRACT FROM AUTHOR]

Published

2023

9. Reconstructing the plumbing system of an off-rift primitive alkaline tuya (Vatnafell, Iceland) using geothermobarometry and CSDs.

Author

Burney, David, Peate, David W., Riishuus, Morten S., and Ukstins, Ingrid A.

Subjects

*PLAGIOCLASE, *LAVA, *LAVA flows, *OLIVINE, *MAGMATISM, *LASER ablation inductively coupled plasma mass spectrometry, *MOHOROVICIC discontinuity

Abstract

The Snæfellsnes Peninsula of western Iceland is a region of transitional to alkaline Quaternary (<1.5 Ma) intraplate magmatism. Vatnafell, a sub-glacial tuya (~410 ka), is centrally located within the peninsula, between the Helgrindur/Lýsuskarð and Ljósufjöll volcanic systems, ~120 km from the divergent Western Volcanic Zone plate boundary. The Vatnafell edifice comprises a basal hyaloclastite unit capped by a ~150 m thick supraglacial lava flow that is highly porphyritic (~15% clinopyroxene, olivine, and plagioclase macrocrysts). We use textural and compositional data to investigate magma transport and storage in this unique strike-slip tectonic setting (minimal extension and old c. 7 Ma crust) that is distinct from all other volcanic zones in Iceland. Textural analysis was done using petrographic observations and by constructing crystal size distributions (CSDs) for clinopyroxene, olivine, and plagioclase. All three phases show kinked CSDs, consistent with macrocryst incorporation through disaggregation of crystal mushes. In detail, the Vatnafell unit contains two distinct macrocryst associations: a dominant population of wehrlitic glomerocrysts (clinopyroxene+olivine), and less common gabbroic-troctolitic glomerocrysts (plagioclase+olivine±clinopyroxene). The wehrlitic glomerocrysts contain the most primitive populations of clinopyroxene (Mg# 84 ± 3) and olivine (Fo% 83 ± 1), while the gabbroic-troctolitic glomerocrysts are dominated by plagioclase (An% 80–89), with more evolved olivine (Fo% 79 ± 1) and minor clinopyroxene (Mg# 76). LA-ICP-MS REE data on the wehrlitic clinopyroxenes indicates an origin from an alkaline melt, similar in composition to the host lava, but slightly more primitive. A range of geothermometers (olivine-clinopyroxene Fe Mg exchange; olivine-spinel Al exchange; clinopyroxene composition; clinopyroxene-melt equilibrium) give broadly consistent crystallization temperatures of ~1220 °C for the wehrlitic glomerocrysts. Clinopyroxene-based geobarometers give pressures of ~6 kbar for the wehrlitic glomerocrysts and <4 kbar for the rare gabbroic-troctolitic glomerocrysts that indicate polybaric fractional crystallization at a range of crustal depths. Geophysical estimates of the crustal thickness beneath Vatnafell are ~25 km, and the dominant wehrlitic crystal population likely experienced magma storage at ~20 km in the lower crust near the Moho. [ABSTRACT FROM AUTHOR]

Published

2020