New 40Ar/39Ar, fission track and sedimentological data on a middle Miocene tuff occurring in the Vienna Basin: Implications for the north-western Central Paratethys region

Rybár, Samuel; Šarinová, Katarína; Sant, Karin; Kuiper, Klaudia F.; Kováčová, Marianna; Vojtko, Rastislav; Reiser, Martin; Fordinál, Klement; Teodoridis, Vasilis; Nováková, Petronela; Vlček, Tomáš

doi:10.2478/geoca-2019-0022

Cited by 17 publications

(18 citation statements)

References 45 publications

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“…Lukács et al (2018a) distinguished at least five major eruptions in the BVF (17.5 ± 0.3 Ma Eger ignimbrite, 17.055 ± 0.024 Ma Mangó ignimbrite, 16.816 ± 0.059 Ma Bogács unit, 14.880 ± 0.014 Ma Demjén ignimbrite and 14.358 ± 0.015 Ma Harsány ignimbrite based on pooling of the youngest zircon population in each unit). These eruptions provided significant volume of erupted material covering extensive areas across the Pannonian Basin and elsewhere in Europe (e.g., Lukács et al, 2018a;Rocholl et al, 2018;Rybár et al, 2019;Sant et al, 2020). These eruption products act as important marker layers in the early to mid-Miocene and could help to constrain the regional Paratethys chronostratigraphy used in central Europe.…”

Section: Geological Settingmentioning

confidence: 99%

“…The Pannonian Basin (eastern-central Europe; Figure 1) produced among the largest silicic volcanic eruptions in Europe for the last 20 Myr (Lukács et al, 2018a). Volcanic ash material was deposited throughout central and southern Europe (e.g., Rocholl et al, 2018;Lukács et al, 2018a;Rybár et al, 2019;Sant et al, 2020) and therefore plays an important role in constraining the regional Paratethys chronostratigraphy in this area (Steininger et al, 1988;Sant et al, 2017). Based on a thorough zircon-based study, Lukács et al (2018a) could identify at least five major eruption events from 18.2 Ma to 14.4 Ma mostly sourced around the southern foreland of the Bükk Mts., called Bükkalja Volcanic Field (BVF; Northern Hungary, Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Tephrostratigraphy and Magma Evolution Based on Combined Zircon Trace Element and U-Pb Age Data: Fingerprinting Miocene Silicic Pyroclastic Rocks in the Pannonian Basin

et al. 2021

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We present a novel approach to use zircon as a correlation tool as well as a monitor for magma reservoir processes in silicic volcanic systems. Fingerprinting eruption products based on trace element content and U-Pb dates of zircon offers a promising, previously underestimated tephra correlation perspective, particularly in cases where the main minerals and glass are altered. Using LA-ICP-MS analyses, a rapid and cost-effective method, this study presents U-Pb dates and trace element concentration data of more than 950 zircon crystals from scattered occurrences of early to mid-Miocene silicic ignimbrites in the northern Pannonian Basin, eastern-central Europe. This magmatic phase produced >4000 km3 of erupted material, which provide unique stratigraphic marker horizons in central and southern Europe. The newly determined zircon U-Pb eruption ages for the distal pyroclastic deposits are between 17.5 and 14.3 Ma, comparable with the previously published ages of the main eruptive events. Multivariate discriminant analysis of selected trace element concentrations in zircon proved to be useful to distinguish the main volcanic units and to correlate the previously ambiguously categorized pyroclastic deposits with them. Using the zircon trace element content together with published glass data from crystal-poor ignimbrites, we determined the zircon/melt partition coefficients. The obtained values of the distinct eruption units are very similar and comparable to published data for silicic volcanic systems. This suggests that zircon/melt partition coefficients in calc-alkaline dacitic to rhyolitic systems are not significantly influenced by the melt composition at >70 wt% SiO2 at near solidus temperature. The partition coefficients and zircon trace element data were used to calculate the equilibrium melt composition, which characterizes the eruption products even where glass is thoroughly altered or missing. Hence, our results provide important proxies for tephrostratigraphy in addition to yielding insights into the complex processes of silicic magma reservoirs.

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Section: Geological Settingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tephrostratigraphy and Magma Evolution Based on Combined Zircon Trace Element and U-Pb Age Data: Fingerprinting Miocene Silicic Pyroclastic Rocks in the Pannonian Basin

et al. 2021

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“…13). In addition, Rybár et al (2019) derived an (eruption) age of 15.23 ± 0.32 Ma by Ar/ Ar dating sanidines from Kuchyňa tuff of the Vienna Basin (Fig. 13; see also Sant et al 2020).…”

Section: Mts Kalnik and Požeška Gora Silicic Volcaniclastics: Current Status And Correlation Potentialmentioning

confidence: 99%

“…In addition, no geochemical data exist for Hörmsdorf-2 tuff of the Styrian Basin (Handler et al 2006). Rybár et al (2019) presented both whole-rock and volcanic glass geochemical compositions of the Kuchyňa tuff of the Vienna basin, which is coeval with ŠKR-12 volcaniclastic rocks. The major element compositions of volcanic glasses of these coeval rhyolitic (~ 77 wt% SiO 2 ) volcaniclastic deposits is similar (Supplementary Table Data 1; Rybár et al 2019).…”

Section: Mts Kalnik and Požeška Gora Silicic Volcaniclastics: Current Status And Correlation Potentialmentioning

confidence: 99%

“…Rybár et al (2019) presented both whole-rock and volcanic glass geochemical compositions of the Kuchyňa tuff of the Vienna basin, which is coeval with ŠKR-12 volcaniclastic rocks. The major element compositions of volcanic glasses of these coeval rhyolitic (~ 77 wt% SiO 2 ) volcaniclastic deposits is similar (Supplementary Table Data 1; Rybár et al 2019). However, to resolve if the ŠKR-12 and Kuchyňa volcaniclastic rocks were derived from the same volcanic source and produced by the same eruption event, additional trace element composition of volcanic glass is required (Harangi et al 2005;Lowe 2011;Kutterolf et al 2014;Lowe et al 2017;Schindlbeck et al 2018;Hopkins and Seward 2019) as these are not available for the Kuchyňa tuff.…”

Section: Mts Kalnik and Požeška Gora Silicic Volcaniclastics: Current Status And Correlation Potentialmentioning

confidence: 99%

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Miocene syn-rift evolution of the North Croatian Basin (Carpathian–Pannonian Region): new constraints from Mts. Kalnik and Požeška gora volcaniclastic record with regional implications

Brlek

Kutterolf

Gaynor

et al. 2020

Int J Earth Sci (Geol Rundsch)

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Mts. Kalnik and Požeška gora volcaniclastic sequences hold valuable information concerning the Miocene syn-rift evolution of the North Croatian Basin, and the evolution of the Carpathian-Pannonian Region and the Central Paratethys. We present volcanological, high-precision geochronological, and compositional data of volcanic glass to constrain their tephrochronology, magmatic provenance, and timing of the initial Central Paratethys flooding of the North Croatian Basin. Based on CA-ID-TIMS U-Pb zircon ages (18.060 ± 0.023 Ma for Mt. Kalnik and 15.345 ± 0.020 Ma for Mt. Požeška gora) and coeval 40 Ar/ 39 Ar sanidine ages (18.14 ± 0.38 Ma and 18.25 ± 0.38 Ma for Mt. Kalnik and 15.34 ± 0.32 Ma and 15.43 ± 0.32 Ma for Mt. Požeška gora), Mt. Kalnik rhyolitic massive ignimbrites and Mt. Požeška gora rhyolitic primary volcaniclastic turbidites are coeval with Carpathian-Pannonian Region Miocene post-collisional silicic volcanism, which was caused by lithospheric thinning of the Pannonian Basin. Their affiliation to Carpathian-Pannonian Region magmatic activity is supported by their subduction-related geochemical signatures. Although Mts. Kalnik and Požeška gora volcaniclastics are coeval with the Bükkalja Volcanic Field Csv-2 rhyolitic ignimbrites, North Alpine Foreland Basin, Styrian Basin, Vienna Basin, and Dinaride Lake System bentonites and volcaniclastic deposits, reliable tephrochronological interpretations based on comparison of volcanic glass geochemical composition are not possible due to a lack of data and/or methodological discrepancies. Our new high-precision geochronology data prove that the initial Middle Miocene (Badenian) marine flooding of parts of the North Croatian Basin occurred at least ~ 0.35 Ma (during the NN4 Zone) before the generally accepted ~ 15 Ma maximum flooding age at the basin scale, calibrating the timing of the onset of the widespread "mid-Langhian" Central Paratethys flooding.

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Paleontological and lithological evidence of the late Karpatian to early Badenian marine succession from Medvednica Mountain (Croatia), Central Paratethys

Fuček¹,

Galović

Mikša³

et al. 2022

Int J Earth Sci (Geol Rundsch)

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New 40Ar/39Ar, fission track and sedimentological data on a middle Miocene tuff occurring in the Vienna Basin: Implications for the north-western Central Paratethys region

Cited by 17 publications

References 45 publications

Tephrostratigraphy and Magma Evolution Based on Combined Zircon Trace Element and U-Pb Age Data: Fingerprinting Miocene Silicic Pyroclastic Rocks in the Pannonian Basin

Tephrostratigraphy and Magma Evolution Based on Combined Zircon Trace Element and U-Pb Age Data: Fingerprinting Miocene Silicic Pyroclastic Rocks in the Pannonian Basin

Miocene syn-rift evolution of the North Croatian Basin (Carpathian–Pannonian Region): new constraints from Mts. Kalnik and Požeška gora volcaniclastic record with regional implications

Paleontological and lithological evidence of the late Karpatian to early Badenian marine succession from Medvednica Mountain (Croatia), Central Paratethys

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