Miocene transpression effects at the boundary of Central Carpathian Paleogene Basin and Pieniny Klippen Belt: examples from Polish-Slovakian borderland

Ludwiniak, Mirosław

doi:10.7494/geol.2018.44.1.91

Cited by 8 publications

(7 citation statements)

References 45 publications

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“…Tectonic deformation of CCPB rocks observed in the vicinity of profile 3-3' are typical for the CCPB/ PKB contact zone, analogously to that observed in other parts of this zone, e.g., western Podhale, Spiš, Spišska Magura and Šariš (e.g., Mastella et al 1988;Plašienka and Soták 1999;Plašienka et al 2013;Ludwiniak 2018; see Text-fig. 6E, F).…”

Section: Profile 3-3' (Ciche)supporting

confidence: 67%

“…The PKB/CCPB contact zone is characterized by much stronger tectonic deformation compared to the remaining part of the CCPB. This is visible directly in the contact zone and in an adjacent, parallel belt, which occurs to the south and is several hundred metres wide (in some cases even up to 1.5 km; see also Mastella 1975;Plašienka et al 2013;Ludwiniak 2018). The contact itself is tectonic in nature and is a narrow (several to over 10 m wide), strongly deformed zone of strongly cataclased rocks, developed through transpression (see Ludwiniak 2018 Among the numerous faults that are subparallel to the contact, dextral faults dominate, although prevailing sinistral faults occur between Maruszyna and Leśnica (Text-fig.…”

Section: Structural Features Of the Ccpb Vs Structural Features Of Th...mentioning

confidence: 97%

“…The formation of the "flower" structure of the PKB resulted from transpression at the late Burdigalian and middle Miocene boundary (Ratschbacher et al 1993;. In effect, some elements of the PKB were retrothrusted onto the CCPB, which caused the development of strong deformation within Palaeogene deposits in the contact zone (e.g., Mastella 1975;Plašienka et al 1998;Plašienka and Soták 1999;Ludwiniak 2018; such backthrusting of the PKB onto the CCPB in northwestern Slovakia accompanied by some ENE-WSWstriking orogen-parallel sinistral faulting is considered to have occurred during the Late Oligocene and Early Miocene -see Peškova et al 2009;Beidinger and Decker 2016). Strike-slip movements along the CCPB/PKB contact zone could also play a significant role at this stage (e.g., Ratschbacher et al 1993;Ludwiniak et al 2009;Ludwiniak 2018).…”

Section: Basement Of the Orava Basinmentioning

confidence: 99%

“…Thus, a database consisting an array of structures typical of CCPB development that was used to track structures unique for OB vicinity was constructed (see Table 2). The analysis was based on earlier collected and partly published data (Mastella et al 1988;Ludwiniak 2006Ludwiniak , 2010Ludwiniak et al 2009;Ludwiniak 2018), supplemented with new measurements and existing maps (Watycha 1976a;Gross et al 1993a)…”

Section: Fieldworkmentioning

confidence: 99%

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Acta Geologica Polonica

Ludwiniak

Śmigielski

Kowalczyk

et al. 2019

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The Carpathian Orava Basin is a tectonic structure filled with Neogene and Quaternary deposits superimposed on the collision zone between the ALCAPA and European plates. Tectonic features of the south-eastern margin of the Orava Basin and the adjoining part of the fore-arc Central Carpathian Palaeogene Basin were studied. Field observations of mesoscopic structures, analyses of digital elevation models and geological maps, supplemented with electrical resistivity tomography surveys were performed. Particular attention was paid to joint network analysis. The NE-SW-trending Krowiarki and Hruštinka-Biela Orava sinistral fault zones were recognized as key tectonic features that influenced the Orava Basin development. They constitute the north-eastern part of a larger Mur-Mürz-Žilina fault system that separates the Western Carpathians from the Eastern Alps. The interaction of these sinistral fault zones with the older tectonic structures of the collision zone caused the initiation and further development of the Orava Basin as a strike-slip-related basin. The Krowiarki Fault Zone subdivides areas with a different deformation pattern within the sediments of the Central Carpathian Palaeogene Basin and was active at least from the time of cessation of its sedimentation in the early Miocene. Comparison of structural data with the recent tectonic stress field, earthquake focal mechanisms and GPS measurements allows us to conclude that the Krowiarki Fault Zone shows a stable general pattern of tectonic activity for more than the last 20 myr and is presently still active.

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Section: Profile 3-3' (Ciche)supporting

confidence: 67%

Section: Structural Features Of the Ccpb Vs Structural Features Of Th...mentioning

confidence: 97%

Section: Basement Of the Orava Basinmentioning

confidence: 99%

Section: Fieldworkmentioning

confidence: 99%

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Acta Geologica Polonica

Ludwiniak

Śmigielski

Kowalczyk

et al. 2019

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“…We also point out that sediments of the Carpathian Paleogene Basin, although poorly deformed, have undergone a multi-stage tectonic evolution which included, among others, a synsedimentary extension and further compression and deformation related to the Miocene uplift (e.g. Jurewicz 2005;Pešková et al 2009;Głowacka 2010;Ludwiniak 2010Ludwiniak , 2018Vojtko et al 2010;Kováčet al 2018;Ludwiniak et al 2019). None of these deformations have been restored by a tectonic correction based on a simple field-measured orientation of strata that may result in a declination bias.…”

Section: Discussionmentioning

confidence: 91%

Paleomagnetic and magnetic fabric data from Lower Triassic redbeds of the Central Western Carpathians: new constraints on the paleogeographic and tectonic evolution of the Carpathian region

Szaniawski

Ludwiniak

Mazzoli

et al. 2020

JGS

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In the Central Western Carpathians (CWC), most published paleomagnetic results from Permo-Mesozoic rocks document extensive remagnetizations and come from thin-skinned thrust units that have undergone multistage deformation. We present results from lower Triassic redbeds from the autochthonous cover overlying the basement that carry a primary magnetization. Petromagnetic results indicate that the dominant ferromagnetic carrier is hematite, while magnetic susceptibility and its anisotropy are controlled by both ferromagnetic and paramagnetic minerals. Magnetic fabrics document weak deformation related to Late Cretaceous shortening. The directions of the high unblocking temperature remanence components pass both reversal and fold tests, attesting to their primary nature. Paleomagnetic inclinations are flatter than expected from reference datasets, suggesting small latitudinal separation between the CWC and stable Europe. Paleomagnetic declinations are mostly clustered within individual mountain massifs, implying their tectonic coherence. They show only minor differences between the massifs, indicating a lack of significant vertical-axis tectonic rotations within the studied central parts of the CWC. The paleomagnetic declinations are therefore representative of the whole of the CWC in terms of regional paleogeographic interpretations, and imply moderate counterclockwise rotations (c. 26°) of the region with respect to stable Europe since the Early Triassic.

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