Your search keyword '"Ladislav Fuček"' showing total 18 results

1. Active Tectonics in the Kvarner Region (External Dinarides, Croatia)—An Alternative Approach Based on Focused Geological Mapping, 3D Seismological, and Shallow Seismic Imaging Data

Author

Tvrtko Korbar, Snježana Markušić, Ozren Hasan, Ladislav Fuček, Dea Brunović, Nikola Belić, Damir Palenik, and Vanja Kastelic

Subjects

Adriatic microplate, External Dinarides fold-and-thrust belt, earthquakes, active tectonics, geological mapping, Quaternary sediments, Science

Abstract

Active tectonics in long-lived orogenic belts usually manifests on the preexisting inherited structures. In the Kvarner region of the External Dinarides, an area with low-to-moderate seismicity related to the Adriatic microplate (Adria) northward movement, we deal with faults in predominantly carbonate rocks within tectonically complex NW-SE striking fold-and-thrust belt, which makes the identification and parametrization of the active structures challenging. Moreover, anthropogenic modifications greatly complicate access to the surface geological and geomorphological data. This paper demonstrates results of focused multidisciplinary research, from surface geological mapping and offshore shallow seismic surveys to earthquake focal mechanisms, as an active fault identification and parametrization kit, with a final goal to produce an across-methodological integrated model of the identified features in the future. Reverse, normal, and strike-slip orogen-parallel (longitudinal) to transverse faults were identified during geological mapping, but there is no clear evidence of their mutual relations and possible recent activity. The focal mechanisms calculated from the instrumental record include weak-to-moderate earthquakes and show solutions for all faulting types in the upper crust, compatible with the NE-SW oriented principal stress direction, with the stronger events favoring reverse and strike-slip faulting. The 3D spatial and temporal distribution of recent earthquake hypocenters indicate their clustering along predominantly subvertical transversal and steeply NE-dipping longitudinal planes. High-resolution shallow seismic geoacoustical survey (subbottom profiler) of the Quaternary sediments in the Rijeka Bay revealed local tectonic deformations of the stratified Late Pleistocene deposits that, along with overlaying mass-transport deposits, could imply prehistorical strong earthquake effects. Neotectonic faults onshore are tentatively recognized as highly fractured zones characterized by enhanced weathering, but there is no evidence for its recent activity. Thus, it seems that the active faults are blind and situated below the thin-skinned and highly deformed early-orogenic tectonic cover of the Adria. A strain accumulating deeper in the crust is probably irregularly redistributed near the surface along the preexisting fault network formed during the earlier phases of the Dinaric orogenesis. The results indicate a need for further multidisciplinary research that will contribute to a better seismic hazard assessment in the densely populated region that is also covered by strategic infrastructure.

Published

2020

2. Stratigraphy and Tectonic Relationships Along the Senj - Ogulin Profile (Velika Kapela Mt., Croatia)

Author

Dubravko Matičec, Igor Vlahović, Ladislav Fuček, Nenad Oštrić, and Ivo Velić

Subjects

Shallow-water carbonates, Compressive Tertiary tectonics, Transpressive Neotectonics, Structures, Jurassic, Lower Cretaceous, Dinarides, Velika Kapela Mt., Croatia, Geology, QE1-996.5

Abstract

Twelve lithostratigraphic units, representing a 5 km thick succession,have been determined from the Senj -Ogulin profile through theVelika Kapela Mt. This 45 km long sequence lies approximately normalto the Dinaric strike. Carbonate deposits ranging from the MiddleLiassic to the Albian include laterally variable environments duringthe Kimmeridgian and Lower Tithonian. The deposits were deformedby compressive tectonics during the Tertiary tectonic cycle, and wereconsequently reshaped by weaker Neotectonic transpression. Thereforestructures with the N-S strike, which are different to the commonDinaric strike (NW-SE), are interpreted as a consequence of syngenetic bending during the Tertiary cycle, rather than rotation during theNeotectonic cycle.

Published

2010

3. The Origin and Importance of the Dolomite-Limestone Breccia Between the Lower and Upper Cretaceous Deposits of the Adriatic Carbonate Platform: An Example from Ćićarija Mt. (Istria, Croatia)

Author

Igor Vlahović, Josip Tišljar, Ladislav Fuček, Nenad Oštrić, Božo Prtoljan, Ivo Velić, and Dubravko Matičec

Subjects

Lower to Upper Cretaceous transition, Tectogenic-diagenetic breccia, Late-diagenetic dolomitization, Late-diagenetic silicification, Ćićarija Mt., Adriatic Carbonate Platform, Croatia, Geology, QE1-996.5

Abstract

On the NE slopes of Ćićarija Mt. (N Istria) a 120-150 m thick complexcomposed of dolomite-limestone breccia crops out between theLower and Upper Cretaceous deposits. This studied breccia sequenceis of post-sedimentary, tectogenic-diagenetic origin. It was formed bypolyphase tectonic fracture of the Upper Albian to Lower Cenomanianearly- and late-diagenetic dolomite succession with relics ofrecrystallized limestone, which enabled very important subsequentdiagenetic alteration. This included partial dissolution, dedolomitization,recrystallization and calcitization of the fine-grained, crusheddolomite matrix, and centripetal dissolution of dolomite fragmentsand their cementation by calcite and ferroan calcite cements, as wellas the partial collapse of fragments from the roofs of dissolution cavitiesand limited late-diagenetic silicification (the silica surplus originatingfrom layers of diagenetic quartz from underlying Upper Albiandeposits). Such a complex pattern of different events resulted in thehigh variability of breccia characteristics over relatively small distances,especially near more intensively tectonized zones.The contemporaneous stratigraphic level (Lower to Upper Cretaceoustransition) in other parts of the Adriatic Carbonate Platform isalso characterised by predominantly late-diagenetic dolomites withrelics of limestones (including local occurrences of early-diageneticdolomites) which are, in more tectonized areas, late-diageneticallyaltered into tectogenic-diagenetic breccias.

Published

2002

4. Jurassic pelagic succession of NW Croatia – a key to better understanding tectonic setting of the Southern Alps – Dinarides transition zone

Author

Matija Vukovski, Duje Kukoč, Tonći Grgasovic, Ladislav Fuček, and Damir Slovenec

Abstract

Ivanščica Mt. is an inselberg in the transitional area where S-verging Southern Alpine structures overprint NNW-verging Dinaric structures (van Gelder et al. 2015, and references therein). It is composed of Triassic to Cretaceous shallow to deep-marine sedimentary succession of the Adriatic continental passive margin (Šimunić et al. 1976), overthrust by ophiolitic mélange (Babić et al. 2002). Early Cretaceous siliciclastic flysch-type deposits continuously overlaying pelagic limestones clearly indicates distal position of these successions on the continental margin. However, so far complete Jurassic succession on Mt. Ivanščica was never found, causing different interpretations of its Mesozoic history. Babić (1974) assumed the existence of Jurassic pelagic succession on top of the Late Triassic shallow-water carbonates, describing up to few meters of Early to Middle Jurassic condensed pelagic limestone overlain by Late Jurassic radiolarian cherts and pelagic limestones. Contrary, Šimunić et al. (1976) assumed shallow-marine conditions throughout the Early Jurassic followed by emersion until latest Jurassic. Our study revealed for the first time complete shallow-water to pelagic Jurassic succession on Mt. Ivanščica. Southern slopes of Ivanščica Mt. are mostly built of ophiolitic mélange, except for prominent hills built of the Late Triassic Dachstein limestone, which were so far interpreted as klippes (Šimunić et al. 1976), or olistoliths (Babić & Zupanič 1978). Our new data indicate continuous succession on top of Dachstein limestones composed of shallow-marine carbonates, represented by intraclastic-peloidal packstones to grainstones, gradually transitioning to wackestones with pelagic influence. The onset of pelagic sedimentation took place around the end of the Early Jurassic when thin bedded marls, shales, marly limestones with intercalated fine-grained calciturbidites were deposited. Higher in the succession Callovian to possibly early Tithonian radiolarian cherts are overlaid by calcarenites, late Tithonian to Early Cretaceous pelagic limestones and Early Cretaceous flysch-type deposits. Discovery of the Jurassic pelagic sediments allows for a new interpretation of structural relations on the Ivanščica Mt. In our opinion occurrence of Dachstein limestone, previously interpreted as klippes or olistoliths represent an imbricate fan. Because the Southern Alps thrust front in this area was interpreted according to these mapped klippes and nappe contact, our findings may also have an impact on the redefining of the easternmost Southern Alps thrust front. Babić, Lj. (1974). Jurassic−Cretaceous sequence of Mt. Ivanščica (North Croatia). Bull. Sci. Cons. Acad. Yugoslav. (A), 19/7−8, 180−181. Zagreb. Babić, Lj. & Zupanič, J. (1978). Mlađi mezozoik Ivanščice. In Babić, Lj. & Jelaska, V. (ured.): Fieldtrip Guidebook 3. Skupa sedimentologa Jugoslavije, 11–23. Hrvatsko Geološko Društvo, Zagreb. Babić, Lj., Hochuli P. A.. & Zupanič, J. (2002). The Jurassic ophiolitic mélange in the NE Dinarides: dating, internal structure and geotectonic implications. Eclogae Geologicae Helvetiae 95, 263–75. Šimunić, A., Pikija, M., Šimunič, Al., Šikić, K. & Milanović, M. (1976): Stratigrafsko - tektonski odnosi centralnog i istočnog dijela Ivanščice. 8. Jugosl.geol.kongres, Bled, 1974., 2, 3003-313, Ljubljana. van Gelder, I., Matenco, L., Willingshofer, E., Tomljenović, B., & Andriessen, P., Ducea, M., Beniest, A. & Gruić, A. (2015). The tectonic evolution of a critical segment of the Dinarides-Alps connection: Kinematic and geochronological inferences from the Medvednica Mountains, NE Croatia. Tectonics. 34. n/a-n/a. 10.1002/2015TC003937.

Published

2022

5. Maastrichtian to Palaeocene and Eocene pelagic carbonates on the island of Svetac (central Adriatic, Croatia)

Author

Nenad Oštrić, Ladislav Fuček, Vlasta Premec Fuček, and Tvrtko Korbar

Subjects

Adriatic Platform and Basin, Cretaceous, Palaeogene, planktonic foraminifera, biology, Carbonate platform, Outcrop, Pelagic zone, biology.organism_classification, Cretaceous, Foraminifera, Paleontology, Adriatic Platform and Basin, Palaeogene, planktonic foraminifera, Benthic zone, General Earth and Planetary Sciences, Intraclasts, Paleogene, Geology, General Environmental Science

Abstract

Maastrichtian to Palaeocene pelagic carbonates on the central Adriatic island of Svetac (Sveti Andrija) are the only outcrops reported to date that document pelagic deposition during the Cretaceous–Palaeogene (K–Pg) transition within the Adriatic Basin. An approximately 3 m thick succession at the Smokvica locality contains a rich and diverse planktonic foraminiferal assemblage which allows dating of the succession and the recognition of some biostratigraphic zones. The lower part of the Smokvica section consists of 1.5 m thick pelagic biomicrite characterized by the abundance of late Maastrichtian planktonic foraminifera that indicate the Abathomphalus mayaroensis Zone. An intercalation of intraclastic floatstone

Published

2020

6. Geological and structural setting of the Vinodol Valley (NW Adriatic, Croatia): insights into its tectonic evolution based on structural investigations

Author

Igor Vlahović, Damir Palenik, Marijan Herak, Dubravko Matičec, Bojan Matoš, and Ladislav Fuček

Subjects

010506 paleontology, Focal mechanism, geography, geography.geographical_feature_category, Carbonate platform, NW Adriatic, Vinodol Valley, Bakar Bay, SW and NE vergences, compression/transpression, neotectonic activity, focal mechanism solutions, seismicity, NW Adriatic, Vinodol valley, Bakar bay, SW and NE vergences, compression/transpression, neotectonic activity, focal mechanism solutions, seismicity, Fault (geology), 01 natural sciences, Cretaceous, Transpression, Paleontology, Tectonics, Sinistral and dextral, General Earth and Planetary Sciences, Paleogene, Geology, 0105 earth and related environmental sciences, General Environmental Science

Abstract

The area of the Vinodol Valley and Bakar Bay represents a NW‒SE oriented valley in the NW Adriatic characterised by prominent historical and instrumentally recorded seismicity. As part of the greater geodynamic domain including the Ilirska Bistrica–Rijeka–Senj seismogenic fault zone, new geological and structural data addressing the tectonic evolution of the area were collected in order to better understand the focal mechanisms of previous earthquakes and to enable identification of potential seismogenic sources. Mapped informal lithostratigraphic units mostly correspond to the Upper Cretaceous, Palaeogene and Quaternary successions described in other parts of the External Dinarides. However, a shorter stratigraphic range of the Gornji Humac fm., the youngest Cretaceous unit in the study area, was determined and suggests that the uplifted area in the central NW part of the Adriatic Carbonate Platform already comprised several thousand km2 (from W and NW Istria to Krk and Vinodol area) at the end of the Turonian. Structural measurements of the fault planes in the study area generally correspond to the existing structural model of the tectonic evolution of the Dinarides. However, in contrast to the SW vergences typical of the Dinarides, NE-vergent reverse structures are common, especially along the SW margin of the Vinodol Valley. Cross-cutting relationships suggest that transpressional (NW–SE and NE–SW striking dextral and sinistral faults) and extensional features (NW–SE and NE–SW striking normal faults) are structurally concurrent or younger than the reverse faults, suggesting a change in the palaeostress field during the Neogene–Quaternary, with prevalent transpression and radial extension. Comparison of results of the palaeostress field analysis and the constructed synthetic focal mechanisms on one side, with available focal mechanism solutions for earthquakes within the Ilirska Bistrica–Rijeka–Senj seismogenic fault zone on the other, shows a favourable orientation of the observed NW‒SE and NE‒SW striking faults with respect to the recent compressional/transpressional stress field (N‒S oriented P-axis), indicating these as potential seismogenic sources within the study area.

Published

2019

7. Maastrichtian to Palaeocene and Eocene pelagic carbonates on the island of Svetac (central Adriatic, Croatia)

Author

Tvrtko Korbar, Ladislav Fuček, Vlasta Premec Fućek, Nenad Oštrić, Tvrtko Korbar, Ladislav Fuček, Vlasta Premec Fućek, and Nenad Oštrić

Abstract

Maastrichtian to Palaeocene pelagic carbonates on the central Adriatic island of Svetac (Sveti Andrija) are the only outcrops reported to date that document pelagic deposition during the Cretaceous–Palaeogene (K–Pg) transition within the Adriatic Basin. An approximately 3 m thick succession at the Smokvica locality contains a rich and diverse planktonic foraminiferal assemblage which allows dating of the succession and the recognition of some biostratigraphic zones. The lower part of the Smokvica section consists of 1.5 m thick pelagic biomicrite characterized by the abundance of late Maastrichtian planktonic foraminifera that indicate the Abathomphalus mayaroensis Zone. An intercalation of intraclastic floatstone <0.5 m in thickness occurring on top of Maastrichtian pelagic biomicrite is characterized by unsorted pelagic intraclasts floating within the pelagic matrix, and both components only contain Maastrichtian planktonic foraminifera.The floatstone is overlain by another <0.5 m thick intraclastic-bioclastic floatstone characterized by rounded pelagic intraclasts (plasticlasts) containing Maastrichtian planktonic foraminifera floating in the pelagic matrix. The matrix of the later floatstone contains Maastrichtian and Palaeocene planktonic foraminifera mixed together. Thus, the transition from the Maastrichtian to the Palaeocene is not continuous but is characterized by amalgamated debrites that are related to at least two separated re-depositional events within the basin. The overlying pure pelagic biomicrite is rich in planktonic foraminifera that indicates the Palaeocene P3 Zone. A few metres apart, after the covered interval, there are also Eocene pelagic biomicrites with planktonic foraminifera which indicate the Eocene E9 Zone, characterized by the co-appearance of benthic foraminifera (Discocyclina) floating within the pelagic matrix. It is assumed that a Maastrichtian opening of the deep-water environment connected to the Adriatic Basin within the for

Published

2020

8. Cenomanian–Turonian oceanic anoxic event (OAE2) imprint on the northwestern part of the Adriatic Carbonate Platform and a coeval intra-platform basin (Istria and Premuda Island, Croatia)

Author

Bosiljka Glumac, Vlatko Brčić, Mihovil Brlek, Ladislav Fuček, and Martina Šparica Miko

Subjects

010506 paleontology, Carbonate platform, Geochemistry, OAE2, Cenomanian–Turonian, Adriatic carbonate platform (AdCP), Sv. Duh Formation, Istria, Kvarner, 010502 geochemistry & geophysics, 01 natural sciences, NATURAL SCIENCES. Geology. Geology and Paleontology, Foraminifera, Sedimentary depositional environment, chemistry.chemical_compound, PRIRODNE ZNANOSTI. Geologija. Geologija i paleontologija, Water environment, 0105 earth and related environmental sciences, biology, Paleontology, biology.organism_classification, Cretaceous, Diagenesis, chemistry, Carbonate, Cenomanian, Geology

Abstract

The Cenomanian–Turonian boundary (CTB) on the intra-Tethyan Adriatic Carbonate Platform (AdCP) is generally characterised by a transition between microbially laminated and/or bioclastic limestones to calcisphere-rich massive limestone with bioturbated intervals, organic-rich interbeds, firmgrounds, as well as neptunian dikes, carbonate turbidites, tempestites and slumped structures. Compilation of the results from two study sites in the northwestern part of the AdCP and from previous research (on Istria Peninsula and islands in the Adriatic Sea in Croatia) provides a more complete overview of geological events and paleoenvironmental conditions that transformed the formerly contiguous shallow-marine environments during this time period. For the first time, a comparison between protected inner-platform area (Barban section) and a coeval intra-platform basin (Premuda Island section) during the CTB was made. This study utilized a combination of litho-, bio-, and microfacies studies with SEM, EDS, TOC, δ13C and δ18O stable isotope analyses. The stratigraphic successions start with shallow-marine carbonate deposits of the Milna Formation that is conformably overlain by the drowned-platform deposits of the Sveti Duh Formation on the platform and by the Veli Rat Formation in the contemporaneously developed intraplatform basin. These deposits are in turn overlain by the Gornji Humac Formation, which represents re-establishment of shallow-marine depositional systems on the AdCP, whereas the deeper water environment persisted in the intra-platform basin until the Santonian. Despite diagenetic modifications of shallow-marine carbonate deposits, the results of TOC and stable isotope analyses indicate the influence of global Oceanic Anoxic Event 2 (OAE2). Combination of local and regional synsedimentary tectonics and global Late Cretaceous sea-level changes accompanied by anoxic and hypoxic conditions, extinction of numerous benthic foraminifera, diversification and expansion of planktonic foraminifera and calcareous dinoflagellates, provide new insights into the character of the CTB interval in this part of the Tethyan realm.

Published

2021

9. Geological and structural setting of the Vinodol Valley (NW Adriatic, Croatia): insights into its tectonic evolution based on structural investigations

Author

Damir Palenik, Dubravko Matičec, Ladislav Fuček, Bojan Matoš, Marijan Herak, Igor Vlahović, Damir Palenik, Dubravko Matičec, Ladislav Fuček, Bojan Matoš, Marijan Herak, and Igor Vlahović

Abstract

The area of the Vinodol Valley and Bakar Bay represents a NW‒SE oriented valley in the NW Adriatic characterised by prominent historical and instrumentally recorded seismicity. As part of the greater geodynamic domain including the Ilirska Bistrica–Rijeka–Senj seismogenic fault zone, new geological and structural data addressing the tectonic evolution of the area were collected in order to better understand the focal mechanisms of previous earthquakes and to enable identification of potential seismogenic sources. Mapped informal lithostratigraphic units mostly correspond to the Upper Cretaceous, Palaeogene and Quaternary successions described in other parts of the External Dinarides. However, a shorter stratigraphic range of the Gornji Humac fm., the youngest Cretaceous unit in the study area, was determined and suggests that the uplifted area in the central NW part of the Adriatic Carbonate Platform already comprised several thousand km2 (from W and NW Istria to Krk and Vinodol area) at the end of the Turonian. Structural measurements of the fault planes in the study area generally correspond to the existing structural model of the tectonic evolution of the Dinarides. However, in contrast to the SW vergences typical of the Dinarides, NE-vergent reverse structures are common, especially along the SW margin of the Vinodol Valley. Cross-cutting relationships suggest that transpressional (NW–SE and NE–SW striking dextral and sinistral faults) and extensional features (NW–SE and NE–SW striking normal faults) are structurally concurrent or younger than the reverse faults, suggesting a change in the palaeostress field during the Neogene–Quaternary, with prevalent transpression and radial extension. Comparison of results of the palaeostress field analysis and the constructed synthetic focal mechanisms on one side, with available focal mechanism solutions for earthquakes within the Ilirska Bistrica–Rijeka–Senj seismogenic fault zone on the other, shows a fa

Published

2019

10. Reply to Comment on 'Post-impact event bed (tsunamite) at the Cretaceous-Palaeogene boundary deposited on a distal carbonate platform interior'

Author

Ladislav Fuček, Vlasta Premec Fućek, Hrvoje Posilović, Tvrtko Korbar, and Iain McDonald

Subjects

Hydrology, 010506 paleontology, Carbonate platform, Event (relativity), Geology, 010502 geochemistry & geophysics, 01 natural sciences, Additional research, Cretaceous, Boundary (real estate), KPg (KT) boundary, western Tethys, distal tsunami, lagoon, Paleontology, Section (archaeology), Paleogene, 0105 earth and related environmental sciences

Abstract

We disagree with many of the concerns raised by Font et al., (2017) and take this opportunity to clarify matters. We wish to emphasise that in our paper (Korbar et al., 2017), as well as in the first report on the “potential” Cretaceous–Palaeogene (K–Pg) tsunami in the Adriatic region (Korbar et al., 2015), we reported on rare shallow marine distal K–Pg records that differ from the dominantly deep marine records commonly reported in other papers. We did not include more references on the latter, since that was not a goal of our paper, and we encourage the authors of the Comment themselves to make additional research of the Likva section, especially the issues that are criticised. This article is protected by copyright. All rights reserved.

Published

2017

11. Post-impact event bed (tsunamite) at the Cretaceous-Palaeogene boundary deposited on a distal carbonate platform interior

Author

Iain McDonald, Tvrtko Korbar, Vlasta Premec Fućek, Ladislav Fuček, and Hrvoje Posilović

Subjects

010506 paleontology, geography, geography.geographical_feature_category, biology, Carbonate platform, Event (relativity), Geology, 010502 geochemistry & geophysics, biology.organism_classification, 01 natural sciences, Cretaceous, Foraminifera, Paleontology, QE, Mesozoic, Cretaceous–Paleogene, Tethys, Adriatic carbonate platform, asteroid impact, tsunami, Bioturbation, Cove, Paleogene, 0105 earth and related environmental sciences

Abstract

We show crucial evidence for the Cretaceous–Palaeogene (K–Pg) boundary event recorded within a rare succession deposited in an inner-platform lagoon on top of a Mesozoic, tropical, intra-oceanic (western Tethys) Adriatic carbonate platform, which is exposed at Likva cove on the island of Brac (Croatia). The last terminal Maastrichtian fossils appear within a distinct 10–12 cm thick event bed that is characterized by soft-sediment bioturbation and rare shocked-quartz grains, and is interpreted as a distal tsunamite. Directly overlying this is a 2 cm thick reddish-brown clayey mudstone containing planktonic foraminifera typical of the basal Danian, and with elevated platinum-group elements in chondritic proportions indicating a clear link to the Chicxulub asteroid impact. These results strongly support the first discovery of a “potential” K–Pg boundary tsunamite on the neighboring island of Hvar, and these two complementary sections represent probably the most complete record of the event among known distal shallow-marine successions.

Published

2017

12. The Cenomanian-Turonian boundary in the northwestern part of the Adriatic Carbonate Platform (Ćićarija Mtn., Istria, Croatia): Characteristics and implications

Author

Marija Horvat, Ladislav Fuček, Ivan Mišur, Anita Grizelj, Bosiljka Glumac, Hrvoje Posilović, and Vlatko Brčić

Subjects

010506 paleontology, biology, Carbonate platform, δ18O, Stratigraphy, Paleontology, Geology, engineering.material, 010502 geochemistry & geophysics, biology.organism_classification, 01 natural sciences, Wackestone, Cretaceous, Foraminifera, chemistry.chemical_compound, chemistry, engineering, Carbonate, Cenomanian, Glauconite, 0105 earth and related environmental sciences, Cenomanian–Turonian, OAE2, Adriatic Carbonate Platform (AdCP), Ćićarija Mtn., Sv. Duh Formation, Glauconite

Abstract

The Cenomanian–Turonian boundary (CTB) in the Cicarija Mountain region (northern Istria, Croatia) is characterized by calcisphere limestone successions with a firmground and glauconite horizon, bioturbated intervals, tempestites, and slumped structures as well as microbially laminated and organic-rich interbeds deposited in the northwestern part of the intra-Tethyan Adriatic Carbonate Platform (AdCP). Compilation of the results from three studied sections (Vodice–Jelovica, Martinjak and Planik) of litho-, bio-, and microfacies analyses, X-ray diffraction, SEM, EDS, and stable isotope analyses allowed reconstruction of marine paleoenvironmental conditions during this time period. Shallow-marine carbonate deposits of the Milna Formation underlie a drowned-platform succession of the Sveti (Sv.) Duh Formation. The contact between these two formations is sharp and commonly marked by slumped deposits. The Sv. Duh Formation consists of about 100 m of calcisphere wackestone enriched in organic matter. The results of preliminary δ13C and δ18O stable isotope analyses indicate the influence of the global Oceanic Anoxic Event (OAE2) on the deposition of this carbonate succession. Anoxic and hypoxic conditions in the water column lead to major changes in the shallow-marine carbonate system of the AdCP. Numerous benthic foraminifera declined during that time, but planktonic foraminifera and calcareous dinoflagellates diversified and expanded greatly. The results of this research provide new insights into the character of the CTB interval in this part of the Tethyan realm. Local and regional synsedimentary tectonics combined with global upper Cretaceous sea-level dynamics allows the correlation of the investigated deeper-marine lithostratigraphic units with OAE2.

Published

2017

13. Potential Cretaceous-Paleogene boundary tsunami deposit in the intra-Tethyan Adriatic carbonate platform section of Hvar (Croatia)

Author

Vlasta Premec Fućek, Rodolfo Coccioni, Iain McDonald, Alessandro Montanari, Philippe Claeys, Ladislav Fuček, Christian Koeberl, Tvrtko Korbar, and Toni Schulz

Subjects

Carbonate platform, PALEOCENE, STORM DEPOSITS, K-T BOUNDARY, Cretaceous–Paleogene boundary, LOOK-UP TABLE, STRONTIUM-ISOTOPE STRATIGRAPHY, Foraminifera, chemistry.chemical_compound, Paleontology, PLATINUM-GROUP ELEMENTS, TERTIARY BOUNDARY, CHICXULUB IMPACT, MAIELLA PLATFORM, NORTH-ATLANTIC, QE, Intraclasts, biology, Geology, biology.organism_classification, chemistry, Rudists, Carbonate, Sedimentary rock, Paleogene, Cretaceous-Paleogene event, tsunami, Adriatic carbonate platform, western Tethys

Abstract

An exceptional 47-m-thick succession of Maastrichtian to Paleocene inner-platform carbonates is exposed on the Dalmatian island of Hvar (Adriatic Sea, Croatia) in a seaside locality called Majerovica. The middle part of this succession is an ~5-m-thick intraformational massive deposit, which is underlain by well-bedded peritidal inner-platform limestones containing latest Maastrichtian rudists and shallow-water benthic foraminifera. This deposit includes a polygenic, matrix-supported carbonate breccia characterized by ripped-up platform limestone lithoclasts, up to boulder sized, and polygenic microbreccia in a muddy matrix. The microbreccia contains rare small intraclasts of pelagic mudstone containing terminal Maastrichtian planktonic foraminifera. The deposit is overlain in turn by mudstone containing a planktonic foraminiferal association belonging to the P0 and Pα zones of the basal Paleogene, and by shallow-water muddy limestones containing planktonic foraminifera belonging to the P1 zone. While facies suggest that the deposit was emplaced over the inner platform by a single large tsunami, the biostratigraphic assessment of this section and the presence of enhanced concentrations of platinum group elements, such as iridium, in the topmost part of the massive deposit lend support to the hypothesis that this tsunamite is related to the Chicxulub impact in Yucatán. This is potentially the first case of a tropical carbonate platform sedimentary succession recording the Cretaceous-Paleogene boundary event, which provides a new constraint for modeling both the western Tethyan paleogeography and the catastrophic aftermaths of the Chicxulub impact at the end of the Mesozoic Era.

Published

2015

14. Cenomanian carbonate facies and rudists along shallow intraplatform basin margin-the island of Cres (Adriatic Sea, Croatia)

Author

Tvrtko Korbar, Ladislav Fuček, Antun Husinec, Vladimir Jelaska, Dubravko Matičec, Nenad Oštrić, and Igor Vlahović

Subjects

Cenomanian, carbonates, rudists, synsedimentary tectonics, Adriatic Carbonate Platform, island of Cres, Dinarides, Croatia, biology, Carbonate platform, Stratigraphy, Paleontology, Geology, Structural basin, biology.organism_classification, Cretaceous, Foraminifera, Rudists, Sedimentary rock, Sedimentology

Abstract

The island of Cres is located in the northern part of the Adriatic Sea. The island is built up of predominantly Cretaceous carbonates deposited in north-western part of extensive and long-lasting Adriatic Carbonate Platform. Owing to the influence of synsedimentary tectonics supported by eustatic changes during the latest Albian/Early Cenomanian, different sedimentary environments were established: from shallow intraplatform basin and related slope, across basin margin to protected shallow-platform. During the Early to Middle Cenomanian rudist communities (ichthyosarcolitid/caprinid/radiolitid) flourished along a relatively high-energy intraplatform basin margin. Fair amounts of coarse-grained bioclasts, derived almost exclusively from broken rudist shells, were deposited over a marginal depocenter. Contemporaneously, pithonellid wackestone-packstones containing microbioclasts and planktonic foraminifera were deposited basinward while marginal bioclastic sediments and limestone blocks of the basin margin origin were sporadically deposited within the basin. The opening of the Cres intraplatform basin was aborted and the basin was finally filled up during the Late Cenomanian. Since the Cres intraplatform basin was established at the beginning of the Cenomanian it probably represented the initiation phase in the north-western extension of the later Adriatic Trough development.

Published

2001

15. Mid Cretaceous orbitolinid (Foraminiferida) record from the islands of Cres and Losinj (Croatia) and its regional stratigraphic correlation

Author

Nenad Oštrić, Igor Vlahović, Ladislav Fuček, Antun Husinec, Dubravko Matičec, Ivo Velić, and Tvrtko Korbar

Subjects

biology, Aptian, Range (biology), Paleontology, Biozone, Biostratigraphy, biology.organism_classification, mid Cretaceous (Aptian, Albian, Cenomanian), biostratigraphy, orbitolinids, Foraminiferida, Dinarides, Croatia, Cretaceous, Foraminifera, Conica, Cenomanian, Geology

Abstract

The mid Cretaceous shallow-water limestones on the islands of Cres and Losinj contain abundant and diversified orbitolinid foraminifera. A biostratigraphy, based on the orbitolinid taxa and their chronostratigraphic interpretation, is proposed for the Aptian, Albian and Cenomanian deposits in the area investigated. Four orbitolinid biozones have been recognized: (1) Palorbitolina lenticularis Taxon-Range Zone in the Lower Aptian; (2) Orbitolina ( Mesorbitolina ) texana Assemblage Zone in the Lower Albian, the body of strata being characterized by a distinctive assemblage of Orbitolina ( Mesorbitolina ) texana , O. ( M .) subconcava , O . ( M .) parva and O. ( M .) pervia ; (3) ‘Valdanchella’ dercourti Taxon-Range Zone in the basal Upper Albian; and (4) Orbitolina ( Conicorbitolina ) conica Abundance Zone in the Lower–Middle Cenomanian, a body of strata in which the abundance of the species Orbitolina ( Conicorbitolina ) conica is significantly greater than is usual in the adjacent parts of the section, regardless of either association or range. The established biozones on the islands of Cres and Losinj are correlated with orbitolinid biozonations and orbitolinid stratigraphic distributions in the adjacent areas, with emphasis on the Karst Dinarides.

Published

2000

16. Stratigraphic framework, discontinuity surfaces and regional significance of Campanian slope to ramp carbonates from central Dalmatia, Croatia

Author

Ladislav Fuček, B. Cvetko Tešović, Mihovil Brlek, Tvrtko Korbar, and Bosiljka Glumac

Subjects

biology, Carbonate platform, Stratigraphy, Paleontology, Geology, Diachronous, biology.organism_classification, Unconformity, Cretaceous, Sedimentary depositional environment, Thalassinoides, Forebulge, Campanian, slope to ramp carbonates, discontinuity surfaces, Adriatic-Dinaridic Carbonate Platform, regional correlation, Paleogene

Abstract

The sedimentology, microfacies, and stratigraphic age (from planktonic and benthic foraminifera and strontium-isotope stratigraphy) of a 300-m-thick Upper Cretaceous carbonate succession from the Island of Ciovo (central Dalmatia, Croatia) were analyzed in order to determine the lithostratigraphic, depositional, and chronostratigraphic framework. The Cretaceous strata were deposited in the southern part of the long-lasting (Late Triassic to Paleogene) Adriatic-Dinaridic Carbonate Platform (ADCP), one of a few late Mesozoic, intra-Tethyan, peri-Adriatic (sub)tropical archipelagos. The succession is separated by a firmground formational boundary into two lithostratigraphic units: the underlying Middle to Upper Campanian Dol Formation consisting of slope pelagic limestone with intercalated turbidites and debrites, and the overlying Upper Campanian Ciovo Formation composed of outer-ramp bioclastic-lithoclastic and echinoderm-dominated packstone. Age, lithology, and depositional settings of the Ciovo Formation are different from other penecontemporaneous, regionally important inner-platform carbonate successions within the ADCP domain. Therefore, the Ciovo Formation is proposed here as a new lithostratigraphic unit. Regionally important condensed intervals in the form of at least two firmground surfaces, characterized by Thalassinoides burrows (with phosphatic mineralization) that belong to the Glossifungites ichnofacies, occur in the lowermost part of the Ciovo Formation. Abrupt shallowing of depositional environments at the boundary between the Dol and the Ciovo Formation, and the generation of the formational boundary firmground, likely correlate with the regionally recorded Upper Campanian Event that represents a global eustatic sea-level fall. A regionally important subaerial exposure surface with nodular calcrete, rhizoliths, and Microcodium aggregates in the upper part of the Ciovo Formation represents a regional subaerial unconformity that was recorded across the ADCP domain and was interpreted as a consequence of diachronous and differential uplift of various parts of the platform in response to the formation of a forebulge in front of the approaching Dinaridic orogen.

Published

2013

17. Late Cretaceous sedimentary evolution of a northern sector of the Adriatic Carbonate Platform (Matarsko Podolje, SW Slovenia)

Author

Bojan Otoničar, Jernej Jež, Bojan Ogorelec, and Ladislav Fuček

Subjects

Carbonate platform, Stratigraphy, Late Cretaceous, Lithofacies, Lithostratigraphic units, Adriatic Carbonate Platform (AdCP), Matarsko Podolje, SW Slovenia, Paleontology, Geology, Unconformity, Cretaceous, Sedimentary depositional environment, chemistry.chemical_compound, chemistry, Carbonate rock, Carbonate, Sedimentary rock, Cenomanian

Abstract

Cretaceous shallow-marine carbonate rocks of SW Slovenia were deposited in the northern part of the Adriatic Carbonate Platform. A 560-m-thick continuous Upper Cenomanian to Santonian carbonate succession has been studied near Hrusica Village in Matarsko Podolje. With regard to lithological, sedimentological, and stratigraphical characteristics, the succession has been divided into nine lithostratigraphic units, mainly reflecting regressive and transgressive intervals of larger scale. During the latest Cenomanian and Early Turonian, hemipelagic limestones were deposited on top of shallow-marine lagoon and peritidal Upper Cenomanian deposits indicating relative sea-level rise. Subsequently, the deeper marine depositional setting was gradually filled by clinoform bioclastic sand bodies overlain by peritidal and shallow-marine low-energy mainly lagoonal lithofacies. Similar lithofacies of predominately inner ramp/shelf depositional settings prevail over the upper part (i.e., Coniacian to Santonian) of the succession. In the area, the Upper Cetaceous carbonate rocks are separated from the overlying Lower Eocene (Upper Paleocene?) carbonate sequence by regional unconformity denoted by distinct paleokarstic features. On the Adriatic Carbonate Platform the deeper marine carbonate setting, developed at the Cenomanian/Turonian boundary, is usually correlated with OAE2 and related eustatic sea-level rise. Similarly, subsequent reestablished shallow-marine conditions are related to Late Turonian long- and short-term sea-level fall. However, we are suggesting that deeper marine deposits were deposited in a tectonically induced intraplatform basin formed simultaneously with the uplift of the northern and northeastern marginal parts of the Adriatic Carbonate Platform.

Published

2011

18. The Origin and Importance of the Dolomite-Limestone Breccia Between the Lower and Upper Cretaceous Deposits of the Adriatic Carbonate Platform: An Example from Cicarija Mt. (Istria, Croatia)

Author

Nenad Oštrić, Igor Vlahović, Dubravko Matičec, Ladislav Fuček, Božo Prtoljan, Ivo Velić, and Josip Tišljar

Subjects

Late-diagenetic dolomitization, Croatia, Carbonate platform, Dolomite, Geochemistry, Lower to Upper Cretaceous transition, Late-diagenetic silicification, Paleontology, chemistry.chemical_compound, Tectogenic-diagenetic breccia, Ćićarija Mt, Adriatic Carbonate Platform, Breccia, Cicarija Mt, General Environmental Science, Calcite, lcsh:QE1-996.5, Cementation (geology), Cretaceous, Diagenesis, lcsh:Geology, chemistry, General Earth and Planetary Sciences, Cenomanian, Geology

Abstract

On the NE slopes of Ćićarija Mt. (N Istria) a 120-150 m thick complexcomposed of dolomite-limestone breccia crops out between theLower and Upper Cretaceous deposits. This studied breccia sequenceis of post-sedimentary, tectogenic-diagenetic origin. It was formed bypolyphase tectonic fracture of the Upper Albian to Lower Cenomanianearly- and late-diagenetic dolomite succession with relics ofrecrystallized limestone, which enabled very important subsequentdiagenetic alteration. This included partial dissolution, dedolomitization,recrystallization and calcitization of the fine-grained, crusheddolomite matrix, and centripetal dissolution of dolomite fragmentsand their cementation by calcite and ferroan calcite cements, as wellas the partial collapse of fragments from the roofs of dissolution cavitiesand limited late-diagenetic silicification (the silica surplus originatingfrom layers of diagenetic quartz from underlying Upper Albiandeposits). Such a complex pattern of different events resulted in thehigh variability of breccia characteristics over relatively small distances,especially near more intensively tectonized zones.The contemporaneous stratigraphic level (Lower to Upper Cretaceoustransition) in other parts of the Adriatic Carbonate Platform isalso characterised by predominantly late-diagenetic dolomites withrelics of limestones (including local occurrences of early-diageneticdolomites) which are, in more tectonized areas, late-diageneticallyaltered into tectogenic-diagenetic breccias.

Published

2002