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Péter Solt Mining and Geological Survey of Hungary, Budapest, Hungary

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Andrea Szuromi-Korecz E&P Laboratory, MOL Plc., Budapest, Hungary

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Attila Ősi Department of Paleontology, Eötvös University, Budapest, Hungary
Hungarian Natural History Museum, Budapest, Hungary

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Abstract

In June 2017 a new sauropod trackway locality was discovered in the central part of the Adriatic–Dinaric Carbonate Platform (ADCP), on the island of Hvar (Croatia). The track site is situated on the northern shore of the western edge (Pelegrin) of the island in the upper Turonian – lower Coniacian limestone series. The track site contains altogether 13 footprints arranged in four possible trackways. The largest footprints have a diameter up to 80 cm. In some places the limestone surface is strongly karstified and the tracks are partly eroded, which has certainly modified the original shape and size of the footprints. Microfossil assemblage from the track-bearing beds suggest an early Coniacian age for the tracks. The new trackways on Hvar Island further strengthen the earlier hypothesis that sauropods were present in the western Tethyan archipelago during the late Cenomanian–late Campanian period. In addition, the new tracks, together with those from the Žukova Cove of Hvar, represent two, possibly slightly different stratigraphic horizons close to the Turonian–Coniacian boundary, and suggest that the occurrence of sauropods on the ADCP and possibly also on other parts of the Apulian microplate was not accidental, but rather periodical and more frequent than previously thought.

Abstract

In June 2017 a new sauropod trackway locality was discovered in the central part of the Adriatic–Dinaric Carbonate Platform (ADCP), on the island of Hvar (Croatia). The track site is situated on the northern shore of the western edge (Pelegrin) of the island in the upper Turonian – lower Coniacian limestone series. The track site contains altogether 13 footprints arranged in four possible trackways. The largest footprints have a diameter up to 80 cm. In some places the limestone surface is strongly karstified and the tracks are partly eroded, which has certainly modified the original shape and size of the footprints. Microfossil assemblage from the track-bearing beds suggest an early Coniacian age for the tracks. The new trackways on Hvar Island further strengthen the earlier hypothesis that sauropods were present in the western Tethyan archipelago during the late Cenomanian–late Campanian period. In addition, the new tracks, together with those from the Žukova Cove of Hvar, represent two, possibly slightly different stratigraphic horizons close to the Turonian–Coniacian boundary, and suggest that the occurrence of sauropods on the ADCP and possibly also on other parts of the Apulian microplate was not accidental, but rather periodical and more frequent than previously thought.

Introduction

Although the Adriatic–Dinaric Carbonate Platform (ADCP) was a critical area in terms of Cretaceous faunal interchanges of the western Tethyan archipelago (Dalla Vecchia 2002; Pereda-Suberbiola 2009; Csiki-Sava et al. 2015), dinosaur fossils (or those of other continental vertebrates) from this region are poorly known. As far as body fossils are concerned, significant dinosaur remains are known from Hauterivian–Barremian sediments lying a few meters below the Adriatic Sea level, close to Bale (Vale) in Istria (Boscarolli et al. 1993; Kozarić et al. 1996; Dalla Vecchia, 1998a, 2001; Boscarolli and Dalla Vecchia 1999). Complete and partial skeletons of the derived hadrosauroid Tethyshadros insularis are known from the Campano–Maastrichtian beds of the Trieste region (Dalla Vecchia 2009). In addition, fissure-filling Campanian sediments discovered in various places of Slovenia provided isolated teeth and bones of different continental vertebrates (Debeljak et al. 1999).

Most of the dinosaur fossils from the ADCP are footprints preserved in various shallow marine, Cretaceous horizons (see e.g., Dalla Vecchia and Tarlao 1995, 2001; Kozarić et al. 1996; Mezga and Bajraktarevic 1999). For a long time, footprints were found only in the northern part of the ADCP, in Istria (Brioni, Cervar, Fazana, Fenoliga, Grakalovac, Kolone, Lovrecica, Mirna, Puntesella; see e.g., Kozarić et al. 1996; Dalla Vecchia 1998b, 2001; Mauko and Florjančič 2003; Mezga et al. 2006a).

In 2005 trackways of medium to large-sized sauropod dinosaurs were discovered in the central part of the ADCP, on Hvar Island at Žukova Cove, Dalmatia (Mezga et al. 2006b), in an upper Turonian – lower Coniacian limestone series. These footprints were among the first two sauropod records from the Cenomanian–late Campanian European “Sauropod hiatus” (Nicosia et al. 1999; Mannion and Upchurch 2011), suggesting that this group of herbivorous dinosaurs did not become extinct in the European archipelago but still survived on some islands (Ősi et al. 2017).

In this work we describe a new locality with sauropod dinosaur tracks from Hvar Island that represents another stratigraphic horizon with sauropod occurrence within the so-called European “Sauropod hiatus.”

Locality

In June 2017 a new locality with dinosaur footprints and trackways was found in a Cretaceous limestone series in the northwestern part (Pelegrin) of Hvar Island (Fig. 1). The new site (Fig. 2) is approximately 15 km westward of the Žukova Cove, from where Mezga et al. (2006b) described the first dinosaur footprints of the island.

Fig. 1.
Fig. 1.

Location of the new Late Cretaceous track site on Hvar Island, Croatia. A, Position of Hvar Island in Croatia. B, The position of the track site on Hvar Island. C, Schematic explanatory drawing of the track site. Labeled circles are tracks

Citation: Central European Geology Central European Geology 63, 1; 10.1556/24.2020.00001

Fig. 2.
Fig. 2.

Some representative elements of the microfossil assemblage from the track-bearing beds. A, Moncharmontia apenninica from sample II-1. B, Pseudocyclammina sphaeroidea from sample II-1. C, Scandonea samnitica from sample II-1. D, Pseudonummuloculina heimi from sample II-2. E, Whiteinella paradubia from sample II-1. F, Hedbergella delrioensis from sample II-1. G, Thaumatoporella parvovesiculifera from sample II-1. H, Aeolisaccus kotori from sample II-1

Citation: Central European Geology Central European Geology 63, 1; 10.1556/24.2020.00001

Leaving the northern shore of Floriana Bay to the west, we follow the stair step-like Upper Cretaceous limestone-beds (Gušić and Jelaska 1990; Jerinić et al. 1994; Fio Firi et al. 2017) on the rocky seaside. Walking ca. 2 km along the shore and passing the little islet of Otočić Duga, we reach the new track site (GPS coordinates: N 43º 11' 40'', E 16º 24' 04''). On the 870 m2 track-bearing surface, probably four trackways are present, altogether with 13 footprints.

Geologic setting and age

The general geology of Hvar Island has been well summarized by Mezga et al. (2006b) when describing the first sauropod trackways from the island. Since the new discoveries described in this paper are from the same region, following a brief general geologic summary we prefer to focus on the sedimentology and micropaleontology of the new track-bearing bed.

General geological background

Hvar Island belongs to the Dalmatian part of the ADCP. The central part of the island is built up by Lower Cretaceous shallow-marine limestone and dolomite (Marinčić and Majcen 1968). On the hillslopes, in every direction toward the coast, Cenomanian–Turonian laminated limestone and thin-laminated deep-water limestone are exposed (Fio Firi et al. 2017). According to previous work (Fio Firi et al. 2017 and references therein) the new track site, situated along the northwestern coast of the island (Pelegrin Peninsula), is built up by an Upper Cretaceous (Turonian and Senonian) bedded and laminated limestone series (Marinčić and Majcen 1968; Mezga et al. 2006b; Diedrich et al. 2011; Fio Firi et al. 2017).

Sampling for microfossils

We carefully collected a single sample from each of the three layers (samples II-1–II-3) from the locality for sedimentological, micropaleontological and palynological analyses. The lowermost, massive, 50 cm-thick light-brownish limestone bed (II-1) is overlain by a 10 cm, light-brown limestone bed (II-2) that contains the tracks on its surface. This track-bearing layer is covered by a 20 cm-thick light-brownish, laminated limestone (II-3). The three rock layers are made up of bioclastic wackestone–packstone, and lamination is present in all the samples (samples II-1, II-2, II-3), but bioturbation can be observed only in sample II-3. The rock samples from the three different layers represent periodically changed environments of the shallow lagoonal or peritidal zone, as observed by Diedrich (2005, 2010) at other dinosaur mega-track sites on the ADCP.

Microfossils and age

Large (5 × 5 cm) thin sections were made from the three rock samples collected from the locality. Unfortunately, no detectable palynological remains have been found (Siegl-Farkas 2018), as it was the case with earlier palynological samplings made close to our site in Hvar by Fio Firi et al. (2017). Other microfossils, however, were present in the samples (for the complete list see Table 1).

Table 1.

Representatives of the microfossil assemblage from the new Late Cretaceous track site on Hvar Island, Croatia. Table shows that the temporal range of the taxa during the Cretaceous suggest an early Coniacian age for the track-bearing bed (based on Premoli Silva and Sliter, 2002; Velič, 2007)

In all samples, the green algae Thaumatoporella parvovesiculifera (Fig. 2G) and cyanobacteria Aeolisaccus kotori (Fig. 2H), the marker forms for semi-restricted, stressed environments, are present (Tasli et al. 2006; Schlagintweit et al. 2015). Foraminifera assemblages (Fig. 2) are dominated by benthic forms, including many species referring to the euryhaline Miliolidae, which preferred closed lagoons (Davies 1970; Murray 1991). In addition, some members of Textularidae and Buliminidae were also present in the samples. Planktonic foraminifera are far less abundant but some of them – identified at species level – have age relevance. Besides foraminifera, specimens of ostracods and mollusks – including rudist shell fragments originating from the nearby reef environment – are also present in the samples.

The age of the track-bearing bed is definitely Late Cretaceous, as was already concluded for the northwestern coast of the island (Fio Firi et al. 2017 and references therein). The benthic and planktonic foraminifera, however, fortunately provided a more precise age. According to Premoli Silva and Sliter (2002) the temporal range of the planktonic foraminifer Whiteinella paradubia (Fig. 2E) is from the Cenomanian to the early Coniacian, and based on Velič (2007) Scandonea samnitica (Fig. 2C) existed from the Coniacian to the Campanian (see Table 1). This suggests an early Coniacian age for the track-bearing bed.

Description of the track site

On the sea-shore the track-bearing surface is a 38.3 m long and 22.7 m wide, 870 m2-large area with a NNW strike of 340°, dipping 20° to the sea (Fig. 1). The overlying limestone bed is preserved at the western and northern sides of the track-bearing layer; the underlying ones are to the south, and at the eastern side of the outcrop a vertical limestone block borders the track-bearing surface. On the surface of the track-bearing layer, large sized (≥40 cm), poorly preserved footprints can be observed (Fig. 3). The rock surface is strongly karstified and there are many cracks across the footprints. Due to the slow breaking up of the limestone surface the upper (dry land-side) and the lower (seaside) zones are quite different. Wider and deeper karstic cracks occur in the upper zone, whereas the lower zone is covered by denser but thinner and shallow cracks. Near the seaside, intensive waves and organic activity also eroded the surface. The tracks have a present depth varying between 10 and 15 cm.

Fig. 3.
Fig. 3.

Sauropod tracks on the new track-bearing beds in an Upper Cretaceous (lower Coniacian) limestone series in the northwestern part (Pelegrin) of Hvar Island. A–C, Trackway A from different angles. Note that track A1 indicated with a red dotted line is partly covered by the overlying bed. D, Eroded tracks of trackway C

Citation: Central European Geology Central European Geology 63, 1; 10.1556/24.2020.00001

Altogether 13 subcircular footprints can be observed on the track-bearing surface (for measurements see Table 2). Although the tracks are poorly preserved and karstified we suggest that they might belong to at least three different trackways. There are rounded, oval-shaped and horseshoe-shaped footprints. The differentiation of manus or pes imprints, however, is not possible, since their original size and shape has been strongly modified. The tracks are undertracks, since the expulsion rims of the tracks together with the uppermost 1–2 cm layer of the original surface were already eroded. The direction of the sauropod trackways is from west to east.

Table 2.

Length measurements (in cm) of 13 tracks in the track site from the Upper Cretaceous of Hvar Island, Croatia. Note that length data are only rough measurements, since the tracks are strongly karstified

TracksGreatest track widthPace length
A150A1–A2195
A256A2–A3180
A355A3–A4190
A440?C0–C170
B140C1–C2320
?C040C2–C3185
C155C3–C4140
C270D1–D2120
C370D2–D3430
C460
D160
D255
?D380

The first potential trackway (A1–A4) is closest to the sea (Fig. 3A–C) and is composed of four tracks, among which the first track (track A1, Fig. 3C) is partly covered by the overlying limestone bed. A single track (B1) is present between trackway A and C and cannot be related to any of the other tracks. A second possible trackway composed of at least four tracks (C1–C4) is the longest (Fig. 3D). Track C0 being just nearby C1 might belong to this trackway as well. A further possible track (?) is also present south of C2 but it is too poorly preserved to show more details. The last assemblage of tracks on this surface includes three large footprints (D1–D3). It cannot be ruled out that they are the continuation of the C trackway.

Discussion and conclusions

Karstic phenomenon or dinosaur footprints?

Since many of these footprints are in a very poor condition, one might think that these holes are perhaps not dinosaur tracks but the results of, for instance, karstic phenomena. The following arguments, however, unambiguously suggest that these holes are not due to biologic or karstic erosion but were made by large-sized, terrestrial animals:

  1. Track A1, located almost directly at the seaside, is partly filled by the overlying sediments (Fig. 3B–C), clearly indicating that the footprint is contemporaneous with the deposition of these beds.

  2. The bottom of the prints is parallel with the dip of the limestone beds. If the tracks would be karstic phenomena (dissolution pan, weathering pit, etc.), their bottom would be horizontal, or dipping in a different (lower) angle.

  3. No karstic forms with similar shape and size can be recorded along the two km-long, 20–40 m wide, and ca. 60,000 m2 surface of limestone beds, from Duga Bay to Parja Bay. Only a few root-karst holes are present in certain parts of the limestone bed.

  4. In some cases (e.g., A1–A2–A3–A4) the similar, periodic distances between the tracks on the same limestone surface further support the “track-bearing bed” hypothesis.

Comparison of the tracks

The large-sized, circular to oval-shaped footprints from the new site of Hvar suggest that they were made by sauropod dinosaurs. None of the tracks show any indication of well-separated digits, excluding an ornithischian or theropod affinity of the trackmaker (Lockley and Hunt 1995; Lockley and Meyer 2000). Since the preservation of the tracks is extremely poor, only some very basic comparisons can be presented here. Track D3 slightly resembles the pes imprint of an Albian track from the Solaris site, Istria (Dalla Vecchia and Tarlao 2001, Fig. 7), although there is no indication of the fingers on the Hvar track. The general shape, size and gauge of the tracks appear to be similar to the pes imprints of the Cenomanian Carigador/Karigador site of Istria, though the pace length is larger in the Hvar trackways (compare e.g., trackway A to that of Dalla Vecchia et al. 2001, Text-Fig. 8), suggesting slightly higher speed of these animals. Since all the footprints are very close to the supposed trackway midline in all the three possible trackways (A, C, D), the gauge can be interpreted as narrow (according to Farlow et al. 1989 and Lockley et al. 1994), similar to that of the Albian (Dalla Vecchia and Tarlao 2000) and Cenomanian sauropod tracks from Istria (Dalla Vecchia et al. 2001). Compared to the sauropod tracks from Žukova beach, Hvar (Mezga et al. 2006b), the new tracks are much deeper, though this is partly due to the karstic erosion.

The track size (>40 cm) makes it possible to estimate the body length of the track-makers. The new footprints, according to the hip height calculation of Alexander (1989), are comparable and some of them even larger than those described by Mezga et al. (2006b), suggesting similarly large-sized (ca. 15–25 m body length) animals on all the Hvar track sites.

Importance of the new Hvar track sites

The continental vertebrate record of the late Cenomanian to Campanian interval of Europe is extremely scanty and sauropod fossils are almost entirely missing from this period. The only records of these quadrupedal herbivores from this 20 myr-long gap, – all of them discovered only relatively recently –, are as follows: 1) a tooth from the Santonian of the Transdanubian Range, Hungary (Ősi et al. 2017) – this region was on the northern part of the Apulian Microplate during the Cretaceous (Csontos and Vörös 2004) –; 2) footprints from the Santonian of Apulia, southern Italy (Nicosia et al. 1999; Mannion and Upchurch 2011) and 3) footprints from the Turonian of the Žukova Cove, Hvar Island, Croatia (Mezga et al. 2006b) – both regions belonging to the ADCP.

The new sauropod footprint record from the mid-Late Cretaceous of Hvar Island extends our knowledge concerning Late Cretaceous sauropods from this critical period. The new site with its early Coniacian age represents a stratigraphic level similar or slightly younger than that of the Žukova Bay tracks, suggesting that the occurrence of sauropod dinosaurs, at least in the eastern part of the European Cretaceous archipelago, was not accidental but could have been periodical (perhaps seasonal) and much more common than previously thought.

The Apulian microplate, including the ADCP and some islands (e.g., the Transdanubian Range during the Santonian; Haas 2001), or the Turonian to Campanian islands of the Northern Calcareous Alps (Wagreich and Faupl 1994; Ősi et al. 2019), might have functioned as transit areas for faunal interchanges between southern (i.e., Africa) and northern (i.e., stable Europe) landmasses (Dalla Vecchia 2002; Pereda-Suberbiola 2009; Csiki-Sava et al. 2015). This hypothesis is supported by increasing evidence from faunal similarities between Cretaceous Gondwanan and European localities (e.g., Buffetaut 1989; Pereda-Suberbiola 2009; Zarcone et al. 2010; Rabi and Sebők 2015; Csiki-Sava et al. 2015; Fanti et al. 2015; Dal Sasso et al. 2016; Sallam et al. 2018; Holwerda et al. 2018). Hopefully, with further systematic fieldwork, more interesting dinosaur track sites will come to light from the Cretaceous series of Dalmatia and probably in other parts of the ADCP as well.

Acknowledgments

We are thankful to Aleksandar Mezga (Department of Geology and Paleontology, Faculty of Science, University of Zagreb) for his important reflections and observations. Grateful thanks go to Ágnes Siegl-Farkas, palynologist, for palynological analysis and for the laboratory work of Istvánné Bátori (Mining and Geological Survey of Hungary), also many thanks to Nikolett Sipka (MOL Laboratory, Budapest) for her accurate work. Attila Ősi thanks the Dinosaur Research Group of the Eötvös University and NKFIH OTKA (Grant No. K116665) for financial support. Viviána Jó is thanked for fieldwork assistance and help in preparation of the figures, and János Magyar for his technical help. We thank the two anonymous reviewers for the constructive comments that highly improved the manuscript.

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  • Mannion, P.D. and Upchurch, P. (2011). A re-evaluation of the ‘mid-Cretaceous Sauropod hiatus’ and the impact of uneven sampling of the fossil record on patterns of regional dinosaur extinction. Palaeogeography, Palaeoclimatology, Palaeoecology, 299: 529540.

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  • Marinčić, S. and Majcen, Ž. (1968). Osnovna geološka karta SFRJ, 1:100.000, list Jelsa K33–34 (Basic geological map of SFRY, 1:100 000, sheet Jelsa K33–34). Institute of Geology Zagreb; Federal Geological Survey, Beograd.

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  • Mauko, A. and Florjančič, B. (2003). Dinosaur footprints in the Upper Turonian–Coniacian limestone in the Krnica Bay. Geologija, 46(1): 93100.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Mezga, A. and Bajraktarević, Z. (1999). Cenomanian dinosaur tracks on the islet of Fenoliga in southern Istria, Croatia. Cretaceous Research, 20(6): 735746.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Mezga A., Tunis, G., Moro, A., Tarlao, A., Ćosović, V., and Bucković, D. (2006a). A new dinosaur tracksite in the cenomanian of Istria, Croatia. Rivista Italica Paleontographica et Startigraphica, 112(3): 435445.

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    • Export Citation
  • Mezga, A., Meyer, C.A., Tešović, B.A., Bajraktarević, Z., and Gušić, I. (2006b). The first record of dinosaurs in the Dalmatian part (Croatia) of the Adriatic–Dinaric Carbonate Platform (ADCP). Cretaceous Research, 27: 735742.

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  • Murray, J.W. 1991). Ecology and paleoecology of benthic foraminifera. Longman Scientific & Technical, Harlow, p. 397.

  • Nicosia, U., Marino, M., Mariotti, N., Muraro, C., Panigutti, S., Petti, F.M., and Sacchi, E. (1999). The Late Cretaceous dinosaur tracksite near Altamura (Bari, southern Italy). Geologica Romana, 35: 231236.

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    • Export Citation
  • Ősi, A., Csiki-Sava, Z., Prondvai, E. (2017). A sauropod tooth from the Santonian of Hungary and the European Late Cretaceous “Sauropod hiatus”. Scientific Reports, 7(1): 18.

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    • Export Citation
  • Ősi, A., Szabó, M., Kollmann, H., Wagreich, M., Kalmár, R., Makádi, L., Szentesi, Z., Summesberger, H. (2019). Vertebrate remains from the Turonian (Upper Cretaceous) Gosau Group of Gams, Austria. Cretaceous Research, 99: 190208.

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  • Pereda-Suberbiola, X. (2009). Biogeographical affinities of Late Cretaceous continental tetrapods of Europe: a review. Bulletin de la Société Géologique de France, 180(1): 5771.

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  • Premoli Silva, I. and Sliter, W.V. (2002). Practical manual of Cretaceous planktonic foraminifera. In: Premoli-Silva, I. and Rettori, R. (Eds.), International School on Planktonic Foraminifera. Dipartimento di Scienze della Terra, Università di Perugia, Perugia, p. 79.

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  • Rabi, M., and Sebők, N. (2015). A revised Eurogondwana model: Late Cretaceous notosuchian crocodyliforms and other vertebrate taxa suggest the retention of episodic faunal links between Europe and Gondwana during most of the Cretaceous. Gondwana Research, 28(3): 11971211.

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  • Sallam, H.M., Gorscak, E., O’Connor, P.M., El-Dawoudi, I.A., El-Sayed, S., Saber, S., Kora, M.A., Sertich, J.J.W., Seiffert, E.R., and Lamanna M.C. (2018). New Egyptian sauropod reveals Late Cretaceous dinosaur dispersal between Europe and Africa. Nature Ecology & Evolution, 2: 445451.

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  • Schlagintweit, F., Kolodziej, B., and Qorri, A. (2015). Foraminiferan-calcimicrobial benthic communities from Upper Cretaceous shallow-water carbonates of Albania (Kruja Zone). Cretaceous Research, 56: 4363.

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  • Siegl-Farkas, Á. (2018). A Hvar szigetén talált új dinoszaurusz lábnyomos rétegsor palynológiai feltárása (Palynological results from the new dinosaur tracksite locality at Hvar Island, Croatia). Manuscript, p. 4 (in Hungarian).

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  • Zarcone, G., Petti, F.M., Cillari, A., Di Stefano, P., Guzzetta, D., Nicosia, U. (2010). A possible bridge between Adria and Africa: new palaeobiogeographic and stratigraphic constraints on the Mesozoic palaeogeography of the Central Mediterranean area. Earth-Science Reviews, 103(3–4): 154162.

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  • Marinčić, S. and Majcen, Ž. (1968). Osnovna geološka karta SFRJ, 1:100.000, list Jelsa K33–34 (Basic geological map of SFRY, 1:100 000, sheet Jelsa K33–34). Institute of Geology Zagreb; Federal Geological Survey, Beograd.

    • Search Google Scholar
    • Export Citation
  • Mauko, A. and Florjančič, B. (2003). Dinosaur footprints in the Upper Turonian–Coniacian limestone in the Krnica Bay. Geologija, 46(1): 93100.

    • Search Google Scholar
    • Export Citation
  • Mezga, A. and Bajraktarević, Z. (1999). Cenomanian dinosaur tracks on the islet of Fenoliga in southern Istria, Croatia. Cretaceous Research, 20(6): 735746.

    • Search Google Scholar
    • Export Citation
  • Mezga A., Tunis, G., Moro, A., Tarlao, A., Ćosović, V., and Bucković, D. (2006a). A new dinosaur tracksite in the cenomanian of Istria, Croatia. Rivista Italica Paleontographica et Startigraphica, 112(3): 435445.

    • Search Google Scholar
    • Export Citation
  • Mezga, A., Meyer, C.A., Tešović, B.A., Bajraktarević, Z., and Gušić, I. (2006b). The first record of dinosaurs in the Dalmatian part (Croatia) of the Adriatic–Dinaric Carbonate Platform (ADCP). Cretaceous Research, 27: 735742.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Murray, J.W. 1991). Ecology and paleoecology of benthic foraminifera. Longman Scientific & Technical, Harlow, p. 397.

  • Nicosia, U., Marino, M., Mariotti, N., Muraro, C., Panigutti, S., Petti, F.M., and Sacchi, E. (1999). The Late Cretaceous dinosaur tracksite near Altamura (Bari, southern Italy). Geologica Romana, 35: 231236.

    • Search Google Scholar
    • Export Citation
  • Ősi, A., Csiki-Sava, Z., Prondvai, E. (2017). A sauropod tooth from the Santonian of Hungary and the European Late Cretaceous “Sauropod hiatus”. Scientific Reports, 7(1): 18.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Ősi, A., Szabó, M., Kollmann, H., Wagreich, M., Kalmár, R., Makádi, L., Szentesi, Z., Summesberger, H. (2019). Vertebrate remains from the Turonian (Upper Cretaceous) Gosau Group of Gams, Austria. Cretaceous Research, 99: 190208.

    • Search Google Scholar
    • Export Citation
  • Pereda-Suberbiola, X. (2009). Biogeographical affinities of Late Cretaceous continental tetrapods of Europe: a review. Bulletin de la Société Géologique de France, 180(1): 5771.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Premoli Silva, I. and Sliter, W.V. (2002). Practical manual of Cretaceous planktonic foraminifera. In: Premoli-Silva, I. and Rettori, R. (Eds.), International School on Planktonic Foraminifera. Dipartimento di Scienze della Terra, Università di Perugia, Perugia, p. 79.

    • Search Google Scholar
    • Export Citation
  • Rabi, M., and Sebők, N. (2015). A revised Eurogondwana model: Late Cretaceous notosuchian crocodyliforms and other vertebrate taxa suggest the retention of episodic faunal links between Europe and Gondwana during most of the Cretaceous. Gondwana Research, 28(3): 11971211.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Sallam, H.M., Gorscak, E., O’Connor, P.M., El-Dawoudi, I.A., El-Sayed, S., Saber, S., Kora, M.A., Sertich, J.J.W., Seiffert, E.R., and Lamanna M.C. (2018). New Egyptian sauropod reveals Late Cretaceous dinosaur dispersal between Europe and Africa. Nature Ecology & Evolution, 2: 445451.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Schlagintweit, F., Kolodziej, B., and Qorri, A. (2015). Foraminiferan-calcimicrobial benthic communities from Upper Cretaceous shallow-water carbonates of Albania (Kruja Zone). Cretaceous Research, 56: 4363.

    • Search Google Scholar
    • Export Citation
  • Siegl-Farkas, Á. (2018). A Hvar szigetén talált új dinoszaurusz lábnyomos rétegsor palynológiai feltárása (Palynological results from the new dinosaur tracksite locality at Hvar Island, Croatia). Manuscript, p. 4 (in Hungarian).

    • Search Google Scholar
    • Export Citation
  • Tasli, K., Özer, E., and Koç, H. (2006). Benthic foraminiferal assemblages of the Cretaceous platform carbonate succession in the Yavca area (Bolkar Mountains, S Turkey): biostratigraphy and paleoenvironments. Géobios, 39(4): 521533.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Velič, I. (2007). Stratigraphy and paleobiogeography of Mesozoic benthic foraminifera of the Karst Dinarides (SE Europe). Geologia Croatica, 60(1): 1113.

    • Search Google Scholar
    • Export Citation
  • Wagreich, M. and Faupl, P. (1994). Palaeogeography and geodynamic evolution of the Gosau Group of the northern Calcareous Alps (Late Cretaceous, eastern Alps, Austria). Palaeogeography, Palaeoclimatology, Palaeoecology, 110(3–4): 235254.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Zarcone, G., Petti, F.M., Cillari, A., Di Stefano, P., Guzzetta, D., Nicosia, U. (2010). A possible bridge between Adria and Africa: new palaeobiogeographic and stratigraphic constraints on the Mesozoic palaeogeography of the Central Mediterranean area. Earth-Science Reviews, 103(3–4): 154162.

    • Crossref
    • Search Google Scholar
    • Export Citation
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Senior editors

Editor(s)-in-Chief: Attila DEMÉNY

Deputy Editor(s)-in-Chief: Béla RAUCSIK

Co-ordinating Editor(s): Gábor SCHMIEDL

Editorial Board

  • Zsolt BENKÓ (Geochemistry, Ar dating; Institute for Nuclear Research, Debrecen)
  • Szabolcs HARANGI (Petrology, geochemistry, volcanology; Eötvös Loránd University, Budapest)
  • Anette GÖTZ (Sedimentology; Landesamt für Bergbau, Energie und Geologie, Hannover)
  • János HAAS (Regional Geology and Sedimentology; Eötvös Loránd University, Budapest)
  • István Gábor HATVANI (Geomathematics; Institute for Geological and Geochemical Research, Budapest)
  • Henry M. LIEBERMAN (Language Editor; Salt Lake City)
  • János KOVÁCS (Quaternary geology; University of Pécs)
  • Szilvia KÖVÉR (Sedimentology; Eötvös Loránd University, Budapest)
  • Tivadar M. TÓTH (Mineralogy; Petrology    University of Szeged)
  • Stephen J. MOJZSIS (Petrology, geochemistry and planetology; University of Colorado Boulder)
  • Norbert NÉMETH (Structural geology; University of Miskolc)
  • Attila ŐSI (Paleontology; Eötvös Loránd University, Budapest)
  • József PÁLFY (Fossils and Stratigraphic Records; Eötvös Loránd University, Budapest)
  • György POGÁCSÁS (Petroleum Geology; Eötvös Loránd University, Budapest)
  • Krisztina SEBE (Tectonics, sedimentology, geomorphology University of Pécs)
  • Ioan SEGHEDY (Petrology and geochemistry; Institute of Geodynamics, Bucharest)
  • Lóránd SILYE (Paleontology; Babeș-Bolyai University, Cluj-Napoca)
  • Ákos TÖRÖK (Applied and Environmental Earth Sciences; Budapest University of Technology and Economics, Budapest)
  • Norbert ZAJZON (Petrology and geochemistry; University of Miskolc)
  • Ferenc MOLNÁR (ore geology, geochemistry, geochronology, archaeometry; Geological Survey of Finland, Espoo)

Advisory Board

Due to the changes in editorial functions, the Advisory Board has been terminated. The participation of former Advisory Board members is highly appreciated and gratefully thanked.

CENTRAL EUROPEAN GEOLOGY
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Hungarian Academy of Sciences
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E-mail: demeny@geochem.hu

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Central European Geology
Language English
Size Vol 1-63: B5
Vol 64- : A4
Year of
Foundation
2007 (1952)
Volumes
per Year
1
Issues
per Year
2
Founder Magyar Tudományos Akadémia  
Founder's
Address
H-1051 Budapest, Hungary, Széchenyi István tér 9.
Publisher Akadémiai Kiadó
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Address
H-1117 Budapest, Hungary 1516 Budapest, PO Box 245.
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ISSN 1788-2281 (Print)
ISSN 1789-3348 (Online)

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