1 Introduction
The present-day tectonic setting of the Turkey can be depicted as a giant geological puzzle represented by amalgamated continental microplates separated by ophiolite-bearing suture zones, whose ages range from Late Neoproterozoic to Cretaceous (e.g., Göncüoglu et al., 1997 and quoted references). One of the most important, even if still poorly studied, suture zones of northern Turkey is represented by the IntraPontide one, originated from the continental collision between the Sakarya (hereafter SK) and Eurasian İstanbul–Zonguldak (hereafter IZ) microplates. The tectonic units of the IntraPontide Suture (hereafter IPS) zone are thrust over the Taraklı Flysch, i.e. a turbidite succession representing the sedimentary cover of SK Terrane.
Thus, the detailed analysis focused on the Taraklı Flysch may provide useful insights into the reconstruction of the IPS zone.
In this paper, an integrate study of the stratigraphical, paleontological and structural features of the Taraklı Flysch cropping out in the Boyalı area, northern Turkey, is presented and the implications for the tectono-sedimentary evolution of the IPS zone are discussed.
2 Geological setting
In northern Turkey (Fig. 1), the IPS zone (Şengör and Yılmaz, 1981) separates the IZ Terrane, in the north, from the SK Terrane of Gondwana affinity, in the south. Whereas the IZ Terrane is regarded as belonging to Eurasia plate, the SK Terrane is interpreted as representative of the SK microplate, separated from the Eurasia continental margin by the IPS oceanic basin.
A. The major tectonic zones of Turkey separated by sutures (modified from Okay and Tüysüz, 1999). B. Tectonic sketch of the Bayramören–Araç area. 1: Alluvial deposits; 2: Pliocene deposits; 3: Eocene deposits; 4: IZ Terrane; 5: IP Suture Zone, Daday Unit; 6: IP Suture Zone, Devrekani Unit; 7: IP Suture Zone, Aylı Dağ ophiolitic Unit; 8: IP Suture Zone, Arkot Dağ Mèlange; 9: SK Terrane.
The IPS zone is regarded as originated by the Late Cretaceous to Early Tertiary convergence between IZ and SK plates, leading to complete destruction of the oceanic basin. The remnants of this basin are preserved in the IPS zone, where an imbricate stack of oceanic and continental units have been detected along its whole extent.
The IZ Terrane includes a Late Neoproterozoic basement (e.g., Ustaömer and Rogers, 1999) unconformably covered by a continuous, well-developed sedimentary sequence ranging in age from Ordovician to Carboniferous, only mildly deformed during the Variscan orogeny (e.g., Görür et al., 1997). The non-metamorphic Paleozoic sequence of the IZ Terrane is unconformably overlain by Late Permian–Earliest Triassic sedimentary rocks, and their transition to turbidite deposits of Late Triassic age. The Triassic rocks are unconformably overlain by Late Cretaceous–Paleocene turbidite deposits (Akveren Flysch) where Senonian andesitic volcanic rocks have been found (e.g., Dizer and Meriç, 1983). This andesitic magmatism is the witness of a north-dipping subduction of the NeoTethys oceanic lithosphere below the continental crust of IZ Terrane.
The IPS units are thrust over the SK Unit derived from SK Terrane and represented, in the studied geotraverse, by the Karakaya Complex and its sedimentary cover. The Karakaya Complex represents the remnants of a Triassic accretionary wedge (Okay and Göncüoglu, 2004 and quoted references), where metabasites and metaserpentinites are preserved (Sayit and Göncüoglu, 2009). The lower Karakaya Complex was strongly deformed under a Latest Triassic, high-pressure facies metamorphism (Okay et al., 2002), interpreted as the result of the Cimmerian orogenesis. The tectonic structures related to the Cimmerian orogeny are unconformably sealed by the continental- to shallow-marine Early Jurassic clastic rocks, in turn disconformably topped by the Middle Jurassic to Early Cretaceous neritic limestones (Altıner et al., 1991). The neritic limestones are unconformably overlain by the Albian–Cenomanian pelagic limestones showing a transition to turbidite deposits (here referred to as Taraklı Flysch) ranging in age from Late Cretaceous to Paleocene.
In the study area (Fig. 1), along the geotraverse Kurşunlu–Araç, the IPS zone can be defined as an imbricate stack of four types of tectonic units: the ophiolite Aylı Dağ Unit (Göncüoglu et al., 2012), the Arkot Dağ Mélange, and two metamorphic units, referred to as Daday and Devrekani Units. The imbricate stack is probably the result of a multiple thrusting event leading to the present-day juxtaposition of oceanic and continental units. These units are sandwiched between the IZ Terrane at the top and the SK Terrane at the bottom. The relationships between the rock-units of the IPS zone are sealed by sedimentary deposits of the Early Eocene. Strike-slip tectonics related to the still active North-Anatolian Fault Zone (hereafter NAFZ) modified the original relationships among the rock-units of the IPS zone.
3 The Taraklı Flysch in the Boyalı area
The study area corresponds to the east–west-trending strip to the North of Kurşunlu and Ilgaz along the Akçay and Boyalıçay valleys between the Aylı Mountain in the north and Gürgenli and Köklüce mountains in the south (Fig. 2). In the Boyalı area, even if their relationships are reworked by strike-slip faults, the overthrust of the Arkot Dağ Mélange onto the Taraklı Flysch can be still identified in the field. Dykes of andesites cutting the Taraklı Flysch have been found.
A. Geological–structural map of the study area. 1: Alluvial deposits; 2: Pliocene deposits; 3: Middle Eocene deposits; 4: Lower Eocene deposits; 5: Daday Unit; 6: Arkot Dağ Mèlange; 7: basalts; 8: Taraklı Flysch, slide-block in shaly-matrix; 9: Taraklı Flysch, orthoconglomerates; 10: Taraklı Flysch, thin-bedded turbidites; 11: Jurassic–Cretaceous limestones; 12: granites; 13: cataclastic zones; 14: main strike-slip faults; 15: main faults; 16: thrust faults; 17: stratigraphic boundaries; 18: bedding; 19: vertical bedding; 20: AP1 axial plane; 21: vertical AP1 axial plane; 22: AP2 axial plane, 23: A1 fold axes; 24: A2 fold axes with vergence; 25: horizontal A2 fold axes; 26: high-angle strike-slip faults; 27: low-angle thrust faults; 28: location of sampled sites for nannoplankton analyses; 29: trace of the geological cross-section. B. Geological cross-section.
3.1 Stratigraphic features
The stratigraphic features of the Taraklı Flysch have been fully reconstructed in the sections cropping out along the northern side of the Akçay Valley, between the Bahçecik and Boyalı Villages and along the Boyalıçay Valley (Fig. 2). The succession, whose thickness has been estimated as at least 700 m, shows a clear thickening and coarsening-upward evolution that can be divided into five different lithofacies (see log in Fig. 3A for more details), which, from the bottom to the top, are: “thin-bedded turbidites”, “medium-grained arenites”, “conglomerates”, “calcareous coarse-grained turbidites”, and “slide-block in shaly-matrix” lithofacies.
(Color online) Stratigraphy and petrographic features of the Taraklı Flysch. A. Reconstructed stratigraphic log of the Taraklı Flysch. The position of the studied samples are indicated in the left side of the log. Lithofacies legend: 1: slide block in shaly-matrix; 2: calcareous coarse-grained turbidites; 3: conglomerates; 4: medium-grained arenites; 5: thin–bedded turbidites. B. Field occurrence of the Taraklı Flysch in the Boyalı area. 1: TBT lithofacies; 2: uppermost part of the TBT lithofacies, the circle indicates decimetric lenticular beds of coarse-grained arenites sampled for arenites petrography (sample TC 188); 3: dm–thick level of well-rounded to matrix-supported conglomerates, Boyalı village area; 4: huge slide blocks of quartz-arenites (sample TC 37) embedded in a fine-grained matrix shaly matrix (Boyalıçay Valley); 5: slide blocks of crinoidal Devonian–Carboniferous limestones (Boyalıçay Valley); 6: photomicrographs of mixed/hybrid siliciclastic–carbonate petrofacies typical of the Taraklı Flysch arenites. Black arrow indicates an extrabasinal carbonate fragment (oolitic grainstone) while the white arrow indicates a coeval carbonate intrabasinal fragment (micritized bivalve fragment), sample TC201. C. Ternary plots showing framework modes of arenites from Taraklı Flysch plotted on: NCE CI+NCI CE (Zuffa, 1980); Q F L+C (Dickinson, 1985); Lm Lv Ls+c (Ingersoll and Suzcek, 1979).
The lowermost part of the Taraklı Flysch is characterized by 400-m-thick thin-bedded turbidites consisting of thin-to-medium beds (5–50 cm) of medium- to fine-grained arenites and coarse-grained siltites (Fig. 3B1). The medium-to-fine-grained arenites are often characterized by thin traction carpets. These strata are generally well graded only in their uppermost part, where current ripples and sinusoidal lamina can be also present. In the uppermost part of this lithofacies, decimetric lenticular beds of coarse-grained arenites can be recognized (Fig. 3B2).
The medium-grained arenites lithofacies is characterized by an up to 50-m-thick sequence of turbidites represented by 0.5–2.5-m-thick beds of amalgamated medium-to-fine-grained arenites alternating with subordinate thin beds of shales (Fig. 3A). These strata are characterized by a massive structure without sedimentary features as graded bedding and lamina. The bottom surface of these strata is marked by sole marks and by the widespread presence of organic matter (leaves and tree cortex fragments).
A decimeter-thick level of well-rounded clast- to matrix-supported conglomerates (Fig. 3B3) characterize the medium part of the Taraklı Flysch and represent, in this area, a key level to understand the geometry of the main structures. The most striking feature of this lithofacies is the granite-dominated composition of the pebbles. These beds, derived from high-density erosive flows probably connected to a coarse-grained river-delta system, are characterized by frequent basal erosional features.
The calcareous coarse-grained turbidites lithofacies consists of a sequence of layers (not thicker than 25–30 m) ranging from clast-supported orthoconglomerates to coarse arenites mainly derived from debris flows and high-density turbidity currents. The most common facies is represented by prevalent monomict clast-supported conglomerates characterized by poor sorting. The internal organization of these deposits, characterized by unsorted coarse clasts, is scarce. These beds, derived from high-density erosive flows, are characterized by frequent basal erosional features. The erosional ability is suggested by frequent bottom bedset scours, diffuse amalgamated surfaces, and common rip-up mud clasts. These strata are associated with coarse-grained high-density turbidity current deposits. Thick-to-medium beds without internal structures and with poor sorting are the most common facies. A subtle normal grading and water escape features can be recognized in a few beds.
The most prominent feature of these members is the quasi-monomict composition of the debris characterized by extrabasinal carbonatic clasts.
The upper part of the succession (up to 400 m thick) is dominated by huge slide-blocks embedded in a fine-grained matrix (Fig. 3B4). The matrix of this lithofacies is characterized by varicolored mainly shaly to silty deposits. Subordinate decimetric lenticular beds of coarse-grained arenites have been also recognized. The slide-blocks, usually with lenticular shapes, show different sizes (ranging from boulder up to 100-m-thick blocks) and compositions. Even if the primary relationships between the slide blocks and the surrounding matrix are always tectonized, their emplacement due to submarine landslides for these blocks is suggested by synsedimentary deformation structures recognized in the sediments around the blocks and by slide block-derived monomict pebbly-mudstones and pebbly-sandstones that are present around several slide-blocks. The slide-blocks are mainly made up of granitoids, orthogneisses, metagabbros/amphibolites, Jurassic carbonatic turbidites next to Ordovician quartz-arenites, black shales, crinoidal (Fig. 3B5) and brachiopod-bearing Devonian–Carboniferous limestones and probably Triassic red quartz-arenites (Fig. 3B4) as typical representatives of the IZ Terrane. Few blocks of serpentinites, basalts and cherts have been also recognized in the uppermost part of the sequence.
3.2 Arenite petrography
Thirty-five thin sections from the Taraklı Flysch (30 arenites and 5 rudites) were analyzed by means of a polarizing microscope. A modal analysis was performed on 19 selected medium- to coarse-grained arenites. Point counting (500 points) of arenites was performed using the Gazzi–Dickinson technique (Zuffa, 1987 and quoted references) to minimize the dependence of arenite composition on grain size. The point counting results are plotted on the triangular diagrams of Fig. 3C.
No large differences can be recognized in the framework composition of arenites from the Taraklı Flysch. They range from quartz-poor mixed arenites up to calclithites. The total framework is characterized by a mixed siliciclastic–carbonate framework composition (Fig. 3C1) where the important carbonatic extrabasinal contribution (CE, up to the 50%) led us to classify these rocks as mixed arenites (Zuffa, 1980).
The extrabasinal siliciclastic framework is characterized by a common presence of mono- and polycrystalline quartz (12÷41% of the total framework) and feldspar (6÷31%). Felsic intrusive coarse-grained rock fragments, such as granitoids, are common (0÷3% of the total framework), while low grade metamorphic rock fragments are not common and include coarse-grained gneisses, metaquartzites, fine-grained schists, and mica-schists (1÷8% of the total framework).
A striking feature of the Taraklı Flysch arenites is the widespread presence of carbonate rock fragments (Fig. 3C1). In all the studied samples, both intra- (1÷30% of the total framework) and extrabasinal (22÷48%) carbonate fragments have been recognized. Carbonate extrabasinal fragments are represented by carbonate platform derived rocks, mainly mudstones, wackestones, and grainstones of Jurassic–Early Cretaceous age (Fig. 3B6). The allochems in the grainstone fragments are peloids, ooids, minor benthic foraminifera, and undeterminable macrofossil fragments. The intrabasinal carbonate fragments are instead represented by mudstone, showing deformed and squeezed soft margins and by isolated bioclasts, mainly benthic foraminifera and macrofossils (Fig. 3B6). The presence of intrabasinal carbonate fragments became relevant in the calcareous coarse-grained turbidites. The composition in arenites of this lithofacies indicates a strong supply from a coeval carbonate platform (up to 65% of the total framework, Fig. 3C1).
The lacking of ophiolite-derived rock fragments represents one of the more striking features of Taraklı Flysch arenites. Therefore, the source areas of these sediments were mainly characterized by a continental basement made up of granitoids, metamorphic rocks, felsic volcanic rocks and the relative sedimentary covers, represented by extrabasinal non-coeval carbonate rock successions.
This source area can be related to a typical continental margin. The lithic fragments in the arenites debris and the composition of the main slide-blocks in the uppermost part of the succession seem to indicate the IZ Terrane as the most probable source area of the Taraklı Flysch.
3.3 Nannofossil analyses
Fifty-five samples were analyzed for the calcareous nannofossil study of the Taraklı Flysch. The analyses were performed on smear slides, prepared from unprocessed material, using a light microscope at ×1250 magnification. The taxa have been recognized following the taxonomy proposed by Perch-Nielsen (1985a, b) and Bown (1999). Several samples (19) are barren, while the investigated assemblages suffered overgrowth and dissolution. However, some information about the age of the identified lithofacies has been obtained.
In the lowermost thin-bedded turbidites lithofacies, a sample with a monogeneric assemblage (ABT04), composed of common Micula staurophora, Micula concava, and Micula sp., has been collected. This sample can be attributed to the Maastrichtian on the basis of paleoclimatic consideration. The genus Micula is considered a cold water indicator and the genus Watznaueria is related to warm water conditions. Bojar Melinte et al. (2009) record a Watznaueria/Micula crossover in Early Maastrichtian times as a result of colder water conditions. The monospecific assemblage of Micula spp. found in our sample could be related to this cold event and indirectly dated to the Early Maastrichtian. Reworking is evidenced by the sample ABT02, where the finding of Ephrolithus floralis indicates the Late Aptian–Late Cenomanian time interval. On the contrary, samples TC21 and TC22 from marls of the shaly-matrix lithofacies around the slide-blocks have been dated to the Middle Paleocene (Selandian zone NP5 of Martini, 1971) on the basis of the occurrence of Heliolithus cantabriae, Fasciculithus ulii, Fasciculithus tympaniformis, and Sphenolithus anarrhopus. The characteristics of this lithofacies resulted in a strong reworking of the nannofossil assemblages. For instance, the sample with Polycostella beckmannii and Diazomatolithus lehmanii (ABT22) can be attributed to the Polycostella beckmannii Subzone (NJ20B) of Bralower et al. (1989) attributable to the Middle Tithonian, and samples bearing Nannoconus sp., Hexalithus noeliae, H. chiastia, P. beckmannii and D. lehmanii (TC196, TC197, TC198) have been dated to the NJK Zone (Jurassic–Cretaceous boundary) of Bralower et al. (1989).
In summary, the nannofossil analyses indicate an Early Maastrichtian age for the lowermost level of the studied succession, whereas a Middle Paleocene age can be proposed for its top, i.e. the slide-block in shaly-matrix lithofacies.
3.4 Deformation history
The Taraklı Flysch is characterized by a complex deformation pattern, even if the whole succession is non-metamorphic. This deformation pattern is the result of two main deformation phases, referred to as D1 and D2 phases, whose structures are well identifiable in the field.
The structures of the D1 phase are represented by F1 folds that commonly display a geometry ranging from isoclinal to subisoclinal. The F1 fold axes show a NW–SE to NNW–SSE trend with steep plunges (Fig. 4A).
(Color online) Examples of deformation structures in the Taraklı Flysch. A. Interference between F1 and F2 folding; AP1: F1 axial plane; AP2: F2 axial plane. B. Folds associated with strike-slip faults; S1: traces of bedding. C. Asymmetric F2 folds associated with low angle thrust faults. D. Stereograms of structural elements; equal area projection, lower hemisphere.
At the outcrop scale, the F1 folds are overprinted by a centimeter- to tens of meter-scale structures (Fig. 4A) represented by a complex association of faults, thrusts and folds, all attributed to the D2 phase (Fig. 4B and C).
The faults occur as high-angle brittle shear zones grouped into three main systems with east-west, NNW–SSE and NNE–SSW strike, respectively attributed to the S1, S2, and S3 systems (Fig. 4D). The faults of S1 and S3 systems show predominantly dextral strike-slip movements, but slip sense indicators of normal movements are also observed. On the contrary, the faults of S2 system are mainly represented by sinistral strike-slip faults. The thrusts are represented by flat shear zones with medium to low dip and NNW–SSE and ENE–WSW strike (Fig. 4C). The thrusts are characterized by both northward and southwestward senses of shear. In the field, examples of structures where the thrusts are rooted into the high angle strike-slip faults are common.
The F2 folds can be instead grouped into two main groups based on their geometry and/or relationships with faults and thrusts. The first type F2a corresponds to upright folds directly associated with steeply dipping faults (Fig. 4B). The strike of axial planes are roughly parallel to that of the related faults. These upright folds show hinge zone that may be partially cut out by the faults, whereas the vertical fold limbs are cut by an array of faults parallel to the bedding planes or cross-cutting at low angles to produce imbricate zones. The second type F2b includes the folds associated with the thrusts. The F2b folds display sub-horizontal axes and axial planes, whose strikes is roughly parallel to the mean directions of the thrusts (Fig. 4C).
The close association among folds, faults and thrusts as well as their cross-cutting relationships clearly indicates their belonging to flower structures, as suggested by the close parallelism between the strike of PA2 axial planes with those of thrusts and faults. All these structures can be regarded as related to the NAFZ system.
The structural setting of the Taraklı Flysch identified in the field can be also recognized in a north-south trending geological cross-section of the Boyalı area reported in Fig. 2. In this cross-section, asymmetric flower structures can be identified, even if the distribution of these structures is not homogeneous. Along the cross-section, the southern contact of the Taraklı Flysch with the Eocene deposits corresponds to a dextral high-angle fault whereas, at the northern edge of the cross-section, the Taraklı Flysch is separated from the IPS units by a low-angle thrust (Fig. 2).
4 Discussion
The succession of the Taraklı Flysch cropping out in the Boyalı area shows a clear thickening and coarsening-upward evolution from thin-bedded turbidites to medium-grained arenites and calcareous coarse-grained turbidite lithofacies. This succession ends with a level of slide-block in shaly-matrix lithofacies, which can be considered as the fast catastrophic event that predates the closure of the basin and its deformation. This evolution is typical of syntectonic sedimentation in a foredeep environment.
The nannofossil analyses indicate an Early Maastrichtian age for the lowermost level of the studied succession, whereas a Middle Paleocene age can be proposed for its top, i.e. the slide-block in shaly-matrix lithofacies.
The arenite composition indicates that the foredeep basin is filled mainly by sediments derived from a source area, related to the IZ Terrane, according to lithic fragments in the arenites debris and the composition of the main slide-blocks in the uppermost part of the succession. This conclusion is confirmed by the finding of blocks of ortho- and paragneisses and amphibolites resembling the pre-Cambrian basement of the IZ Terrane together with the blocks of Ordovician quartz-arenites, Silurian black shales and Devonian–Carboniferous limestones of Upper Paleozoic age, which are only observed in the IZ Terrane in NW Anatolia (Yanev et al., 2006). The IZ Terrane was probably thrust over the IPS ophiolites and the mélange, that only rarely provided debris, according to the occurrence of scattered block of serpentinites, basalts and cherts in the youngest lithofacies.
The D1 deformation can be regarded as the result of the emplacement over the Taraklı Flysch of the IZ Terrane with the IPS ophiolites and mélange at its base. The age of the D1 phase can be thus bracketed between the Middle Paleocene, i.e. the age of the youngest deposits involved in the deformation and the Early Eocene (NP 14, our unpublished data), i.e. the age of the oldest deposits unconformably overlying the Taraklı Flysch as well as the overlying tectonic units.
The structures of the D2 phase can be instead regarded as related to the flower structures developed during the transpressional tectonics connected with the NAFZ system. Therefore, if the inception of the NAFZ activity has been generally regarded as Miocene (e.g. Bozkurt, 2001), a same age can be assigned to the D2 structures in the Taraklı Flysch.
5 Conclusions
The Taraklı Flysch in the Boyalı area can be interpreted as an Early Maastrichtian-Paleocene turbidite and mass-gravity deposits sedimented in a foredeep basin. The substratum of this basin was represented by the SK Terrane whereas its northern edge was constituted by a mobile belt, that, according to arenite and slide blocks composition, was represented by the IZ Terrane thrust over the IPS units. The latter provide scattered slide blocks of ophiolites found only in the uppermost levels of the Taraklı Flysch. This basin was developed during the final stage of the closure of the IPS zone as result of the progressive convergence between SK and Eurasia plates. After the Middle Paleocene, but before the Early Eocene, the D1 deformation phase can be regarded as the signal of final emplacement of the IZ Terrane and the IPS units zones over the foredeep basin where the Taraklı Flysch sedimented. The structure originated during this event are sealed by Early Eocene deposits and strongly reworked by the NAFZ tectonics starting from the Miocene time when the Taraklı Flysch was affected by the D2 phase deformation.
Acknowledgements
The research has been funded by the Darius Project (resp. M. Marroni). This research benefits also by grants from PRIN 2008 project (resp. M. Marroni) and from IGG–CNR. Kaan Sayit, Ali Uygar Karabeyoglu and Remziye Ezgi Çakıroglu are thanked for their assistance in the field.