Quaternary International xxx (xxxx) xxx–xxx Contents lists available at ScienceDirect Quaternary International journal homepage: www.elsevier.com/locate/quaint Middle Paleolithic variability in Central Asia: Lithic assemblage of Sel’Ungur cave Andrey Krivoshapkina,b,∗, Bence Violac, Temirlan Chargynovd, Maciej T. Krajcarze, Magdalena Krajcarzf, Stanisław Fedorowiczg, Svetlana Shnaidera,h, Kseniya Kolobovaa,h,∗∗ a Institute of Archaeology and Ethnography, Siberian Branch of the Russian Academy of Sciences, Ac. Lavrentieva 17, 630090, Novosibirsk, Russia Novosibirsk State University, Pirogova 1, 630090, Novosibirsk, Russia c Department of Anthropology, University of Toronto, 19 Russell St., Toronto, ON M5S 2S2, Canada d Kyrgyz National University, Frunze 547, 720033, Bishkek, Kyrgyzstan e Institute of Geological Sciences, Polish Academy of Sciences, Twarda 51/55, 00-818, Warszawa, Poland f Institute of Archaeology, Nicolaus Copernicus University, Szosa Bydgoska 44/48, 87-100, Toruń, Poland g Institute of Geography, Department of Geomorphology and Quaternary Geology, University of Gdańsk, Jana Bażyńskiego 4, 80-952, Gdańsk, Poland h Altai State University, Lenina 61, 656049, Barnaul, Russia b ARTICLE INFO Keywords: Sel’Ungur cave Archaeology Lower paleolithic Middle paleolithic Variability Reassessment Lithic assemblage Techno-typological analysis Since the beginning of 21st century, a new stage began in investigations of the Central Asian Palaeolithic. The main concern is to re-study the key regional sites, applying modern excavation techniques and up-to-date laboratory methods (including chronometric dating) in order to clarify the rationale and chronology of the local cultural sequences. This research allowed some crucial corrections about the chronological and cultural interpretations of the lithic industries in western Central Asia. This paper presents the first results obtained during our reexcavation of Sel’Ungur cave – usually assumed to be one of the earliest Paleolithic sites in Central Asia, described in the late 1980s as belonging to the early Acheulian technocomplex. Sel’Ungur cave is among the most important pre-Upper Palaeolithic site for our understanding of the Pleistocene inhabitants of Central Asia, as did not only yield rich lithic collections found stratified context but also numerous fossil faunal and even some hominin remains. Re-started at 2014, the new excavations at the site have provided enough evidence to refuse an Acheulian interpretation of site's assemblages. Based on detailed technological and typological analyses of the new lithic collection we argue that Sel’Ungurian complex fits better into the early stage of the regional Middle Paleolithic cultural variability. The previously available U-series date of around 126 ka (albeit without a reliable stratigraphic and spatial context), the new TL date 112 ± 19 ka establishing the lower limit, paleontological analyses of newly obtained material as well as the re-examination of the available information on macro- and microfaunal remains excavated in the earlier excavations, as well as the re-study of the anthropological finds support this assessment. 1. Introduction Recently, the issue of the initial peopling of Central Asia arose again, as new data became available on the chronology and material culture of Paleolithic sites presumed to represent the Lower Paleolithic. The key sites which are thought to evidence the initial peopling of western Central Asia during the Lower Paleolithic were: pebble-tool industries from loess sites situated in Afghan-Tajik Depression (Tajikistan); the lower layers of Kulbulak (Uzbekistan); and the assemblage from Sel’Ungur cave (Kyrgyzstan) (Islamov and Krakhmal, 1995; Kasymov and Grechkina, 1994; Davis and Ranov, 1999; Vishnyatsky, 1999). The earliest archaeological localities in Central Asia are the Lower Paleolithic sites in the Tajik Depression, an intermountain basin in which up to 200 m thick loess cover was deposited in the course of the Pleistocene. The Kul'dara cultural unit was the first to appear in the ∗ Corresponding author. Institute of Archaeology and Ethnography, Siberian Branch of the Russian Academy of Sciences, Ac. Lavrentieva 17, 630090, Novosibirsk, Russia. ∗∗ Corresponding author. Institute of Archaeology and Ethnography, Siberian Branch, Russian Academy of Sciences, Lavrentieva Ave., 17, Novosibirsk, 630090, Russia. E-mail addresses: krivoshapkin@mail.ru (A. Krivoshapkin), kolobovak@yandex.ru (K. Kolobova). https://doi.org/10.1016/j.quaint.2018.09.051 Received 19 February 2018; Received in revised form 8 August 2018; Accepted 30 September 2018 1040-6182/ © 2018 Elsevier Ltd and INQUA. All rights reserved. Please cite this article as: Krivoshapkin, A., Quaternary International, https://doi.org/10.1016/j.quaint.2018.09.051 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Tajik Depression, with artifacts at Kul'dara deriving from pedocomplexes which predate the Brunhes/Matuyama boundary, and are thus earlier than 780 ka (Ranov et al., 1995; Davis and Ranov, 1999). Similar, somewhat later industries were excavated at Lakhuti and Karatau. These sites were originally dated to 400-200 ka (Ranov and Davis, 1979), but more recent studies indicate an age closer to 400 to 600 ka for some of the sites (Shackleton et al., 1995). The archaeological complexes from the lowermost part of the Kulbulak sequence (lower 22 layers) have been assigned to the Acheulean based mostly on the results of paleomagnetic studies carried out by H. Toichiev. It was claimed that Brunhes-Matuyama boundary was identified in the lowest section of the site (Kasymov and Toichiev, 1981). The re-examination of Kulbulak in the last decade led us to refute both chronological and cultural interpretations accepted before (Kolobova et al., 2018a). The new studies found no Acheulian features of the assemblage and we interpreted the lower cultural layers of Kulbulak as belonging to a regional Middle Paleolithic blade assemblage, the Obi-Rakhmatian. The last significant site for the Central Asian Lower Paleolithic is Sel’Ungur cave in the Fergana valley, of special importance because it is the only one of these sites that is stratified. Excavations in the 1980s by Utkur Islamov revealed a rich lithic assemblage associated with animal and hominin fossils. The excavators described the lithic assemblage as early Acheulian but also compared it to late Oldowan complexes (Islamov, 1990; Islamov et al., 1988; Islamov and Krakhmal, 1995). Currently it is the one of the most important sites in Central Asia the revision of which can provide answers to challenging questions regarding the earliest stage of peopling and first inhabitants in the region. 100 m long) faces south-east and is at an altitude of about 1900 m above sea level. In 1956, 1964 A. Okladnikov and colleagues dug several test pits in the cave (Zones 1–3 in Fig. 2) and found both faunal and lithic remains (Viola and Krivoshapkin, 2014). In 1980 the site was excavated under the direction of U. Islamov, who worked both inside and outside the cave (Zones 4–7 in Fig. 2). Further excavations by Islamov and Krakhmal were undertaken in 1988–1990 (Zone 9 in Fig. 2. Zones 8 and 10 are not documented in the plans published by Islamov & Krakhmal). Islamov and Krakhmal, described the Pleistocene strata as consisting of a series of loam and silt layers up to 8 m thick. The number of in situ cultural horizons ranges from 2 to 13, depending on excavation area location. All horizons were grouped into five major units which Islamov called ‘cultural layers’, each separated by 40–100 cm thick sterile horizons. At Sel’Ungur cave total of 1500 lithic artifacts have been found during field seasons from 1980 to 1988, all defined as belonging to the Lower Paleolithic (Islamov and Krakhmal, 1995). The chronology of the Sel’Ungur deposits is unclear. U. Godin (in Islamov and Krakhmal, 1995) interpreted the deposits in the cave as part of the Lower Pleistocene Sokh series; an unpublished Ar/Ar date of 1.4 MYA supposedly supports this estimate (Islamov, pers. comm., 2004). According to Islamov and colleagues (Islamov et al., 1988a,b; Velichko et al., 1990), the microfaunal evidence excludes a Late or Middle Pleistocene age. There are several arguments though that a Lower Pleistocene chronostratigraphy for Sel’Ungur deposits is unlikely: a breccia or speleothem (described as “travertine”) associated with the uppermost cultural horizon gave a U/Th date of 126+-5 ka (Vishnyatsky, 1999); the large mammal fauna shows elements that are more characteristic of the Middle or Late Pleistocene; new studies of the microfauna found no Early Pleistocene elements (Markova, 2013). The lithic assemblage is dominated by short and massive flakes and contains choppers, simple side-scrapers, notches and denticulate tools. Islamov et al. (1988) initially interpreted the assemblage as Acheulean, 2. History of research Sel’Ungur cave is located in the Sokh river valley of the Fergana depression (Kyrgyzstan), near the present day town of Khaidarkan (39° 57′ 12″ N, 71° 19′ 31″ E) (Fig. 1). The large cave (34 m wide, 25 m high, Fig. 1. Map showing the location of Sel’Ungur & other Middle Paleolithic sites. 2 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Fig. 2. Plan of Sel’Ungur cave showing the location of excavation areas. 3. Materials and methods arguing that the presence of a cleaver and a handaxe indicated affinities with the South Asian Acheulean. Later, Islamov started to refer Sel’Ungur complex even to Oldowan industries with similarities to the lower Oldowan layers of Ubeidiya (Islamov and Krakhmal, 1995). Vishnyatsky (1999) assigned the Sel’Ungur assemblage to the Lower Paleolithic pebble industries of Central Asia while Davis and Ranov (1999) compared it to the pebble and flake industries also known from Central Asian loess sites. The site delivered over 4000 faunal remains obtained in a course of 1980s excavations. Species identification was published as a list, including Ovis ammon, Capra sibirica, Cervus cf. elaphus bactrianus, Equus stenonis, Bos primigenius, “Dicerorhinus” kirchbergensis, Ursus spelaeus, Crocuta crocuta and Panthera spelaea (Islamov et al., 1988a,b; Velichko et al., 1990). The human remains described consisted of six teeth and a juvenile humeral shaft fragment (mistakenly reported as scapula by Davis and Ranov, 1999), all deriving from cultural horizon 3 in excavation Zone 5. Islamov et al. (1988a,b) and Zubov (2009) interpreted the teeth as lower premolars and upper incisors of a local variant of Homo erectus (”Ferganthropus” – name that was proposed by U. Islamov), but several morphological details contradict this interpretation, and indicate that at least five of the teeth do not represent hominins (Viola, 2009; Viola and Krivoshapkin, 2014; contra Zubov, 2009). The juvenile humerus on the other hand is clearly hominin. It preserves most of the shaft from the distal epiphyseal line to the proximal part of the deltoid tuberosity, and seems very long and gracile, though with very thick cortical bone. The distal half of the shaft is triangular in cross section and flattened mediolaterally, reminiscent of the morphology seen in Neanderthals, but also other archaic hominins (Viola, pers. obs.). A fragmentary hominin occipital, and several additional hominin teeth were found in cultural horizon 2 of Zone 8 in 1988 (Islamov and Krakhmal, 1995, p.68.), but sadly these specimens seem to have been lost in the early 1990s. Since the first publications describing the chronology and cultural attribution of Sel’Ungur, Islamov's main conclusions have been criticized (Vishniatsky, 1996; Ranov and Dodonov, 1994; Dodonov, 2002). 3.1. Archaeological excavation As the previous excavations at Sel’Ungur were not up to modern standards, we started a re-excavation of the site in 2014 aimed at a recovery of a well documented and stratigraphically constrained lithic and faunal assemblage, as well as samples for dating, and other geoarchaeological studies. The excavations followed established standards of Palaeolithic excavations, piece plotting all objects and recording their detailed stratigraphic position. We excavated following stratigraphic units, lithic and faunal remains > 2 cm were piece plotted individually, while fragments smaller than this were collected in bulk for each decapage and quarter m2. The documentation process was digital, based on the protocols Viola co-developed with P. Nigst for Willendorf and Grub-Kranawetberg (see, Nigst et al., 2014; SI 2.1). As the water available near the cave is contaminated with heavy metals (Hg, As, Bi, Sb) from mining residues (UNEP/UNITAR, 2009), sediments excavated from the cave were dry-sieved using a 2 mm sieve. Keeping in mind a formidable size of the cave and a notable thickness of its deposits several geophysical methods have been applied to choose the most potentially informative areas to excavate. The application of electromotography and magnetometry methods helped to preliminary evaluate a thickness of deposits at selected excavation area – Zone 8 (Tsibizov et al., 2017). 3.2. Geological investigation The lithostratigraphical description of sediments was based on texture (grain size of matrix, presence, size and orientation of limestone clasts) and sedimentary structures (presence, angle and dip of bedding or lamination). In addition to this, the occurrence of characteristic nongeological material was noted, such as bones, coprolites and lithic assemblages. 3 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Petrographic identification of raw material was used for pieces of tools and cores larger than 2 cm. The non-destructive method using microscopy of lithic surface in water immersion was applied (Přichystal, 2013). The same method was used for alluvial gravel that served as a source of Paleolithic raw material. The potential occurrence of particular lithotypes in alluvia was also based on geological maps (Igemberdiyev and Osmonbetov, 1980). removed from deeper parts of the cave and deposited by mud flows or debris flows. The relatively small thickness of the colluvial layers, the low angle of inclination and the presence of intra-layer refittings indicate a short geological transport, presumably limited to several meters. The TL age of layer 7 has been estimated to 112 ± 19 ka BP (Table 1). The uncertainty of the calculation of equivalent dose is relatively high. It results from a relatively considerable variation in the energy stored in the studied grains, what increased the uncertainty of dating result up to 17%. Nevertheless, the achieved date strongly supports the Late Pleistocene chronology of all sediments bearing the Middle Paleolithic material, which are situated above the dated strata. 3.3. Paleontological data Remains of vertebrates were collected during excavation directly from the sediment and after sieving with use of 2 mm mesh. Possible specimens were identified to skeletal element and taxon. The bones excavated during seasons 2014 and 2015 were identified using the comparative collection of mammal bones of the Institute of Archaeology and Ethnography, Siberian Branch RAS (Novosibirsk, Russia). Remains collected during seasons 2016 and 2017 are stored in State History Museum (Bishkek, Kyrgyzstan) and it was not yet possible to identify these using a comparative collection. The whole assemblage was a subject of taphonomic examination and studied for natural and anthropic modifications. 4.2. Faunal remains The identification and taphonomical analysis of the large mammals remains collected from the Zone 8 during excavations 2015–2017 is currently underway and at this moment only preliminary data can be presented. Field observations show that the assemblage is dominated by highly fragmented, unidentifiable remains. Until 2017, a total of 6112 bones and teeth was collected. Complete bones and teeth are rare in the assemblage, and comprise 1% of the NISP. Herbivores are represented mostly by argali (Ovis ammon) and Siberian ibex (Capra sibirica). Three specimens with deciduous allowed the age estimation based on teeth eruption, which is less than 24 months (Vigal and Machordom, 1985). Single remains were attributed to steppe bison (Bison priscus), undetermined equids and cervids. Rhinoceratid remains were found in 2017 in Layer 6. Carnivore remains are rare, the identified remains derive from large cats (Panthera cf. spelaea) and small canids. The preservation of all paleontological material is very good. The bone surfaces correspond to weathering stage 0/1 of Behrensmeyer (1978), with no cracking or flaking, the edges of bones are sharp with no traces of transportation or abrasion. The main factor responsible for fragmentation of bones is still not clear. Though the spiral fractures and oblique fractured angles of long bone shafts are common, no direct traces of human activity, such as cut marks or percussion marks, were found. The traces of carnivore modifications are also rare, only twelve examples show bite marks and further seven were digested. 3.4. Lithic analysis We analyzed all lithic assemblages found during the 2014–2016 seasons from the new excavations in Zone 8 of Sel’Ungur Cave. We followed attribute analysis aimed at the reconstruction of raw material exploitation in the pattern that was proposed by K. Monigal and V. Chabay (Monigal, 2002; Chabai, 2006). Reconstruction of raw material exploitation provides the identification of many technologically significant attributes. 3.5. Chronometric dating A sediment sample of ca. 0.5 kg was taken from fresh wall of archaeological trench, from layer 7 in Zone 8, with restrictions applying to TL sampling (Nelson et al., 2015, i.e., sampling under dark conditions, the external part of sediment removed and sample secured in a nontransparent container). The TL dating was performed in the Institute of Geography, University of Gdańsk (Poland). The concentrations of radium, thorium and potassium isotopes were determined by gamma spectrometry. In calculating the annual dose (dr), the sediment moisture at 20% as well as cosmic ray corrections were taken into account. To determine the equivalent dose (de) the polymineral fraction of 63–80 μm was separated on the mesh and later analyzed. The multiple aliquot method was used using irradiation with the doses of 100, 200, 300, 400 and 500 Gy. The TL age is the quotient of the equivalent dose and the annual dose. The detailed description of the method used is included in the paper by Fedorowicz (2006). 4.3. Archaeological assemblages Between 2014 and 2017, we excavated 2.5 m2 in the entrance area of the cave (Zone 8 of Islamov), with layers 4.4–6.2 containing cultural horizons. According to the results of preliminary petrographic analysis, approximately 20 types of raw material have been used to produce Sel’Ungur assemblage; among these a mudstone of relatively good quality and a radiolarite of good quality obtained from river beds are the most numerous types. The assemblage includes also porphyritic and aphanitic effusives, sandstones, silificied carbonate rocks, nodular cherts, jasperoids and quartz. Raw material of poor quality, such as tectonically brecciated chert and shale, can be found in close proximity of the cave and even inside the cave, but the raw material of good quality has been transported from some distance. Pebbles of mudstone and porphyry were accessible from alluvial deposits in the direct proximity of the cave (Fig. 4). Radiolarites and jasperoids are absent in the riverine sediments near the cave, but could be found approximately 5 km away. The total number of the lithic artifacts excavated in 2014–2016 is 2505; nearly half of them are debris and chips (Table 2). Seven lithic assemblages (sets of artifacts found inside one sedimentary stratum) were analyzed. Based on our interpretation of site formation processes artefacts included into layers 5.1 and 5.2 show more or less “in situ” context while artifacts presented above are the result of their re-deposition from the same “cultural layer” existed in the back of the cave due to colluvial processes. That is why 4. Results 4.1. Stratigraphy and chronology The two areas of excavation, Zone 5 and Zone 8, consist of different sedimentary sequences, therefore we cannot correlate them lithostratigraphically at the moment. In Zone 5, the Pleistocene sequence exhibits little lithological variability. The subdivision into layers is possible due to slight differences in color, but the grain size distribution of both loamy matrix and limestone clasts does not change from the bottom to the top. Sediments are inclined towards the entrance and contain numerous fine clay clasts and sparse limestone clasts. These characteristics indicate a colluvial origin for the sediments, connected to transport by water from the deeper parts of cave. In Zone 8, the Pleistocene sequence comprises several series of different texture and origin (Fig. 3). Paleolithic artifacts occur in colluvial sediments, 4 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Fig. 3. Litho-stratigraphical profile of the sediments from Zone 8, Sel’Ungur Cave. Arrows mark the strata with Paleolithic artifacts. archaeological remains found in upper layers cannot be described in terms of “archaeological occupations” and, according to our opinion, could be included into one unit. In general, the structure of the whole complex is typical for a workshop because to the presence of cores, bifacial pre-forms, raw material chunks, various core preparation blanks, primary flakes and bifacial thinning flakes. The relatively high number of tools, relatively low number of chips and high cores-to-tools ratio could be indicative of the import of tools into the site. The primary knapping process is represented by pre-cores, core preparation blanks, cores, flakes and sporadic blades and bladelets. Pre5 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Table 1 Results of TL dating of the sediment sample from Sel’Ungur Cave, layer 7. lab. No. Radionuclide concentration −1 [Bq kg 226 UG-7091 ] 232 Ra 20.6 ± 2.5 4 Th 41.2 ± 4.0 K 662 ± 60 Dose rate Equivalent dose TL age dr de [ka] [Gy/ka] [Gy] 3.67 ± 0.36 411.0 ± 46.0 112 ± 19 Fig. 4. Accessibility of the main types of raw material in alluvial gravels of the northern part of Sokh-Obishir water drainage basin: a – porphyries, b – radiolarites and jasperoids, c – mudstones. The watershed of the Sokh-Obishir basin is marked with a dashed line. Table 2 Breakdown of the lithic assemblage from Sel’Ungur cave. layer 6.2 layer 6.1 layer 5.2 layer 5.1 layer 4.7 layer 4.6 layer 4.4 TOTAL: N % N % N % N % N % N % N % N % N % Pre-cores Cores Pre-formes Tools* Flakes** Blades** Bladelets** Chips*** Chunks Unidentifiable debitage – 2 – – 22 – – 21 10 – – 3,64 – – 40,00 – – 38,18 18,18 – 1 – – 1 31 – – 13 9 – 1,82 – – 1,82 56,36 – – 23,64 16,36 – – 3 – 24 261 2 – 310 61 3 – 0,45 – 3,61 39,31 0,30 – 46,69 9,19 0,45 2 1 5 114 467 8 5 617 239 9 0,14 0,07 0,34 7,77 31,83 0,55 0,34 42,06 16,29 0,61 1 1 – 7 47 – – 45 18 1 0,83 0,83 – 5,83 39,17 – – 37,50 15,00 0,83 – 1 – 7 51 – – 28 17 – – 0,96 – 6,73 49,04 – – 26,92 16,35 – – – – 7 24 – – 6 3 – – – – 17,50 60,00 – – 15,00 7,50 – 4 8 5 160 903 10 5 1040 357 13 0,16 0,32 0,20 6,39 36,04 0,40 0,21 41,51 14,25 0,52 4 8 5 159 903 10 5 – – – 0,37 0,73 0,46 14,53 82,54 0,91 0,46 – – – TOTAL 55 100,00 55,00 100,00 664 99,55 1467 100,00 120 100,00 104 100,00 40 100,00 2505 100,00 1094 100,00 *Tools - only the retouched tools have been included. **To define blank's parameters and definition we follow after Debenath and Dibble, 1994. ***Chips - flakes which do not exceed 20 mm in maximal dimension. 6 Total, esse Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Fig. 5. Cores from Sel’Ungur cave assemblages. 1, 3, 4, 7 - unidirectional/bidirectional cores; 2, 5 – radial cores; 6 – orthogonal core. Table 3 Breakdown of the cores from Sel’Ungur cave. CORES layer 6.2 layer 5.2 layer 5.1 layer 4.7 layer 4.6 Bidirectional, rectangular, naturally convex back Bidirectional, ovoid, naturally convex back Unidirectional,rectangular, naturally convex back Unidirectional, ovoid, flattened back Orthogonal, ovoid, flattened back Orthogonal, rectangular, naturally convex back Radial, rectangular, naturally convex back 1 – 1 – – – – 1 – – 1 1 – – – – – – – – 1 – – – – – 1 – – – 1 – – – – TOTAL: 2 3 1 1 1 7 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Table 4 Sel’Ungur cave: composition of blank assemblage. layer 6.2 layer 6.1 layer 5.2 layer 5.1 layer 4.7 layer 4.6 layer 4.4 TOTAL: Total, esse N % N % N % N % N % N % N % N % N % Flakes Flakes, cortical débordant Flakes, lateral débordant Flakes, crested débordant Flakes, overpassed Flakes, radial core débordant Flakes, technical Flakes, bifacial thinning Flakes, primary Flakes, natural Blades Bladelets Unidentifiable debitage 9 0 2 – – – – – 2 – – – – 69,23 0,00 15,38 – – – – – 15,38 – – – – 14 0 2 – – – – – – – – – – 87,50 0,00 12,50 – – – – – – – – – – 95 8 12 – – 3 4 3 8 0 2 0 3 68,84 5,80 8,70 – – 2,17 2,90 2,17 5,80 0,00 1,45 0,00 2,17 310 7 22 4 2 15 8 4 24 1 6 5 9 74,34 1,68 5,28 0,96 0,48 3,60 1,92 0,96 5,76 0,24 1,44 1,20 2,16 27 0 1 1 – – – – 1 – – – 1 87,10 0,00 3,23 3,23 – – – – 3,23 – – – 3,23 32 1 1 – – 1 – 1 1 – – – – 86,49 2,70 2,70 – – 2,70 – 2,70 2,70 – – – – 15 0 2 – – – – – – – – – – 88,24 0,00 11,76 – – – – – – – – – – 502 16 42 5 2 19 12 8 36 1 8 5 13 75,15 2,40 6,29 0,75 0,30 2,84 1,80 1,20 5,39 0,15 1,20 0,75 1,95 502 16 42 5 2 19 12 8 36 1 7 5 – 76,64 2,44 6,41 0,76 0,31 2,90 1,83 1,22 5,50 0,15 1,07 0,76 – TOTAL: 13 668 100,15 655 100,00 16 138 417 31 37 17 Fig. 6. Core preparation blanks from Sel’Ungur cave assemblages. 1–3, 7 - bifacial thinning flakes; 4, 6, 8, 10, 11 - radial débordant (core-edge) flakes; 9 - technical flake. 8 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. that part of the decortication activity took place outside the cave (Tables 4 and 5). The frequency of core preparation flakes without primary blanks in the assemblage is 16.03% (of total without debris and chips). The relatively high frequency of débordant (12.52%) and technical flakes (1.83%) demonstrate that the active process of flaking had been done inside the cave. The dominance of lateral débordant flakes and radial débordant flakes without cortical surface shows the subsequent stages of knapping following the decortication (Table 5). The cortex placement demonstrates the high frequency of lateral and distal positions of the cortical parts on the regular flakes and core preparation blanks, consistent with radial and orthogonal techniques (Table 6). Among all blank types, unidirectional, orthogonal and radial scar patterns predominate, which corresponds to the unidirectional, radial and orthogonal cores in the collection (Table 7). Metrical parameters of blanks with different scar patterns do not allow us to distinguish different stages of knapping, based on scar pattern. Levallois flakes or points have not been found. Metrical parameters demonstrate the prevalence of relatively short and wide blanks with very wide striking platforms (Fig. 7: a, b, c). The tool kit consists of 158 pieces (Table 8). Tools were made of all blank types, except for bladelets and crested lateral flakes. In general, we found no metrical or morphological differences between tools and blanks without secondary treatment (Fig. 7: a, b, c). The most vivid part of the tool kit consists of bifacial tools. One complete (Fig. 8: 1), two incomplete bifacial tools (Fig. 8: 2) and three bifacial pre-forms (Fig. 8: 3–5) have been found in the assemblage. The complete bifacial tool – a semi-crescent scraper - was made of mudstone of good quality in plano-convex technique, evidenced by clear differentiation of surfaces. Eight bifacial thinning flakes prove that at least part of bifacial production took place at the cave. The most interesting circumstance is a presence of tools, made of bifacial thinning flakes (Fig. 6: 7). Within the scraper group a new and unique type was identified that we name ‘Sel’Ungur scraper’. Sel’Ungur scrapers were usually manufactured on short and wide flakes with a wide and thick striking platform. Both proximal and dorsal parts of the blank had been alternately retouched. As a result, a «diamond shaped » longitudinal cross-section is formed (Fig. 9; Fig. 10: 3, 4). Two variations in the secondary treatment of Sel’Ungur scrapers are identified: with only one edge (distal or proximal) retouched (Fig. 10: 1, 2, 5), and with both edges retouched dorsally (Fig. 10: 6, 7). According to Islamov's illustrations, the Sel’Ungur scrapers were described by him as “pointe de Quinson” (Islamov and Krakhmal, 1995). Several Tayacian points (Debenath and Dibble, 1994) with convergent denticulate retouch, made of thick flakes were manufactured from radiolarite of good quality (Fig. 11: 1–5). Table 5 Sel’Ungur cave: cortex surface by blank types. 0% 1–25% 26–50% 51–75% 76–100% TOTAL: Flakes Flakes, cortical débordant Flakes, lateral débordant Flakes, crested débordant Flakes, overpassed Flakes, radial core débordant Flakes, technical Flakes, bifacial thinning Flakes, primary Flakes, natural Blades Bladelets Unidentifiable debitage 384 0 58 7 48 4 11 1 – 4 501 16 33 6 2 1 – 42 5 – – – – 5 1 16 1 3 – – – – – – 2 19 3 7 3 – 4 1 2 – – – 12 8 – – 7 4 8 – – – – – – – – 1 1 – – – – – 36 1 1 – 4 36 1 8 5 13 TOTAL: % 468 70,06 78 11,68 61 9,13 15 2,25 46 6,89 668 100,00 cores and cores are 1.1% of the total assemblage, while the category of blanks, including shaped in to tools, comprises 43.02% of all artifacts and 98.45% of the inventory without debris and chips. The tool kit is numerous – 14.53% (of the total without debris and chips). The primary knapping was based on three reduction strategies: radial (Fig. 5: 2, 5), unidirectional/bidirectional (Fig. 5: 1, 3, 4, 7) and orthogonal (Fig. 5: 6; Table 3). We did not find any features of a blade reduction strategy. The cores are small and most of them are exhausted (Fig. 5: 7). We define a blank for each lithic artifact with apparent ventral and dorsal surfaces with length or width ≥20 mm (Table 4). Core preparation blanks reflect the lateral treatment of the cores and are characterized by triangular or trapezoidal lateral steep cross sections (Fig. 6). We divided core preparation blanks into several categories based on metrical parameters and types of the dorsal scar patterns. These include among others radial débordant flakes (Fig. 6: 4, 6, 8, 10, 11), technical flakes (Kantenabschläge) (Figs. 6 and 9) (Richter, 1997, p.186–187) and bifacial thinning flakes (Fig. 6: 1–3, 7) (Table 4). The frequency of blades and bladelets is 1.83% of the flakes and core preparation blanks (Table 4). No core preparation blanks made of blades or bladelets have been found; there is no evidence for intentional blade or bladelet production in the assemblage. The small number of primary flakes (completely covered by cortex; 5.5%) coupled with relatively high amount of cortical flakes indicates Table 6 Sel’Ungur cave: cortex placement by blank types. Cortex Lateral Bi-Lateral Proximal Central Distal None TOTAL: Flakes Flakes, cortical débordant Flakes, lateral débordant Flakes, crested débordant Flakes, overpassed (flanc de nucleus) Flakes, radial core débordant Flakes, technical Flakes, bifacial thinning Flakes, primary Flakes, natural Blades Bladelets Unidentifiable debitage 2 4 – – – 1 2 – 36 1 1 – 4 49 12 – – – 2 – – – – – 1 – 2 – – – – – – – – – – – – 11 – 1 – – – 1 – – – – – 1 9 – 3 – – – 1 – – – – – – 44 – 5 – 1 1 5 – – – – – – 384 – 33 5 1 15 3 8 – – 7 4 8 501 16 42 5 2 19 12 8 36 1 8 5 13 TOTAL: % 51 7,63 64 9,58 2 0,30 14 2,10 13 1,95 56 8,38 468 70,06 668 100,00 9 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Table 7 Sel’Ungur cave: dorsal scar patterns, by blank types. Cortex Radial Convergent Unidirectional Bidirectional Bidirectional/ lateral Orthogonal Crossed Crested Plain Unidentifiable TOTAL: Flakes Flakes, cortical débordant Flakes, lateral débordant Flakes, crested débordant Flakes, overpassed (flanc de nucleus) Flakes, radial core débordant Flakes, technical Flakes, bifacial thinning Flakes, primary Flakes, natural Blades Bladelets Unidentifiable debitage 28 4 2 – – 45 – – – 18 1 1 – – 132 11 15 1 1 12 – 1 – – 10 – 1 – – 68 – 14 1 1 37 – 2 1 – – – 1 1 – 48 – 3 – – 103 – 2 1 – 501 16 42 5 2 – 3 2 3 – – 4 4 – 1 2 19 5 – 36 1 1 – – – – – – – 1 1 – – 7 4 1 – – – – – – – – – – – – – 1 – – – – – – 2 1 – – – – – – – – – – – 1 – – – – – 1 – 6 – – – 3 2 – – – – – – 9 12 8 36 1 8 5 13 TOTAL: % 80 11,98 50 7,49 22 3,29 176 26,35 14 2,10 11 1,65 89 13,32 47 7,04 3 0,45 53 7,93 123 18,41 668 100,00 % esse 14,68 9,17 4,04 32,29 2,57 2,02 16,33 8,62 0,55 9,72 – 100,00 Fig. 7. a - Comparison of the dimensions (length and width) of the complete blanks from Sel’Ungur cave assemblages; b - Comparison of the dimensions (width and thickness) of blanks from Sel’Ungur cave assemblages; c - Comparison of the dimensions (width and thickness) of blanks's striking platforms. There are several other tool types more typical for the Middle Paleolithic typology in the assemblage, including a series of Mousterian tranchets (Debenath and Dibble, 1994) characterized by working edges mostly similar to retouch-less splintered pieces (Fig. 11: 6–9). There are also several convergent scrapers identified as well as a triple dejete scraper (Fig. 11: 10, 11). The Sel’Ungur scrapers, Tayacian points and Mousterian tranchets have a high degree of metrical (Fig. 12) as well as morphological regularity, associated with exploitation of high quality raw material. Transversal and diagonal side-scrapers are frequent in the tool kit. Among the transversal scrapers with a high and steep working edge (abrupt scrapers) there are several tools which were made of natural shatters of tectonically brecciated chert. Single and double straight scrapers, raclette, borers, notched, denticulate tools and retouched flakes are also noted. 5. Discussion Due to the colluvial character of sediments bearing the Paleolithic artifacts, we have to assume that the inventories have been re-deposited 10 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Table 8 Breakdown of the tool kit from Sel’Ungur cave. Tool types layer 6.1 layer 5.2 layer 5.1 layer 4.7 layer 4.6 layer 4.4 Total Тауас point Transversal scrapers: transverse with a high steep working edge transverse diagonal Selungurian type: double-alternate double-dorsal single-on striking plarform Side scrapers single-straight double-straight Convergent scrapers Dejete scraper Bifacial scraper Iincomplete bifasial scraper Mousterian tranche Raclette Borers Dentoculated tools Notched tools Retouched flakes Unidentifiable tools 1 – – – 1 – – 1 – – 1 - 1 2 – 1 1 – – – – 6 2 4 1 2 3 7 1 4 26 9 4 7 6 3 2 1 15 13 2 3 1 1 1 7 4 4 10 6 21 9 – – – – – – – 1 1 – 1 1 3 1 - 1 – – 1 – – – – 3 2 1 1 1 1 - 1 – – – 1 1 – – 1 1 – 1 1 3 - 5 31 TOTAL: 3 24 113 7 7 7 158 26 6 1 1 2 10 4 6 14 9 33 10 Fig. 8. Bifacial tools and pre-forms from Sel’Ungur cave assemblages. 1 – Semi-crescent scraper; 2 – Incomplete leaf-shape bifacial tool; 3–5 – bifacial pre-forms. 11 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. parts of decortication process took place outside the cave. Technological parameters such as core metrics, presence of primary flakes, and lateral core preparation blanks and the totality of blanks, presuppose a high core utilization degree. This was most probably related to the necessity of transport of a significant frequency of the raw material from quite distant localities (5 km or more). Based on characteristics of scar pattern, ventral angles between the striking platform and the ventral surface, as well as cores utilized along their short axis, we can assume that one of the major goals of primary knapping was to manufacture short and wide blanks with very massive striking platforms in frame of radial knapping. The prevalence of blanks with rectangular/trapezoidal shapes, with discordance between the longitudinal and technological axis mostly corresponds to radial and orthogonal knapping. The predominance of straight lateral profiles with feathering distal end profiles demonstrates a sufficiently highly controlled knapping process. Ratios of the overhang trimming on striking platforms and types of striking platforms are usual for non-Levallois Middle Paleolithic assemblages. All stages of bifacial production are present in the assemblage (preforms, bifacial thinning flakes incomplete bifacial tools, and complete bifacial tools). The typological structure of the blanks demonstrates the predominance of flake core knapping in the assemblage. It is supported by low frequency of the bifacial thinning flakes, pre-forms and bifaces itself. The relatively high frequency of tools in the assemblage is remarkable. Bearing in mind the relatively low frequency of chips, it cannot be excluded that part of the tools could be transported from different parts of cave or from outside the cave. Comparisons of the tools and other blanks did not show any specific features of blanks used for production of tools. The tool kit is characterized by the predominance of transversal and diagonal scrapers, including the Sel’Ungur scrapers. Tayacian points, Mousterian tranchets, abrupt and convergent scrapers have also been recorded. The high degree of regularity with regards to raw material and morpho-metrics of the Sel’Ungur scrapers, Tayacian points and Mousterian tranchets attest to intentional manufacture of blanks with required characteristics. On the basis of techno-typological characteristics presented above, the previous interpretation of Sel’Ungur assemblage as Acheulian or even late Oldowan, as proposed by Islamov and Krakhmal (1995), cannot be accepted. Sel’Ungur does not show any similarities to other Lower Paleolithic techno-complexes known from western Central Asia either. The Karatau culture (600-400 ka) and Kul'dara (850–950 ka) assemblages, are characterized as pebble-tool industries occurring in loess deposits (Davis and Ranov, 1999; Ranov and Schafer, 2000; Ranov and Karimova, 2005), and clearly differ from Sel’Ungur. Keeping in mind the not secure dated context of Sel’Ungur assemblage and in order to check the possibility of Upper Paleolithic interpretation we tried to find similarities with known regional Upper Paleolithic assemblages (upper layers of Kulbulak, Dodecatym-2, Shugnou, Samarkandkaya etc.; Vishnyatsky, 1999; Ranov et al., 2012; Kolobova et al., 2014; Kolobova et al., 2018b) and did not find any. Based on the technical and typological characteristics described above, the Sel’Ungur assemblage from layers 4.4–6.2 should be considered as Middle Paleolithic. The most important arguments for this are the: a) systematic core reduction; b) presence of plano-convex technique; c) typologically definitive side-scrapers which predominate in tool kit; and d) presence of highly standardized tool types. It is worth to note that plano-convex bifacial tools identified in the Sel’Ungur assemblage, are the very first ones found in western Central Asia. Several bifaces from Sel’Ungur cave have been reported by Islamov previously, but the published figures are insufficient to propose a detailed classification (Islamov and Krakhmal, 1995; Vishnyatsky, 1999). Several bifaces from a stratified context were also known from another “Acheulian” site, namely the lower layers of Kulbulak (excavations done in 1960–80), according to Kasymov. Unfortunately, all those bifaces have been lost, and based on illustrations only (Kasymov Fig. 9. Sel’Ungur scrapers from Sel’Ungur cave assemblages. 1 - Operation chain of Sel’Ungur scraper production; 2 – Sel’Ungur type side-scraper. and their spatial arrangement does not reflect the original structure of the site. However, small vertical distances and techno-typological similarities between the lithic inventories from particular Paleolithic layers allow us to suppose that the most or all of these inventories represent more or less the same original assemblage. Pending the new absolute age determinations, we can only rely only on the published U/Th date of 126 ± 5 ka (Vishnyatsky, 1999. P. 110). However, according to the documentation accessible to us, this date was received on sediments from the inner part of the cave, situated quite far from Zone 8, and does not therefore correlate directly with the archaeological assemblage. We also discount the unpublished Ar/Ar date of 1.4 MYA due to lack of any stratigraphic and spatial context. The new TL date 112 ± 19 ka marks the lower limit for the Middle Paleolithic sequence. Although this date cannot be used to establish the exact chronology of the archaeological assemblages, it narrows the chronological range of the Paleolithic layers to the Upper Pleistocene. Considering that the new studies of the microfauna found no Early Pleistocene elements (Markova, 2013) and the large mammals consist of Middle and Late Pleistocene taxa (some of them typical also for Holocene), the period of Sel’Ungur cave occupation can be preliminary estimated to be Late Pleistocene. Based on the results of the analysis of cores and blanks it could be argued that radial, orthogonal and unipolar knapping has been used in Sel’Ungur cave. The small number of cores does not allow us to reconstruct the whole knapping sequence, but it is possible to reconstruct the general features of the knapping processes. Cores were manufactured on tested pebbles, and only one specimen was produced of local tectonically brecciated chert. The profrequencys of primary, technical and lateral flakes provide evidence for the incomplete core reduction sequence in the cave, and suggest that some 12 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Fig. 10. Sel’Ungur scrapers. 1, 2, 5 - distally/proximally retouched Sel’Ungur scrapers with one working edge; 3, 4 – alternate Sel’Ungur scrapers; 6, 7 - dorsally retouched with two working edges. and Grechkina, 1994; Kolobova et al., 2018a) those bifaces can be described as biconvex forms. Currently, it is not possible to find any analogies to the Sel’Ungur assemblage in terms of technological or typological characteristics in the Middle Paleolithic of western Central Asia. Up until now, several Middle Palaeolithic techno-complexes have been identified in this region, including the Teshik-Tashian and Obi-Rakhmatian. The TeshikTashian variant of Middle Paleolithic (Teshik-Tash rockshelter, Katta Sai-1 and -2, all in Uzbekistan) is characterized by flake Levallois Preferential technique, with relatively recent chronology, around 38 ka (Okladnikov, 1949; Krajcarz et al., 2016). No predecessors of this variant have been identified thus far. The Obi-Rakhmatian variant (ObiRakhmat rockshelter and Kulbulak - layer 23, Uzbekistan; Khudji and Dzhar-Kutan - Tajikistan) is characterized by a developed blade technology with an insignificant frequency of Levallois Convergent unidirectional blade technique, and is dated back to 100-40 ka. To date, Levantine Middle Paleolithic blade industries such as found at Hayonim and Misliya Caves, Israel, are regarded as a likely source of this variant (Shalagina et al., 2015; Krivoshapkin, 2012). Several other techno-complexes, such as Kara-Bura, Ogzi-Kichik, Tosor and Yutash-sai, had been previously associated with different Middle Paleolithic variants, but this requires revision (Vishnyatsky, 1999; Zenin et al., 2004; Ranov and Karimova, 2005). For the assemblage from Anghilak Cave, associated with Neanderthals (Glantz et al., 2003), it is not yet clear whether it represents a part of a known Middle Paleolithic variant, or a separate variant (Glantz et al., 2003). Looking at the broader geographical range, we have to mention the technological and typological similarities between Sel’Ungur assemblage and the Middle Pleistocene complexes from Yarimburgaz cave (Turkey). According to ESR results, the Yarimburgaz cave sequence is in the chronological range of OIS 6 to OIS 9. The Yarimburgaz lithic assemblage containing 1675 artifacts is characterized by a reduction of discoidal cores aimed at the manufacture of flakes. The most important part of the tool kit consists of tools made on flakes, among which 13 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. Fig. 11. Tools from Sel’Ungur cave assemblages. 1–5 - Tayacian points; 6–9 - Mousterian tranchets; 10 - triple dejete scraper; 11 - convergent scraper. denticulate tools and side-scrapers are the most numerous ones. Flake tools exceed the pebble tools represented by choppers. In the assemblage of Yarimburgaz cave neither the Levallois technique, nor handaxes (bifaces), nor bifacial thinning flakes have been identified. The principal investigator of the Yarimburgaz Cave, S. Kuhn, emphasized that parameters of raw material used in the assemblage allowed the manufacturing of bifaces. The absence of bifaces has been explained in terms of extreme rarity of its discovering in such deep karstic cavity (Kuhn et al., 1996). In both Sel’Ungur and Yarimburgaz caves, the radial/discoidal knapping aimed at manufacturing flakes predominates, with an absence of Levallois technique. The most significant resemblance among tools is obvious: denticulate tools from Yarimburgaz Cave are similar to Tayacian points from Sel’Ungur Cave; the same is true for abrupt scrapers as well. However, in Yarimburgaz Cave a significant amount of pebble tools were identified, which are missing at Sel’Ungur Cave. Another difference includes plano-convex bifaces from Sel’Ungur Cave, absent at Yarimburgaz cave (Kuhn et al., 1996). 6. Conclusions The new study of the lithic assemblages from Sel’Ungur cave provides important information on the Central Asian Lower and Middle Paleolithic, but raises a lot of new questions. The most important result is that the Sel’Ungur assemblage can be attributed neither to Oldowan nor Acheulian complexes as it was claimed earlier by U. Islamov and his colleagues. Hence, the only known indisputable stratified Lower Paleolithic sites in Central Asia are Karatau and Kul'dara pebble-tool techno-complexes. Based on newly obtained data and preliminary re-examination of available material from previous excavations (published illustrations and lithics) it could be proposed that the Sel’Ungur lithic assemblage stays detached from known local Middle Paleolithic variability. The main specifics of Sel’Ungur site are as follows: 14 Quaternary International xxx (xxxx) xxx–xxx A. Krivoshapkin et al. widht, mm 70 60 50 mousterian splintered pieces 40 Тауасpoints Selungurian scrapers 30 20 lenght, mm 10 10 15 20 25 30 35 40 Fig. 12. Comparison of the dimensions (length and width) of the complete Sel’Ungur scrapers, Tayacian points and Mousterian tranchets from Sel’Ungur cave assemblages. 1. Absolute absence of Levallois technology. The primary knapping is based on radial, orthogonal and unipolar knapping aimed to obtain short and wide flakes. 2. Presence of plano-convex bifacial tools, accompanied with bifacial thinning flakes and tools made on bifacial thinning flakes. 3. Presence of specific tool types unknown in other Central Asian Paleolithic assemblages, for example transversal scrapers made on thick blanks with alternatively worked edges, Tayacian points and Mousterian tranchets. Chabai, V.P., 2006. History and recearch methods of Crimea Middle Paleolithic typological variability. Archaeological Almanac 18, 5–46 (In Ukraine). Davis, R., Ranov, V., 1999. Recent work on the paleolithic of Central Asia. Evol. Anthropol. 8, 186–193. Debenath, A., Dibble, H.L., 1994. Handbook of Paleolithic Typology. Volum One: Lower and Middle Paleolithic of Europe. University of Pennsylvania, Philadelphia. Dodonov, А.E., 2002. Chetvertichnyj Period Srednej Аzii. Stratigrafiya, Korrelyatsiya, Paleogeografiya. Geos, Moskva. Fedorowicz, S., 2006. Methodological Aspects of Luminescence Dating of Central Europe’s Neopleistocene Deposits. 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Paleoliticheskaya stoyanka Sel’ungur v Ferganskoy doline (The palaeolithic site of Sel’ungur in the Fergana Valley). Vopr. Antropol. 80, 38–49 (in Russian). Kasymov, M.R., Grechkina, T.Y., 1994. Kulbulak (Uzbekistan) and its significance for the paleolithic of Central Asia. In: Masson, V.M. (Ed.), New Archaeological Discoveries in Asiatic Russia and Central Asia. Institute for the History of Material Culture, St Petersburg, pp. 5–13. Kasymov, M.R., Toichiev, H., 1981. Otchet O Rezul'tatakh Polevykh Issledovanij Аkhangoranskogo Paleoliticheskogo Otryada V 1981 G. Tashkent. Unpublished (in Russian). Kolobova, K.A., Krivoshapkin, A.I., Pavlenok, K.K., 2014. Carinated pieces in paleolithic assemblages of Central Asia. Archaeol. Ethnol. Anthropol. Eurasia 42 (4), 13–29. Kolobova, K.A., Flas, D., Krivoshapkin, A.I., Pavlenok, K.K., Vandenberghe, D., Dapper, M. De, 2018a. Reassessment of the lower paleolithic (Acheulean) presencein the western Tien Shan. Archaeolog. Anthropolog. Sci. 10 (3), 615–630. Kolobova, K., Krivoshapkin, A., Shnaider, S., 2018b. Early geometric microlith technology in Central Asia. Archaeolog. Anthropolog. Sci 1–13. https://doi.org/10.1007/ s12520-018-0613-y. Krajcarz, M., Kot, M., Pavlenok, K., Fedorowicz, S., Krajcarz, M., Lazarev, S., Mroczek, P., Radzhabov, A., Shnaider, S., Szymanek, M., Szymczak, K., 2016. Middle Paleolithic sites of Katta Sai in western Tian Shan piedmont, Central Asiatic loess zone: geoarchaeological investigation of the site formation and the integrity of the lithic assemblages. Quat. Int. 399, 136–150. Krivoshapkin, A.I., 2012. Obirakhmatien Version of Middle to Upper Paleolithic Transition. Institute of Archaeology and Ethnography, Siberian Branch of the Russian Academy of Sciences, Novosibirsk (in Russian). Kuhn, S.L., Arsebük, G., Howell, F.C., 1996. The Middle Pleistocene lithic assemblage from Yarimburgaz cave, Turkey. Paleorient 22 (1), 31–49. Markova, A., 2013. Small mammals from Acheulean cave site Sel'Ungur (the Fergana valley, Uzbekistan). In: Neogene to Quaternary Geological Evolution of Mediterranian, Paratethys and Black Sea, Proceedings of the 14th RCMNS Congress, pp. 261. Monigal, K., 2002. The Levantine Leptolithic: Blade Technology from the Lower Paleolithic to the Dawn of the Upper Paleolithic Unpublished Ph.D. Dissertation. Thus, based on revealed techno-typological uniqueness combined with new geological, sedimentological, and paleontological data the Sel’Ungur assemblage could be preliminary defined as a peculiar manifestation of western Central Asian Middle Paleolithic variability. The origin and cultural meaning of such peculiarity is a matter of further investigations which demand, first of all, a significant increase in lithic sample and detailed chronological binding. Acknowledgements We thank the organizers of the session and APA Congress 2016, in particular Dr. Masami Izuho (Tokyo Metropolitan University) for the invitation to participate in this special issue of Quaternary International. We acknowledge the incredible contributions of Natalia Vavilina (Institute of Archaeology and Ethnography, SB RAS, Novosibirsk, Russia) in producing illustrations for this article. The excavations at Sel’Ungur were supported by the Leakey Foundation (general grant "Middle Pleistocene hominins in Central Asia - Excavations at Sel'Ungur" to B. Viola and A. I. Krivoshapkin, Russian Foundation for Basic Recearch project (RFBR) #18-09-00222, and the Social Sciences and Humanities Research Council of Canada (430-201600590 to B. Viola). We are thankful to the Russian Science Foundation (RNF) for support of the lithic analysis of this research project under grant #14-50-00036, “Multidisciplinary Research in Archaeology and Ethnography of Northern and Central Asia”. 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