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RADIOCARBON DATING OF GRASS-TEMPERED CERAMIC REVEALS THE EARLIEST POTTERY FROM SLOVAKIA PREDATES THE ARRIVAL OF FARMING

Published online by Cambridge University Press:  05 June 2023

Peter Tóth Open the ORCID record for Peter Tóth [Opens in a new window] ,
Jan Petřík Open the ORCID record for Jan Petřík [Opens in a new window] ,
Penny Bickle Open the ORCID record for Penny Bickle [Opens in a new window] ,
Katarína Adameková Open the ORCID record for Katarína Adameková [Opens in a new window] ,
Solène Denis Open the ORCID record for Solène Denis [Opens in a new window] ,
Karel Slavíček Open the ORCID record for Karel Slavíček [Opens in a new window] ,
Libor Petr Open the ORCID record for Libor Petr [Opens in a new window] ,
Dalia Pokutta Open the ORCID record for Dalia Pokutta [Opens in a new window]  and
Sven Isaksson Open the ORCID record for Sven Isaksson [Opens in a new window]
Peter Tóth*
Affiliation:
Masaryk University, Department of Archaeology and Museology, Brno, Czech Republic
Jan Petřík
Affiliation:
Masaryk University, Faculty of Science, Department of Geological Sciences, Kotlářská 2, 611 37 Brno, Czech Republic
Penny Bickle
Affiliation:
University of York, Department of Archaeology, The King’s Manor, York, YO1 7EP, UK
Katarína Adameková
Affiliation:
Masaryk University, Faculty of Science, Department of Geological Sciences, Kotlářská 2, 611 37 Brno, Czech Republic
Solène Denis
Affiliation:
Masaryk University, Department of Archaeology and Museology, Brno, Czech Republic CNRS, UMR 8068 TEMPS, MSH Mondes, Nanterre, France
Karel Slavíček
Affiliation:
Masaryk University, Faculty of Science, Department of Geological Sciences, Kotlářská 2, 611 37 Brno, Czech Republic
Libor Petr
Affiliation:
Masaryk University, Faculty of Science, Department of Botany and Zoology, Kotlářská 2, 611 37 Brno, Czech Republic
Dalia Pokutta
Affiliation:
Masaryk University, Department of Archaeology and Museology, Brno, Czech Republic Stockholm University, Department of Archaeology and Classical Studies, Stockholm, Sweden University of Rzeszów, Institute of Archaeology, Poland
Sven Isaksson
Affiliation:
Stockholm University, Department of Archaeology and Classical Studies, Stockholm, Sweden
*
*Corresponding author Email: peter.toth@phil.muni.cz
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Abstract

In the absence of wood, bone, and other organics, one possible candidate for determining the age of a site is the radiocarbon (14C) dating of pottery. In central Europe during the Early Neolithic, pottery was ubiquitous and contained substantial quantities of organic temper. However, attempts at the direct dating of organic inclusions raises a lot of methodological issues, especially when several sources of carbon contribute to the resulting radiocarbon age. Hence an alternative approach to dating of the early pottery is necessary. Here, we present a novel method of bulk separation of organic content from the grass-tempered pottery from Santovka (Slovakia). The procedure is based on the consecutive application of three inorganic acids, dissolving clay, silica content, and low molecular or mobile fractions to separate organic inclusions added to the pottery matrix during the formation of vessels. Radiocarbon dates obtained with this method are coherent and produce the shortest time span compared to other pretreatment methods presented in this study. The paired dates of grass-tempered pots with the 14C age of lipids extracted from the same pots point to a difference of 400–600 14C yr, however they are in line with the site’s chronostratigraphic Bayesian model. Grass-tempered pottery from Santovka (Slovakia) is dated to the first half of the 6th millennium cal BC, making it the earliest pottery north of the Danube. It seems feasible that ceramic containers from Santovka were produced by hunter-gatherers, and pottery predated the arrival of farming in the Carpathian region by a couple of centuries.

Keywords

Bayesian modelinglipidsorganic temperpottery vesselsradiocarbon datingSlovakia
Type
Research Article
Information
Radiocarbon , Volume 65 , Issue 3 , June 2023 , pp. 733 - 753
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press for the Arizona Board of Regents on behalf of the University of Arizona

INTRODUCTION

Radiocarbon (14C) dating is one of the most common methods for determining the age of organic material (Bayliss Reference Bayliss2009; Strydonck Reference Strydonck2017). Unfortunately, materials typically utilized for 14C dating are not always recovered during archaeological excavations, therefore the chance to date pottery, one of the most ubiquitous archaeological finds from the early Neolithic, is particularly promising (e.g., Casanova et al. Reference Casanova, Knowles, Bayliss, Dunne, Barański, Denaire, Lefranc, di Lernia, Roffet-Salque and Smyth2020; Teetaert et al. Reference Teetaert, Boudin, Goemaere and Crombé2020). In the Early Neolithic of Central Europe (first half of the 6th millennium BC), the pottery contains an abundance of organic temper, which makes it a suitable candidate for 14C dating (Quitta Reference Quitta1960; e.g., Bente et al. Reference Bente, Durini, Küsel, Kunert, Keilholz and Hölzig2019; Sauer Reference Sauer2019).

Applicability of direct 14C dating of pottery, however, depends on the origin of organic carbon. Previous research demonstrated that several sources of carbon contribute to the resulting 14C date of pottery: clay, temper, vessel use, carbon from fuel deposited as soot on vessel surface and depositional environment (Atley Reference Atley1980; Gabasio et al. Reference Gabasio, Evin, Arnal and Andrieux1986; Johnson et al. Reference Johnson, Stipp, Tamers, Bonani, Suter and Wölfli1986; Evin et al. Reference Evin, Gabasio and Lefevre1989; Hedges et al. Reference Hedges, Tiemei and Housley1992; Nakamura et al. Reference Nakamura, Taniguchi, Tsuji and Oda2001; Stott et al. Reference Stott, Berstan, Evershed, Hedges, Ramsey and Humm2001; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004; Anderson et al. Reference Anderson, Chappell, Clark and Phear2005; Zaitseva et al. Reference Zaitseva, Skripkin, Kovaliukh, Possnert, Dolukhanov and Vybornov2009; Goslar et al. Reference Goslar, Kozłowski, Szmyt and Czernik2013; Teetaert et al. Reference Teetaert, Boudin, Goemaere and Crombé2020). The first experiments with directly dating the ceramic material were conducted in the 1960s (Ralph Reference Ralph1959; e.g., Evans and Meggers Reference Evans and Meggers1962; Stuckenrath Reference Stuckenrath1963). They were based on the assumption that organic material in the pottery paste results from cultural activity. During these initial experiments, it was discovered that sherds with an extremely small amount of organic carbon (<0.6%) produced questionable dates (Atley Reference Atley1980). Further works comparing 14C ages and other independent dates from the same stratigraphic contexts pointed out that the resulting age could have been affected by non-cultural sources (Taylor and Berger Reference Taylor and Berger1968; e.g., Stäuble Reference Stäuble1995).

The application of accelerator mass spectrometry (AMS) resulted in a breakthrough in enabling 14C dating of isolated fractions, such as temper (Teetaert et al. Reference Teetaert, Boudin, Goemaere and Crombé2020), lipids (Stott et al. Reference Stott, Berstan, Evershed, Hedges, Ramsey and Humm2001; Casanova et al. Reference Casanova, Knowles, Bayliss, Dunne, Barański, Denaire, Lefranc, di Lernia, Roffet-Salque and Smyth2020), humics (Količ Reference Količ1995; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004) or residual carbon (Hedges et al. Reference Hedges, Tiemei and Housley1992; Goslar et al. Reference Goslar, Kozłowski, Szmyt and Czernik2013). Experiments with the dating of residual carbon provided older than expected dates associated with the incorporation of geological carbon (Hedges et al. Reference Hedges, Tiemei and Housley1992). Application of hydrofluoric acid (HF) leaching led to similar results due to mobilisation of the old carbon from the raw clay (Goslar et al. Reference Goslar, Kozłowski, Szmyt and Czernik2013). By contrast, lipid material surviving in cooking pots can provide a 14C age of the vessel usage, but freshwater/marine reservoir effect needs to be considered from cooking food (e.g., Fischer and Heinemeier Reference Fischer and Heinemeier2003; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004; Boudin et al. Reference Boudin, Strydonck, Crombé, Clercq, Dierendonck, Jongepier, Ervynck and Lentacker2010; Hartz et al. Reference Hartz, Kostyleva, Piezonka, Terberger, Tsydenova and Zhilin2012; Miyata et al. Reference Miyata, Horiuchi, Kondo, Onbe, Yoshida, Nagao, Group and Nishimoto2016; Gauthier Reference Gauthier2022). To avoid the old carbon from the clay, and increase the chance of reliable dates, it is better to isolate the charred organic temper remains from the pottery prior to 14C dating (Hedges et al. Reference Hedges, Tiemei and Housley1992; Gomes and Vega Reference Gomes and Vega1999). This method has already been successfully applied to date grass temper (e.g., Bollong et al. Reference Bollong, Vogel, Jacobson, van der Westhuizen and Sampson1993), moss tempers (Gilmore Reference Gilmore2015) and accidental inclusions of organic macrofossils in pottery (Arobba et al. Reference Arobba, Panelli, Caramiello, Gabriele and Maggi2017).

In this paper, we present a novel method of bulk separation of organic content from the grass-tempered pottery and the results of direct AMS 14C dating of the clay vessels from Santovka (Slovakia). Due to the presence of the mineral thermal springs, this territory was a centre of human activities from the Palaeolithic, with high intensity during the Neolithic and the Bronze Age (Bárta Reference Bárta1961; Bátora et al. Reference Bátora, Tóth and Bača2015; Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018). Previous palaeoecological research of Santovka led to the discovery of stratified sequence of prehistoric pottery (Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018). The lowermost finds from calcareous lake sediments represent grass-tempered pottery, which stylistically and technologically does not correspond to the Early Neolithic pottery known from the area (ca. 5600–5300 cal BC; Jakucs et al. Reference Jakucs, Bánffy, Oross, Voicsek, Bronk Ramsey, Dunbar, Kromer, Bayliss, Hofmann and Marshall2016). We test the hypothesis that grass-tempered pots represent the earliest pottery north of the Danube. In order to achieve this, we aim to (1) 14C date the grass temper of the pottery from Santovka, (2) compare the resulting 14C dates with 14C dates produced on lipids extracted from the same pottery, and (3) test the accuracy of direct 14C dating of pottery by a chronostratigraphic Bayesian model.

MATERIAL AND METHODS

The Santovka site is located 120 km east of Bratislava (Slovakia) at the transition of the Pannonian Basin and Western Carpathians (E18.7692, N48.1538; WGS84; Figure 1; Supplement 1.1). The excavated section is situated on the right bank of the Búr brook, close to one of the travertine accumulations, at 140 m a.s.l. and is formed of organic-rich carbonate sediments. The section was monitored in 2012–2014 through standard archaeological methods (cleaning, photographic documentation, photogrammetry). During the fieldwork, a sequence of 24 archaeological layers was uncovered and classified into ten lithostratigraphic units (Figure 2; Table 1). During these campaigns, 86 artefacts (such as pottery, animal and human bones, daub, lithics) were collected and documented, including 25 fragments of an unusual hitherto unknown type of grass-tempered pottery.

Figure 1 A and B: Location of the Santovka site in a wider geographic context; C: location of the documented section on the right bank of the Búr brook; D: fieldwork campaign in 2012. Data sources: A–B—Natural Earth; C—ÚGKK SR.

Figure 2 Stratigraphy sequence of the southern section of the Búr creek showing the position of the lithostratigraphic units. Only grass-tempered pottery was found in unit 5a. Displayed dates are based on the chronostratigraphic Bayesian model (Supplement 1.2, 1.3). The complete cross-section of the Búr creek with the position of 14C dated pottery is shown in Supplement 1.1.

Table 1 Lithostratigraphic development of the section in Santovka and archaeological chronology. P—pottery; B—bone; L—lithics; D—daub; Pre-N—pre-Neolithic; N—Neolithic; BA—Bronze Age (Data sources: Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018; Petřík et al. in prep.).

Cultural-chronological classification of the pottery was carried out based on Pavúk (Reference Pavúk1969, Reference Pavúk1980, Reference Pavúk2018), Nikitin et al. (Reference Nikitin, Stadler, Kotova, Teschler-Nicola, Price, Hoover, Kennett, Lazaridis, Rohland and Lipson2019), Bátora (Reference Bátora2018), and Furmánek (Reference Furmánek2015), considering the technological and typological elements of the pottery and its stratigraphic position. Thin-sections of 30 μm thickness were prepared from the grass-tempered pottery. Organic temper was studied in transmitted light under a polarising microscope Olympus BX 51. Photographic documentation was carried out with a Canon 40D camera.

To determine the age of this pottery, we selected 8 pieces of grass-tempered pottery and 1 organic residue from the pottery surface. Six pottery sherds were analyzed in the Beta Analytic (USA). The laboratory used the acid-alkali-acid (AAA) pretreatment (on whole pottery matrix) to remove possible contaminants by humic acids and dated the resulting organic material (De Vries and Barendsen Reference De Vries and Barendsen1954). The measurements were conducted in the NEC accelerator mass spectrometer, whereas the carbon ratios were measured in the Thermo-Finnigan Delta IRMS machine. The organic residue was submitted to the Centre for Applied Isotope studies, University of Georgia, USA (UGAMS). The sample was pretreated by AAA wash method in the laboratory, the high precision measurement of 14C/12C ratio was conducted in 500 kV NEC 1.5SDH-1 pelletron in tandem with an accelerator equipped with a 134-cathode MC-SNICS negative ion source.

For direct dating of organic inclusions we developed a novel triple acid wash method. Three sherds of around 1 cm3 size were pretreated by an adaptation of a method which is used for pollen separation (Moore et al. Reference Moore, Webb and Collinson1991). The principle of triple acid pretreatment method (Figure 3) is based on reducing pottery clay mass by using inorganic acids dissolving clay, silica contents, carbonates and low molecular or mobile organic fractions. Samples were crushed in a mortar to a fraction close to fine powder. Crushed material was transferred to the PET tube where hydrofluoric acid (100 mL, concentration 38–40%, per analytic, further as p. a.) was carefully added. This process is followed by a strong exothermic reaction which removes silicate minerals. Subsequently, centrifugation (3000 rpm, 180 s) in ultra-distillate water was repeated two times to homogenise samples. Afterwards, tubes were put into the centrifuge (3000 rpm, 180 s) and treatment with HF (100 mL, concentration 38–40%, p. a.) was repeated until a reaction had stopped. Carbonates were then removed using hydrochloric acid (50 mL, concentration 35–38%, p. a.) until a reaction was running. The fourth centrifugation (3000 rpm, 180 s) followed after any reaction was over. Following that, removal of small organic molecules using nitric acid (50 mL, concentration 65%, p. a) in boiling water was conducted. Resulting organic residues were inspected by a light microscope (400× magnification, Olympus BX51) and inorganic content had been excluded. Lastly, samples were slowly dried at room conditions, packed and submitted to the 14C dating to Isotoptech Zrt. laboratory in Debrecen (Hungary), where they were further purified by standard laboratory protocols (Bird et al. Reference Bird, Ayliffe, Fifield, Turney, Cresswell, Barrows and David1999, Reference Bird, Turney, Fifield, Smith, Miller, Roberts and Magee2003; ABOX pretreatment; Bird Reference Bird2013). The AMS measurements were performed in Mini Carbon Dating System MICADAS.

Figure 3 Principle of the novel triple acid wash method.

For direct dating of lipids, the potsherds were first investigated for lipid residues using standard solvent extraction procedures for molecular analyses (c.f. Isaksson and Hallgren Reference Isaksson and Hallgren2012) and acid catalysed extraction and methylation (Eggers and Schwudke Reference Eggers, Schwudke and Wenk2016) for compound specific stable carbon isotope analysis of palmitic and stearic acid (Papakosta et al. Reference Papakosta, Smittenberg, Gibbs, Jordan and Isaksson2015). The GCMS and GC-C-IRMS analyses were performed first. Based on these results samples were selected for the second extraction of lipid residues for 14C dating. For this purpose a modified version of the so-called Folch’s method was used (Folch et al. Reference Folch, Lees and Stanley1957; Eggers and Schwudke Reference Eggers, Schwudke and Wenk2016; Llewellin and Isaksson, Reference Llewellin and Isakssonin press). The dried and purified lipid extracts were blown down to a few hundred microliters under a gentle stream of nitrogen gas. The highly concentrated extracts were then pipetted directly into preweighed tin foil capsules for 14C dating and very carefully blown down to dryness. In order to maximize the removal of solvents (Casanova et al. Reference Casanova, Knowles, Williams, Crump and Evershed2018: 11028) the tin foil capsules were heated to 70°C, i.e., ca. 10°C above the boiling point of chloroform, for 1 hr. The tin foil capsules were then allowed to cool and weighed to check the lipid residue yields before being sent to the Mass Spectrometry Laboratory, Center for Physical Sciences and Technology in Vilnius, Lithuania (Vilnius 14C Laboratory), for 14C analysis.

Extracted lipids were graphitized directly with Automated Graphitization Equipment AGE-3 (IonPlus AG). The AMS measurement was performed in a 240 KV Single Stage Accelerator Mass Spectrometer at the Vilnius Radiocarbon Laboratory. The background of measurements is approximately 2.45 × 10−3 fM (fraction of modern carbon) using phthalic anhydride. As reference materials were used the IAEA-C2, IAEA-C3, IAEA-C7, IAEA-C9, NIST OXII, SIRI K (carbonate) standards. The 14C/12C ratio is measured with an accuracy better than 0.3% (±30 yr or better; Vilnius Radiocarbon 2022).

Calibration and combination of 14C dates was undertaken using the program OxCal v4.4 (Bronk Ramsey Reference Bronk Ramsey2009) and the IntCal20 calibration curve (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Bronk Ramsey, Butzin, Cheng, Edwards and Friedrich2020). A chronostratigraphic Bayesian model with an outlier analysis (Supplement 1.4 and 1.5; adapted after Petřík et al. Reference Petřík, Adameková and Škrdla2022) was used to test whether 14C dates from the grass-tempered pottery agree with the sedimentation sequence on the site. For this modeling, as input data were used 14C dates of grass temper and lipids (Table 3), published 14C dates from site’s stratigraphic sequence (Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018) and data acquired from the age-depth model, which represent an expected age based on sample’s depth (Supplement 1.2, 1.3; Petřík et al. in prep.). Age-depth model data consists of top and bottom of lithostratigraphic unit 5a, where only grass-tempered pottery was located, as well as from surrounding units (4 and 5b) in order to estimate the start and end of the pottery tempered with grass. At the same time we also made a phase model for the grass-tempered pottery. The dates judged most reliable (agreement index is above 60%) were then selected for chronological modeling (KDE model) to determine a likely span of dates for pottery sherds tempered with grass.

Table 2 Lipid residue analysis. Lipid content is given in mg lipid extracts per gram ceramic powder. FA describes the fatty acid distribution detected using the format n(m)k where n is the chain-length of the shortest fatty acid detected, m is the chain-length of the most abundant fatty acid in the distribution and k is the chain-length of the longest fatty acid detected. C18:0/C16:0 is the ratio of stearic to palmitic acid. BR is the carbon chain lengths registered for branched chained fatty acids. DA is dicarboxylic acids, OHFA is hydroxy-fatty acid, LCK is long-chain ketones, isoprenoid is isoprenoid fatty acids, APFA is ω(o-alkyl phenyl)fatty acids, δ13C C16:0 and δ13C C18:0 are the δ13C-values of the palmitic and stearic acids, respectively. Δ is the difference in δ13C-value between the palmitic and stearic acids ([δ13C C18:0] – [δ13C C16:0]). Presence/absence of diterpenoids for estimating the “smoke/soot” effect is marked as x/–.

Table 3 AMS 14C determination of organic temper, organic residue and lipids extracted from pottery. OT—organic temper; OR—organic residue; L—lipids extracted from the pottery (graphitized directly); 3A—triple acid method; AAA—acid-alkali-acid wash method. Where missing (–), specifications for δ13C (‰), pMC and C (%) were not available.

RESULTS

Relative Chronology of the Site and Macroscopic Description of Pottery

Human presence was documented in 7 lithostratigraphic units (Table 1). Upper units (1, 2a, 2b, 2c) contain ceramic material classified as the Early Bronze Age. Unit 2c included a mixed material attributed to the Early Bronze Age and Neolithic (LBK, an abbreviation to Linearbandkeramik or Linear Pottery Culture). Units 3 and 4 contained LBK pottery with several animal bones, human skull, and daub. The unit 5a contained only grass-tempered pottery. Due to post-depositional processes and later settlement activities, LBK ceramics were mixed with the newly discovered grass-tempered pottery in these lithostratigraphic units. The unit 5a contained only grass-tempered pottery (Figure 4).

Figure 4 Grass-tempered pottery from Santovka (Slovakia) analyzed in this study. 1—K23/2014, unit 3; 2—K4/2014, unit 5a; 3—K10/2014, unit 5a; 4—K8/2012, sherd 5a, unit 5a; 5—K8/2012, sherd 3, unit 5a; 6—K8/2012, sherd 5b, unit 5a; 7—K8/2012, sherd 2, unit 5a; 8—K11/2014, unit 3.

Reconstruction of the original vessel forms was not possible, however sherds K8-2 and K8-5 come from the same vessel. None of the grass-tempered pottery bears any signs of decoration enabling typological identification or cultural attribution. The fragments are very fragile. The clay contains a high amount of organic temper, grass stems and leaves (Festuca sp.; Figure 5), that also regularly appear on the smoothed surface of the pottery.

Figure 5 Thin section of grass-tempered pottery from Santovka (Slovakia) in this study. Fine-grained pottery matrix containing leaves of Festuca sp. added as a temper during the formation of vessels. 1—K4/2014 (figure 4:2); 2—K10/2014 (figure 4:3); 3—K8, sherd 2 (figure 4:7); 4—K11/2014 (figure 4:8).

Lipid Analysis

The results of the lipid residue analysis of the three samples selected for 14C dating are presented in Table 2 and Figure 6. These samples were selected since they had good yields of lipids with a distribution of components characteristic of ancient lipid residues and showed very little evidence for recent contamination in the resulting chromatograms and mass spectra. The recovered lipid residues are dominated by a distribution of saturated fatty acids dominated by palmitic acid (C16:0) and the stearic acid (C18:0). All samples contained a distribution of branched fatty acids that can derive from ruminant animal sources or from microbial sources. There is no molecular evidence (dicarboxylic acids, isoprenoid alkanoic acids or ω(o-alkyl phenyl)fatty acids for aquatic lipid residues in these samples. Sample K8-2 and K10 do contain possible traces of the C18 ω(o-alkyl phenyl)fatty acid but that is not alone enough evidence for contribution from aquatic animal lipids. The stable carbon isotope values of the two dominating fatty acids (C16:0, C18:0) clearly indicate a primarily terrestrial origin for these fatty acids. From the molecular analysis of the lipid extracts there is evidence for a potential “smoke/soot” effect on sherd K10; the rest of the sherds are without the evidence of diterpenoids.

Figure 6 Plot of the δ13C values of the major fatty acid components (C16:0 and C18:0) of grass-tempered pottery (red dots) compared to modern reference fats (black dots). Reference values were collected from published studies (Dudd et al. Reference Dudd, Evershed and Gibson1999:3; Copley et al. Reference Copley, Berstan, Dudd, Docherty, Mukherjee, Straker, Payne and Evershed2003:2; Craig et al. Reference Craig, Forster, Andersen, Koch, Crombé, Milner, Stern, Bailey and Heron2007:5; Lucquin et al. Reference Lucquin, Gibbs, Uchiyama, Saul, Ajimoto, Eley, Radini, Heron, Shoda and Nishida2016:ST02) and represent average value (black dot), and the standard error displayed as an error bar.

14C Dating of Grass-Tempered Pottery and Chronostratigraphic Bayesian Modeling

Eight pieces of grass-tempered pottery from lithostratigraphic units 2c, 3, 4, and 5a were selected for AMS 14C dating, returning 14 results. Results of dating by material (organic temper, organic residue and lipids extracted from the pottery) and pretreatment method (triple acid, AAA) are presented in Table 3. The AAA method (7 dates), produced the widest span of dates, ranging from 7310 ± 30 BP to 5810 ± 30 BP. 14C age of the organic residue taken from one the grass-tempered vessel (UGAMS 19701), purified by the AAA method, is 6470 ± 50 BP. The triple acid method (3 dates), produced a more restricted range of dates ranging from 6668 ± 49 BP to 6449 ± 33 BP. The dating of the lipids (3 dates) provided a time span from 7201 ± 35 BP to 6874 ± 34 BP.

Sherds K4, further K8-2 and K8-5 (multiple sherds from the same vessel), K9 and K9B (two fragments from the same sherd) and K10 were subjected to multiple 14C dating, testing various pretreatment methods and dated materials. In the cases of K4, K8-2, K8-5 and K10, the lipids provided much earlier 14C date than dating organic temper. Dates DeA-24370 and DeA-24372 extracted from the organic temper (sherds K8-2 and K8-5) and pretreated by triple acid wash method are very close to each other, although a combination of 14C dates produced a poor agreement (Acomb=13.7%). Dates Beta-425294 and Beta-434617 extracted from the organic temper (sherds K9 and K9B) and pretreated by AAA wash method are much more distant from each other; a combination of dates returned a poor agreement (Acomb=0.0%). These results produce a wide span of dates, with the AAA extraction method showing the most disparate range.

We carried out a chronostratigraphic Bayesian model (Figure 7, Supplement 1.4, 1.5) to test how well the 14C dates from grass-tempered pottery fit within the stratigraphic sequence of the site. Based on the model, the lithostratigraphic unit 5a with only grass-tempered pottery was sedimented after 6152–5882 cal BC (95% probability) and before 5476–5310 cal BC (95% probability). KDE model (Figure 7, Supplement 1.4) shows the grass-tempered pottery existed between 5896–5514 cal BC. From this time span we can reject Beta-429297, Beta-429296 and Beta-429295 whose agreement index is below 60% (Acomb=5.4%, Acomb=32.2%, Acomb=5.5% respectively) and chronologically do not fall within the site stratigraphy.

Figure 7 Chronostratigraphic Bayesian model of the site’s stratigraphy based on 14C data acquired from the grass-tempered pottery (Table 3), published 14C dates from stratigraphic sequence (Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018) and data acquired from the age-depth model Supplement 1.21.5). Red—sherd K4; green—sherds K8-2 and K8-5; blue—sherd K10; purple—sherds K9 and K9B; light gray—unmodeled 14C dates; dark gray—modeled dates from all the other sherds; orange—14C age of sherds based on age-depth model. OT—organic temper; OR—organic residue; L—lipids exctracted from the pottery (graphitized directly); 3A—triple acid wash method; AAA—acid-alkali-acid wash method.

DISCUSSION

Dating of the Grass Temper

There is a considerable chronological distance between 14C data acquired from organic temper obtained by the AAA washing method and their expected age based on the age-depth model (Figure 7, Table 3). Beta-425296 and Beta-425297 are dated a few hundred 14C yr earlier than expected, whereas Beta-429295 is dated later than the expected pottery age, showing a dispersal of almost 2000 14C yr (Table 3). It could be associated with unsuccessful removal of all possible contaminants from the grass-tempered pottery, which has been also demonstrated by past research, as humic acids, due to the high porosity of pottery, can resist the NaOH treatment usually recommended for their extraction (Gillespie et al. Reference Gillespie, Prosser, Dlugokencky, Sparks, Wallace and Chappell1992; Količ Reference Količ1995; Bird et al. Reference Bird, Ayliffe, Fifield, Turney, Cresswell, Barrows and David1999; Bird et al. Reference Bird, Turney, Fifield, Smith, Miller, Roberts and Magee2003; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004; Anderson et al. Reference Anderson, Chappell, Clark and Phear2005). The mentioned dates were also rejected by the chronostratigraphic Bayesian model due to low agreement index (<60%; Supplement 1.5). Only three dates (Beta-425293, Beta-425294, Beta-434617) fall within their expected age according to the age-depth model (combine test results: Acomb=90.4%; Acomb=121.7%, respectively; Supplement 1.5), however these dates are not reliable due to the pretreatment method and because they do not agree with the other dates from the same sherd. The last three mentioned dates were also confirmed by the chronostratigraphic Bayesian model, as their agreement index is above 60% (Supplement 1.5)

Three samples (DeA-24370, DeA-24372 and DeA-24373) were treated with the triple acid wash method proposed by the authors of this study. In all of these cases the dates correspond with a timeframe given by the age-depth and chronostratigraphic Bayesian models (Figure 7; Supplement 1.5). The difference between the AAA treatment and our triple acid method can be shown by sherd K10, from which two 14C dates were obtained (Figure 7). Sample from the grass-tempered pottery treated with the AAA method (Beta-429295) is by 800 yr younger than the sample prepared with our triple acid method (DeA-24373). The unsuccessful removal of contaminants due to the high porosity of pottery when applying the AAA pretreatment method might explain this discrepancy, as mentioned earlier.

Dating of the Lipids

The purpose of 14C dating of lipids was to provide an age which could be directly compared with the dating of the grass temper, since lipid material surviving in cooking pots can provide a 14C age of the vessel usage (Nakamura et al. Reference Nakamura, Taniguchi, Tsuji and Oda2001; Stott et al. Reference Stott, Berstan, Evershed, Hedges, Ramsey and Humm2001; Casanova et al. Reference Casanova, Knowles, Bayliss, Dunne, Barański, Denaire, Lefranc, di Lernia, Roffet-Salque and Smyth2020; Robson et al. Reference Robson, Saul, Steele, Meadows, Otto Nielsen, Fischer, Heron and Craig2021). Lipid analysis of the samples K4, K8-2, K10 indicate that one or more types of substance were cooked in the vessels from Santovka (Table 2, Figure 6). However, in the current state of the research we can not clearly identify the source of the lipid signal. The difference (Δ) in δ13C-value between the fatty acids of all three samples are well within the conventional range for lipid residues of terrestrial fats. However, δ13C16:0 and δ13C18:0 values are closer to wild ruminants (Craig et al. Reference Craig, Forster, Andersen, Koch, Crombé, Milner, Stern, Bailey and Heron2007:7; Papakosta et al. Reference Papakosta, Oras and Isaksson2019:5; cf. Bondetti et al. Reference Bondetti, González Carretero, Dolbunova, McGrath, Presslee, Lucquin, Tsybriy, Mazurkevich, Tsybriy and Jordan2021:4) or acorn (Lucquin et al. Reference Lucquin, Gibbs, Uchiyama, Saul, Ajimoto, Eley, Radini, Heron, Shoda and Nishida2016:ST2). The stable carbon isotope values of the lipid residues fall to the lower end but are not separate from published distributions (e.g., Dudd et al. Reference Dudd, Evershed and Gibson1999:3; Copley et al. Reference Copley, Berstan, Dudd, Docherty, Mukherjee, Straker, Payne and Evershed2003:2; Craig et al. 2007:5, Reference Craig, Allen, Thompson, Stevens, Steele and Heron2012:1; Lucquin et al. Reference Lucquin, Gibbs, Uchiyama, Saul, Ajimoto, Eley, Radini, Heron, Shoda and Nishida2016:ST02).

14C age of lipids proved to be older by 400–600 14C yr than the age of charred grass extracted from pottery by our triple acid method. This difference is even more pronounced when comparing both kinds of dates from sherds K8-2 and K10 (Figure 7). The carbon content (C (%) in Table 3) of sample FTMC-YH59-6, FTMC-YH59-7 is within the expected range for lipids (72–79% C) while it is slightly low for FTMC-YH59-9. This could indicate recent contamination from chlorinated organic with very old carbon, e.g., PVC (ca. 38% C) or chloroform (ca. 10% C). Instead of compound specific approach we are exploring another approach using total lipid extracts, which considers further cleaning steps (such as filtration, ultra filtration and column chromatography). Following that approach, micro-particles of PVC could be suspended in the lipid extracts without being detected by the molecular analysis performed. This is more likely than the retention of the solvent chloroform. We can also exclude the freshwater reservoir effect as a result from the cooking of fish (e.g., Fischer and Heinemeier Reference Fischer and Heinemeier2003; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004; Boudin et al. Reference Boudin, Strydonck, Crombé, Clercq, Dierendonck, Jongepier, Ervynck and Lentacker2010; Hartz et al. Reference Hartz, Kostyleva, Piezonka, Terberger, Tsydenova and Zhilin2012; Miyata et al. Reference Miyata, Horiuchi, Kondo, Onbe, Yoshida, Nagao, Group and Nishimoto2016). Either we can consider (1) an effect of depositional environment or firing of old wood (considering sherd K10 with traces of resinous material; Gabasio et al. Reference Gabasio, Evin, Arnal and Andrieux1986; Hedges et al. Reference Hedges, Tiemei and Housley1992; Bonsall et al. Reference Bonsall, Cook, Manson and Sanderson2002; Mihara et al. Reference Mihara, Miyamoto, Ogawa, Kurosaka, Nakamura and Koike2004; Zaitseva et al. Reference Zaitseva, Skripkin, Kovaliukh, Possnert, Dolukhanov and Vybornov2009), (2) the samples are contaminated by packing materials (e.g., PVC particles), (3) there are other methodological issues yet to be resolved, or (4) all of the above.

A comparison of 14C dated lipids with the age-depth model shows that only sample FTMC-YH59-7 corresponds with their expected age (combine test result: Acomb=76.7%). Samples FTMC-YH59-6 and FTMC-YH59-9 are older than their expected age specified by age-depth model (combine test results: Acomb=1.3%; Acomb=19.3%, respectively). However, all of these samples fall within the range of sedimentation of lithostratigraphic unit 5a, given by the chronostratigraphic Bayesian model (Supplement 1.5).

Comparing various pretreatment methods and 14C dated materials, we judge that the most reliable procedure for pretreating the grass-tempered pottery was the triple acid method, showing an interval of 297 14C yr (68% probability: Table 4).

Table 4 A comparison of time spans (unmodeled) for the pottery from Santovka based on different pretreatment methods and dating of lipids (Amodel=95.1; Aoverall=96.4) calculated in OxCal v.4.4. Input data is based on Table 3. OT—organic temper.

Grass-Tempered Pottery and the Origins of Ceramic Vessels in Central Europe

Absolute dating of grass-tempered pottery from Santovka (Slovakia) fits into the current debate regarding the spread of the Neolithic in Central Europe. According to traditional archaeological narrative, the earliest pottery arrives with first farming communities to migrate into the region (c.f. Bondetti et al. Reference Bondetti, González Carretero, Dolbunova, McGrath, Presslee, Lucquin, Tsybriy, Mazurkevich, Tsybriy and Jordan2021; Nordqvist and Kriiska Reference Nordqvist and Kriiska2015). However, pottery tempered with grass chronologically precedes the emergence of the LBK over a larger area (Jakucs et al. Reference Jakucs, Bánffy, Oross, Voicsek, Bronk Ramsey, Dunbar, Kromer, Bayliss, Hofmann and Marshall2016; 5625–5320 cal BC, 95% probability; 5565–5330 cal BC, 68% probability; Stadler and Kotova Reference Stadler and Kotova2019, table 14.8; 5685–5370 cal BC). To date, there are only a few sites dated to the formative LBK, such as Brunn 2 near Vienna, Szentgyörgyvölgy-Pityerdomb and Zalaegerszeg-Andráshida (Simon Reference Simon2002; Bánffy Reference Bánffy2004; Oross and Bánffy Reference Oross and Bánffy2009:1; Stadler and Kotova Reference Stadler and Kotova2010; Stadler and Kotova Reference Stadler and Kotova2019). The main characteristics of these sites is the absence of fine pottery and use of only coarseware with clear Starčevo elements (Nikitin et al. Reference Nikitin, Stadler, Kotova, Teschler-Nicola, Price, Hoover, Kennett, Lazaridis, Rohland and Lipson2019). Whether there was a presence of the formative LBK north of the Danube has been debated largely from surface finds, but because of a lack of 14C dates in this area, no conclusions could be drawn (Beljak Pažinová and Daráková Reference Beljak Pažinová and Daráková2019). Besides the formative LBK, the grass-tempered pottery from Santovka is broadly chronologically contemporary with Starčevo culture located south of lake Balaton in south-western Hungary (6070–5080 cal BC), and Körös culture (5790–5580 cal BC) from which the Alföld Linear pottery culture developed, particularly its Szatmár phase (5580–5250 cal BC) in the Tisza region of eastern Hungary (Stadler and Kotova Reference Stadler and Kotova2019:table 14.4), all of them tempered with chaff (e.g., Gomart et al. Reference Gomart, Anders, Kreiter, Marton, Oross and Raczky2020).

Given the nature of the grass-tempered pottery, its chronological position, cooking practices and the lack of evidence for human impact in the paleoecological record contemporary with the Pre-Neolithic pottery (Šolcová et al. Reference Šolcová, Petr, Hájková, Petřík, Tóth, Rohovec, Bátora and Horsák2018), we suggest that pots from Santovka were not produced by initial farming population coming from the south, but emerged in the Late Mesolithic context without any apparent links to the Neolithic cultures located south of the Central European-Balkanic agro-ecological barrier (further as CEB-AEB; Bánffi and Sümegi Reference Bánffy and Sümegi2012). Recent research demonstrated that using of pottery by hunter-gatherers suggests seasonal intensification of resource exploitation, broadening subsistence systems, new food traditions, increased sedentism associated with establishing new settlements at highly productive ecotones and population growth, which implies that pottery was under strong social control regulated by culinary practices and spread through a process of cultural transmission (Jordan and Zvelebil Reference Jordan, Zvelebil, Jordan and Zvelebil2009; Nordqvist and Kriiska Reference Nordqvist and Kriiska2015; Oras et al. Reference Oras, Lucquin, Lõugas, Tõrv, Kriiska and Craig2017; Bondetti et al. Reference Bondetti, González Carretero, Dolbunova, McGrath, Presslee, Lucquin, Tsybriy, Mazurkevich, Tsybriy and Jordan2021; Courel et al. Reference Courel, Meadows, Carretero, Lucquin, McLaughlin, Bondetti, Andreev, Skorobogatov, Smolyaninov and Surkov2021; Dolbunova et al. Reference Dolbunova, Lucquin, McLaughlin, Bondetti, Courel, Oras, Piezonka, Robson, Talbot and Adamczak2022). A case from Rakushechny Yar (lower Don valley, Russia), chronologically contemporary with grass-tempered pottery from Santovka, suggests that (1) the knowledge of pottery production was transmitted through contact with farming communities and incorporated into foragers economy, or (2) early farmers moved to this region, but favored wild resources, or (3) pottery production was a local innovation, or (4) was acquired from other hunter-gatherers (Bondetti et al. Reference Bondetti, González Carretero, Dolbunova, McGrath, Presslee, Lucquin, Tsybriy, Mazurkevich, Tsybriy and Jordan2021). Different mechanisms are assumed for Kiçik Tepe (south Caucasus, Azerbaijan), again, from the same timeframe as Santovka pottery. Available archaeological evidence shows that local forager populations had contacts with farming groups during the process of Neolithisation, but these interactions did not cause an abrupt and full adoption of the Neolithic package. It suggests that pottery making technology was re-elaborated and adapted to better suit the needs and cooking practices of foragers (Nishiaki et al. Reference Nishiaki, Guliyev and Kadowaki2015; Palumbi et al. Reference Palumbi, Guliyev, Astruc, Baudouin, Berthon, D’Anna, Decaix, Gratuze, Hamon and Poulmarc’h2021).

However, we might consider other possibilities, as well. The organic tempering at Santovka, yet again different in nature from other hunter-gatherer pottery, could also suggest some links with farming populations located south of CEB-AEB. Contacts between foragers and farmers across the CEB-AEB have remained frustratingly hard to identify, with possible glimpses argued for through lithic exchange networks or blade technology (Gronenborn Reference Gronenborn1990; Reference Gronenborn2003a, Reference Gronenborn2003b, Reference Gronenborn, Whittle and Cummings2007; Mateiciucová Reference Mateiciucová2004, Reference Mateiciucová2008) and a small contribution to the genetic history of the LBK (Lipson et al. Reference Lipson, Szécsényi-Nagy, Mallick, Pósa, Stégmár, Keerl, Rohland, Stewardson, Ferry and Michel2017).

CONCLUSION

Our study shows that prehistoric vessels with organic temper can be successfully 14C dated using appropriate pretreatment procedures. We developed and successfully applied a novel triple acid wash method to extract charred content from grass-tempered pottery, which is the most reliable method to treat this kind of archaeological material. The 14C dates obtained are coherent and were successfully validated through several tests. In comparison to the triple acid method, 14C data from lipids provided earlier age, which is an aspect that needs future attention.

Chronostratigraphic Bayesian modeling shows that grass-tempered pottery from Santovka was made between 5896–5514 cal BC. This time frame makes them the earliest pots north of the Danube, chronologically preceding the period characterised as the formative LBK, and technologically different from the fully developed Neolithic cultures of Danubian origin distributed south of the CEB-AEB.

The most probable explanation is that the grass-tempered pottery from Santovka developed within the context of Late Mesolithic hunter-gatherers. Comparative evidence in Prehistoric Eurasia shows that early pottery is fired in low temperatures, and is very diverse in terms of tempering practices, contrasting with early Neolithic cultures of the Danubian origin. However, the current evidence provides less resolution on the origins of this style of pottery at Santovka. Currently we propose two competing possible options: (1) knowledge of pottery production was acquired from other forager groups of Eurasian origin, or (2) concept of fired-clay containers was adapted from farming communities and was re-elaborated for the needs of forager groups while preserving their mobile way of life and subsistence patterns.

In the future we will further focus on the application of the triple acid wash method in dating Early Neolithic pottery from Slovakia, testing its potential and acquiring more 14C dates, which are lacking in the region. More research is required on the mechanisms underlying the adoption of pottery and the development of pottery making technology during the Neolithic transition. The results presented here add further complexity to the transition to farming by indicating that pottery may predate the arrival of farming subsistence activities and, importantly, shows innovation and adaptation to a hunter-gatherer lifestyle.

ACKNOWLEDGMENTS

Research was funded by the project GAČR GA20-19542S (Tracing the Neolithic transition through the first pottery), Grant Agency of Masaryk University, project APVV-14-0550 (Natura et cultura. The coevolution of mankind and nature between 6th and 2nd millennium BC in the area north of the middle Danube studied on the basis of archaeological and environmental sources) and VEGA 1/0477/11 (Paleoecological reconstruction of the northern part of the Pannonian Plain). We want to express our gratitude to Juraj Lauko, who allowed us to conduct the field activities and collect archaeological material on his property. We want to thank Jozef Bátora for his continuous support during the fieldwork campaigns and initial 14C analysis of pottery material. We thank to Jack Dury for inspirational comments that improved the draft of thestudy. Lastly, we thank two anonymous reviewers whose comments and suggestions improved the final manuscript.

SUPPLEMENTARY MATERIAL

To view supplementary material for this article, please visit https://doi.org/10.1017/RDC.2023.39

References

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Figure 0

Figure 1 A and B: Location of the Santovka site in a wider geographic context; C: location of the documented section on the right bank of the Búr brook; D: fieldwork campaign in 2012. Data sources: A–B—Natural Earth; C—ÚGKK SR.

Figure 1

Figure 2 Stratigraphy sequence of the southern section of the Búr creek showing the position of the lithostratigraphic units. Only grass-tempered pottery was found in unit 5a. Displayed dates are based on the chronostratigraphic Bayesian model (Supplement 1.2, 1.3). The complete cross-section of the Búr creek with the position of 14C dated pottery is shown in Supplement 1.1.

Figure 2

Table 1 Lithostratigraphic development of the section in Santovka and archaeological chronology. P—pottery; B—bone; L—lithics; D—daub; Pre-N—pre-Neolithic; N—Neolithic; BA—Bronze Age (Data sources: Šolcová et al. 2018; Petřík et al. in prep.).

Figure 3

Figure 3 Principle of the novel triple acid wash method.

Figure 4

Table 2 Lipid residue analysis. Lipid content is given in mg lipid extracts per gram ceramic powder. FA describes the fatty acid distribution detected using the format n(m)k where n is the chain-length of the shortest fatty acid detected, m is the chain-length of the most abundant fatty acid in the distribution and k is the chain-length of the longest fatty acid detected. C18:0/C16:0 is the ratio of stearic to palmitic acid. BR is the carbon chain lengths registered for branched chained fatty acids. DA is dicarboxylic acids, OHFA is hydroxy-fatty acid, LCK is long-chain ketones, isoprenoid is isoprenoid fatty acids, APFA is ω(o-alkyl phenyl)fatty acids, δ13C C16:0 and δ13C C18:0 are the δ13C-values of the palmitic and stearic acids, respectively. Δ is the difference in δ13C-value between the palmitic and stearic acids ([δ13C C18:0] – [δ13C C16:0]). Presence/absence of diterpenoids for estimating the “smoke/soot” effect is marked as x/–.

Figure 5

Table 3 AMS 14C determination of organic temper, organic residue and lipids extracted from pottery. OT—organic temper; OR—organic residue; L—lipids extracted from the pottery (graphitized directly); 3A—triple acid method; AAA—acid-alkali-acid wash method. Where missing (–), specifications for δ13C (‰), pMC and C (%) were not available.

Figure 6

Figure 4 Grass-tempered pottery from Santovka (Slovakia) analyzed in this study. 1—K23/2014, unit 3; 2—K4/2014, unit 5a; 3—K10/2014, unit 5a; 4—K8/2012, sherd 5a, unit 5a; 5—K8/2012, sherd 3, unit 5a; 6—K8/2012, sherd 5b, unit 5a; 7—K8/2012, sherd 2, unit 5a; 8—K11/2014, unit 3.

Figure 7

Figure 5 Thin section of grass-tempered pottery from Santovka (Slovakia) in this study. Fine-grained pottery matrix containing leaves of Festuca sp. added as a temper during the formation of vessels. 1—K4/2014 (figure 4:2); 2—K10/2014 (figure 4:3); 3—K8, sherd 2 (figure 4:7); 4—K11/2014 (figure 4:8).

Figure 8

Figure 6 Plot of the δ13C values of the major fatty acid components (C16:0 and C18:0) of grass-tempered pottery (red dots) compared to modern reference fats (black dots). Reference values were collected from published studies (Dudd et al. 1999:3; Copley et al. 2003:2; Craig et al. 2007:5; Lucquin et al. 2016:ST02) and represent average value (black dot), and the standard error displayed as an error bar.

Figure 9

Figure 7 Chronostratigraphic Bayesian model of the site’s stratigraphy based on 14C data acquired from the grass-tempered pottery (Table 3), published 14C dates from stratigraphic sequence (Šolcová et al. 2018) and data acquired from the age-depth model Supplement 1.21.5). Red—sherd K4; green—sherds K8-2 and K8-5; blue—sherd K10; purple—sherds K9 and K9B; light gray—unmodeled 14C dates; dark gray—modeled dates from all the other sherds; orange—14C age of sherds based on age-depth model. OT—organic temper; OR—organic residue; L—lipids exctracted from the pottery (graphitized directly); 3A—triple acid wash method; AAA—acid-alkali-acid wash method.

Figure 10

Table 4 A comparison of time spans (unmodeled) for the pottery from Santovka based on different pretreatment methods and dating of lipids (Amodel=95.1; Aoverall=96.4) calculated in OxCal v.4.4. Input data is based on Table 3. OT—organic temper.

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