Vol.: (0123456789) 1 3 Afr Archaeol Rev (2023) 40:647–672 https://doi.org/10.1007/s10437-023-09534-9 ORIGINAL ARTICLE A Holocene Ceramic Sequence in the Central Sahara: Pottery Traditions and Social Dynamics Seen from the Takarkori Rockshelter (SW Libya) Rocco Rotunno  · Lucia Cavorsi · Savino di Lernia Accepted: 23 May 2023 / Published online: 1 August 2023 © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2023 Abstract This article presents the Early and Mid- dle Holocene pottery repertoire of the Takarkori archaeological site, a rockshelter in the Tadrart Aca- cus massif in southwestern Libya, Central Sahara. This long sequence, extending from 10,200 to 4300 cal BP, is one of the best preserved Holocene con- texts in North Africa, recording much of Holocene cultural evolution and chronologically framed by a large number of radiocarbon dates. The study of the assemblage resulted in a well-defined seriation of the pottery sequence, supported by statistical and com- parative methods. Following an integrated approach, the study identifies continuities and changes in ceramic production that enhance our understanding of the human occupation of Takarkori and its cultural variations. The multi-scalar and multi-dimensional perspectives highlight technological traditions and cultural dynamics and provide new insights into the origin and use of pottery, first among Late Acacus hunter-gatherers and later among Pastoral Neolithic herders and their regional interconnections. This study clarifies the position of the Takarkori ceramic sequence within the broader regional and interre- gional contexts from the Early to the Middle Holo- cene. By indicating contacts and interrelationships among different areas of the Sahara and neighboring regions, from the massifs of Central Algerian Sahara to the plains of the Eastern Sahara, the study adds new insights into North Africa’s prehistory. It con- tributes to an increasingly accurate reconstruction of the Holocene’s chronological and cultural sequences. Résumé Le présent article décrit le répertoire de poteries de l’Holocène ancien et moyen du site ar- chéologique de Takarkori, un abri sous roche situé dans le massif de Tadrart Acacus, dans le sud-ouest de la Libye, au Sahara central. Cette longue séquence, qui s’étend de 10200 à 4300 cal. BP, est l’une des mieux préservées de l’Holocène nord-africain dans son ensemble, enregistrant une grande partie de son évolution culturelle et garantie par un grand nom- bre de dates radiocarbones. ’étude de l’assemblage a achevé à une sériation bien définie de la séquence de poterie, soutenue par des méthodes statistiques et comparatives. En suivant une approche intégrée, l’étude a identifié des continuités et des changements dans la production de céramique qui améliorent notre compréhension de l’occupation humaine de Takarkori et de ses variations culturelles. La perspective multi- scalaire et multi-dimensionnelle a mis en évidence des attributs fournissant des données sur les traditions R. Rotunno (*) · S. di Lernia  Dipartimento di Scienze dell’Antichità, Sapienza University of Rome, Rome, Italy e-mail: rotunno.rocco@gmail.com L. Cavorsi  The Archaeological Mission in the Sahara, Sapienza University of Rome, Rome, Italy S. di Lernia  GAES, University of Witwatersrand, Johannesburg, South Africa http://crossmark.crossref.org/dialog/?doi=10.1007/s10437-023-09534-9&domain=pdf http://orcid.org/0000-0001-9235-8082 https://orcid.org/0000-0003-1732-1567 648 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) technologiques et la dynamique culturelle, offrant de nouvelles perspectives sur l’origine et l’utilisation de la poterie, d’abord chez les chasseurs-cueilleurs de l’Acacus Tardif (Late Acacus), puis chez les élev- eurs du Néolithique pastoral et sur leurs interconnex- ions régionales. Cette étude clarifie la position de la séquence céramique de Takarkori dans le contexte régional et inter-régional plus large de l’Holocène pré- coce à l’Holocène moyen. En indiquant les contacts et les rapports entre les différentes zones du Sahara et les régions voisines, des massifs du Sahara central algérien aux plaines du Sahara oriental, elle ajoute des nouvelles informations à notre connaissance actuelle de la préhistoire de l’Afrique du Nord et contribue à une reconstruction et à une définition de plus en plus précise de ses aspects chronologiques et culturels. Keywords Pottery · Holocene · Foragers · Herders · Central Sahara Introduction Africa is home to one of the world’s oldest pottery traditions. The archaeological sequences in Africa have yielded very early dates that place the emer- gence of this material class at around the beginning of the Early Holocene (Huysecom, 2020; Huysecom et  al., 2009; Jesse, 2010). The origin of pottery in Africa is still disputed, both chronologically and geographically. It is generally accepted that the earliest African pottery was produced by human groups with an extractive economy, an occurrence that finds parallels elsewhere in the world (Craig, 2021; Craig et  al., 2013; Jordan & Zvelebil, 2010; Kim & Seong, 2022; Wu et al., 2012). To date, the oldest African pottery comes from sites in the Sahel, southern Sahara, and the Nile Val- ley (D’Ercole, 2021; Huysecom, 2020). Potsherds from Ounjougou in Mali are associated with dates as early as 11,400–10,800 cal BP (e.g., Huysecom, 2020; Huysecom et al., 2009 [All dates in this article are calibrated using OxCal 4.4, with the last calibra- tion curve IntCal20—95.4% probability, Bronk Ram- sey, 2009; Reimer et al., 2020]). Tagalagal and Adrar Bous in southern Sahara, Niger (Jesse, 2003a; Roset, 2000) and Sarourab and Bir Kiseiba, in Sudan’s Nile Valley and Egypt’s Western Desert, respectively, have yielded pottery specimens in layers dated to between 11,000 and 10,100 cal BP (Hakem & Khabir, 1989; Jordeczka et al., 2011). In the Central Sahara, specifically the Tadrart Acacus, pottery-bearing contexts can also be placed in the early Holocene. However, the dates are more recent and probably related to population diffusion dynamics and migratory drifts (for a recent synthe- sis, see di Lernia, 2022). The lowest pottery-bearing layer at Takarkori is dated ca. 10,200 cal BP (Cher- kinsky & di Lernia, 2013), matching those at Ti-n- Torha Two Caves, Ti-n-Torha East, Uan Afuda, and Uan Tabu (Barich, 1974, 1987a; di Lernia, 1999; Garcea, 2001a). Ti-n-Hanakaten and Amekni, in the Algerian Tassili and Ahaggar, respectively, date roughly to the late tenth millennium and early ninth millennium cal BP (Aumassip & Delibrias, 1982; Camps, 1969, Fig. 1). Pottery represents an extraordinary material through which the various social and cultural enti- ties in the Holocene greater central Sahara can be disentangled. Presenting some degree of stylistic and technological similarity over large geographi- cal and temporal areas, yet regionally diversified, the ceramic production from the earliest Holocene up to the Middle Holocene serves as an indicator of cul- tural spheres, mobility strategies, settlement organiza- tions, and exchange patterns (e.g., Caneva & Marks, 1990; Jesse, 2010; Keding, 2017; Salvatori, 2012). The study of pottery allows us to answer numerous questions regarding chronology, regional and inter- regional contacts and traditions, resource exploitation, and social formation processes. Here, we present an account of the pottery assemblage of the Takarkori rockshelter, which offers information on one of the longest and most complete sequences of the Holocene Central Sahara, thanks to its well-preserved deposits, the meticulous excavation strategy employed, and the large dataset of 14C dates. The Takarkori Rockshelter: Archaeological and Cultural Sequence The Takarkori rockshelter is located in the wadi of the same name, which connects the Tanezzuft val- ley with the eastern foothills of the Tadrart Acacus massif, near the current Libyan-Algerian border. The shelter is roughly 70 m long and runs north-south on a terrace of over 2200 m2. It opens to the west and 649Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) is bounded to the east by a 30-m-high rock wall. The location at 1100 m above sea level, and 150 m above the valley below, is in correspondence with a major mountain pass between the Tadrart Acacus in Libya and the Algerian Tadrart and adjacent to a paleolake basin (Biagetti & di Lernia, 2013). The depression, Ghat Uan Tabu Uan Muhuggiag Nabta Playa Germa Takarkori Geographical feature Major riv e) Approximate actual extent of the Sahara Acacus Country NameLibya Archaeological site Town/City Tibesti Ahoggar Air Ennedi Tassili N’Ajjer Ta dr ar t A ca cu s Messak Setaffet Libya Algeria Tunisia Chad Niger Mali Sudan Egypt Mediterranean Sea Wadi Howar Germa Ghat Fig. 1 Map of North Africa with the location of places mentioned in the text and the Tadrart Acacus and Tassili N’Ajjer area (by RR) 650 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) currently filled by an endorheic basin, was fed by a complex hydrographic system originating from the Algerian Tassili that remained active until the onset of more arid climatic conditions at the end of the Middle Holocene (Cremaschi et  al., 2014). During the African Humid Period (AHP), the area was home to a rich variety of flora and fauna thanks to the moist conditions, very different from the current hyper-arid climate with annual precipitation below 25 mm (Cre- maschi et  al., 2014; Fornaciari et  al., 2018; Zerboni et al., 2015). The archaeological deposits were excavated during four field seasons (2003–2006) in four areas: Main, Northern, Western, and Southern Sectors (Fig.  2). The bedrock was reached only in the Northern Sec- tor, where the stratigraphy was 1.6 m thick, whereas the excavation stopped in the other sectors before reaching the bedrock because of conservation con- siderations (Biagetti & di Lernia, 2013, Fig. 2c). The excavations brought to light the remains of a long human occupation divided into four principal cul- tural phases: Late Acacus (LA), Early Pastoral (EP), Middle Pastoral (MP), and Late Pastoral (LP), cover- ing the Early and Middle Holocene. An analysis of the differences in the numerical dis- tribution of archaeological features, the sequence and relationships between stratigraphic units, and the sta- tistical analysis of 14C measurements (Cherkinsky & di Lernia, 2013; Table  1) made it possible to further divide the main cultural horizons into sub-phases (Bia- getti & di Lernia, 2013; Table 2). These form the main chronological framework referred to in this article. The occupation started with the so-called Late Acacus dwellers, subdivided into three sub-phases. The bottom of the sequence relates to the LA1 occupation, which, though reached only in the Northern Sector, contained important features indicating an intensive occupation of the shelter by hunter-gatherer-fishers. The dates associated with this sub-phase fall within 10,200–9500 cal BP. The subsequent Late Acacus 2 (LA2) and Late Acacus 3 (LA3) occupations, respectively 9500–8600 and 9000–8000 cal BP, represent the bulk of the early Holocene occupation (Cherkinsky & di Lernia, 2013). Characterized by a complex palimpsest of long-lasting N S unexcavated area LP MP EP LA 0 5050 cm a b c d e f h g Key SOUTHERN SECTOR WESTERN SECTOR MAIN SECTORNORTHERN SECTOR DRIP LINE SHELTER’S WALL A A’ a) b) c) C14 C14 C14 C14 C14 i 9550-8800 calBP (GX-31072) 8180-7740 calBP (GX-31064) 5920-5650 calBP (LTL-907A) 5670-5460 calBP (LTL-908A) Fig. 2 The Takarkori rockshelter: a general view from the East (photo: The Archaeological Mission in the Sahara); b DEM and location of the excavated sectors; c main sector N-S stratigraphic profile (key: a eolian sand; b dung; c ash layer; d hearth; e organic sand with a variable amount of organics; f humified organic sand; g organic sand; h floor, hardened organic sand; i radiocarbon dates) (see Table 1) 651Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) Table 1 Selection of radiocarbon dates and calibrations (according to OxCal online version 4.4.4 (Bronk Ramsey, 2009), and calibration curve IntCal 20 (Reimer et al., 2020)) from the Takarkori rockshelter (modified from Biagetti & di Lernia, 2013; Cherkinsky & Di Lernia, 2013; Cremaschi et al., 2014) Lab sample Material Age Calibrated yrs BC (95.4% confidence) Calibrated yrs BP (95.4% confidence) Cultural attribution/subphase LTL670A Human bone 4291±50 3090–2700 5040–4650 Late Pastoral (LP1) GX-30325 Dung 4800±70 3710–3370 5660–5320 Late Pastoral (LP1) LTL908A Coprolite 4841±50 3750–3510 5670–5460 Late Pastoral (LP1) LTL907A Charcoal 5064±55 3970–3710 5920–5650 Middle Pastoral (MP2) UGAMS#10149 Dung 5170±25 4003–3951 5990–5900 Middle Pastoral (MP2) UGAMS#01841 Collagen 5340±50 4330–4040 6280–5990 Middle Pastoral (MP2) GX-31077 Bone collagen 5600±70 4600–4330 6550–6280 Middle Pastoral (MP1) GX-30324-AMS Human bone 6090±60 5210–4840 7160–6790 Middle Pastoral (MP1) UGAMS#01842 Collagen 6230±90 5470–4940 7420–6890 Early Pastoral (EP2) GX-31074-AMS Human bone 6540±70 5630–5370 7570–7310 Early Pastoral (EP2) GX-31073-AMS Human bone 6740±70 5760–5520 7710–7470 Early Pastoral (EP2) LTL1585A Human bone 6763±55 5750–5560 7700–7510 Early Pastoral (EP2) GX-31075-AMS Human bone 6900±70 5980–5660 7930–7610 Early Pastoral (EP1) LTL911A Human bone 7068±100 6210–5730 8160–7670 Early Pastoral (EP1) GX-30326 Dung 7070±100 6210–5730 8160–7680 Early Pastoral (EP1) GX-31064 Soil 7130±100 6230–5800 8180–7750 Early Pastoral (EP1) LTL1586A Human bone 7155±65 6210–5890 8160–7840 Early Pastoral (EP1) GX-31069 Soil 7580±110 6650–6230 8590–8180 Late Acacus (LA3) LTL369A Charcoal 7694±60 6640–6440 8590–8390 Late Acacus (LA3) LTL364A Charcoal 7801±35 6700–6510 8650–8450 Late Acacus (LA2) LTL368A Charcoal 8031±65 7140–6690 9090–8640 Late Acacus (LA2) LTL366A Charcoal 8049±40 7140–6820 9030–8760 Late Acacus (LA2) GX-31072 Charcoal 8290±140 7600–6850 9550–8800 Late Acacus (LA2) UGAMS#10150 Charcoal 8410±30 7553–7452 9520–9400 Late Acacus (LA2) UGAMS#01844 Charcoal 8820±60 8220–7720 10,170–9670 Late Acacus (LA1) Table 2 Chronology of the main chrono-cultural phases and their sub-phases identified in the Takarkori area (modified after Cherkinsky & di Lernia, 2013, and Biagetti & di Lernia, 2013). The calibrated dates express the maximum chronologi- cal range and overlap are statistically possible. For the calibra- tion: OxCal online version 4.4.4 (Bronk Ramsey, 2009; Reimer et al., 2020) Cultural phase Sub-phase uncal BP cal BCE cal BP* Chronology Late Pastoral (LP) LP1 5000–4000 3950–2350 5900–4300 Middle Pastoral (MP) MP2 5500–5000 4450–3700 6400–5600 MP1 6100–5500 5200–4250 7100–6200 Early Pastoral (EP) EP2 6900–6400 5900–5300 7800–7300 EP1 7400–6900 6400–5700 8300–7600 Late Acacus (LA) LA3 7900–7400 7050–6100 9000–8000 LA2 8500–7900 7600–6650 9500–8600 LA1 8900–8500 8250–7500 10,200–9400 652 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) occupations, the study of the social and economic aspects of this phase greatly enhanced our understand- ing of this cultural entity within a broader regional context. Highly formalized stone structures identified as huts, pens, and stone alignments indicate a struc- tured site arrangement (Biagetti & di Lernia, 2013; Rotunno et al., 2019; Scancarello et al., 2022). These, together with floors and organic sand accumulations yielding numerous artifacts and ecofacts, testify to an intense and prolonged occupation (Biagetti & di Ler- nia, 2013). An advanced delayed-return strategy of resource exploitation distinguishes the LA, as attested by the penning of wild Barbary Sheep (Rotunno et al., 2019) and the cultivation and storage of wild cereals (Dunne et al., 2016; Mercuri et al., 2018). This cultural phase sees the introduction and widespread use of pot- tery and lithic assemblages characterized by micro- liths, increased macrolithic components, and grinding equipment (di Lernia, 2022). The Early Pastoral (8300–7200 cal BP) is linked with the first, and among the oldest, evidence for domesticated animal species in the African continent, dated to the arid interval of 8300–8000 cal BP (di Lernia, 2021). The herding of domestic livestock is complemented by mul- tispectral resource exploitation (Van Neer et  al., 2020), which, together with specific funerary customs, repre- sents one of the principal features of this cultural phase (di Lernia & Tafuri, 2013). The Takarkori rockshelter was used intensively as a burial ground throughout this occupational phase, differentiated into two sub-phases, Early Pastoral 1 (EP1) (8300–7600 cal BP) and Early Pastoral 2 (EP2) (7800–7300). Alongside the funerary evidence, the occupation features pits, fireplaces, stone structures, and a varied and rich material culture (Scan- carello et al., 2022). A short arid phase separates the Early from the Mid- dle Pastoral, signaled by decreased hygrophilous plants in the sequences (Cremaschi et al., 2014). The Middle Pastoral is divided into two sub-phases: Middle Pasto- ral 1 (MP1) and Middle Pastoral 2 (MP2). The Middle Pastoral chronology ranges from 7100 to 5600 years cal BP. This highly distinctive cultural phase saw the presence of mobile herders with a settlement strategy focused on the intensive use of lakeside areas during the wet season (summer) and a move to the mountain ranges during the dry winter, indicating vertical sea- sonal transhumance (di Lernia & Biagetti, 2007). A fully pastoral economy is attested by dairy products, as suggested by the analysis of lipid residues on pottery (Dunne et  al., 2012, 2013). The funerary evidence is heterogenous (di Lernia & Tafuri, 2013). The Takar- kori sequence ends with a Late Pastoral occupation, here limited to Late Pastoral 1 (LP1, 5900–4300 cal BP), one of the two sub-phases into which this period is subdivided in the regional context (e.g., Biagetti & di Lernia, 2013; Cremaschi & di Lernia, 1998; Gar- cea & Sebastiani, 1998). Groups of nomadic shep- herds accompanied by their herds occupied the shelter for short periods on a seasonal basis, as evidenced by hearths, burials, artifacts, and numerous ecofacts (e.g., Rotunno et al., 2020). Materials and Methods A total of 2944 potsherds were retrieved from all the excavation sectors and are considered here, excluding the surface collection already studied (Biagetti et al., 2004; Table 3). The analysis of the pottery assemblage adopted a holistic and integrated approach, combining typo-sty- listic, morpho-technological, and contextual aspects of ceramic production. This multifaceted approach combines methods and insights from ceramic ecology, Table 3 Potsherds distinguished by sector and chronology (the number of samples used in the archaeometric study is in brackets, modified after Eramo et al., 2020) No. of potsherds (samples) Main sector Northern sector Western sector Southern sector Surface collection Total 2149 (63) 173 (6) 202 18 402 2944 (69) LA 490 (15) 130 (5) 23 - - - 29 - - (20) EP 635 (19) 16 (1) - - - 34 - - (20) MP 829 (22) 28 - 179 - - - 187 - - (22) LP 172 (7) - - - - 18 - 36 - - (7) Unclassified 25 - - - - - - - 116 - - - 653Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) behavioral archaeology, and chaîne opératoire (e.g., Duistermaat, 2017; Garcea, 2005; Rice, 2015; Roux, 2016, 2019; Skibo & Schiffer, 2008, 2001) to identify diachronic changes in the production system within social groups and technological variations between social entities at a regional and macro-regional scale. Reconstructing pottery production may help to evalu- ate the social behavior underlying technical and social choices made in different spatiotemporal contexts and provide information about the people who produced and used the resulting items. The technological features were analyzed using macroscopic and microscopic approaches, following the principles and parameters of the relevant litera- ture (e.g., Orton & Hughes, 2013; Rice, 2015; Roux, 2019; Rye, 1981; Skibo, 2015). An in-depth study of tempers and fabrics based on archaeometric and pet- rographic characterization has already been published elsewhere (Eramo et  al., 2014, 2020), and it under- pins the observations on technology and manufactur- ing reported here. That study used standard pottery analyses (optical microscopy, X-ray powder diffrac- tion, X-ray fluorescence) and digital image processing of polarized light photomicrographs to address issues relating to provenance and the technology of pottery production combined with the characterization of clay sediment samples (Eramo et al., 2020). The decorations and typologies of the repertoire were studied following the guidelines established by Caneva (Caneva, 1987; Caneva & Marks, 1990), used in studies of North African pottery (e.g., D’Ercole, 2017; Garcea, 2008, 2013; Gatto, 2002; Jesse, 2003b, 2010; Mohammed-Ali & Khabir, 2003; Nelson, 2002), appropriately expanded and adapted to reflect the spe- cificities of the assemblage under consideration. This method emphasizes the role of technique, assuming that the object or the tool, together with the gesture and the method employed, may reflect stylistic and technologi- cal differences arising from social and cultural choices (Caneva, 1989; Gosselain, 1992b, 2000; Livingstone Smith, 2007; Roux, 2019). These attributes can be eas- ily identified even on small fragments, which comprise most Saharan collections, consisting of partially to highly fragmented ceramics. Additionally, this system, more or less modified by various scholars and adopted in many Africanist pottery studies (Ashley & Grillo, 2015; Caneva et  al., 1993; CISEM II, 2004; Comme- lin et al., 1992; di Lernia, 1999; Dittrich, 2015; Jesse, 2003b; Keding, 2006; Salvatori, 2012), aims to create a shared language and framework to facilitate cross- cultural and trans-geographical comparisons and thus permit broad chrono-cultural evaluations. The analysis of vessel shapes followed a geomet- ric approach, where the terms used refer to figures of the solid geometry and to intended functional classes (for example, Orton & Hughes, 2013; Shep- ard, 1974). Shapes are defined as closed or restricted (R) when the orifice is smaller than the total height, as open or unrestricted (U) when it is not. These are estimates based on comparing the few more or less complete forms and the diagnostic sherds’ inclina- tion and wall layout, given the limited and highly fragmented state of the sherd assemblage. Descriptive and multivariate statistical analyses were performed on the dataset using specific software (SPSS vs. 27; PAST vs.4.2; ([Hammer et al., 2001]) to assess the principal attributes of the pottery, including shape, decoration, and technological features. Specifically, correspondence analysis was used because it offers an easy and accurate way of analyzing and quantifying multivariable data by bringing data into the sequence when they follow a unimodal model (Bellanger et  al., 2006; Greenacre, 2010; Nielsen, 1991; Smith & Nei- man, 2007). It has the potential to assess the reliability of the chronostratigraphic reconstruction and to increase its chronological resolution. In addition, the correspond- ence analysis in this article seeks to scrutinize the seri- ation proposed and some of the significant associations between the attributes of the pottery. Sherds are the units of observation in association with other independent variables/attributes, including the type of decoration, the pertaining layer, and the occupation phase deduced from the stratigraphic context. This allows us to assess the chronological-diagnostical significance of the vari- ous decoration techniques, and the sequence of decora- tions obtained from the stratigraphic analysis (Peeples & Schachner, 2012). Results Attributes, Frequency, and Descriptive Statistics Technological Features The pottery from Takarkori is made by hand with- out employing rotating kinetic energy (Roux, 2019). Firing processes were directly and indirectly 654 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) evaluated. The estimated firing temperature, assessed based on mineralogical analysis and microstructural alterations (Eramo et  al., 2020), was 500–800 °C. The oxidation patterns on the pot- sherds indicate a reducing atmosphere during the firing and cooling stages. The surface colors signal differences between the Early and the Middle Holo- cene assemblages. The surfaces of Late Acacus pots range from dark brown to gray (from 2.5 YR 3/3 to 10YR 3/2), indicating a reducing firing and cool- ing atmosphere; those of the EP range from dark brown (7.5YR 3/2) to dark reddish brown (5YR 3/2 to 5YR 4/3). MP and LP potsherds are more hetero- geneous in color, in the red and brown range (from 5YR 3/4 to 10YR 3/4), related to a more oxidiz- ing atmosphere. The frequent presence of a “black core” among the specimens indicates that after ini- tial reducing conditions, the vessels underwent an oxidizing stage, either when the fire was opened or during the final cooling process (Gliozzo, 2020; Gosselain, 1992a; Maritan et al., 2006). The fabrics presented considerable variability and were assigned to macro-fabric groups based on the mac- roscopic observation of (i) the amount and quality of inclusions and (ii) the degree of refinement (Orton & Hughes, 2013, p. 74 ff.; 273 ff.; Fig. 3a). The five groups are as follows: (1) Fine: Fine-grained and compact fabric with a mini- mal quantity of small mineral (sandy) and fibrous (vegetable) inclusions barely visible to the naked eye (up to 0.1 mm). Fig. 3 Technological and manufacturing features: a examples of semi-fine and coarse fabrics; b biplot graph of correspondence between macro-fabrics and petrofabrics (processing on Past v.4.3 by RR) Q QVe QA QKa QF QFKa Fine Semifine Semifine w mica Semicoarse w mica Coarse -4.5 -3.0 -1.5 1.5 3.0 4.5 6.0 7.5 -4.5 -3.0 -1.5 1.5 3.0 4.5 6.0 5 mm5 mm Se m ifi ne C oa rs e 6.0 a) b) 655Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) (2) Semi-fine: fine and compact groundmass with a medium quantity of small/fine (0.1–0.25 mm) to medium (0.25–05 mm) vegetable and mineral (sandy) inclusions and fairly sorted. (3) Semi-fine with mica: a low to medium quantity of small/fine (0.1–0.25 mm) to medium (0.25–0.5 mm) vegetable and mineral inclusions with sig- nificant mica flakes scattered in the matrix and fair sorting. (4) Semi-coarse with mica: a medium to high quantity of small medium to large (0.1–1 mm) vegetable (rare) and/or mineral inclusions with frequent mica flakes (biotite) and poor sorting. (5) Coarse: large quantities of small to large (0.2–1.5 mm) vegetable (sporadic) and mineral inclusions and poor sorting. As shown in the biplot graph (Fig.  3b), these groups broadly match the six petrofabrics identified by archaeometric analysis (see Eramo et al., 2020 and references therein for further discussion): • Q* (Q, QVe, QA, QKa): quartz and sandstone- related raw materials, with the differential pre- ponderance of quartz (Q), carbonized vegetable (Ve), mudstone (A), or calcareous (Ka) inclu- sions. • QF* (QF, QFKa): plutonic rock-related raw materials, with the prevalence of some calcare- ous (Ka) inclusions distinguishing between the two sub-groups. Overall, Q* petro-fabrics compare with Groups 1, 2, and 3 of the macro-fabrics, and QF* petro-fab- rics with groups 3, 4, and 5, suggesting a time- and culture-sensitive polarization in the production and use of specific raw materials and fabrics. The Early Holocene production of the LA tradition is mostly characterized by semi-coarse and coarse fabrics with sub-millimetric and millimetric micaceous and mineral inclusions. Finer fabrics, more often organic-rich matrixes and inclusions, are mostly used in the Middle and Late Pastoral (Fig. 3). Body thickness also presents a chronological trend, with LA and EP specimens having thicker walls on aver- age. In contrast, the Middle Pastoral production shows a clear decrease in wall thickness linked to the presence of slightly more closed and lighter vessels (Table 4). Ta bl e 4 P rin ci pa l t ec hn ol og ic al a ttr ib ut es o f th e Ta ka rk or i p ot te ry p ro du ct io n by c hr on ol og ic al p ha se ( pe rc en ta ge r ef er s to th e gr an d m ax im um o f 25 42 w ith th e ex cl us io n of su rfa ce c ol le ct io n Pr ep ar at io n Fo rm in g Co lo r ( fir in g) M ac ro fa br ic 1/ fin e M ac ro fa br ic 2/ se m ifi ne Se m ifi ne m ic a Se m ic oa rs e m ic a Co ar se Av er ag e b od y th ick ne ss M ax b od y th ick ne ss M in b od y th ick ne ss G ra ys fr om 2 .5 Y R 3/ 3 to 1 0Y R 3/ 2 D ar k br ow ns (7 .5 Y R 3/ 2) D ar k re dd ish b ro w n (5 Y R2 ,5 /2 -3 /4 ) Br ow ns (2 ,5 Y R 2, 5/ 1- -7 ,5 Y R5 /4 ) Re ds (1 0Y R ¾ ) LA 0% 9% 10 % 50 % 31 % 10 24 7 19 % 37 % 21 % 16 % 7% EP 4% 58 % 10 % 17 % 11 % 8 27 4 14 % 24 % 34 % 23 % 5% M P 5% 74 % 9% 10 % 3% 7 18 3 12 % 20 % 22 % 27 % 19 % LP 5% 67 % 14 % 12 % 1% 7 13 4 13 % 25 % 27 % 27 % 8% 656 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) Shapes and Morphology During the LA, the main shapes are simple, slightly restricted vessels with a spherical (Rs, 36%) or coni- cal (Rc, 45%) profile (Fig. 4 and Table 5). Both are also present in the EP when a good percentage is rep- resented by restricted Rr vessels with a short collar. Though less frequently, these simpler shapes, Rs and Rc, are also present in the subsequent MP and LP phases. The bulk of the assemblages in the MP and LP phases could be assigned to Rr (50% and 38%, respectively), with a reverted expanded rim often forming a short collar. These shapes are typical of Middle Pastoral chronologies and are also attested in other contemporaneous assemblages together with rare necked types (Barich, 1987a; Cremaschi & di Lernia, 1998; Garcea & Sebastiani, 1998; Ponti et al., 1998). Necked jars are also representative of Pastoral Rs Rc restrcited conical vessel with straight slightly convergent contour and straight rounded or flattened rim restrcited spherical-co- nical vessel with convergent contour and straight rounded rim restrcited globular/- spherical vessel with everted thickened rim of short collar Rr restrcited globular vessel (jar) with short vertical or flaring neck Rn Us Ud simple shallow hemisperical vessel (bowl) with rounded or thinned rim. deep hemishperical vessel with slightly convex walls and straight or inverted rounded/thinned rim. Closed/Restricted Open/Unrestricted re ve rte d ev er te d st ra ig ht thinned rounded flattened thickend/ modelled Rim types Fig. 4 Shapes and morphology of the Takarkori pottery (scale 5 cm) 657Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) pottery, in particular of the MP and LP phases. There are fewer open forms, though almost evenly spread among the principal chronological phases (under 10% in every phase, Table  5). Two kinds can be distin- guished (Fig. 4): a shallow, medium-sized (18–20 cm in diameter) bowl (Us) and a medium-sized (12–30 cm in diameter) hemispherical deep bowl (Ud). Chronological trends are also apparent in the rim out- line: LA production is characterized by a preponder- ance of simple rounded straight or slightly reverted rims, features which also partially characterize the EP vessels. The Middle Pastoral and Late Pastoral pot- tery present more everted or thickened rims. Decoration The decorative types include impressed and incised decorations, with a clear preponderance of the former. Among the impressions, the rocker technique is com- mon in the earlier production, whereas alternately piv- oting stamp (APS) is common in the Pastoral phases. These two techniques and the implements used (mul- tiple-toothed combs, 2-toothed comb, and plain edge tools) determine the main decorative types identified. They are inserted into the taxonomic tree, following the Caneva system, with motifs and structures defining the varieties (Table 6). The LA1 assemblage presents a limited number of types and varieties, with rocker-packed dotted zig- zags (RPD) being the most common (>86%, Table 7) (Fig.  5). The patterns are created with evenly serrated edge tools and belong to two varieties: small rounded dots and large coarse dots (Fig.  6: 1–3). The comb teeth used for the decorations are large, 3–9 cm long, and have many notches. The LA2 subphase yielded numerous potsherds. The most common decoration is rocker-packed dotted zigzags in continuous lines, RPD_ct (>39%), with a slight preference for variety b with coarser and larger dots, created by an instru- ment with ten or more notches (Fig. 6: 4). The Dotted Wavy Line (DWL) is the second most frequent decora- tion (~13%), present in all its varieties (Fig. 6: 5–7), in particular, DWL_b (long waves, Fig. 6: 6) and DWL_c (short flat wave, Fig. 6: 7). DWL_a, with very short and small wave impressions applied to the rim band area, is relatively rare and sees its peak in the subsequent LA3. Like the sherds bearing the RPD pattern, numerous pot- sherds present a rocker plain-edged decoration on the lips. DWL-decorated vessels sometimes have an RPL motif on the rim band (the area just below the rim) fol- lowed by the wavy decoration, sometimes combined with the typical RPD decoration. The combs used to make both RPD and DWL, especially for the long wave varieties (DWL_b and DWL_c), are fairly large (average of seven indentations and up to 4 cm long), but the depth of the impression is shallow with light pressure over the surface. Simple impressions are present but rare. Undec- orated pottery sherds are frequent; although this may be linked to zonal decoration, it is difficult to ascertain because of the absence of diagnostic rim sherds. LA3 is characterized by the significant presence of undecorated sherds, but the few with decorations have the same attributes as LA2 pottery. Among the DWL varieties, the most common is the “a-variety,” often framed by a horizontal line of simple impressed dots without further decoration on the ceramic body. Rocker- packed dotted zig zags are the main motif found on LA3 vessels, principally in the variety with large dots (Fig. 6: 8). Other decorative motifs include simple impressions, such as SI_wt, an impression of a wolftooth pattern cre- ated by applying a stylus/reed implement obliquely to form a pattern organized in a wolftooth fashion. It is always combined with the DWL_a variant on the upper register or rim band (Fig. 6: 9). Table 5 Relative percentages of vessel shapes, diameters, and rim shapes Chro- nology Vessel Shapes Diameter (mm) Rim shapes Rs Rc Rr Rn Us Ud Average Min Max Straight rounded Everted/ thick- ened Other LA 36% 45% 5% 0% 9% 5% 23 10 38 55% 2% 43% EP 24% 26% 33% 0% 9% 7% 20 5 34 59% 12 29% MP 12% 19% 50% 2% 12% 4% 19 6 30 43% 22% 35% LP 12% 27% 38% 8% 15% 0% 19 10 30 50% 10% 40% 658 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) The EP1 pottery presents a discontinuity in the relative and absolute quantities of some decora- tions compared to the previous phase. RPD (Fig. 6: 11) declines in frequency (8%), and the most com- mon variety is that with fine rectangular impressions. DWL is rare, as is undecorated pottery. Rocker dec- orations of straight and curved motifs, made with a plain edge tool increase (Fig.  6: 12). The most fre- quent decoration is APS continuous, mainly with small and very small irregular dots, though the lat- ter variety is mostly restricted to the EP phase. APS return is also well represented. Another type, restricted to the EP phase, is what we have termed SI_crd, created when a simple cord or a cord- wrapped stick is applied to the surface of the vessel. The result is a syntactical chevron design (Fig.  6: 13–14). The EP2 shows a clear increase of APS (Fig. 6: 15–16) in both its continuous regular (Fig. 6: 16) and return technique variants. DWL is absent, and the formerly typical RPD becomes rare, continu- ing the trend already seen in the preceding subphase. Rocker plain edge, both straight and curved, deco- rative motifs have become common, especially the loosely-spaced varieties (Fig. 6: 17). The MP1 sub-phase has yielded few potsherds due to severe post-depositional disturbance processes (Biagetti & di Lernia, 2013). The assemblage mainly consists of sherds decorated with APS continuous (Fig.  6: 18) and using the return technique (Fig.  6: 19). It indicates a clear pertinence to the Pastoral horizon, though with some archaic features, such as the irregular fine dots in some patterns, such as vari- ety C (di Lernia, 2021; Garcea, 2003, 2005). By con- trast, APS return is mainly attested in its fine (a) and Table 6 Classification scheme and attributes of main decorative types Technique Name General description Variety Variety description Alternately pivoting stamp APS_ct Alternately pivoting stamp in a continu- ous regular pattern a Small dots b Large dots c Tiny dots APS_r Alternately pivoting stamp, return technique a Small b Small fine dots c Tiny dots, sometimes in irregular fashion Rocker RPD_ct Rocker packed dotted zigzags in continu- ous bands a Fine dots b Large dots c Very fine dots RS Rocker spaced dotted zigzags DWL Dotted wavy line a Very short, small angular waves b Long waves c Short and flat waves d Angular short waves e Juxtaposed fanlike arches RPLs_ct Rocker, plain edge straight continuous zigzags. RPLc_ct Rocker, plain edge curved continuous zigzags. RPL_fn Rocker plain edge, fishnet pattern. Simple impression SI_CRD SI_crd- simple impression with a cord implement. SI_wt Juxtaposition of two oblique dashed impressions connected at one end to form lines of “chevrons” or wolf-teeth. SI_varia Simple impression of various patterns, mainly single dots or lines. Incision SInc Varia-simple incisions. 659Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) Ta bl e 7 R el at iv e pe rc en ta ge s o f m ai n di ag no sti c de co ra tiv e ty pe s p er su b- ph as e LA 1 LA 2 LA 3 EP 1 EP 2 M P1 M P2 LP 1 % N % N % N % N % N % N % N % N A lte rn at el y pi vo tin g st am p A PS _c t 0% 1% 3 3% 12 14 % 34 37 % 14 0 33 % 23 35 % 32 8 32 % 57 a 0% 0% 1 2% 8 4% 11 18 % 70 16 % 11 19 % 17 5 14 % 25 b 0% 1% 2 1% 3 7% 16 8% 30 7% 5 10 % 98 11 % 20 c 0% 0% 0% 1 3% 7 10 % 37 10 % 7 6% 55 6% 10 A PS _r 0% 3% 7 2% 7 17 % 42 25 % 94 28 % 19 36 % 33 6 24 % 43 a 0% 1% 2 1% 4 10 % 25 11 % 42 16 % 11 15 % 14 5 12 % 21 b 0% 2% 4 1% 2 4% 11 7% 27 10 % 7 16 % 14 7 9% 16 c 0% 0% 0% 0% 1% 3 0% 0% 1% 2 A PS _t r_ ct 0% 0% 1 0% 1 2% 4 4% 17 9% 6 6% 59 6% 11 A PS _t r_ r 0% 0% 0% 0% 2% 6 0% 0% 1 0% D ot te d w av y lin e D W L 5% 1 13 % 29 6% 22 4% 9 0% 0% 0% 1% 1 a 0% 4% 9 4% 15 3% 8 0% 0% 0% 1% 1 b 5% 1 5% 11 1% 2 0% 0% 0% 0% 0% c 0% 2% 5 1% 2 0% 1 0% 0% 0% 0% d 0% 1% 3 1% 3 0% 0% 0% 0% 0% e 0% 0% 1 0% 0% 0% 0% 0% 0% Ro ck er p ac ke d do ts R PD _c t 86 % 18 39 % 89 12 % 43 8% 20 5% 18 4% 3 3% 30 3% 6 a 48 % 10 12 % 27 3% 11 3% 7 2% 8 3% 2 1% 14 1% 2 b 38 % 8 26 % 60 8% 28 3% 8 2% 7 1% 1 1% 7 2% 3 c 0% 1% 2 1% 4 2% 5 1% 3 0% 1% 9 1% 1 Ro ck er p la in e dg e R PL c_ ct 0% 0% 0% 1 3% 7 1% 4 1% 1 1% 12 2% 3 R PL s_ ct 0% 2% 4 3% 10 6% 14 8% 29 6% 4 6% 54 6% 10 R PL s_ fn 0% 0% 0% 0% 1% 2 0% 2% 18 3% 5 Ro ck er sp ac ed R S 0% 3% 8 3% 9 4% 10 6% 22 1% 1 2% 22 3% 5 Si m pl e im pr es si on SI _v ar ia 0% 3% 6 3% 12 3% 7 2% 6 1% 1 1% 10 3% 6 SI _w t 0% 0% 1% 2 0% 1 0% 0% 0% 0% SI _c rd 0% 1% 3 1% 3 13 % 31 2% 8 0% 1% 9 1% 1 Si m pl e in ci si on Si nc _v ar ia 0% 0% 1 0% 1 0% 0% 0% 0% 2% 3 U nd ec or at ed U N D 10 % 2 32 % 73 64 % 22 4 26 % 64 5% 19 16 % 11 6% 55 16 % 28 To ta l 10 0% 21 10 0% 23 0 10 0% 35 1 10 0% 24 5 10 0% 37 9 10 0% 69 10 0% 94 2 10 0% 17 9 660 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) thick (b) dotted variety. The MP2 is epitomized by the APS technique in both the continuous and return vari- ants (Fig. 6: 21–25), which make up more than 70% of the assemblage. Both are created with fine or large dots with a slight preponderance of the former. RPL fishnet (Fig. 6: 26) is also well represented. The LP1 layers yielded relatively few sherds compared to the other sub-phases (Fig.  6: 28–34). The repertoire mainly consists of APS_continu- ous decorations (~34%, Fig.  6: 29), APS_return (̴24%, Fig. 6: 30), and undecorated, sometimes bur- nished, pottery (~15%). APS with triangular impres- sions (Fig.  6: 32) is also more frequent than other subphases. Other decoration types appear in small quantities. These include the simple impressed pat- tern made with a serrated edge implement, which in its oblique (herringbone) form, is the most frequent here (Fig. 6: 34). Simple incised motifs are also pre- sent, including an oblique application mostly near the rim band area. Combining Multivariable Data The correspondence analysis performed on the data- set highlights the use of tempering materials and fabrics. Although a general homogeneity of pro- duction technology in the main cultural phases is confirmed, there is relatively high variability in the proportions of the various fabrics. These two obser- vations are consistent with a household level of production, where choices are made by individuals (potters), albeit within a well-defined technological and cultural tradition (e.g., Arnold, 1985; Dietler & Herbich, 1994; Eerkens & Lipo, 2005; Wenger, 1999). These features fully match the socioeco- nomic ways of hunter-gatherers and pastoralists liv- ing in small communities where societal and labor specialization were virtually absent (e.g., Costin, 1991; di Lernia, 2022). The correspondence analysis’s biplot (Fig.  7) com- bining the macro-fabrics and the main decoration types shows a clear polarization in the assemblage. RPD and DWL are found mainly in association with semi- coarse fabrics with a significant quantity of micaceous inclusions, corresponding to fabrics made from gran- ite-derived raw materials as determined by the micro- scopic analysis (QF* group fabrics; Eramo et al., 2020). Undecorated (UND) pottery sherds are likewise pre- dominantly ascribed to semi-coarse wares, like the sim- ple impressed pottery (e.g., SI_sd: simple impression single dots and SI_wt: simple impression wolftooth). Rocker plain edge straight zig-zag (RPLs_ct) motifs are associated with semi-fine fabrics with a sandy and vegetable component. Subsequent thin-section analyses may suggest the use of particular tempering agents like crushed sheep/goat dung mixed with clay. By contrast, the same motifs made using a curved edge implement (RPLc_ct) are associated with more specimens made in semi-coarse fabrics, a pattern with chronological LA1 LA2 LA3 EP1 EP2 MP1 MP2 LP1 RPD_ct DWL SI_crd RPLs_ct RPLc_ct RPLs_fn APS_r APS_ctSI_wt SI_ser UNDSInc_varia SI_variaRS C hr on ol og ic al s ub ph as e Cal BP 10200-9400 9500-8600 9000-8000 8300-7600 7800-7300 7100-6200 6400-5600 5900-4300 10% Decorative types Fig. 5 Battleship graph of the main diagnostic decoration types, by sub-phase Fig. 6 Main diagnostic pottery decorations divided by sub- phase (scale 2 cm) ◂ 661Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) DWL_b DWL_c DWL_d DWL_e LA1 LA2 RPD RPD RPD EP2 DWL_a + SI_wt LA3 SI_crd RPD APS_irregular APS_ct APS_r(eturn) APS_ct RPL_fn MP2 APS_r(eturn) APS_ct RPL APS_tr(iangle) SI LP1 EP1 RPL RPL MP1 APS_ct APS_tr(iangle) APS_tr(iangle) RPL APS_r(eturn) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 662 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) significance. Fishnet motifs were also associated with semi-fine pastes. A separate cluster is represented by the APS pottery with continuous dotted motifs (APS_ ct) and the typical return variant (APS_r), associated with distinctive semi-fine fabrics with fine to medium mineral and vegetable inclusions. Like most Pastoral pottery, this production uses Q fabrics made from locally-procured raw materials, with differing amounts of quartz and organic inclusions (e.g., QVe) interpreted as a dung-related tempering material. The correspondence analysis scatterplot (Fig. 8) also shows a chronological arrangement of the decoration COARSEFINE SEMICOARSE MICA SEMIFINE SEMIFINE MICA APS_ct APS_ds_bn APS_r DWLRPD_ct RPD RPD RPL_ct RPL_fn SI_ds SI_crd SI_sd SI_wt UND -2.0 -1.5 -1.0 -0.5 0.5 1.0 1.5 2.0 -2.0 -1.5 -1.0 -0.5 0.5 1.0 1.5 2.0 2.5 Fig. 7 Biplot graph of main decoration types and macroscopic fabric groups LA1 LA2 LA3 APS_ct APS_r DWL RPD RPL RPLs_fn RS SI_varia SI_crd SI_wt SInc_varia -2.0 -1.5 -1.0 -0.5 0.5 1.0 -2.0 -1.5 -1.0 -0.5 0.5 1.0 1.5 2.0 EP1 EP2 MP1 MP2 LP1 Dimension 1 (70.1%) D im en si on 2 (1 5. 8 % ) Fig. 8 Correspondence analysis of main decoration type elab- orated on the matrices of decorations and layers pertaining to each sub-phase; note that the data shown are simplified and aggregated to facilitate the reading of existing relationships (processing on Past v.4.3, by RR). Colored triangles indicate chronological sub-phases (green: Late Acacus; sky-blue: Early Pastoral; yellow: Middle Pastoral; red: Late Pastoral), and blue dots indicate main decorative types. Note the horseshoe arrangement of data underlined by the dashed black line 663Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) types along the displayed sequence, which indicates time as the organizing parameter in its parabolic, or horse-shoe, layout. The plot of cultural subphases and decorative types shows two dimensions that account for 85.9% of the assemblage’s overall variability. The first dimension (70.1%) demonstrates a correlation between APS decorative types and pastoral cultural phases (EP, MP, and LP). The second dimension (15.8%), on the other hand, emphasizes a correlation between DWL, RPD, and Late Acacus (LA) contexts. The APS pat- terns are separate from the RPD patterns. The latter are associated with DWL, emphasizing their shared chron- ological and cultural horizons. Discussion: The Takarkori Pottery in Regional Context The Early Holocene Sequence Pottery production, a distinctive lithic assemblage, and a diverse array of cultural, economic, and social fea- tures distinguish the Late Acacus hunter-gatherer-fish- ers of the Tadrart Acacus mountains from the previous Early Acacus specialized hunters and the later Early Pastoral herders (e.g., Barich, 1987a; di Lernia, 2022; Garcea, 2001a). Late Acacus pottery presents semi- coarse or coarse-textured fabrics with mainly min- eral tempers. The few organic inclusions, deliberately added or naturally present in the clay, are represented by vegetable macro-remains (chaff/stems). The exter- nal and internal surfaces are generally smoothed, with some specimens of rougher appearance. As to whether the raw material selection should be seen as a conse- quence of deliberate choices or as determined by the geopedological configuration of the area, the associa- tions discussed above appear to favor the former expla- nation. On a high-resolution scale, we can plausibly assume the habitus (sensu Gosselain, 2000, p. 189) of individual potters to be the cause of high variability in the pottery fabrics (where no pot is completely equal to another); the same is true of the decorative motifs (especially for the widespread presence of unique variations). On the other hand, higher-level social pro- cesses—interaction, technical identity, and community of practices—of historical and cultural significance may explain the dichotomy between Late Acacus and Pastoral Neolithic productions (e.g., Gosselain, 2011; Wallaert-Pêtre, 2001; Wenger, 1999). Coarse vs. fine fabrics are chronologically situated, and their asso- ciation with diagnostic decoration types reinforces the typological designation, the overall chronostratigraphic reconstruction of the site, and the resulting cultural attribution (Casanova et al., 2020). Late Acacus pottery production is probably mul- tifunctional. Simple hemispherical or conical vessels fashioned with coarse-grained clay fabrics may have been used in food processing, cooking, and storing. Mineral-tempered fabrics with some macro-organic inclusions enable “performance characteristics” (e.g., coarseness and porosity of the fabrics) suitable for this task, namely good heat transfer and reduced thermal stress (e.g., Braun, 1983; Rice, 2015; Skibo, 2013). The weakly closed profiles hinder boiling over but ease access to the contents, whereas the textured surfaces may ease grip and shock resistance (Schiffer et al., 1994; Tite et al., 2001; Fig. 9). The use of such pots for cooking and the processing of plant materials is also supported by the analysis of organic residues (Dunne et al., 2016). Stylistically, the pottery repertoire of the LA horizon at Takarkori is characterized by the pre- dominance of rocker impressions of dotted zigzags arranged to form various motifs and structures. These comprised simple outlines on mostly restricted coni- cal/spherical pots and simple wide-open hemispheri- cal bowls. The lowest layers (LA1) present sherds decorated with evenly serrated edge combs (small to medium circular teeth). Some have long-wave DWL combined with RPD. These are followed in the sub- sequent periods (LA2 and LA3) by increased deco- ration types and more varied combinations of motifs and structures. All the variants of DWL are present in the LA2 subphase, which is also characterized by the greatest variety of decoration types in the entire Late Acacus horizon. The use of shorter combs dis- tinguishes the LA3. Short, wavy, and fine, some- times steep and angular, decoration in the rim band area (DWL_a) is the main variety in this group. The fabrics and the choices of raw materials remain the same across the subphases, with mainly mineral-tem- pered fabrics, from semi-fine with abundant mica and quartz inclusions to semi-coarse and coarse. Overall, these decoration types fit within the Early Holocene horizon of the Tadrart Acacus and the neighboring massifs of Central Sahara, char- acterized mainly by rocker stamp impressions of 664 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) dotted zigzags, persisting in the sequence with few stylistic changes. These stylistic features shed light on some cultural connections and allow us to glimpse social and cultural implications and inter- relationships. The closest similarities are with the adjacent regions of the Central Saharan Massifs, namely the Tadrart Acacus and the Tassil N’Ajjer. The stratigraphic contexts dated between 10,200 and 8000 cal BP at sites like Ti-n Torha East (levels C), Uan Tabu (Units II and I), and Uan Afuda (Layers 5meso to Layer 1) present repertoires with decora- tion types and techno-morphological features com- parable to the LA at Takarkori (Barich, 1974, 1987c; di Lernia, 1999; Garcea, 2001b, 2001c; Livingstone Smith, 2001). Decorations are mostly RPD and DWL with some variations, compared to the Takar- kori assemblage. From a technological perspective, significant similarities can be attributed to a shared identity in the form of communities of practice (Wenger, 1999). Mineral, micaceous inclusions and the use of specific raw materials of plutonic origin are also attested in other contemporary repertoires from sites of the Tadrart, like Uan Tabu (Eramo et  al., 2020; Livingstone Smith, 2001). The stabil- ity of the manufacturing tradition suggests cultural continuity in the communities that lived at Takar- kori over several centuries and with other communi- ties that shared their “way of doing” and belonged to the same social network. As shown by the pres- ence of raw materials from different and non-local geological environments, communities from various locations in the Tadrart Acacus were connected in a common interrelationship represented by the persis- tence of a single shared technical tradition. The same can be said regarding the adjoining Tassili N’Ajjer and further west to some assemblages from the Hoggar. Ti-n Hanakaten, in the Tassili, presents RPD decorated pottery accompanied by some DWL in Sequence 8, dated to ca. 9000 cal BP (8100 ± 130 bp) (Aumassip et  al., 2013; Aumas- sip & Tauveron, 1993). Further important evidence comes from the site of Ti-n-Tartait, a rockshelter in the Meddak of the Tassili. Thick, coarse, and low- fired sherds decorated with RPD, DWL, and simple impressions were directly dated and ascribed to the Pre-Pastoral, with chronologies comprised between the late tenth and the mid-ninth millennium cal BP, fully overlapping with the LA subphases at Takar- kori (Messili et al., 2013). In the Hoggar, the site of Amekni has yielded fairly similar repertoires. The lower layers of the site excavated by Gabriel Camps and dated to around 8900 cal BP (couche inférieur: 8050 ±80 bp) contained pottery with comparable motifs and techniques, with RPD and DWL in simi- lar variants (Camps, 1969). Moving further away from the core area repre- sented by the Central Saharan Massifs of the Hoggar, the Tassili, and the Tadrart, other localities feature pottery of similar age with comparable attributes. Layers ascribed to the tenth millennium cal BP at LA2 LA2 LA3 a) b) c) Fig. 9 Three Late Acacus reconstructed vessels: a LA2 RPD decorated vessel; b LA2 DWL_b decorated vessel; c LA3 DWL_a decorated sherd (scale 5 cm) 665Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) Tagalagal in Niger Republic present pottery with RPD and DWL in the assemblage (Echallier & Roset, 1986; Roset, 1983). The Pre-Pastoral production from the well-known areas of the Adrar Bous and the Aïr, dated to around the tenth to ninth millennium cal BP, presents pottery with mainly medium-grained fabrics made from local raw materials, with very variable inclusions. The principal decoration types, represented by RPD and sometimes combined with a DWL in the rim-band area, are comparable with the Takarkori LA assemblage (Garcea, 2008, 2013). Other correlates and similarities can be found in areas distant from the principal core area, across the Sahara and North Africa, from assemblages of the Nabta-Kiseiba region in Egypt to the shores of the Sudanese Nile, up to the Tibesti and Ennedi in Chad (Bailloud, 1969; Gabriel, 1978; Jesse, 2003a, b). For instance, the appearance of the wolftooth pattern (SI_wt), often complemented by the DWL_a (Fig. 6), is significant. This suggests some connections with areas to the east, where it is attested in the reper- toire of the Nabta-Kiseiba area in a slightly earlier phase (Gatto, 2002; Nelson, 2002, p.10-13, figs. 2.1, 2.2). The motifs are similar in the esthetic pattern but differ in the technique and general arrangement, perhaps implying a mechanism of “imitation” rather than direct cultural transmission and suggesting dis- tinct social boundaries within a broader, fairly uni- form “cultural horizon” (Gosselain, 2011; Wallaert- Pêtre, 2001). This, together with the widespread dissemination of other decorative types like RPD and DWL, may corroborate the existence of an extensive network of contacts and connections over the vast Sahara-Sahel area facilitated by eco-geographical features and active throughout the Holocene though with different routes and timings (Brass et al., 2018; Caneva, 1987; Mohammed-Ali & Khabir, 2003). The result is regionalization within a common cultural tradition, as exemplified in the re-interpretation of some decorative patterns which, though similar, are never identical (Garcea, 2013; Jesse, 2010). The wide dissemination of the rocker stamp deco- ration, in particular of the packed zigzags, together with the “wavy” motifs (the so-called Incised Wavy Line (IWL) in eastern Northern Africa and the DWL in western North Africa seem to characterize the Early Holocene or more accurately the HGF horizon (for further discussion on this topic, see Jesse, 2002; Keding, 2017; Mohammed-Ali & Khabir, 2003). In some areas, like the southern part of the Central and Eastern Sahara (i.e., the Wadi Howar or the Ennedi), the associated chronology is much later and dated to the Middle Holocene (Jesse, 2004; Jesse & Keding, 2007). However, these areas are always related to an HGF socioeconomic milieu more as a cultural occur- rence than a strictly chronological one. The existence of a common cultural milieu is evi- dent in the distribution pattern of motifs on the pot’s surface and the way the motifs were executed, but with understandable local and regional differences and traditions (e.g., Brass et  al., 2018; Jesse, 2010; Ked- ing, 2006, 2017). Style-based arguments regarding social identity rely on numerous aspects of sociocul- tural variability and are thus neither straightforward nor easy to simplify (Gosselain, 2000; Hodder, 1982; Plog, 1983; Shanks & Tilley, 1992; Shennan, 2003). An example is the decorations applied to the rim top and rim-band area: simple “linear” decorations on rim tops are found throughout the vast “impressed horizon” of the Early Holocene Sahara, but they are created in different “modes” throughout the various cultural-regional areas, from milled rims (straight thin linear impression at the lip: cf. Gatto, 2002, p. 70) to the RPL impressions at Takarkori. Style is understood as a technological attribute, and decoration is regarded as a highly visible fea- ture that may convey information and suggest vari- ous social and cultural dynamics of transmission: common craftsmanship, knowledge, and vertical transmission on the one hand (Eerkens & Lipo, 2005; Gosselain, 2000; Roux, 2019) and more horizontal processes, from imitation to deliberate manipulation, on the other (Carr, 1995; Gosselain, 2011; Sackett, 1977). A shared cultural background may have facilitated, supported, and substantiated stylistic similarities. At the same time, their dissem- ination, if not directly linked to local and independ- ent innovations or inventions, may be the result of processes based on a network of social and cultural ties (di Lernia, 2022; Garcea & Hildebrand, 2009; Keding, 2017). The Middle Holocene Sequence The seriation proposed for the Middle Holocene sequence, corresponding to the Pastoral Neolithic, features pots with thinner walls, more closed shapes, and the most decoration types, such as APS—the 666 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) most widespread throughout this horizon. (Fig. 10). The EP1 assemblage exhibits elements of continuity with the earlier LA horizon regarding technologi- cal and decorative attributes. This is particularly the case with the preceding LA3 sub-phase. However, the overall impression is of a different pottery, where even the old rocker stamp-packed zigzag pattern seems to be executed using different and finer combs. Here and in the subsequent EP2, some specific deco- rations seem highly distinctive and circumscribed to these two subphases, i.e., the simple impressed cord decoration resulting in a vaguely diagonal (herring- bone-like) pattern (SI_crd). Executed on pottery quite similar in texture and fabric to the earlier LA pottery and made from local raw materials (Eramo et al., 2020), it may respond to mechanisms of imi- tation or hybridization rather than actual imports. If so, this would further substantiate the explanatory paradigm of the Neolithization process advanced for such periods (di Lernia, 2021). Connections to the east can be inferred based on similarities with some productions of the Nabta-Kiseiba area dated around or slightly before 8000 cal BP (Gatto, 2002; Nel- son, 2002). Other examples can also be seen in the Al Khiday site sequence in central Sudan (Salvatori, 2012; Salvatori et al., 2018). The successive appearance of similar decorative schemes and patterns apparent in more southerly and later areas may suggest complex movements and trajectories active between the final Early and initial Middle Holocene periods. This is true of the Laqiya pottery of the Wadi Howar in northern Sudan, which strongly recalls our cord-impressed motifs, espe- cially in the so-called older variant, albeit associated with some slightly more recent dates (Jesse, 2003b). The EP2 sees an increase in the APS decorative technique, as well as in the rocker stamp impression now made using a plain instrument (RPL s), also identified as typical of the Early Pastoral in other assemblages such as Uan Telocat and Uan Muhug- giag in the Tadrart Acacus (di Lernia, 2021; Garcea, 2003). The return variant continues to demonstrate its significance in this sub-phase. Similar to EP1, the primary type consists of either fine dots (APS r a) or very fine dots (APS r c). In the Middle Pastoral sub-phases, there is a gen- eral shift toward “homogeneity” in ceramic decora- tion, with a notable decrease in the variety of decora- tive patterns and a predominance of APS continuous and APS in the return (APS r) variant. While in the Early Pastoral, the fabrics had “transitional” charac- teristics, with coarse and semi-coarse fabrics coexist- ing with finer ones, and the Middle Pastoral pottery is made primarily from locally gathered (sandstone- derived) raw materials with semi-fine to fine fabrics, with compact texture and fine sand or organic inclu- sions (Eramo et al., 2014, 2020). The preference for local raw materials and the use of readily available materials (e.g., dung) as a tempering agent (Eramo et al., 2020) may suggest an attempt to speed up pro- duction, though without compromising quality. There appears to be an attempt to obtain low porosity and compactness, perhaps confirming the use of vessels for storage purposes (Rice, 2015, p. 411-32). The Fig. 10 Pastoral horizon vessels: a EP, SI_crd decoration; b MP, APS_r decoration; c LP, SI decora- tion (5 cm) EP MP LP a) b) c) 667Afr Archaeol Rev (2023) 40:647–672 1 3 Vol.: (0123456789) vessel forms mainly feature collared or necked bowls or jars suited to holding liquids. The walls are fairly thin to reduce the weight and increase portability. These circumstantial data may be linked to the more mobile settlement strategies of the full Pasto- ral horizon, characterized by a complex pattern of major settlements in the vast plains of the Erg Uan Kasa and vertical seasonal transhumance camps in the mountain ranges, especially in the Middle Pas- toral phase (Cremaschi & di Lernia, 1999; 2001; di Lernia, 2002). Numerous sites of comparable date present pottery repertoires similar to those of Takar- kori. Sites like Uan Muhuggiag, Ti-n-Torha North (Barich, 1974, 1987b, c; Caneva, 1987), Wadi Athal (Barich & Mori, 1970), and Uan Telocat (Garcea & Sebastiani, 1998) in the Tadrart Acacus all preserve assemblages with same features and trends in the development of decorative and technological styles: the pre-eminence of the APS decoration, especially in the return technique variant, together with the RPL, and the creation of mostly closed and fine- walled pots made from local and sub-local raw mate- rials. This type of pottery is consistently present in almost all sites, both sheltered and open-air, located in the explored areas of the Tadrart Acacus and the surrounding ergs and neighboring massifs such as Messak Setaffet (Cremaschi & di Lernia, 1998, 1999; Gallin & Le Quellec, 2008; Ponti et al., 1998). Stylistic similarities can be observed in the ceramic production of the Tassili-n-Ajjer, where sites like Ti-n Hanakaten present pots with analo- gous motifs (Aumassip & Delibrias, 1982; Aumas- sip & Tauveron, 1993). Given other cultural features, this may suggest the existence of a relatively uniform cultural area encompassing the Hoggar, where sites like Amekni and Meniet (both in the upper layers) have yielded pottery similar to those of the Pastoral horizon (Camps, 1969; Hugot, 1963). Some analo- gies might also be sought in the Pastoral production in northern Niger, specifically in the Aïr and the sur- roundings of the Adrar Bous (Garcea, 2008, 2013). In the Late Pastoral, the increasing aridity of the early sixth millennium BP fostered an eco- nomic change toward exploiting small livestock and large-scale mobility. In this period, human occu- pation indicates nomadic, highly mobile groups at mountain sites (Cremaschi & di Lernia, 1998; Cremaschi & Zerboni, 2009; Garcea & Sebastiani, 1998; Rotunno et al., 2020) and relatively sedentary communities in the river valleys with increased exchange between groups as a further adaptive strategy (Tafuri et  al., 2006). The few pottery at Takarkori are mainly made from fine and semi-fine fabrics. This testifies, on the one hand, to the more temporary use of shelters as part of a nomadic set- tlement system (e.g., Rotunno et al., 2020), and, on the other hand, to the focus of this system on the Acacus range, the main source of raw materials for pottery production. Decorations are still mostly APS, but undecorated burnished/polished pottery is also present. APS motifs with impressed triangular elements are present and decorative patterns with simple impressed or incised lines below the rim were also found. Similar decorative typologies can be observed in other Late Pastoral sites of the Tadrart Acacus (Cremaschi & di Lernia, 1998). At Uan Telocat, for instance, especially in Levels I and II (the former dated to around 5590–5280 cal BP), the potsherds present similar attributes: APS as the dominant technique, simple impressions with serrated-edge combs used to create diagonal and herring-bone motifs, and a steady increase in undecorated sherds from bottom to the top of the sequence (for a detailed discussion see Garcea & Sebastiani, 1998). Likewise, in the comparable upper levels (level 1) of Uan Muhuggiag, dated to around 4500 cal BP, the assemblage presents similar traits, such as the scarce presence of the return technique and the increase in undecorated sherds (Barich, 1987b, c; Cremaschi & di Lernia, 1998). Other sites recorded in the mountain range of the Acacus and neighbor- ing regions present similar assemblages (Cremaschi & di Lernia, 1998). Further specific decorative types present in this period (e.g., the triangular impressed decoration) are known in the eastern Messak and Erg Uan Kasa, indicating that the Late Pastoral set- tlement system covered a very large territory (Cre- maschi & di Lernia, 1998; Cremaschi & Zerboni, 2009). Trans-Saharan networks can be traced for these periods, as also testified by the much more frequent presence of “exotic” raw materials and tools in the lithic repertoires compared to the pre- ceding phases (Cremaschi & di Lernia, 1998, 1999; di Lernia & Cremaschi, 1997; Garcea, 2001a). Further southeast, there are some similarities with decoration types identified in the Wadi Howar area and the Handessi Horizon, all within a comparable 668 Afr Archaeol Rev (2023) 40:647–672 1 3 Vol:. (1234567890) chronological range (Jesse, 2006; Jesse & Keding, 2007; Keding, 2006), indicating the high mobility of these groups and the presence of an intricate net- work of contacts and exchanges. Conclusion This paper offers new data on the pottery assem- blages from a well-documented site in Central Sahara with a long-lasting Holocene occupation. The radiocarbon chronology helped to situate varia- tions and changes in the ceramic repertoire within a secure chronological framework, indicating cultural and technological modifications over time. The quan- titative and qualitative analysis allowed us to eluci- date variations in decorative techniques and pottery manufacturing processes. The relative frequencies of decoration types and tempers allowed us to bet- ter determine different spheres of use and production chains, deepening our understanding of the cultures studied, their likely changes in economic strategies, and degrees of mobility. At the same time, numer- ous issues remain to be clarified, from the questions surrounding the origins and spread of pottery to the reasons for the homogeneity apparent over vast expanses of space and time. The non-exhaustive comparative outline aimed to provide comparable chronological data for situating the Takarkori pottery sequence in its broader cultural context. Given the long history of research involved and the lack of new excavations and reliable radiocarbon dates in certain crucial localities, North African pottery studies and the resulting sequences are still puzzling. How some pivotal decorative styles disseminate geographically and chronologically, cutting across socioeconomic and cultural entities and terminologies, needs fur- ther refinement. This can be achieved with high- resolution studies of old and new collections. Novel approaches to re-examining old assemblages may help clarify some of these issues without forgetting the pressing need for new data and fieldwork. Acknowledgements We thank the many useful sugges- tions provided throughout our years of research by Prof. B. E. Barich, Prof. E. E. Garcea, and Prof. M. C. Gatto. All errors remain the responsibility of the authors. Finally, we are grateful to the editors and the three anonymous reviewers for insight- ful and useful comments that greatly improved the clarity and quality of the paper. Author Contributions RR and SdL wrote the paper. RR per- formed the statistical analysis and study of the assemblage. LC performed the preliminary analysis of the repertoire in the field under the supervision of SdL. All authors read and approved the final manuscript. Funding The work was supported by Sapienza University of Rome (Grandi Scavi di Ateneo) and by the Minister of For- eign Affairs (DGSP-VI), with the funds entrusted to SdL. The Italian Ministry of University and Research and the Sapienza University of Rome funded part of the study through the Ph.D. grant awarded to RR. Data Availability The datasets generated during and/or analysed dur- ing the current study are available from the corresponding author on rea- sonable request. 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Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law. https://doi.org/10.1080/14614103.2020.1777057 https://doi.org/10.1080/14614103.2020.1777057 A Holocene Ceramic Sequence in the Central Sahara: Pottery Traditions and Social Dynamics Seen from the Takarkori Rockshelter (SW Libya) Abstract Résumé Introduction The Takarkori Rockshelter: Archaeological and Cultural Sequence Materials and Methods Results Attributes, Frequency, and Descriptive Statistics Technological Features Shapes and Morphology Decoration Combining Multivariable Data Discussion: The Takarkori Pottery in Regional Context The Early Holocene Sequence The Middle Holocene Sequence Conclusion Acknowledgements References