Inside the “African Cattle Complex”: Animal Burials in the Holocene Central Sahara
Abstract
Cattle pastoralism is an important trait of African cultures. Ethnographic studies describe the central role played by domestic cattle within many societies, highlighting its social and ideological value well beyond its mere function as ‘walking larder’. Historical depth of this African legacy has been repeatedly assessed in an archaeological perspective, mostly emphasizing a continental vision. Nevertheless, in-depth site-specific studies, with a few exceptions, are lacking. Despite the long tradition of a multi-disciplinary approach to the analysis of pastoral systems in Africa, rarely do early and middle Holocene archaeological contexts feature in the same area the combination of settlement, ceremonial and rock art features so as to be multi-dimensionally explored: the Messak plateau in the Libyan central Sahara represents an outstanding exception. Known for its rich Pleistocene occupation and abundant Holocene rock art, the region, through our research, has also shown to preserve the material evidence of a complex ritual dated to the Middle Pastoral (6080–5120 BP or 5200–3800 BC). This was centred on the frequent deposition in stone monuments of disarticulated animal remains, mostly cattle. Animal burials are known also from other African contexts, but regional extent of the phenomenon, state of preservation of monuments, and associated rock art make the Messak case unique. GIS analysis, excavation data, radiocarbon dating, zooarchaeological and isotopic (Sr, C, O) analyses of animal remains, and botanical information are used to explore this highly formalized ritual and the lifeways of a pastoral community in the Holocene Sahara.
Citation: di Lernia S,
Tafuri MA, Gallinaro M, Alhaique F, Balasse M, et al. (2013) Inside the
“African Cattle Complex”: Animal Burials in the Holocene Central
Sahara. PLoS ONE 8(2):
e56879.
doi:10.1371/journal.pone.0056879
Editor: Michael D. Petraglia, University of Oxford, United Kingdom
Received: November 1, 2012; Accepted: January 15, 2013; Published: February 20, 2013
Copyright: © 2013 di Lernia et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Funds come from: Sapienza University of Rome (Grandi Scavi di Ateneo); Italian Minister of Foreign Affairs (DGSP); Eni North Africa (The Messak Project), entrusted to Savino di Lernia. Additional funds come from MIUR and Marie Curie IEF, entrusted to Mary Anne Tafuri. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Editor: Michael D. Petraglia, University of Oxford, United Kingdom
Received: November 1, 2012; Accepted: January 15, 2013; Published: February 20, 2013
Copyright: © 2013 di Lernia et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Funds come from: Sapienza University of Rome (Grandi Scavi di Ateneo); Italian Minister of Foreign Affairs (DGSP); Eni North Africa (The Messak Project), entrusted to Savino di Lernia. Additional funds come from MIUR and Marie Curie IEF, entrusted to Mary Anne Tafuri. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Stone monuments, rock art and cattle: an African legacy
Early Holocene cattle-based pastoralism is the oldest form of productive economy in Africa, which precedes agriculture [1], [2]. Despite the idea of an independent African domestication of Bos primigenius remains still controversial [3], [4], a genetic input of African aurochs during the long and discontinuous domestication process is possible [5]. Timing and mechanisms of livestock spread in Africa have been studied primarily combining radiocarbon dates of morphologically domestic remains with specific regional trajectories [6]. Secondary exploitation of cattle appears much later, with the earliest evidence of dairying from the central Sahara at around 6100 BP [7].Notwithstanding ecological barriers and diseases such as trypanosomes [8], cattle pastoralism spread all over the continent, becoming a momentous segment of African economy and society. Even today, relations between herders and their animals, especially in Eastern Africa, are particularly strong and well beyond the mere use of cattle as ‘walking larder’ [9]. Travellers, explorers and ethnographers of the 19th and early 20th century gave vivid narratives about the crucial importance of cows and bulls: Herskovits [10] coined the concept of “African Cattle Complex”, underlining the role of these animals within many African populations.
Bovines represent the primary wealth and are often used to pay bride and blood fines, being the basis for social prestige. Only rarely eaten, their slaughtering is often strongly socialized and special places are required for this purpose e.g., [11]–[13].
There is therefore scarce doubt that cattle exploitation and pastoral identity in Africa largely overlap e.g., [4], [11]–[16] and roots of this African legacy must be found in its remote past.
Given the extraordinary historical depth of cattle management in Africa, it is not a surprise that most archaeological investigations focussed on defining nature and organization of African pastoralists [6], [17]. However, the exploration of ideological and ritual aspects was mostly directed towards the study of human mortuary practices [18], [19], monumental architecture [20], [21] and rock art [22], [23]. Yet, cattle and pastoral activity are obsessively present in African iconography: in the Sahara, more than 60% of art panels portrait cattle or cattle-related scenes [24].
Artworks of bovidian/pastoral style are thus the tangible evidence of a shared heritage ideologically focussed on cattle. However, problems in its dating [25] make it difficult to relate settlement and subsistence data with the Saharan pastoral ideological world.
Another important archaeological evidence of cattle centrality in the African prehistoric pastoral world is represented by stone monuments with articulated or disarticulated remains of bovines, repeatedly interpreted as the expression of the “African Cattle Complex”, such as those of Nabta Playa in Egypt [26] or Adrar Bous in Niger [27]–[29]. More recent research relates the presence of accumulations of cattle bones, defined by the authors “Tenerian meals”, to feasting activities [30]. Further contexts with possible ritual depositions of cattle are reported from Talak–Timenrsoi in western Air, Niger, and dated between 5400 and 4800 BP [28]. The site of Mankhor, in the Algerian Tadrart, dated between 5525 and 4865 BP, shows evidence of ritual deposition [31]. The ritual interment of cattle remains appears however to be a long standing habitus, as testified by other Niger sites dated as late as 3500 BP [28], plus for example the evidence from the Nile valley e.g., [32].
Cattle, stone monuments and rock art appear to be important elements of African prehistoric pastoral societies, but they rarely occur together so as to be multi-dimensionally explored: the Messak plateau (SW Libya) in the central Sahara represents an outstanding exception (Fig. 1). Here, engravings portraying pastoral activities–which include the vivid representation of cattle sacrifices (Fig. 2)–are common and often in spatial relations with stone monuments. Some of these structures were already excavated in the 1990s [33]: they revealed the existence of deliberate depositions, mainly of cattle, with engravings of bovines strictly associated. A specific project was later launched (Messak Ceremonial Monuments Project, MCMP, 2007–2010) with the aim to explore the complexity of this cultural phenomenon, either in time or space.
Figure 1. The Messak plateau and surroundings.
The white insert shows the area of fieldwork (2000; 2007–2010).
doi:10.1371/journal.pone.0056879.g001
The white insert shows the area of fieldwork (2000; 2007–2010).
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Figure 2. The sacrifice of a bull at In Erahar.
The corbeille 07/110 C1 is just above the engraved wall: it yielded the remains of a bull, with offerings of flowers, a pot and the stone maces possibly used to kill the animal.
doi:10.1371/journal.pone.0056879.g002
This
has been achieved through a campaign of surveys and excavations of
stone monuments and associated rock art, combining environmental
information, GIS spatial analysis, archaeological data, radiocarbon
chronology, zooarchaeology, archaeobotany and isotopic investigation.The corbeille 07/110 C1 is just above the engraved wall: it yielded the remains of a bull, with offerings of flowers, a pot and the stone maces possibly used to kill the animal.
doi:10.1371/journal.pone.0056879.g002
Middle Pastoral herders of the central Sahara
Cattle and small livestock were introduced in the Central Sahara at the end of the 8th millennium BP, and slowly adopted by local groups of hunter-gatherers [2]. In the Acacus and Messak mountains (SW Libya) a full exploitation of domesticates, which included dairying [7], is dated to the Middle Pastoral (6100–5000 BP), a cultural phase generally characterized by wet and warm environmental conditions [34]–[36].Past geoarchaeological surveys and excavations helped to define settlement system, food security, mortuary and social practices of Middle Pastoral groups [37]–[39]. This was mainly achieved in the Acacus massif and neighbouring dune fields (Erg Uan Kasa), thanks to the good state of preservation of stratigraphic contexts in the mountain range, which yielded a rich archaeological record [37]. The territorial scale of analysis also allowed for the understanding of mobility patterns between different ecological niches of these cattle herders [38]–[40], which were regulated by the high seasonality of monsoonal precipitation recorded for the middle Holocene [34]. Large and semi-residential sites are abundant along the former shores of lakes in the dune fields; they were likely occupied during the rainy season (summer), while during the drier season (winter) herders concentrated in the mountain range, as also indicated by pollen data [35].
The Acacus-Uan Kasa model might also apply to the Messak plateau and the vast Edeyen of Murzuq, where solid locational relations might have linked the two areas. In the latter, several rich Middle Pastoral sites were mapped and some were excavated [37], [41]. They can be reasonably interpreted as summer semi-residential sites, exploiting the water-rich areas surrounding the lakes [34]. Unlike for the Acacus-Uan Kasa system, we found poor evidence of Holocene settlement in the Messak, with a dozen of Middle Pastoral contexts, generally showing ephemeral and light occupation [42], [43]. Along with dated sites, a large number of contexts lack chronologically diagnostic features: some or many of them could be of Middle Pastoral age. As a general tendency however, no Holocene settlement site, regardless of its chronological attribution, shows complex and articulated features. In this sense, the paucity of settlements (be it numerical or in terms of complexity) contrasts with the richness of stone ceremonial monuments [33], [44]–[49], rock art [47]–[49] and quartzarenite quarrying [50]. Many of these archaeological contexts might belong to the Middle Pastoral, as recently proposed for the “Messak school” engravings [25].
The Messak. Environmental and archaeological background
Our study area is a large plateau which extends over more than 15,000 km2 between 24° and 26° 30′ latitude N, and 11° and 13° longitude E [51]. It can be divided into two adjoining regions separated by the Tilemsin corridor: Settafet (‘black’, in local language) and Mellet (‘white’). The Messak is a cuesta type massif cut into the Jurassic to Cretaceous Messak Sandstone, gently tilted eastward and delimited by an abrupt scarp. The maximum altitude is 1200 m asl. A dense network of fossil wadis with a dendritic pattern dissects the plateau, originated in the Tertiary under a pluvial climate. The present climate of the region is hyperarid: mean annual temperature is 22°–25 °C; mean annual rainfall is 0–10 mm. Both climate and palaeoclimate depend on low altitude pressure and winds over the continent and the seasonal migration of the Intertropical Convergence Zone, resulting in belts of monsoonal climate with summer rains and dry winters [52].The flora is still not fully known, but most of the species described for the central Sahara [53] were observed in the field. Acacias include Faidherbia albida, Acacia tortilis and A.nilotica. Shrubs of Cornulaca monacantha, Pulicaria crispa, Panicum turgidum and Spipagrostis pungens are common. Desert savannah and Saharo-montane vegetation, typical of the Saharan Transitional zone [54], is prevalent in the wadis.
The main physiographic units of the massif correspond to residual surfaces (hamada and serir), solutional depressions, slope deposits, and a composite escarpment [51]. The typical landscape of the Messak plateau is the black hamada surface, whose clasts are coated by a dark Mn-rich varnish [55], interrupted by wide serir spots. The desert pavement overlies relict and complex rubified paleosols, which are discontinuously present on the plateau. These formed under pluvial phases since the early Pleistocene. The most recent pedogenesis is dated to the middle Holocene [56].
The hamada is now a palimpsest of lithic scatters dating from Early Stone Age to historical times [43], [57]. Holocene occupation features hundreds of funerary and ritual structures [33], [43], [44], whereas, as already emphasized, only light and ephemeral dwellings were recorded [37], [42], [43], [58], [59]. Rare deposits are preserved in rock shelters [60]. The most impressive Messak feature is rock art: the wadi areas are dotted by thousands of engraved panels of Holocene age [25], [47]–[49], [61], [62].
The Messak Ceremonial Monuments Project (MCMP)
The first monuments with animal remains were found during a rescue operation to assess damages caused during oil prospecting [33], [42]. These added to the results of the excavation of a standing stone located at In Habeter, also containing cattle remains [63]. Such features suggested the existence of ceremonies clearly connected to pastoral rituals focussed on cattle ideology [33].To assess the extent of the phenomenon, and to define its nature and meaning, we launched the “Messak Ceremonial Monuments Project” (MCMP 2007–2010).
The research has been carried out within the activities of The Archaeological Mission in the Sahara, Sapienza University of Rome and the Department of Archaeology (DoA), Tripoli, directed by SDL. All necessary permits were obtained for the field studies and laboratory analyses (including destructive ones) presented here.
Results and Discussion
Our data convey to suggest that during the middle Holocene (6080–5120 BP or 5200–3800 BC) the Messak plateau homed the highly formalized local expression of a wider ideological phenomenon centred on domestic cattle. The slaughtering of bovines was an impressive enduring ritual, which should be considered as a central part of the socio-cultural system of Messak Middle Pastoral herders.The arguments to support our interpretation combine different territorial scales of analysis (from regions to monuments) and involve several perspectives: GIS analysis of corbeilles and rock art contexts (including their geomorphological setting); archaeological excavations; radiocarbon dates on animal bones and/or associated contexts; classification of archaeological materials (pottery, lithics); zooarchaeological analysis; isotopic data (87Sr/86Sr, δ13C, δ18O) on faunal remains; botanical information, as described below.
Corbeilles and rock art: a GIS approach
The sources for our GIS platform are published and unpublished information, together with our fieldwork data, for a total of 197 structures (Text S1; Table S1). Depending on the different sources, quantity and quality of data for each structure can vary from a simple positioning to a full excavation record. To overcome this heterogeneity, the analyses were first performed on the spatial location of the structures, also using satellite imagery: for each structure we have analysed topographical and geomorphological setting, together with the hierarchy, geography and morphology of the related wadi (Table S1).The distribution map proves the widespread presence of corbeilles all over the region, but for the north-eastern Settafet (Fig. 3). The structures are mainly located in specific and recurrent locales: they are placed on the hamada (79%), along the middle courses of the principal wadis (79%), in correspondence with their widest meanders (86%) and close to the wadi bank (<75 m, 83%).
Figure 3. Desktop and GIS analysis.
Distribution maps of corbeilles (A) and Middle Pastoral engravings (C–red triangle indicates the artworks depicting the slaughtering of cattle) and their density analysis (B, D). The four densest clusters are indicated (I–IV).
doi:10.1371/journal.pone.0056879.g003
The geomorphology of these locales corresponds to valleys with flat floors and steep sides [51].
Wadi cuts are mostly attributed to groundwater seepage erosion; it is
likely that these parts of the wadis experienced high water availability
thanks to groundwater coming to light a few hundreds of meters ahead.
These places thus represented favourable areas for grazing and water
supply in an otherwise harsh landscape.Distribution maps of corbeilles (A) and Middle Pastoral engravings (C–red triangle indicates the artworks depicting the slaughtering of cattle) and their density analysis (B, D). The four densest clusters are indicated (I–IV).
doi:10.1371/journal.pone.0056879.g003
The minimum reciprocal distance between monuments, the distance of the structure(s) from the wadi banks and the accessibility to the ancient river are important elements to define the micro-topographic features of these contexts. Corbeilles are commonly very close to one another (ca. 41% under 30 m), creating ‘aggregate’ contexts. Interestingly, very remote and isolated structures are not rare (> 15%).
The striking proximity between monuments is mirrored by the analysis of the Average Nearest Neighbour, which shows a high index of clustering (Observed Mean Distance 1546.52 m; Expected Mean Distance 4125.53 m; NN ratio 0.37; z Score −16.79; p-value 0.0000), highlighting the non-random distribution of the structures all over the region and validating the regional organization of the cultural phenomenon. Analysis of density of corbeilles' location, based on the kernel method [64], identifies the existence of four areas with very high clustering, located respectively at Wadi Bedis and Wadi Tilizaghen (Northern Settafet); Wadi Taleschout -possibly being part of a wider cluster together with Tin Sharuma- (Southern Settafet); and Wadi Ankbritt (Mellet). Although the chronological relationships between the monuments cannot be ascertained on the basis of survey information alone, the presence of many and very similar structures in specific locales should be in any case interpreted as evidence of important places in the pastoral landscape.
Most interestingly, none of the architectural features of the corbeilles (size, elevation, building elements, presence and type of standing stone) show significant distribution in the landscape: this reinforces the value of the corbeille itself (and not of its building elements) as a codified landmark in the Messak Middle Pastoral world.
The distribution of the corbeilles and particularly that of the main concentrations of monuments largely matches that of rock art. Combining different sources on rock art contexts, we identified 102 scenes (Table S3) clearly referable to a Middle Pastoral phase (following [25]), whose spatial distribution and density are extremely similar to those of the corbeilles (Fig. 3). In these rock art scenes, cattle is obsessively present as an isolated subject or as part of complex scenes referring both to everyday life duties and more symbolic settings. Interestingly, the only three artworks depicting the slaughtering of cattle are all located in the northern area, where one of the most significant concentrations of corbeilles occurs (at least in one case, 07/110 C1, the structure with cattle remains is located immediately above the engraving).
Survey in the Northern Messak Settafet
The rationale of the MCMP fieldwork was to assess the distribution of stone monuments and to investigate their correlations with the landscape. A series of sampling areas were set along an ideal N–S transect intercepting the main geographic and physiographic units, following the course of one of the main fossil hydrographical arteries of the Messak (In Tullult, In Erahar, Wadi Bedis: Fig. 4; Text S2). This fieldwork adds to research undertaken in the 1990s in the areas of Tin Einessnis (1 and 2) and In Habeter III (see [33]).
Figure 4. Detail of the area of intensive survey.
General area (A); detail of Transect 5 (B); magnified view of red square in Transect 4 (C). The excavated monuments are indicated by full dots (black for the corbeilles, white for the other monuments) and their Id number (see Table 1 for details).
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A total surface of approximately 75 km2 was investigated, with 219 Holocene archaeological contexts identified (Text S2; Table S2). Most of them are conical tumuli, followed by stone structures and other stone features: the corbeilles
are 34. The chronological or cultural attribution is difficult: most of
the contexts are generically referred to Pastoral age; many structures
are of recent, historical occupation. The contexts attributed to the
Middle Pastoral are a few dozens.General area (A); detail of Transect 5 (B); magnified view of red square in Transect 4 (C). The excavated monuments are indicated by full dots (black for the corbeilles, white for the other monuments) and their Id number (see Table 1 for details).
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However, it is clear that some locations, i.e. the most (and probably the few) geomorphologically favourable places for grazing and water supply, assumed a key role for the cultural and ritual activities of the Middle Pastoral herders, and were reoccupied and reused by later pastoralists. This evidence is also supported by the high concentration in a few areas of trapping/tethering stones (TS): these stones, generally represented in rock engravings as hunting devices e.g., [48], are made of slabs or boulders of different size (up to 1 m) with notches or grooves to block a rope. Even if reused over time (Fig. 5), the very large quantity of these stones in places clearly unsuitable for hunting activity -such as the area of Tin Einessnis I (256 TS) and the Bedis meander (around 07/39 and 07/40: 187 TS; around 07/68: 126 TS)-, suggests a functional interpretation of these stones as tethering elements for domestic animals. Should they either represent the archaeological evidence of the gathering of several people (as potentially suggested by the presence of ceremonial monuments) or the reuse over time of the same place, the outcome is the same: these concentrations of tethering stones mark, together with the densest clusters of ceremonial monuments, locales of social importance and enduring value for Messak pastoral groups.
Figure 5. Examples of excavated archaeological features.
View of the excavations at 07/39 C2 and C3 (A), with detail of the skull from C3 (B). From monument 07/39 C1, the engraved boulder reused as trapping stone and then as building material (C).
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View of the excavations at 07/39 C2 and C3 (A), with detail of the skull from C3 (B). From monument 07/39 C1, the engraved boulder reused as trapping stone and then as building material (C).
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The excavations of stone monuments
As a whole we excavated 42 stone monuments, mostly in Wadi Bedis meander. Most of the monuments were corbeilles (26), together with stone structures (7), tumuli (4), stone platforms (2) and other elements (Table 1; Fig. 5): when monuments were very close to each other, extended excavations or test pits were carried out to assess their function and possibly verify the chronological correlation.
Table 1. Main features of excavated contexts with evidence of rituals related to animals, sorted by geographic position.
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In
sum, 22 between structures and associated features yielded faunal
remains; stone tools or potsherds are present in 15 contexts; and 9
monuments shown slabs/boulders with rock art engravings.doi:10.1371/journal.pone.0056879.t001
Twenty-two structures were radiocarbon dated (on charcoal, charred animal bones), indicating a time span for the animal burial phenomenon in the region between 6080 and 5120 BP (approximately 5200–3800 BC: Table 2). The most ancient date refers to structure 00/301, a small deflated tumulus with animal remains coming from distinct fire points, very close to an empty, but not datable, corbeille (00/301a). The earliest date for a corbeille itself comes from structure 07/39 C6, dated to 5660±30 BP. The dates cluster between approximately 5400 and 5200 BP. Two dates on small features, both from Wadi Bedis meander, are much later and point to Final Pastoral and Garamantian visits, reinforcing once more the key role of these specific places over the centuries.
Table 2. Radiocarbon measures from excavated contexts (calibration: Oxcal online 4.1).
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The corbeilles
differ in their architectural settings, varying from a simple type
characterized by a circular perimeter made of slabs vertically set in
the ground and often a central standing stone, to more complex
structures with external annexes and standing stones. Fillings and
stratigraphic settings vary according to the location and the
substratum. One or two series of superimposed stones alternating with
sand sediments can be set directly over the bedrock or cover a pit dug
in the bedrock. The accumulation of faunal remains, including the skull,
is usually located at the bottom of the structures.doi:10.1371/journal.pone.0056879.t002
Stone monuments are not static entities. They were part of a living landscape–sometimes reopened or revitalised. This is evident in some ab antiquo ‘plundered’ monuments, such as structures 00/300 and 07/39 C2, and is evident in the rock markings within the monuments and on top of them [25]. Corbeilles are not isolated features: stratigraphic relations, analysis of faunal remains and radiocarbon measures helped to better articulate the rituality involved in the use of these monuments. Larger excavations allowed us to reconstruct some of the relations between structures (such as 07/39 C2 and C3; 00/556 and its external stele), where the remains of the slaughtered animals were disposed inside and outside the different monuments.
Archaeological materials
Although the filling of the structures can occasionally include archaeological finds, firmly associated materials fall in two main categories: stone artefacts (especially maces) and pottery.As a whole (Table S4), we found 16 maces from 11 different structures, mostly corbeilles. Maces show similar morphology and opportunistic features (Fig. 6): made on quartzarenite, they are heavy tools (ca. 2.8 kg on average) exclusively produced by means of façonnage technique. They can feature a very worn handle, whereas the active protruding part was most likely re-sharpened just before its last use (C. Lemorini unpublished data). They were then ritually placed either in the structure, for example close to the cattle head, or immediately outside the monument. At 07/110 C1, where 3 maces were found, at least one was produced on the very spot, probably to replace a broken one: façonnage flakes were placed with the mace close to the animal head and a few could be refitted. Other formal tools, including a grinding stone with traces of ochre (07/55 C1), come from structures 00/301 (1 gouge), 07/79 C1 (2 bifacial knives), 07/110 C1 (1 arrow head, 1 gouge) and 09/69 C1 (1 bifacial tool).
Figure 6. Archaeological materials from the excavation.
Selection of stone maces (a–b: 00/301; c–d: 07/39 C3; e–f: 07/110 C1) and other stone tools (gouges, g: 07/110; h: 00/301; scrapers, i–l: 07/79 C1; grinding stone with traces of ochre, m: 07/55 C1).
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Pottery
is rare: only 9 structures yielded fragments of pots, usually 1 or 2,
with the exception of 00/557 (59) and 00/556 (35), 07/110 C1 (34) and
07/39 C2 (10), for a whole sample of 145 potsherds. Decoration is of the
Middle Pastoral tradition, mostly using a rocker stamp/plain edge
technique or, less frequently, the Alternately Pivoting Stamp (APS) one
(see [65]).
Undecorated potsherds are also present. Only at 07/110 C1 the pot could
be partially refitted, showing a globular morphology and distinct neck (Fig. 7).
In all of the structures but one (07/39 C2), pottery sherds were found
in the lowest layers, next to the skull of the animal (when present:
07/39 C3, 07/110 C1, 07/79 C1) or at the bottom of the structure.Selection of stone maces (a–b: 00/301; c–d: 07/39 C3; e–f: 07/110 C1) and other stone tools (gouges, g: 07/110; h: 00/301; scrapers, i–l: 07/79 C1; grinding stone with traces of ochre, m: 07/55 C1).
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Figure 7. Refitted potsherds from 07/110 C1, showing a rocker plain edge decoration.
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To
summarize, stone maces represent the authentic emblem of the complex
gestures involved in the ritual slaughtering of the animal. Their
presence is signalled also in other monumental structures, such as Tin
Iblal [62] and most interestingly from the Middle Pastoral quarrying site of In Habeter III [50].
Maces were most likely used to kill the animal(s)–or at least to give
them the fatal, symbolic, blow–and their systematic presence in
monuments across several centuries supports the high formalization
embedded in the ritual. The presence of fragments of pots strengthens
the ritual value of the offerings, frequently deposed near the animal
skull.doi:10.1371/journal.pone.0056879.g007
Analysis of faunal remains
Zooarchaeological analysis provided interesting insights on the rituals performed. Over 25,000 specimens were collected from 30 features belonging to 22 monuments. The distribution of the specimens in the different contexts is variable and only some of them yielded a significant number of identifiable remains (Tables 3 and 4; Text S1; Tables S5 and S6).
Table 3. Faunal assemblage.
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Table 4. Synoptic table of the faunal information available for the main structures.
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As far as species are concerned, 17 features contain cattle or large ungulates: in 6 cases Bos taurus
was the only species recovered, in 3 others large ungulate was the only
taxonomic category, while in 8 occurrences cattle is associated with
ovicaprines or small ungulates. In these latter cases, however, small
livestock is usually represented by few fragments, the only exception is
structure 00/301 where Ovis vel Capra specimens are
more abundant. Ovicaprines or small ungulate were the only taxon
identified in 6 features. Structure 07/39 C1 yielded some equid
specimens associated with very few small ungulates. In the last 5
features only unidentifiable fragments were recovered.doi:10.1371/journal.pone.0056879.t004
In most structures, for the main species a single individual is present (cattle, caprine or equid). The exceptions, with two Bos, are 07/40 C1 and 07/39 C3: in the latter, however, the single extra fragment may belong to the animal of 07/39 C2 external area, likely connecting the two monuments. Structure 00/301 with a minimum number of 2 cattle and 3 ovicaprine individuals represents an extreme outlier: here there seems to be also a differential distribution of cattle and small livestock in the various points of fire identified during the excavations. A similar differential distribution of species was found in 07/39 C5 where cattle remains were collected only in the corbeille and ovicaprines mainly under the external stele.
In most cases, the poor state of preservation of the bones prevented further assessments (sex, short-horn vs. long-horn, etc.) and only a few specimens could be measured (Table S5). Comparisons with available metric data from other sites in North Africa e.g., [26], [66] show that the animals from the Messak were of similar size or slightly larger. The sex of Bos taurus, based of the size and morphology of metapodials, was tentatively attributed only for 4 animals, all males (Table 4): one of them is from 07/110 C1 where the close rock art engraving (Fig. 2) shows the sacrifice of a bull. A further example of this sexual selection is represented by the bull from In Habeter III [63].
The analysis of body part frequencies was achievable only for 18 features (Table S6). Cattle shows some variability: the skeleton is almost complete in 6 contexts; in five other cases the head (cranium and/or mandible) is preserved, sometimes associated with only few other elements. At 00/556 there seems to be a patterned distribution of the skeletal elements with the head placed in the corbeille and the long bones found at the basis of the external stele. Radiocarbon dates of the two samples, even if slightly different, have overlapping sigmas (Table 2). The cranial portions of the animal seem to have been important also at 07/39 C1 where the equid specimens were recovered. The anatomical pattern for the ovicaprines is usually less complete and standardized, except for structure 00/301 where almost all the skeleton is present. The only possible evidence for a selection of ovicaprine elements may occur at 07/39 C2 external area where 3 out of 4 identified specimens are humeri.
Only in a few cases it was possible to indicate the age at death of the animals (Table 4; see Text S1 for discussion). Except for structure 00/301 where cattle are less than 36 months old, the bovines are mainly adults, while the few ovicaprines tend to be younger. All the other individuals of the identified species could only generically be considered as “adults”.
Given the poor state of preservation of the assemblage, it was difficult to observe bone surface modifications. As a consequence, butchering traces are apparently very rare, but related to different stages of carcass processing, from skinning, disarticulation and defleshing to bone fracturing for marrow extraction.
A large proportion of the fragments was burnt: the incidence of fire damage on the bones is usually very high, often with many calcined specimens.
Differences were also observed in the location of these traces, in particular among the head portions. In structures 07/55 C1 and 09/69 C1 the presence of unburnt cranium, mandible as well as hyoid fragments may suggest that the cattle head was placed in the structure with soft tissues still attached. Differences in the frequency of burning were recorded also between cattle and ovicaprines when present in the same structure in significant numbers, as well as sometimes between the corbeille and the associated external stele.
Considering the available faunal data it is clear that, although with some variability and few exceptions, the ritual in this region was quite standardized. In most contexts domestic cattle played the main role with ovicaprines representing only a secondary species, as also suggested by the different treatment of the two animals (e.g., frequency of specimens, skeletal element representation, age, burning). The only real outlier is structure 00/301 where the rituals seem to involve in a similar manner Bos taurus and Ovis vel Capra, however such anomaly could be explained by the fact that this is the oldest structure analysed.
Age selection indicates that for cattle mainly adult individuals were chosen, while for the ovicaprines younger animals were preferentially killed. In other African sites [26], [30], age data indicate slightly less mature animals. In the Messak, probably only bulls, rather than cows as in the case of some Egyptian and Niger sites, were selected for the sacrifice. The head of the animal was considered a relevant portion and was often placed at the bottom of the structure while, at least in some cases, the rest of the carcass was skinned, disarticulated and meat as well as marrow were consumed before the “leftovers” were collected and deposited in the monument after being intentionally burnt. Such intentionality is suggested in many contexts by the high frequency of calcined bones, which cannot be merely the result of cooking processes. On the basis of age and sex of the cattle, a large amount of meat was available (with the addition in some cases of the ovicaprines), suggesting that many people took part to the ritual. In a few structures (e.g., 00/301; 07/39 C2 and C3; 07/40 C1) more animals were slaughtered; this could be the evidence of special gathering places.
In other North African ritual sites with cattle bones the animal or parts of it are usually still articulated and burning is not a common occurrence e.g., [26], [30], [67]. Some similarities may be found with the so called “Tenerian meals” found in the Adrar Bous area [31], especially for the high incidence of burning, mainly on cattle elements, produced after consumption. However, there are dissimilarities in secondary species composition, number of individuals, anatomical representation as well as archaeological context.
The type of ritual identified in the Messak, although involving the same species of other North African areas, shows marked differences in the age and sex of the animals, as well as carcass treatment; they reflect the existence of a regional tradition, which given its level of standardization might have lasted over several centuries.
Isotope study
To have a measure of the environmental conditions in the area during the Pastoral phase and explore cultural phenomena linked to animal mobility we performed an isotope investigation on the animals buried in the stone monuments in the Messak and nearby areas. Animal stable isotope history was explored at the seasonal scale by means of sequential sampling of enamel along the tooth crown axis for carbon (δ13C) and oxygen (δ18O) isotope analysis [68], while local/exogenous origin and seasonal mobility were investigated through strontium isotope ratio (87Sr/86Sr) measured at the two furthermost oxygen values.The state of preservation of the faunal remains was generally rather poor, we thus decided to sample only teeth in good conditions; out of 17, twelve came from the Messak (MK, respectively 10 of Bos taurus; 1 of Equus sp.; 1 of Ovis vel Capra), while 4 teeth were selected from the Edeyen of Murzuq (MQ, respectively 2 of Bos taurus; 1 of Ovis vel Capra; 1 of Hippopotamus amphibius), and 1 from the Erg Uan Kasa (UK, Bos taurus).
For strontium isotope analysis we collected 8 further specimens of terrestrial shells (Pupoides hogarensis) from the stone structures in the Messak: bulk readings could provide a measure of the local Sr isotope signature. While terrestrial shells are good indicators of the local geology, their association with the structures remains uncertain thus data should be considered with caution. Three samples of carbonate concretions from the nearby wadis were also collected. Bulk analysis of modern animal teeth from other areas (respectively 3 modern goat teeth–leftovers provided by local–from the area of Mathendous in the Messak and 2 teeth of Ammotragus lervia from carcasses found during our surveys in the Acacus Mountains) was performed as a further proxy of the local geology (see Fig. 1).
We excluded from our sampling burnt materials. The general poor state of preservation of the teeth only allowed the subsampling–for C and O isotope analysis–of 11 individuals from the Messak area (respectively 9 of Bos taurus, 1 of Equus sp. and 1 of Ovis vel Capra) and 2 from the Murzuq area (2 Bos taurus).
A general background of C, O and Sr isotope studies, together with methods of pre-treatment and analysis are included with the supplementary material (Text S1).
Only 9 teeth sequentially sampled for O and C isotope analysis yielded reliable results (respectively 7 Bos taurus and 1 Equus sp. from the Messak area and 1 Bos taurus from the Murzuq–the ovicaprines, mostly of young age, did not preserve enough enamel) (Table 5).
Table 5. Carbon (δ13C), oxygen (δ18O) and strontium (87Sr/86Sr)
isotope ratio of tooth enamel bioapatite, carbonate rock and
terrestrial shells from archaeological and modern specimens collected in
the Libyan Sahara.
doi:10.1371/journal.pone.0056879.t005
The δ13C
values vary from −6.7 to 3.4‰ in bovine molars and premolars and from
−3.3 to −0.5‰ in the equid molar. Excluding the very short sequences
measured in 07/40 C1 individuals A and B, intra-tooth variability varies
from 0.9‰ to 9.3‰ for δ13C and from 1.4 to 3.1‰ for δ18O in bovine teeth (Fig. 8). In the equid molar, intra-tooth variability is 2.8‰ for δ13C values and 2‰ for δ18O values. Within each sequence, the highest δ13C values occur shortly after the δ18O
values reach their maximum, in agreement with what would be expected
from the natural vegetation cycle, with a higher relative abundance of C4 plants and/or higher δ13C values for C3 plants in the dry season, and/or higher δ13C values for C3 plants in the wet one [69]. At these latitudes, with temperatures exceeding the amount effect threshold [70], the variations recorded in the δ18O values reflect seasonal variation in precipitation, with the highest δ18O
values reflecting the dry season (winter), while in most sampled teeth,
the wet (summer) season is truncated from the sequence, biasing the δ13C
values recorded in tooth enamel towards dry season diet. The stable
isotope sequences measured in the four bovine molars (07/39 C2 ext.
area; 07/110 C1, 07/79 C1 and M4A/34) show very similar trends, with the
highest δ18O and δ13C values occurring
approximately at a distance from the enamel-root junction of 25 mm in
the first case and 15 mm in the further three.doi:10.1371/journal.pone.0056879.t005
Figure 8. Carbon (δ13C) and oxygen (δ18O) data.
Intra-tooth variation of carbon (solid diamonds) and oxygen (open diamonds) isotope ratios (in ‰) of enamel bioapatite of archaeological animals from the Messak and Murzuq. Abbreviations: cej = cement-enamel junction.
doi:10.1371/journal.pone.0056879.g008
87Sr/86Sr ratios from the Messak area range between 0.70966 and 0.70998 for the bovine teeth, and 0.70971 and 0.70972 for the Equus,
while the only sheep/goat sample has a signature of 0.70976. The bovine
specimens from the area of Murzuq range between 0.70985 and 0.70998,
with 0.70982 for the sheep/goat sample and 0.70981 for the hippopotamus.
Hence, there is a substantial overlap in the Sr isotope signature from
samples of the two areas. Significantly, the bovine specimen from the
Erg Uan Kasa represents the only exception, with a Sr isotope signature
of 0.71107 (Table 5).
Mean Sr ratio of the terrestrial shells is 0.70968±0.00006, while the
carbonate samples range between 0.70954 and 0.70971. Modern Sr isotope
signature is not dissimilar to that of the prehistoric specimens: the
two wild ruminants have comparable values that average 0.71068 while the
goats range between 0.70988 and 0.71017.Intra-tooth variation of carbon (solid diamonds) and oxygen (open diamonds) isotope ratios (in ‰) of enamel bioapatite of archaeological animals from the Messak and Murzuq. Abbreviations: cej = cement-enamel junction.
doi:10.1371/journal.pone.0056879.g008
All animals from the Messak monuments appear to be feeding on similar geological substrates. When defining the local range using 2 times the standard deviation of the mean Sr isotope values of the ancient enamel samples [71], all cattle show a common ‘local’ origin (Fig. 9a). However, four individuals (07/39 C3, 07/39 C2 ext. area, 07/110 and 00/556) despite being local, cluster on the furthermost values of the local mean and group with the specimens from the Murzuq (Fig. 9a). The bovine sample from the Erg Uan Kasa falls outside both Messak and Murzuq ranges, which is unsurprising given the geological background of the area; the Sr signature of this single specimen appears more in line with those of humans of different Pastoral ages from the Wadi Tanezzuft and Wadi Takarkori [18], [39]. The signatures of modern goat samples are consistent or close to the geological background of the sample area even if, in two cases, they might reflect the contribution of imported fodder to the diet of these animals. The Ammotragus samples confirm an origin non-local to the Messak or Murzuq, and match that of the area of sampling (Acacus Mts.).
Figure 9. Strontium isotope ratio (87Sr/86Sr) of archaeological and modern samples.
(A) For both the Messak (dotted line) and Murzuq (dashed line) the local range is defined by 2 sd of the enamel mean values of the ancient animal samples. Intra-individual Sr signatures are measured at the two furthermost oxygen values. Messak sample codes: 24 = 07/39 C3; 26a = 07/39 C2 ext.; 10 = 07/79 C1; 30(A) = 07/40 C1(A); 30(B) = 07/40 C1(B); 9 = 07/28 C1; 41 = 07/55 C1; 39 = 07/110 C1; 7 = 09/69 C1; 38 = 00/556. (B) Range of strontium isotope ratio (87Sr/86Sr) for the Messak and Murzuq animals. Abbreviations: MK = Messak; MQ = Murzuq; UK = Uan Kasa.
doi:10.1371/journal.pone.0056879.g009
When combining δ13C and δ18O data with Sr isotope ratio, the picture becomes more integrated.(A) For both the Messak (dotted line) and Murzuq (dashed line) the local range is defined by 2 sd of the enamel mean values of the ancient animal samples. Intra-individual Sr signatures are measured at the two furthermost oxygen values. Messak sample codes: 24 = 07/39 C3; 26a = 07/39 C2 ext.; 10 = 07/79 C1; 30(A) = 07/40 C1(A); 30(B) = 07/40 C1(B); 9 = 07/28 C1; 41 = 07/55 C1; 39 = 07/110 C1; 7 = 09/69 C1; 38 = 00/556. (B) Range of strontium isotope ratio (87Sr/86Sr) for the Messak and Murzuq animals. Abbreviations: MK = Messak; MQ = Murzuq; UK = Uan Kasa.
doi:10.1371/journal.pone.0056879.g009
Similar trends in the sequences of δ18O and δ13C values in 07/39 C2 ext. area; 07/110 C1, 07/79 C1 and M4A/34 suggest these individuals were born at the same period of the year. Given that in extensive conditions, cattle breeding cycle is driven by environmental variables including the vegetation annual cycle [72], this would suggest that these individuals were born in areas similar at least from this point of view. Still, a great inter-individual variability in the range of δ13C values suggest they grazed on different pastural areas. The latter seems to be confirmed, at least for individual 07/39 C2 ext. area and 07/79 C1, by the range of the Sr isotope signature at the furthermost peaks of δ18O (dry vs. wet season) which appears to indicate that the bovines have moved between two geologically different areas (Fig. 9b). Unfortunately individual 09/69, which also suggests mobility, yielded unreliable C and O data.
Using a 14.1 ‰ isotope enrichment (ε*) of 13C between diet and enamel bioapatite [73], the δ13C values measured in the enamel were converted to diet δ13C values, leading to an estimation of the relative proportion of C3 and C4 plants in diet, using the mean values of −25.5‰ and −11‰ for pre-industrial C3 and C4 plants (see Text S1). Individuals may be grouped according to the relative proportion of C4 plants in their diet. 07/40 C1 individual B, although represented only by one value, is the only tooth that gave a δ13C value reflecting a C3 dominated signal (approximately 60% C3 in diet). In 07/39 C3, 07/79 C1, and 07/40 C1 individual A (represented only by three values), C4 plants are largely dominant (≥90%) to exclusive in diet. These δ13C values are comparable to those measured in bovine teeth from low altitude modern and Neolithic (Elmenteitan) pastoral settlements in the savannah grassland of the Central Rift Valley in Kenya [74]. In 07/110 C1, M4A/34 and 07/28 C1, C4 plants dominate in diet, but a fair contribution of C3 plants is also detected seasonally (approximately 30–40%). This group of individuals gave similar range of δ13C values as the Equus. They may also be compared to δ13C values measured in cattle tooth enamel from historical and Elmenteitan occupations at higher elevation (2600 m) in the Central Rift Valley in Kenya, for which altitudinal mobility is suspected [74]. 07/39 C2 external area has the widest range of intra-tooth variation for δ13C values (9.3‰). In this tooth were measured the highest δ13C values of the sample (3.4‰) but also one of the lowest δ13C values (−5.9‰) suggesting a contribution of approximately 54% C3 plants to diet seasonally, this is also one of the individuals with greater variation in the Sr signal; the two proxies might suggest mobility between two diverse environments.
This great variability in the relative proportion of C3/C4 plants in the bovine diet is higher than what could be expected from individuals grazing in a single location and may suggest that these animals were coming from different places. Variability is also indicated by residue studies on potsherds from sites in the nearby Acacus Mountains [7]. We do not expect mean δ13C and δ18O values to be correlated in this sense (they are not), but would rather explain these different signals as reflecting diverse herding practices in terms of grazing areas, including location of pastures in altitude and possible seasonal mobility during the year to cope with variations in rainfall and other environmental constraints [34], [35], [38].
The Sr signature from all of the individuals (either Messak and Murzuq) is coherent with such a scenario, 87Sr/86Sr in most of the animals suggests a common origin. Within the Messak sub-sample, the 4 outliers fall within the Murzuq range. The integration of δ13C and δ18O data with the 87Sr/86Sr ratio outlines a picture of ‘local’ animals, mostly grazing on C4 plants though accessing diversified pastures, likely in connection to intra-annual mobility between geologically consistent areas (along the wadis of the Messak and in the dunes of the Edeyen of Murzuq).
The integration of δ13C, δ18O and 87Sr/86Sr data is particularly interesting for two structures (07/39 C3 with C2 external area and 07/40 C1). The two bovines in structure 07/39, even if hypothetically born at different times of the annual cycle show very different values, especially in the δ13C, so as to suggest different pastural areas. The discrepancy in the intra-individual mobility of the two animals, as reflected in the Sr isotope ratio supports this scenario.
Structure 07/40 C1 also contained two bovines, which were local as far as Sr isotope ratio is concerned, but–despite having both very short δ13C and δ18O sequences, show rather different values hence different proportions of C3 and C4 plant contribution to their diet.
In both such cases a single structure or a single architectural context, host animals likely to thrive on different pastures or move at different scales of resolution. It is tempting to suggest that these animals might have been parts of different herds, which conveyed at a same area or were part of a same ritual.
Archaeobotanical analyses
To investigate possible plant accumulation in burials, a random set of botanical samples was taken from four well preserved monuments with Bos taurus bones, together with a few preserved and naked-eye visible remains of plants.Pollen samples (structures 07/39 C3, 07/79 C1, 07/110 C1) were treated according to [75], and macroremains (structures 07/79 C1, 07/110 C1, 09/69 C1) were sorted under stereomicroscope (Text S1). The main results are reported in Table 6. Pollen flora is fairly similar in the different structures, showing prevalence of non arboreal pollen (NAP) and presence of tropical taxa (Fig. 10). Pollen spectra are dominated by the daisy family-Asteraceae (38% on average, 12 pollen types besides the undifferentiated Asteroideae) and by grass family-Poaceae (17%). Chenopods belonging to Chenopodiaceae/Amaranthaceae (6%), herbs of the carnation family-Caryophyllaceae (5%) and sedges-Cyperaceae (4%) are less represented. Plantains-Plantago and nettle family-Urticaceae are 3% each. Trees are low (7% on average) confirming that vegetation was open, and only fig tree-Ficus, toothbrush tree-Salvadora persica and tamarisks-Tamarix reach 1–1.5% on average. The sums of Asteraceae+Chenopodiaceae/Amaranthaceae (D) and Poaceae+Cyperaceae (W) indicate that the dry shrubland is almost always more represented than the savannah vegetation in the spectra. The D/W ratio is <1 only in sample p5 (structure 07/79 C1) as a result of the local abundance of grass pollen.
Figure 10. Percentage pollen diagram of three structures showing most of the identified pollen types.
Selected pollen sums (bottom) include the D (dry) and W (wet) sums, and pollen from plants living in water habitats.
doi:10.1371/journal.pone.0056879.g010
Selected pollen sums (bottom) include the D (dry) and W (wet) sums, and pollen from plants living in water habitats.
doi:10.1371/journal.pone.0056879.g010
Table 6. Botanical samples and main results of microscopical analyses of pollen and plant macroremains.
doi:10.1371/journal.pone.0056879.t006
Seeds and fruits are well preserved in a desiccate state. Remains mainly consist of fruits of Rumex cyprius/vesicarius (cypriot dock/sorrel; Fig. 11) that amounts to 93% of the carpological record. Whole or fragmented fruits are preserved together with fruits (achenes) of Ficus
and stem fragments of Poaceae in sample mc1, while other types of
records are present in sample mc2. In structure 09/69 C1, only a few
charred stems and twigs were found, while fruits were absent (Table 6).doi:10.1371/journal.pone.0056879.t006
Figure 11. Botanical remains.
Fruits of Rumex cyprius/vesicarius from structures 07/79 C1 (a, c = sample mc1; b, e = sample mc3) and 07/110 C1 (d = sample mc4). Record a still preserves the membranaceous parts of one wing; b has the remains of the wings, while records c and d lost their wings; d has still some purple colours in the remains of the veins (see detail).
doi:10.1371/journal.pone.0056879.g011
Altogether,
data show that the environments near the monuments were characterised
by desert shrublands that periodically became brackish alternated with
fresh-water habitats (especially at structures 07/79 C1 and 07/110 C1).
Interestingly, the pollen list includes a significant number of tropical
tree taxa (e.g., Balanites, Commiphora, Salvadora) spread in the Sahara during the mid-Holocene [76], [77].Fruits of Rumex cyprius/vesicarius from structures 07/79 C1 (a, c = sample mc1; b, e = sample mc3) and 07/110 C1 (d = sample mc4). Record a still preserves the membranaceous parts of one wing; b has the remains of the wings, while records c and d lost their wings; d has still some purple colours in the remains of the veins (see detail).
doi:10.1371/journal.pone.0056879.g011
Inside structure 07/110 C1, a low concentration of microscopical organic matter, including that of pollen and charcoal particles, was observed. The sum of Plantago+Urtica pollen is 3.3%, and this is an indication of some trampling and frequentation around the monument [78]. A significant amount of Rumex cyprius/vesicarius was found in sample mc4, collected at 145 cm depth: given the exclusive presence within this level, we interpret this as evidence of an intentional deposition inside the burial.
Samples from the other two monuments, 07/39 C3 and 07/79 C1, contain more organic matter, probably related to a higher local accumulation of plants as flowers, fruits and charcoals. A relatively more intense frequentation around these two structures is signalled by the Plantago+Urtica sum (8.0–7.4%, respectively). In structure 07/79 C1, sample mc3 contains a very high amount of Rumex cyprius/vesicarius and, just below, sample mc2 shows the highest diversity of seeds/fruits in these deposits. In this monument, a special consideration for this plant is confirmed, though also other plants were collected.
On the basis of these data some palaeo-ethnobotanical inferences can be drawn. Burials have specific features that make their archaeobotany fairly different from that of settlements. Sometimes, distinctive pollen assemblages witness floral depositions and rituals, and mixed pollen spectra could reveal subsequent input of terrigenous material in burials e.g., [79]. According to [80], these contexts are particularly hard to interpret since samples can include pollen and plant remains from different sources (floor context, objects lain on the floor, stomachs, hairs, etc.). As contamination may have occurred in several times, biases can be faced by a multidisciplinary approach. In our case study, however, the building of the monuments and their quasi-immediate closure after the burial of the animal remains, strongly reduce the limits indicated before. The contexts here analysed were well preserved and did not show any evidence of heavy plundering: for these reason, we are inclined to use pollen and plant remains as proxy for the understanding of seasonality and rituals.
In this sense, we can consider the few plant remains as offerings in the burials here studied, in particular at structures 07/79 C1, 07/39 C3, and 07/110 C1. There is here a significant presence of fruits and other plant parts of a limited number of species, together with abundance of pollen of the daisy family. A special selection of fruits of Rumex is evident suggesting that they were expressively collected from the whole plants.
In the first two structures, anthers of Asteraceae (pollen clumps) were also found signalling the presence of flowers. Moreover, concentrations of macroremains and pollen are relatively high. This is true if we consider the open-air position of the stone monuments though it is not comparable to the very high levels common in rock shelters [35].
The prevalent taxa in the botanical records possess attractive features for humans. The flowers of the daisy family have scent, some of them have beautiful colours and many are used for their medicinal properties (for example, species of Pulicaria and Artemisia).
The fruits of Rumex cyprius Murb. and Rumex vesicarius L. give colour to the landscape. When their fruits are ripe, they become winged and purplish-red veined [81] (Fig. 11). Today, sorrel flowers in spring, from March to April, at any time after rain in the desert.
The whole plant is rich of constituents (flavonoids, C-glycosides, oxalic acid, tannins, mucilage, mineral salts and vitamin C). Particularly the leaves and seeds are collected and prepared fresh or as a powder for internal use, to treat liver diseases and as a laxative. Traditional medicine uses the plant as an antiscorbutic, appetiser, astringent, carminative, stomachic and tonic, and for jaundice. The leaves are eaten fresh and much appreciated for their acid taste [53].
Methods
During the desktop phase, available and published data on stone monuments were entered in a GIS platform, in order to perform analysis on Landsat satellite imagery, together with high-resolution spots (Quickbird; Google Earth ©). In particular, we targeted the corbeilles (‘baskets’): circular platforms with slabs obliquely set around their external perimeter often with an associated standing stone. They appeared to be in spatial connection with rock art concentrations [44], with early excavations revealing their function as favoured loci for the deposition of cattle [33].In the field, we focussed on a specific region, the northern Messak Settafet (Figs. 1 and 4). Survey was carried out on foot with sampling kept to the minimum. Areas of particular relevance were mapped by means of Differential GPS and ETS (Electronic Total Station) with the aim of creating 3D terrain models (DTM).
We excavated selected monuments trying to minimize our impact: when possible, we preserved the external perimeter of each structure, so as to simplify systematic post-excavation reconstruction. Archaeological materials (mostly pottery and lithics), animal bones and botanical remains were sampled for laboratory analysis, which included a systematic radiocarbon dating programme.
Full information about the methods adopted by the different disciplines involved is available in Text S1.
Conclusions
Convincing evidence of a very early and enduring ritual in the central Sahara is provided by the Middle Pastoral monuments of the Messak with cattle remains and associated rock art. The exceptionality of our case study resides, we believe, in the multidimensional investigation of a phenomenon that we have known mainly for its extension in time and space e.g., [3], [26], [28], [33], [82], [83], with little understanding of its nature or complexity.Our work shows how Middle Pastoral human groups settled along the lake shores of the Edeyen of Murzuq during the rainy season, moved with the arrival of the dry months towards the higher and water-richer areas of the Messak plateau. This seasonal transhumance allowed them to cope with strong variations in rainfall and environmental constraints. In the Messak, settlements were light and ephemeral–probably to favour rapid drifts to other areas as soon as water and pasture were exhausted. During these stays, Messak herders built stone monuments and performed specific, formalized, rituals centred primarily on bovines. The capillary construction of highly codified monumental structures over a large area indicates a ritual deeply rooted within these human groups and represents the material evidence of collective ceremonies. On the basis of monument density and rock art concentration (and in a few cases on the quantity and clustering of trapping stones), we identify within the Messak four main loci (Bedis, Tilizaghen, Taleschout, Tin Sharuma), apparently of greater importance, which could be considered places of memory [84], whose meaning was actualized and revitalized generation after generation [25].
Several stone structures yielded animal bones, mainly of domestic cattle (adults and males) at their highest meat yield. In some cases, especially in the Bedis and Tin Einessnis area, the concentration of hundreds of trapping stones together with the number of animals slaughtered suggest the gathering of many people. Once animals were killed and meat shared, the leftovers were burnt outside the structures and later placed in the monument. In several contexts, standing stones with engraved animals were erected, while scenes centred on bovines were carved on the wadi walls in the immediate vicinity.
On the basis of isotopic evidence, the buried animals showed to be ‘local’ to the Messak-Murzuq region, moving between geologically similar substrates (as reflected in the Sr isotope ratios) yet variable environments (in accordance with δ13C and δ18 O data), thus reinforcing the transhumance model on a seasonal basis. In some cases, our evidence shows how animals grazing on different pastural areas were buried in the same structure, so as to suggest the assembly of different groups to share the same monument.
The systematic presence of stone maces, inside or outside the structure, often next to the animal remains, is another highly standardized part of the scenario. Archaeobotanical data indicate–at least for the monuments analysed–the performing of the rituals at the very end of the dry season: sorrels and many daises bloom in winter and spring, and we may indicate April/May (for the overlap of the flowering of Asteraceae and the fructification of Rumex) as an approximate time frame. The total lack of Rumex pollen in the samples studied also indicates the end of its blooming season (late spring). Inside the monuments, the rarity of offered fruits may be related to their fragility, but their intrinsic characteristics–rarity, beauty, and medical properties–reflect the important value given to these plants.
Although it is impossible to archaeologically connect the rituals performed to specific ceremonial events (initiation, passage, wedding, transhumance, etc.), the gathering of different groups that involved feasting with the slaughtering of cattle might be considered a peculiar, distinctive trait of Middle Pastoral herders. It would be fascinating to place these events at the end of the dry period, just before the transhumance from the Messak plateau towards the Murzuq lowlands, when the rainy season allowed the dispersal of these groups over a large area.
Even if the emergence of ritual burials of domestic cattle has been seen as a social response to deteriorating environmental conditions and expression of collective identity [33] or, alternatively, as material manifestation of ‘rain-making’ ceremonies and indicator of increasing complexity within Neolithic herders [21], it is its persistence and codification across the centuries to characterize this ritual as a specific ideological trait of Saharan pastoralists, as shown by the Middle Pastoral groups of the Messak: a potential, evocative analogue for the “African Cattle Complex” as known today.
Supporting Information
Text S1.Background, methods and supplementary data of the different disciplines.
(DOCX)
Text S2.
Survey in the Northern Messak Settafet.
(DOCX)
Table S1.
Main features of the corbeilles , used for GIS analysis.
(XLS)
Table S2.
Main features of the surveyed contexts in Northern Messak Settafet.
(XLSX)
Table S3.
Database of the main rock art features, used for GIS analysis.
(XLS)
Table S4.
Main features of quartzarenite stone maces.
(DOC)
Table S5.
Measurements of cattle and ovicaprines elements (in mm following von den Driesch 1976; * indicates approximate measurements).
(XLSX)
Table S6.
Skeletal element quantification in the main structures (NISP = Number of Identified Specimens, MNE = Minimum Number of Elements, MNI = Minimum Number of Individuals). The elements indicating the presence of more than one individual are in bold and underlined.
(XLSX)
Acknowledgments
The research has been carried out within the activities of The Archaeological Mission in the Sahara, Sapienza University of Rome and the Department of Archaeology (DoA), Tripoli, directed by SDL. We thank Dr S. Agab, DoA chairman and the staff from Tripoli, Sebha and Ghat: in particular B. Galgam, M. Turjman, A. Khalfalla, M. Denda. We are profoundly indebted to Axel and Anne-Michelle Van Albada for advice and help. We thank M. Cremaschi for providing faunal samples from Murzuq. We thank S. AbdulAziz, F. Del Fattore, A. Felici, A. Jamali, M. Massussi, L. Mori and D. Zampetti for helping during field survey and excavations. Many thanks to I. Massamba N'siala who surveyed the vegetation of the Messak area, and to R. Rinaldi for her help on plants identification. Warmest thanks to S. Biagetti and E. Cancellieri for their help.Author Contributions
Directed the fieldwork: SDL. Coordinated and performed isotopic studies: MAT. Implemented GIS information and analysed rock art: MG. Studied the faunal remains and wrote the relevant parts of the paper: FA. Performed and interpreted Carbon and Oxygen analyses and wrote the relevant parts of the paper: MB. Performed pollen and botanical studies and wrote the relevant parts of the paper: AMM. Performed strontium analysis: PF. Provided geomorphological data: AP AZ. Excavated and studied archaeological materials: LC MG AM. Conceived and designed the experiments: SDL MAT. Performed the experiments: SDL MAT MG FA MB PF AMM AM. Analyzed the data: SDL MAT MG FA MB AMM. Contributed reagents/materials/analysis tools: SDL MAT MG FA MB LC PF AMM AM AP AZ. Wrote the paper: SDL MAT MG.References
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