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Development of an Interdisciplinary Approach to the Radiocarbon Dating of Earth Mortars from Alula Old Town (Saudi Arabia). Integration of Building Archaeology, Mortar Analysis and Radiocarbon Dating

Published online by Cambridge University Press:  18 September 2024

Piero Gilento
Affiliation:
Archaïos, Paris, France Inrap, National Institute for Preventive Archaeological Research (UMR7041-ArScAn), Paris, France
Giovanni Pesce*
Affiliation:
Northumbria University, Department of Mechanical and Civil Engineering, Newcastle upon Tyne, United Kingdom
Apolline Vernet
Affiliation:
Archaïos, Paris, France
Cecilia Pesce
Affiliation:
Northumbria University, Department of Architecture and Built environment, Newcastle upon Tyne, United Kingdom (now at Sheffield University, Department of Material Science and Engineering, Sheffield, United Kingdom)
*
Corresponding author: Giovanni Pesce; Email: [email protected]
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Abstract

This paper discusses the approach used to identify the most relevant chronological information on the historic development of the abandoned site of AlUla Old Town, in the northwest of the Kingdom of Saudi Arabia (Western Asia). The approach is based on the use of the radiocarbon method to date earth mortars samples and soil layers used to create the constructive sequence of some buildings and, in turn, the chronological evolution of the site. Eleven samples of organic material (i.e., charcoal and vegetable fibers) were carefully removed from mortar samples and soil levels from six buildings and structures in the northern and southern areas of the town. Buildings and soil layers were chosen for their stratigraphic relevance and conservation conditions, based on an initial archaeological analysis of both, buildings and underground structures. Laboratory-based mortar analysis led to the characterization of the mortar’s inorganic fraction, and to the isolation of the organic material for the radiocarbon dating. Results from the accelerator mass spectrometry (AMS) laboratory provides evidence of a Late Mamluk/Early Ottoman constructive phase (i.e., 15th–17th c. AD) of the Old Town that was only partially known until very recently. Furthermore, the results allowed the identification of an Ottoman phase (i.e., 17th–19th c. AD) during which most of the buildings and structures were rebuilt, and of a Late Ottoman phase (i.e., 19th–20th c. AD) representing the most recent interventions before the end of the Ottoman occupation of the area.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of University of Arizona

Introduction

AlUla Old Town is an abandoned small town in the fertile oasis of Wādi al-Qurā, in the northwest of the Kingdom of Saudi Arabia, an area currently subject to an intense investigation and conservation program of its heritage (i.e., archaeological sites, still standing buildings, palm tree oasis). In this oasis, agricultural activities have been carried out for millennia thanks to the rich groundwater network that allows the intense cultivation of date palm (Battesti and Marty Reference Battesti and Marty2023) (Figure 1). The Wādi (also known as AlUla valley) is surrounded to the east and west by two mountain ranges. At the base of the west range was built AlUla Old Town, that stretches for about 7 hectares along the north-south axis of the valley (the modern town is a few kilometres south from it). Its original core was probably located around the small rock formation called Umm Nāṣir (Nasif Reference Nasif1988) that divides the settlement in a “north” and a “south” part, likely inhabited by two different leagues (the Shqîq league in the north and the Ḥilf league in the south, see Battesti and Marty Reference Battesti and Marty2023: 16–17). Before its abandonment in the 1980s, the Old Town had more than 900 buildings (Figure 2), mostly dwelling houses but also five mosques, a public bath, a school, and some open market spaces.

Figure 1. View of AlUla Old Town and of the oasis (centre) within the valley. The two mountain ranges protecting the wadi can be seen in the bottom-right corner of the image (west range) and in the top of it (east range). At the centre of the settlement, the Umm Nāṣir rock formation emerges from the buildings (picture by Piero Gilento, Archaïos).

Figure 2. Map of AlUla Old Town with the individual Building Units and, highlighted with colors, the Units discussed in this paper. The white space in the centre of the settlement is occupied by the Umm Nāṣir rock formation that divides the settlement into two parts (map by Anne Godefroy and Gabriela Camargo-Méndez, Archaïos).

The first historic references to AlUla Old Town are in documents dating to the 8th c. AD (e.g., the name “AlUla” is in the list of places between Medina and Tabuk where the Prophet has offered prayers, as compiled by Ibn-Zubalah), where it is often associated to the other big settlement of the region: Al-Hijr (Arabic name of the UNESCO site of Hegra). In such documents, both sites are described as crossing points of the pilgrimage routes to Mecca. Other medieval sources from the 13th c. AD (e.g., a report of Abu Shamah indicates that the town had been settled by the early part of the 13th century under the rule of the Ayyubids) confirm the importance of AlUla as a passage for the convoys of pilgrims heading to Medina and Mecca. However, from the 16th to the 20th c. AD, the documents refer to AlUla not only in connection to its role in the journey to Mecca (e.g., descriptions from Al-Jaziri and Kibrit al-Madani), but also for the taxes due to the central government. Some documents refer to the construction activities carried out to improve the settlement’s fortifications, with the aim of protecting it from the attacks of the nomads (a detailed list of sources, including those mentioned above, can be found in Nasif Reference Nasif1988, 135–137; Al-Muraikhi Reference Al-Muraikhi2019). In the early 20th c. AD, the first dedicated railway station was constructed in AlManshiyah district just 3.5 km southeast of the settlement; this placed it on the important route connecting Damascus to Medina, with the consequent introduction of new construction materials and techniques such as lime mortars and sandstone ashlars. Overall, the written sources currently available for AlUla Old Town suggest the existence of an inhabited settlement from the 8th c. AD until the end of the 20th c. AD. However, such sources do not provide information on the size of the settlement, nor on its characteristics (Nasif Reference Nasif1988).

The MuDUD Project

This lack of information led, in 2020, to the creation of the research project “Historical Investigation of AlUla Old Town – Multiscalar Documentation for Urban Dynamics” (MuDUD) that aims at investigating the evolution of the Old Town over the time. The project is carried out by the French archaeological company Archaïos and is funded and steered by the French Agency for the Development of AlUla (Afalula) in collaboration with the Royal Commission for AlUla (RCU). MuDUD is part of a wider research program that encompasses the entire valley and includes a number of scientific investigations in various sites, such as the “Dadan Archaeological Project” (Rohmer et al. Reference Rohmer, Alsuhaibani, Kesguer and Alahmari2020a, 2020b, 2022a, 2022b). All these activities aim at producing new chronological information (largely based on the use of the radiocarbon dating method) that, in the future, will allow the detailed and reliable reconstruction of the historic occupation of the valley. When completed, this reconstruction will be a unique reference for the entire Southwest of Asia.

More specifically, MuDUD entails a variety of activities including archaeological excavations and the detailed analysis of the still standing buildings using the methods of Building Archaeology (Gilento Reference Gilento and Anastasio2020a, Reference Gilento2020b). Considering the limited archaeological record available for the Old Town, the use of radiocarbon dating as the main method to produce absolute chronologies was planned since the design stage and implemented throughout the project. To the best of our knowledge, to date, only a handful of individual radiocarbon dating have been attempted in AlUla Old Town, although no result is currently available in the public domain. Furthermore, none of the pre-existing chronological data was produced as a part of a large-scale investigation of the built heritage, or as a part of a structured investigation of the materials and technologies used for the construction of the settlement.

Application of Building Archaeology Methods and Production of an Initial Chronological Sequence

Prior to the sampling for the radiocarbon dating, chosen groups of still standing buildings (i.e., Building Groups, or BG) in the north and south of the Old Town were subject to a detailed archaeological analysis using the methods of “Building Archaeology”, based on the application of the stratigraphic principles to still standing buildings and structures. Underpinning this field of study is the detailed observation of the masonries (or parts of them) and the identification of their smallest homogeneous parts (i.e., Stratigraphic Building Unit, or SBU) and their respective relationships. To manage the complexity of the data emerging from such observations, a recording system that considers different “Reference Units” is adopted, as detailed in Brogiolo, Cagnana Reference Brogiolo and Cagnana2012. Like in traditional archaeological excavations, Building Archaeology makes use of the Harris’ Matrix to provide a visual summary of the relative sequences of the SBU (i.e., before/after relationships), and to promote further analysis and interpretations of the data collected (Figure 3). The transformation of such relative sequences into absolute sequences is based on the use of specific chronological indicators such as in situ inscriptions, architectural decorations of known age, and—when possible—the results of archaeometric dating methods such as dendrochronology of timber elements, thermoluminescence of fired bricks, and the radiocarbon dating of mortars and plasters (Pesce et al. Reference Pesce, Quarta, Calcagnile, D’Elia, Cavaciocchi, Lastrico and Guastella2009, Reference Pesce, Ball, Quarta and Calcagnile2012).

Figure 3. Stratigraphic reading and related Harris’ matrix of U54, 53, 51 and 50 in the northern sector of the Old Town (analysis and drawing Piero Gilento, Archaïos; topographical location Gabriela Camargo-Méndez, Archaïos).

In AlUla Old Town, the stratigraphic analysis of the buildings focussed on selected Units chosen for their accessibility, stratigraphic complexity, and the use of specific building techniques (Figure 2). This allowed the identification of three main construction periods that led to the production of an initial relative chronological sequence (subsequently modified based on 14C results obtained) (Gilento Reference Gilento2020b, 143–145). The related periodization is reported below:

  • Period 1 – to this period were attributed some wall sections of various façades mostly located in the northern area of the Town, like Unit 54 (Figures 3 and 4). Further Units presenting features related to Period I were also identified in the south and centre of the settlement. The stratigraphic analysis demonstrated that these façades were built before any adjacent building. Their constructive technique is characterised by the reuse of previously produced sandstone blocks, organised in very regular layers and laid on very thin mortar joints (1–1.5 cm). These characteristics are substantially different from those of the technique used in other buildings of the Old Town. Based on the stratigraphic relationships of these wall sections with the other buildings, it is possible to suggest a construction time preceding the beginning of the 20th c. AD.

    Figure 4. General view from west of the façade of the U54 with the sampling point of the mortar (in yellow) (picture by Piero Gilento, Archaïos; b. Detail of the sampling point (picture by Giovanni Pesce, Northumbria University); c. Macrophotography of the charcoal sample embedded in the mortar (picture by Giovanni Pesce, Northumbria University).

  • Period 2 – this period represents an important time for the development of the settlement since it denotes a substantial construction (or reconstruction) phase of the local built heritage. The construction activity that was identified in this period is likely to be related to a substantial urban expansion, clearly visible in the north-eastern part of the Town. The most representative units related to this period (e.g., U772, U787, U791 in the north part of the settlement, U631 and U635 in the south part) are characterised by a floor plan including an atrium around which other rooms are organised on one or two levels and, in some cases, by large terraces on the first floor. The building technique is based on the use of approximately dressed stone blocks specifically quarried for these buildings, laid on regular layers of 18/20 cm height. Door and window frames are made with finely worked stone blocks. Using the numerous inscriptions engraved in some of the door lintels, this period was dated between 1918 and the 1980s AD.

  • Period 3 – to this period were attributed all the traces of restoration activities carried out in the Old Town since the 1980s. No specific constructive technique can be associated to this period. However, unfired earth bricks or hand-shaped adobe elements were used in the reconstruction of the walls, whereas the metal rails originally used in the Ottoman railway were reused as horizontal elements (e.g., beams) in the buildings.

Beside the results emerged from the analysis of the still standing buildings and structures, some archaeological excavations, mostly concentrated in the southern part of the Town, brought to light several masonry structures (e.g., foundations), about 1 m below the ground level. The lack of physical connections (except in some very limited cases) with the still standing buildings and the different organization of the underground structures suggest the existence of an even earlier phase of use of the settlement that precedes the above-mentioned Period 1. Unfortunately, the pottery fragments found during the excavations could not be used for the absolute dating of these evidence because of the limited knowledge currently available on the historic pottery production in the region (although various studies are currently in progress to more accurately identify the chronologies of specific pottery productions). This led the archaeologists to extend the use of radiocarbon dating to the underground structures.

Earth Mortars in AlUla Old Town

AlUla’s built heritage was constructed using a variety of locally sourced materials: stone, earth, and timber. The timber from tamarind trees and date palm trees was mainly used for horizonal structures (e.g., floors and roofs), whereas stones and earth-based materials were mainly used for the vertical structures (e.g., walls, foundations). Individual stone elements cut from the locally available yellow, red and violet sandstones were used in a variety of forms: from fully dressed ashlars to completely undressed pieces of stones. Earth-based building elements were used in the form of unfired earth bricks and balls of mud to be piled on the top of each other (i.e., the so-called Hand Shape Adobe; Houben Reference Houben1994). To improve the properties of the locally poor soil, all earth-based materials were mixed with locally sourced organic and inorganic material such as straw (to improve cohesion and tensile strength) and crushed limestone concretion (likely to improve workability). Because of the limited durability of such materials, the heavy rains that occur in the valley once a year (albeit for a short period of time) have probably caused frequent loss of materials in the masonries (including their joints) that, therefore, had to be regularly repaired, as the local tradition suggests.

This paper presents the interdisciplinary methodological approach used to investigate the chronological evolution of the built heritage in AlUla Old Town. Within such context, building archaeology was used to identify the main development phases of the town; mortar analysis was carried out to provide a basic characterization of the mixes and define the materials and processes used in the mortar preparation at different stages, whereas the radiocarbon method was used to date the main phases. The selection of different materials or processes used in the construction of AlUla’s built heritage at different times is essential, since it helps improving the current knowledge of the societies that built and lived in this settlement over the centuries. Indeed, changes in the local material culture could be related to a substantial change in the local society, to the influence exerted by an external constructive culture (e.g., arrival of builders from other areas), or to the exploitation of new locally available resources or the abandonment of exhausted ones.

Within the paper, six different historical times are mentioned. From the earliest to the latest these are: the Late Mamluk Sultanate (15th–16th c. AD), the Early Ottoman Empire (16th–17th c. AD), Ottoman Empire (18th–19th c. AD; time of the maximum expansion of this empire), the Late Ottoman Empire (19th–20th c. AD), the Modern Saudi Arabia (1920s–1980s AD), the Contemporary age (1980s AD–ongoing) (for specific historical and chronological references for the region, see Haykel Reference Haykel2010, 436–450; Lawson Reference Lawson2017; Masters Reference Masters2013; Peskes Reference Peskes2010, 285–298).

Materials and Methods

The mortar sampling was led by building archaeologists and carried out by mortar specialists, on the basis of the results of the archaeological analysis of the buildings. In AlUla Old Town, over 40 mortars samples were collected. From these, 6 samples from 6 Units (details in Table 1), in addition to one soil sample from Unit 687 were used for a detailed analysis.

Table 1. List of organic samples sent to the laboratory for the 14C determination with the related laboratory code and information on their origin and nature

The mortar characterization was carried out at Northumbria University’s laboratories. Each sample was initially observed at low magnification (e.g., 10×) under a Leica MZ6 stereomicroscope. This allowed the identification and—when possible—the sampling of some of the most relevant elements of the mixtures (e.g., large aggregate particles, hair), including charcoal fragments and vegetable fibers. Subsequently, the samples (extremely crumbly) were gently hand-crushed and dry-sieved using meshes from 3.35 mm to 0.063 mm according to the BS ISO 11277:2020. This allowed for the assessment of the particle size distribution of the sandy/coarse fraction, and to separate the silty/clayey fraction for further analysis. The latter was used to determine the percentage of silt and clay by sedimentation using the pipette method according to the BS ISO 11277:2020, and to carry out X-ray diffraction analyses for the determination of the main clay minerals. X-ray analyses were carried out using a Rigaku StudioLab diffractometer. Quantitative analysis of various crystalline phases was obtained by applying the Rietveld refinement method using the tool provided by the Rigaku SmartLab Studio II software.

Samples for the Radiocarbon Dating

Following the observation under the stereomicroscope of various mortar samples, 11 samples of organic material were isolated from the 7 mortar and soil samples subject to laboratory analyses, and individually sealed into plastic tubes to be sent to the Beta Analytics’ AMS laboratory for radiocarbon dating. Table 1 reports the list of the samples sent to the AMS laboratory with the related information on the Unit where they were taken from, their supposed chronology (based on the archaeological analysis of the buildings and structures), the type of material (i.e., charcoal or vegetable fiber) and the related mass. As the table shows, of the 11 samples, 7 were made of charred material and 4 were non-charred vegetable fiber. When possible, 2 samples for each SBU were collected and dated to verify individual results. Particular attention was paid on-site and inside the laboratories to sample different types of organic material from the same SBU. This approach was used to assess the archaeological significance of the results obtained from the various materials. A detailed description of the SBU where the samples were collected and their relevance within the archaeological context is reported in the next paragraphs. As demonstrated by Table 1, all samples for the radiocarbon dating were within the recommended size (i.e., 5–100 mg). At the AMS laboratory, the samples were pretreated by washing alternatively in acid, alkaline and acid baths. This entailed a wash with HCl to remove the carbonates, followed by a wash with NaOH to remove the organic acid. The samples were, then, rinsed a final time with HCl to neutralize the NaOH. The samples were, subsequently, burned and turned into graphite, and then vaporized and run through the mass spectrometer.

Samples MS_AU_10 (B) _CH01 and MS_AU_10(A)_VF01 (Unit 54)

A charcoal sample (MS_AU_10(B)_CH01) and a vegetable fiber (MS_AU_10(A)_VF01) were collected from the façade of Unit 54 (Figure 4), in the northern area of the Old Town. This is the façade of a building overlooking a small open space in front of the northernmost mosque (U128). The façade was built using yellow-white sandstone elements reused from previous buildings, partially reworked and arranged in regular layers with rather thin mortar joints (1–2 cm thick). The stratigraphic analysis of the façade led to the identification of three construction phases within it (Figure 3). Both samples for the radiocarbon dating were taken from the mortar of the oldest part of the façade (BG9_U54_SBU0001). Results of the stratigraphic analysis suggested that this could be one of the oldest façades in the area, with a possible Late Ottoman (19th–20th c. AD) chronology.

Samples MS_AU_27(A)_CH02 and MS_AU_27(A)_VF02 (Unit 74)

A charcoal fragment (MS_AU_27(A)_CH02) and a vegetable fiber (MS_AU_27(A)_VF02) were taken from the north-facing external wall of U74 (Figure 2). This Unit is located to the northernmost area of the Old Town, built on the top of an embarkment that was based on a large calcareous concretion probably used as a quarry for construction material at some point in time. The topographical location, structural grandeur (7 m high), and stratigraphic composition of the wall from which the sample was taken suggested the possibility that this Unit was part of a town wall. The stratigraphic analysis of the Unit highlighted several construction phases within it. Attention was paid during the sampling work to make sure that the charcoal and vegetable fibers were taken from its oldest part (BG3_FU001_F3_SBU20409). The analysis of the wall suggested a possible construction time in the Late Mamluk - Early Ottoman period (i.e., 15th–17th c. AD).

Samples MS_AU_34(A)_CH03 and MS_AU_34(B)_CH04 (Unit 386)

These two charcoal samples were taken from some masonry structures emerged from an archaeological excavation carried out by the RCU inside the Ibn Yunus Mosque (U386, north of one of the main roads in the southern part of the Old Town; Figure 2). At the time of the excavation, some charcoal samples were collected from various soil levels to radiocarbon date the structures. However, little is known about this archaeological excavation and the interpretation of the 14C results. Hence, a new study of the same archaeological sections and structures was carried out within the MuDUD project to elucidate their stratigraphic sequences and clarify their existence within the rest of the mosque. As a part of this activity, two new charcoal samples were collected from the two stratigraphically oldest structures found in the excavation. The charcoal sample MS_AU_34 (A) _CH03 was embedded in the mortar of a wall with north-south orientation (U386_FUA_F8_SBU21280) at the edge of the eastern section of the excavation. The charcoal sample MS_AU_34 (B) _CH04, instead, was taken from the mortar of the wall U386_FUA_F9_SBU21282, perpendicular to the previous one. The stratigraphic analysis determined that the SBU21280 was built before the SBU21282 (Figure 5, left). Building Archaeology specialists suggested a sequence where the oldest structures (U386_FUA_F8_SBU21280 and U386_FUA_F9_SBU21282) could be of Late Mamluk–Early Ottoman origin (i.e., 15th–17th c. AD).

Figure 5. Stratigraphic analyses of the masonry walls found in the Ibn Yusun mosque with the related sampling points for the charcoal fragments collected: (left) U386 and (right) U670 (Pictures and elaboration by Piero Gilento, Archaïos).

Sample MS_AU_40_CH07 (Unit 670)

Unit 670 is in the southernmost part of the Old Town and is part of BG34 (Figure 2). The sample collected in this Unit was taken from an archaeological excavation carried out in the rear room of the Unit (U670_FUB), where an east-west orientated wall (U670_FUB_F6) was found in the north section. SBU21291 was made of undressed stone elements arranged in irregular layers with large mortar joints filled with wedges (likely the foundation of a wall built using earth-based elements). From this SBU a charcoal fragment (MS_AU_40_CH07) was collected (Figure 5, right). The excavation found soil layers rich in pottery that has preliminarily been dated between the 6th and the 10th c. AD (although these are only initial chronological hypothesis). Hence, the radiocarbon dating of this wall was considered essential to better define the chronology of the entire settlement. Considering the condition of the structure and its position, a preliminary chronology placed the construction of this wall in the Late Mamluk – Early Ottoman period (i.e., 15th–17th c. AD).

Samples MS_AU_35 (A) _VF03, MS_AU_35 (B) _CH05 and CH_AU_36_CH06 (Unit 687)

U687 is a rather long rectangular dwelling house in the centre of BG37, not far from U670 mentioned above (Figure 2). A test trench was opened within a small space in the easternmost part of the Unit (U687_FUC). From this excavation, a rich archaeological stratigraphy emerged that included two masonry structures (U687_FUC_F4 and U687_FUC_F8) running parallel to each other, with no physical connection. The structures were analysed, and a mortar sample was taken from each of them: from SBU21297 in U687_FUC_F8, and from SBU21300 in U687_FUC_F4. The laboratory analysis of these mortars allowed the collection of, respectively, a vegetable fiber (MS_AU_35(A)_VF03) and a charcoal sample (MS_AU_35(B)_CH05; respectively Figures 6 right and 6 left). Another charcoal sample (CH_AU_36_CH06) was taken from a layer of soil (SU21299) extremely rich in charcoal fragments, located in the lowest part of the southern end of the excavation (Figure 6, right). The archaeological analysis of the two walls suggests a Late Mamluk–Early Ottoman origin (i.e., 15th–17th c. AD), or an even older origin.

Figure 6. Images of the masonry walls emerged from the test trench excavated inside the Unit 687 with the sampling points of the organic material collected: (left) east section of the trench with the location of the charcoal sample MS_AU35(B)_CH05; (right) west section of the trench with the sampling points of the charcoal sample MS_AU_36_CH06 and of the vegetable fibre MS_AU_35(A)_VF03 (Pictures and elaboration by Piero Gilento, Archaïos).

MS_AU_50_CH10 (U408)

U408 corresponds to Al-Itham Mosque, which is the last congregational mosque in AlUla Old Town (Figure 2). This building is located on the east edge of the southern area of the settlement and is made of just a single praying room 37 m long and 13 m wide, with an east-west orientation. When the mosque was subject to some conservation works in 2022, archaeological excavations were carried out by an archaeological company. The largest of these excavations was in the centre of the room, in front of the mihrab (the apsidal space indicating the direction to Mecca; Figure 7, top left). Inside this trench several masonry structures emerged, that were subsequently subject to documentation and historical analysis by the MuDUD project. Because of its shape, orientation and position, one of these structures was interpreted as the remains of an older mihrab. The external side of this wall was built using undressed stones laid on irregular layers and bonded by thick mortar joints that allowed the collection of the charcoal sample MS_AU_50_CH10 from U408_FUA_F8_SBU21252 (Figure 7, bottom left). Archaeological evidence suggested a construction time between the 15th and the 16th c. AD.

Figure 7. Plan of the excavation inside the Al-Itham mosque (right-hand side) and images of the sounding (left-hand side). The image on the top left shows the relationship between the current and old mihrab of the mosque, whereas the image on the bottom left shows the SU where the dated sample was collected (Analysis, pictures and CAD drawing by Piero Gilento, Archaïos).

Results and Discussion

Mortar Analysis

Observations of the mortar samples under the stereomicroscope led to the identification of 4 ingredients that strongly characterise the mortars: concretion fragments of various diameter (likely from a quarry at the northern edge of the settlement), vegetable fibers, animal hair, and charcoal fragments. As shown in Table 2, three of the 7 mortar samples that were used for the radiocarbon dating did not contain vegetable fibers, whereas all of them contained charcoal fragments (the sample from U670 was not characterised because collected during an archaeological activity that took place after the laboratory analyses were concluded). Furthermore, 5 samples did not contain hair but contained concretion fragments (only the sample from U54 did not contain these fragments but contained animal hair).

Table 2. List of the mortar samples analysed with the related topographic location, and some of the results from the laboratory characterization (i.e., particle size distribution of the aggregate—PSD—grouping based on the percentage of silt/clay content, record of the presence of vegetal fibers, animal hair, charred material, and concretion lumps)

The dry sieving of the samples led to the identification of 3 groups of mortars with different percentage of particles with a diameter above 3.35 mm (i.e., the largest mesh used): group I is the group of samples with 70–90% particles above the sieve limit; group II.A includes samples with 35–45% of particles with diameter >3.35 mm, and Group II.B includes samples with 5–25% of particles with diameter >3.35 mm. As shown in Table 1, all mortars containing organic material were part of the Group II.B (with the smallest percentage of large particles).

Results of the analysis on the silt and clay fractions proved that all mixtures were very poor in silt and clay: the sample containing the highest percentage of clay produced a result of only 3%. Results of the XRD analyses for the silt/clay fraction showed that the finest fractions in all mortars consisted of: quartz (with percentage varying between 4% and 70%), calcite (6%–61%), clay minerals (1%–40%) mainly represented by kaolinite and illite (however, sample MS_AU_30 also contained traces of sepiolite), and hematite (1%–14%). Dolomite was detected only in sample MS_AU_36 (i.e., mortar sample from which charcoal sample CH_AU_36_CH06 was extracted), whereas halite only in sample MS_AU_34(A). Gypsum was detected only in traces (2–6%) in samples MS_AU_36 and in sample MS_AU_34(A/B) (11-35%).

Overall, the mortar analysis suggested a rather similar composition for all samples bearing organic material. All mortars have a very low clay content (i.e., a modern earth mortar requires a clay content between 10% and 40%; Henry et al. Reference Henry, McCaig, Willet, Godfraind and Steward2015), and—considering some of the ingredients used (i.e., the concretion fragments)—it is likely that these were produced using only locally sourced materials.

Radiocarbon Dating

The results obtained from the AMS laboratory are presented in Table 3 and in Figure 8, where they are quoted in accordance with the Trondheim Convention (Stuiver and Pearson Reference Stuiver and Pearson1986) as conventional 14C ages (Stuiver and Polach Reference Stuiver and Polach1977). The calibrated date ranges were calculated using the IntCal20 calibration curve of Reimer et al. (Reference Reimer, Austin, Bard, Bayliss, Blackwell, Bronk Ramsey, Butzin, Cheng, Edwards and Friedrich2020) and BetaCal 4.20. Calibrations are cited in the table and in the text with the related confidence intervals.

Table 3. Results of radiocarbon dating

Figure 8. Results of the radiocarbon dating method for the samples of charcoal and vegetable fibre analysed in this research. The different colours represent different SBUs where the samples were taken: pink=U54; yellow=U74; green=U386; red=U687; purple=U408 (same colours are used in Figure 2) (Elaboration by Maureen Le Doaré and Piero Gilento Archaïos).

Overall, the results can be divided in 3 main chronological groups:

  • The first group includes the samples MS_AU_10(B)_CH01, MS_AU_34(B)_CH04 and MS_AU_50_CH07 dated between the 15th and the 17th c. AD. However, whereas the first sample was taken from a still standing wall, the other two samples were removed from walls found in archaeological excavations.

  • The second group includes two vegetable samples removed from standing walls (MS_AU_10(A)_VF01 and MS_AU_27(A)_VF02) and a charcoal sample taken from a layer of soil during an archaeological excavation (CH_AU_36_CH06). Results of the radiocarbon dating suggest an age between the end of the 17th and the beginning of the 20th c. AD.

  • The third group includes 3 charcoal samples MS_AU_27 (A)_CH02, MS_AU_34 (A)_CH03, MS_AU_35 (B)_CH05, MS_AU_50_CH10, and a vegetal fiber (MS_AU_35 (A)_VF03) all dated to a period between the 16th and the 20th c. AD (however a higher probability relates to a period between the 16th and the 17th c. AD).

A more detailed analysis of the results obtained based on the SBU where the samples were taken is reported in the following paragraphs.

Units 54 and 74—Radiocarbon Dating of Charcoal and Vegetable Fibers

Different results were obtained for the charcoal and the vegetable fiber collected in the mortar of Unit 74 (colored in yellow in Figure 8). The charcoal sample MS_AU_27 (A)_CH02 was dated to 1618–1670 AD (45.3%) and to 1508–1594 AD (42.7%), whereas the vegetable fiber sample MS_AU_27 (A) _VF02 was dated to 1810–1918 AD (67.8%) and to 1694–1726 AD (27.6%). Similarly to this unit, different results were also obtained for the charcoal sample MS_AU_10(B)_CH01 and the vegetable fiber MS_AU_10 (A) _VF01 taken from the façade of Unit 54 (colored in pink in Figure 8). The charcoal sample was dated to 1474–1638 AD (95.4%), while the vegetable fiber was dated to 1800–1908 AD (68.6%) and 1682–1738 AD (25.7%).

Various hypotheses were considered to explain such difference between the results of the charcoal samples and those of the vegetable fiber. A hypothesis that was initially considered was the possibility that the charcoal samples represented the actual construction time of the buildings, whereas the vegetable fiber a later maintenance work. However, a careful analysis of the stratigraphy, of the photographs taken during the sampling work, and of all radiocarbon data, did not support such difference in the origin for the dated materials. Another hypothesis considered the 14C results of the vegetable fibers as representing the actual construction time of the buildings, whereas the charcoal samples as a contamination due to the accidental embedding of older material in the mortars at the time when these were prepared. A further hypothesis entailed the “old wood” problem (Schiffer Reference Schiffer1986), although in desertic area like in the AlUla region is less relevant due to the limited lifespan of species like tamarind and palm. After careful evaluation of all data, the first hypothesis was disregarded, because the results obtained are in good agreement with the results of the stratigraphic analysis of the building that suggested a possible construction time between the 18th and the 19th c. AD for Unit 54.

Consequence of this interpretation is that the buildings where these mortar samples were collected can be dated to the Ottoman time (i.e., 18th–19th c. AD). In this case, it is likely that the façade of U54 remained intact over the centuries because of the good quality of the building technique and, possibly, of the “prestige” of the building itself (as also suggested by its location in a very central part of the northern area of the Old Town). If this is the case, the façade can, then, be used as a “fossil guide” for the study of the masonry techniques and typologies (doors and windows) used in AlUla Old Town during the Ottoman period (Bonnal et al, forthcoming).

It is important to stress that, differently from the case of Unit 54 (where the initial chronological hypothesis was confirmed by the results of the radiocarbon dating), the initial suggested construction time for the Unit 74 is between the 15th–16th c. AD was not supported by the results of the radiocarbon dating and, therefore, the initial suggestion was reconsidered by the archaeologists.

Ibn Yunus Mosque: Stratigraphic Sequence and Radiocarbon Results

The two charcoal samples MS_AU_34(A)_CH03 and MS_AU_34(B)_CH04 (colored green in Figure 8) were taken from two walls found in the archaeological excavation inside the Ibn Yunus Mosque (U386). Their stratigraphy clearly suggested an older age for the wall with north-south orientation compared to the one with east-west orientation. This sequence is confirmed by the radiocarbon dating results that dates the north-south wall to 330 ± 30 BP whereas the east-west wall to the 270 ± 30 BP. The fact that the two results belong to the same historic period confirms that in the Late Mamluk–Early Ottoman period (i.e., 15th–17th c. AD), some structures already existed in the area currently occupied by the mosque. Very little is known about these structures and their functions since they are only marginally preserved above the foundation level. A clear indication that emerges from these structures is that, at that time, the buildings had a different orientation compared to the mosque currently visible.

Al-Itham Mosque: An Early Ottoman Building in the Southern Area

Some masonry structures including a mihrab emerged inside one of the soundings within the Al-Itham mosque (U408). The mihrab found in the excavation is almost aligned with the one currently in use. The charcoal sample MS_AU_50_CH10 (colored purple in Figure 8) taken from its external side was dated to 1620–1674 AD (51.5%) and to 1516–1590 AD (28.7%). Both results (making a total probability of 80%) are within the Early Ottoman period (16th–17th c. AD). A later chronological period making an overall probability of about 15% suggests a later period: 1766–1800 AD (13.6%) and 1941-Post 1950 (1.6%). However, considering the conditions of the structures where the sample was collected and its context, it is most likely that the mosque was built in the Early Ottoman period (16th–17th c. AD) and this allow inferring that at this time a mosque did exist in the southern area of the Old Town.

Unit 687

Both masonry structures found in the archaeological excavation of U687 have been dated to the same Ottoman period (17th c. AD) using the charcoal sample MS_AU_35(B)_CH05 and a vegetable fiber MS_AU_35(A)_VF03 (colored red in Figure 8). This is the only case where different materials taken from separate structures were dated to the same period. All data related to these masonries (i.e., the archaeological context, the building technology used, and the mortar analysis) confirm a homogenous “constructive culture” for the two structures, which supports the results of the radiocarbon dating.

Furthermore, the result of the additional charcoal sample (CH_AU_36_CH06) collected within U687 supports the chronology obtained for the two masonry structures. Indeed, this charcoal sample was taken from a layer of soil that had a clear stratigraphic relationship with the masonries, having formed later. The charcoal sample from this layer was dated to 1720–1815 AD (46%), 1907-Post 1950 AD (19.5%), 1660–1700 AD (17.4%), 1832–1890 AD (12.5%). Overall, this is the only sample dated to the Ottoman Period (18th–20th c. AD) among all samples dated in the south area of the Old Town, and its chronology is in good agreement with the chronology of the two vegetable fibers dated in the north area of the Old Town discussed earlier.

Unit 670

Despite having been found in association with a large amount of pottery fragments, little is known about the masonry structure unearthed in the archaeological excavation opened inside Unit 670. However, the charcoal sample MS_AU_40_CH07 (colored blue in Figure 8) taken from a section of the structure was dated to 1540–1634 AD (49.9%) and 1456–1529 AD (45.5%). The first chronological range is within the Early Ottoman Empire (16th–17th c. AD), whereas the second one spans across the Late Mamluk Sultanate and the Early Ottoman Empire (15th–17th c. AD). Considering the probabilities emerged from the analysis, it is difficult to identify the most likely period of construction but it is interesting to note that the second chronological range is in good agreement with one of the two chronological groups already identified (i.e., the Late Mamluk-Early Ottoman period). If confirmed, this sample might play an important role in the study of the pottery fragments.

Discussion

Considering the results obtained and the topographic position of the buildings and structures analysed, it is possible to suggest that two important times related to the history of the Town are represented in these results: the first period dates between the mid-15th c. AD and the second half of the 17th c. AD and corresponds to a Late Mamluk-Early Ottoman period, whereas the second period is between the end of the 17th c. AD and the 1920s AD, and corresponds to the Ottoman period.

The first of the two periods is mainly represented in the masonries found inside archaeological excavations in the southern area of the settlement, below the current ground level. This means that, between the end of the Mamluk Sultanate and the beginning of the Ottoman Empire, the southern area of the Old Town was already built, although different buildings existed compared with those visible nowadays. This part of the settlement included a mosque and other structures (likely dwelling houses) that had a different orientation compared to the current settlement, since the road system was based on wider alleys with different orientation compared to the current one. Probably in the Ottoman period, this area of the Town was substantially rebuilt acquiring the characteristics we see nowadays.

The few radiocarbon data related to the northern area provide further information on the settlement in the Ottoman period, since they confirm that between mid-15th and mid-17th c. AD the Old Town covered an area approximately similar to the one currently occupied, except for the north-eastern part of the settlement that was probably built between 1918 and the 1980s (i.e., phase 3 mentioned above). It is important to stress that constructive activities carried out in the 17th c. are known from a written source (Ḥājjī Khalīfah) documenting the restoration of the stronghold and its fortifications for protection against the Bedouins raids (Nasif Reference Nasif1988).

The second major constructive period highlighted by the radiocarbon results, between the end of the 17th c. and the 1920s, is a rather long historic period during which most of the still standing buildings were built. Some of these buildings are of high technical quality (at least for the façades) and are still now in rather good conditions.

Considering the very consistent results of all the mortar analysis, the consistency of the radiocarbon dating and the widespread distribution of the buildings analysed, it is worth considering the possibility that the soil used to produce all mortars was sourced in a very specific area of or around the town, and that such area was used regularly for the supply of construction materials over the centuries.

From a methodological perspective, this research proves that the usability of the chronological information obtained from the radiocarbon dating of organic material embedded in earth mortars is strictly related to two factors: (1) a correct sampling work (e.g., that pays particular attention to the presence of repairing mortars), and (2) a correct and detailed stratigraphic analysis of the buildings and structures where the samples are taken (e.g., to identify the correct sampling points). In such context, the MuDUD project represents a reference point in the investigation of the built heritage of the Arabian Peninsula.

Conclusions

This paper discussed the results of the radiocarbon dating of 11 samples of organic material (i.e., charcoal and vegetable fibers) taken from 7 mortar samples from soil level and structures in AlUla Old Town, with the aim of improving our knowledge of the history of the settlement and acquiring a better understanding of the still standing buildings. The main challenge faced by the archaeologists in AlUla Old Town was the creation of a verifiable, coherent, and reproducible dating tools like the typology of the masonry techniques that can be used on a large scale such as entire settlements. To create such tool, this project focussed on the radiocarbon dating of the organic materials embedded in the mortars used for the construction of buildings and structures (for which a detailed archaeological analysis of the buildings, a laboratory characterization of the mortars, and their radiocarbon dating were necessary). The presence of material of various ages embedded in the mortars led to the identification of the vegetable fibers as the most accurate chronological indicators of the construction time of the buildings. However, the results of this research demonstrate that, if the radiocarbon dating of charred material is used within precise stratigraphic contexts and coherent datasets, it can still bear some useful information, as proved by the results of Unit 687.

Overall, from the results obtained emerges that most of the buildings currently visible above the ground in AlUla Old Town were constructed during the late Ottoman period (19th–20th c. AD), and that an earlier settlement dated between the end of the Mamluk Sultanate and the beginning of the Ottoman Empire (15th–17th c. AD) likely existed in the same location although is currently preserved only in some structures underground.

To conclude, it is important to stress that these results are only preliminary, and the analysis of further samples are needed to reconstruct the chronological development of the entire settlement. As this research confirms, independently from the number of samples analysed, the results of the radiocarbon dating of any sample should be used in conjunction with other tools such as the archaeological analysis of the buildings that can be used to validate the results obtained (e.g., Unit 54), or as a method to question and deepen our understanding of the historic events that affected a building or a structure (e.g., reparation works) when in disagreement (e.g., Unit 74).

Acknowledgments

The authors would like to acknowledge Jessica Giraud (Archaïos CEO) and Panida Pesonel (Archaïos Adjunct director) who made possible the scientific collaboration within the MuDUD Project between Northumbria University and Archaïos. The authors would also like to thank Nairusz Haidar-Vela for all the logistical organization provided and management of the samples, Bénédicte Khan for reviewing the text and Maureen Le Doaré and Gabriela Camargo-Méndez for the support provided within the graphic materials.

References

Al-Muraikhi, M (2019) Al-‘Ulā sous le regard des voyageurs et des pèlerins. In: AlUla. Merveille d’Arabie. Paris: Gallimard, 100–103.Google Scholar
Battesti, V and Marty, L (2023) Bedouins and Sedentaries today in al-‘Ulâ (Kingdom of Saudi Arabia): al-diyâr and al-Dîra in the rear-view mirror. Arabian Humanities 17. Available at: <http://journals.openedition.org/cy/10103; DOI: https://doi.org/10.4000/cy.10103>(Accessed: February 14, 2024).CrossRef(Accessed:+February+14,+2024).>Google Scholar
Bonnal, M, Caciagli, P, Camargo-Méndez, G, Gilento, P, Torre-Guibert, M and Vernet, A (Accepted and forthcoming) Research on traditional architecture of AlUla Old Town (Saudi Arabia): From the stratigraphy to the transformation of the urban pattern through time. In: Proceedings of the Thirteenth International Congress of Archaeology of the Ancient Near East (ICAANE), Copenhagen, 22–26 May 2023.Google Scholar
Brogiolo, GP and Cagnana, A (2012) Archeoliogia dell’Architettura. Metodi e Interpretazioni. Florence: All’Insegna del Giglio.Google Scholar
Gilento, P (2020a) Appendix: the methods of building archaeology. In Anastasio, S (ed), Building between the Two Rivers. An introduction to the Building Archaeology of Ancient Mesopotamia. Oxford: Archaeopress Archaeology, 124144.CrossRefGoogle Scholar
Gilento, P (2020b) Building Archaeology. In Vernet, A, Baaklini, A, Marquqire, C, Gilento, P and Mèreuze R (eds), MuDUD. Old Town Investigation Project for AlUla. Scientific Report. Phase 0. s.l. Paris: Archaïos.Google Scholar
Haykel, B (2010) Western Arabia and Yemen during the Ottoman period. In Fierro M (ed), The New Cambridge History of Islam, vol. 2. The Western Islamic World, Eleventh to Eighteenth Centuries. Cambridge: Cambridge University Press, 436–450. Available at: https://doi.org/10.1017/CHOL9780521839570.017.CrossRefGoogle Scholar
Henry, A, McCaig, I, Willet, C, Godfraind, S and Steward, J (2015) Practical Building Conservation: Earth, Brick & Terracotta. s.l.: Taylor & Francis - Routledge.Google Scholar
Houben, H (1994) Earth Construction. A Comprehensive Guide. s.l.: Practical Action Publishing.Google Scholar
Lawson, FH (2017) Modern Saudi Arabia. In: Oxford Research Encyclopedias. Asian History. Oxford: Oxford University Press. Available at: https://doi.org/10.1093/acrefore/9780190277727.013.270.CrossRefGoogle Scholar
Masters, B (2013) The Arabs of the Ottoman Empire, 1516–1918. A Social and Cultural History. Cambridge: Cambridge University Press. Available at: https://doi.org/10.1017/CBO9781139521970.CrossRefGoogle Scholar
Nasif, A (1988) Al-‘Ulā. An Historical and Archaeological Survey with Special Reference to Its Irrigation System. Riyadh: King Saud University Press.Google Scholar
Pesce, GL, Ball, R, Quarta, G and Calcagnile, L (2012) Identification, extraction, and preparation of reliable lime samples for 14C dating of plasters and mortars with the “pure lime lumps” technique. Radiocarbon 54(3–4), 933942.CrossRefGoogle Scholar
Pesce, G, Quarta, G, Calcagnile, L, D’Elia, M, Cavaciocchi, P, Lastrico, C and Guastella, R (2009) radiocarbon dating of lumps from aerial lime mortars and plasters: methodological issues and results from San Nicolò of Capodimonte Church (Camogli, Genoa, Italy). Radiocarbon 51(2), 867872.CrossRefGoogle Scholar
Peskes, E (2010) Western Arabia and Yemen (fifth/eleventh century to the Ottoman conquest). In M Fierro (ed), The New Cambridge History of Islam, vol. 2. The Western Islamic World, Eleventh to Eighteenth Centuries. Cambridge: Cambridge University Press, 285–298. Available at: https://doi.org/10.1017/CHOL9780521839570.011.CrossRefGoogle Scholar
Reimer, P, Austin, W, Bard, E, Bayliss, A, Blackwell, P, Bronk Ramsey, C, Butzin, M, Cheng, H, Edwards, RL, Friedrich, M et al. (2020) The IntCal20 Northern Hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon 62(4), 725757.CrossRefGoogle Scholar
Rohmer, J, Alsuhaibani, A, Kesguer, F and Alahmari, S (2020a) The Dadan Archaeological Project. Report on the first field season (2020). s.l.: Centre national de la recherche scientifique (CNRS); Agence française pour le développement d’AlUla (Afalula).Google Scholar
Rohmer, J, Alsuhaibani, A, Lesguer, F, Alahmari, S, Bigot, L, Cervantes, P, Desormeau, X, Dumas-Lattaque, P, Girardi, C, Housse, R, Kootstra, F, Lora, S, M’Barek, B, Misme, A, Monchamp, J, Monchot, H, Othman, A, Peignot, P, Pinot, J, Rosak, A, Rossi, I, Shabo, S and Tourtet, F (2022a) The Dadan Archaeological Project. Report on the second field season (2021). s.l.: Cnrs – Umr Orient & Méditerranée; Agence française pour le développement d’AlUla (Afalula); Royal Commission for AlUla (RCU).Google Scholar
Rohmer, J, Lesguer, F, Alsuhaibani, A and Alkhatib-Alkontar, R (2020b) Test Excavation on Site 4215 (al-'Ula, Saudi Arabia). Report of the Oct./Nov. 2019 field campaign s.l.: s.n.Google Scholar
Rohmer, J, Lesguer, F, Bouchaud, C, Purdue, L, Alsuhaibani, A, Tourtet, F, Monchot, H, Dobrowski, V, Decaix, A, Desormeau, P, Alkhatib-Alkontar, R and Reiller, H (2022b) New clues to the development of the oasis of Dadan. Results from a test excavation at Tall al-Sālimīyyah (al-ʿUlā, Saudi Arabia). In Foote R, Guagnin M, Périssé I and Karacic S (eds), Revealing Cultural Landscapes in Northwest Arabia. Proceedings of the Seminar for Arabian Studies 21 (Supplement). Oxford: Archaeopress, 157–190.Google Scholar
Schiffer, MB (1986) Radiocarbon dating and the “old wood” problem: The case of the Hohokam chronology. Journal of Archaeological Science 13(1), 1330.CrossRefGoogle Scholar
Stuiver, M and Pearson, G (1986) High-precision calibration of the radiocarbon time scale, AD 1950–500 BC. Radiocarbon 28(2B), 805838.CrossRefGoogle Scholar
Stuiver, M and Polach, H (1977) Discussion reporting of 14C data. Radiocarbon 19(3), 355363.CrossRefGoogle Scholar
Figure 0

Figure 1. View of AlUla Old Town and of the oasis (centre) within the valley. The two mountain ranges protecting the wadi can be seen in the bottom-right corner of the image (west range) and in the top of it (east range). At the centre of the settlement, the Umm Nāṣir rock formation emerges from the buildings (picture by Piero Gilento, Archaïos).

Figure 1

Figure 2. Map of AlUla Old Town with the individual Building Units and, highlighted with colors, the Units discussed in this paper. The white space in the centre of the settlement is occupied by the Umm Nāṣir rock formation that divides the settlement into two parts (map by Anne Godefroy and Gabriela Camargo-Méndez, Archaïos).

Figure 2

Figure 3. Stratigraphic reading and related Harris’ matrix of U54, 53, 51 and 50 in the northern sector of the Old Town (analysis and drawing Piero Gilento, Archaïos; topographical location Gabriela Camargo-Méndez, Archaïos).

Figure 3

Figure 4. General view from west of the façade of the U54 with the sampling point of the mortar (in yellow) (picture by Piero Gilento, Archaïos; b. Detail of the sampling point (picture by Giovanni Pesce, Northumbria University); c. Macrophotography of the charcoal sample embedded in the mortar (picture by Giovanni Pesce, Northumbria University).

Figure 4

Table 1. List of organic samples sent to the laboratory for the 14C determination with the related laboratory code and information on their origin and nature

Figure 5

Figure 5. Stratigraphic analyses of the masonry walls found in the Ibn Yusun mosque with the related sampling points for the charcoal fragments collected: (left) U386 and (right) U670 (Pictures and elaboration by Piero Gilento, Archaïos).

Figure 6

Figure 6. Images of the masonry walls emerged from the test trench excavated inside the Unit 687 with the sampling points of the organic material collected: (left) east section of the trench with the location of the charcoal sample MS_AU35(B)_CH05; (right) west section of the trench with the sampling points of the charcoal sample MS_AU_36_CH06 and of the vegetable fibre MS_AU_35(A)_VF03 (Pictures and elaboration by Piero Gilento, Archaïos).

Figure 7

Figure 7. Plan of the excavation inside the Al-Itham mosque (right-hand side) and images of the sounding (left-hand side). The image on the top left shows the relationship between the current and old mihrab of the mosque, whereas the image on the bottom left shows the SU where the dated sample was collected (Analysis, pictures and CAD drawing by Piero Gilento, Archaïos).

Figure 8

Table 2. List of the mortar samples analysed with the related topographic location, and some of the results from the laboratory characterization (i.e., particle size distribution of the aggregate—PSD—grouping based on the percentage of silt/clay content, record of the presence of vegetal fibers, animal hair, charred material, and concretion lumps)

Figure 9

Table 3. Results of radiocarbon dating

Figure 10

Figure 8. Results of the radiocarbon dating method for the samples of charcoal and vegetable fibre analysed in this research. The different colours represent different SBUs where the samples were taken: pink=U54; yellow=U74; green=U386; red=U687; purple=U408 (same colours are used in Figure 2) (Elaboration by Maureen Le Doaré and Piero Gilento Archaïos).