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The 2016-2023 archaeological investigations carried out on the top of the Helawa mound (Area A) and along its southern slopes (Step Trench B) brought to light a seamless Halaf to Late Chalcolithic 3 (LC) sequence featuring an exceptional state of preservation of the structures, with rich in situ inventories encompassing complete and restorable vessels (Peyronel et al. 2019; Peyronel, Vacca 2020; Vacca et al. 2020). Moreover, two pottery workshops dating to the Ubaid and LC1 were excavated, allowing the analysis of both direct evidence of ceramic manufacture (furnaces and installations), and indirect variables inferred from the products themselves (Fig. 2).

The last phase of occupation of the prehistoric mound dates to the early LC 3 (ca. 3850-3600 BC), and encompasses domestic structures excavated on the lower mounded area to the north-east (Area D)and one large tripartite building with adjoined rooms to the east and a courtyard paved with pebbles and sherds to the west (Area A, Step Trench B; Figs 2-3). After the LC 3 period, the site was abandoned and reoccupied a few centuries later, during the mid-2nd millennium BC.

A large number of vessels has been collected��from the Ubaid and Late Chalcolithic contexts excavated thus far and sorted out for chrono-typological studies (ca. 3042 diagnostic sherds). Pottery finds have been classified in relation to the detailed stratigraphic and architectural sequence allowing the reconstruction of a relative ceramic periodization, that has been then anchored to a series of radiocarbon dating obtained for the Ubaid and Late Chalcolithic levels (Vacca, Peyronel 2022). This preliminary typological and functional classification of the pottery assemblage from stratified contexts represents a solid base to carry out targeted analyses on techno-morphological and techno-petrographic feature.

Materials and Method

The available dataset consists of 3042 sherds from the 2016-2022 excavations at Helawa, which have been already drawn, filed, and arranged in the MAIPE GIS platform. The whole assemblage has been sorted out in major ceramic classes, or ware groups (e.g., Simple Ware, Painted Simple Ware, Gray Ware, Cooking Ware), based on observable macroscopic characteristics, such as paste colour, hardness, inclusions, and surface treatment. Within each ware group, vessels have been then sorted out according to specific shape classes (open/closed) and morpho-functional types previously defined based on the statistical occurrence of formal and stylistic attributes (Fig. 4).

Out of 3042 sherds, 100 diagnostic fragments (25 dating to the Ubaid, 25 to the LC1, 25 to the LC2 and 25 to the LC3) have been selected and imported in Italy in agreement with the Directorate of Antiquities to carry out archaeometric analyses. Selected sherds are being analysed according to two main interrelated tasks:

1) Technological analyses: the different types of vessels classified according to morphological criteria, have been also studied and described based on recognizable diagnostic features related to specific techniques, methods, and tools, making use of digital high-resolution images obtained with a portable microscope (Dino-lite®) and experimental reference material (Roux and Courty 1998). Different manufacturing techniques (e.g., slab modelling, moulding, coiling, and throwing) have been identified, considering that each method produces characteristic surface features or macro-traces that can be interpreted as distinct manufacturing modes or potter’s gestures. Information about the formation and shaping process, including the use of rotative kinetic energy (RKE), has thus been described through the observation of macro traces recognised on the surface of the vessels and in cross-section. These descriptions have then been compared with information on the distribution and alignment of voids gathered through the analysis of thin sections.��

2) Mineralogical-petrographic investigations: a selection of 100 sherds has already been sampled and submitted to petrographic analyses at the Department of Earth Science of the University of Milan (G.D. Gatta, G. Morabito, D. Comboni). Pottery samples are being analysed in thin section under polarizing optical microscope, using SEM with attached X-ray spectrometer and EMP, to define petrographic groups homogeneous in the microstructure and groundmass, and to obtain a detailed characterisation of inclusions, matrix, porosity, and slip. Moreover, the mineral composition is being determined by X-ray diffraction of the selected ceramics (XRF) at the Department of Geosciences, University of Padova (L. Maritan).��The ware groups, previously defined through macroscopic observations of sherds, are thus being reassessed according to petrographic groups suggesting a reduced number of fabric types identified through petrographic analysis compared with those recognized by the excavators.

Moreover, a selection of 50 sherds that have been previously thin sectioned in Milan have been shipped to the USA to perform multielement bulk compositional analyses (INAA) at the Oregon State University Archaeometric Laboratory (L. Minc). Instrumental Neutron Activation Analysis is aimed to explore compositional variation in ceramics in the Erbil Plain, comparing the results of the Helawa assemblage with that obtained for the site of Surezha (Minc et al. 2019) and more broadly with analyses of ceramics from the northernmost site of Tepe Gawra (Rothman and Blackman 2003). Furthermore, the chemical composition of pottery will be compared with geomorphological samples collected in the area around the site and already processed by the Department of Earth Science of the University of Milan (A. Zerboni, L. Forti).

Preliminary Results��

While archaeometric analyses are still ongoing some preliminary results can be described in terms of petrofabrics and manufacture of vessels in a diachronic perspective, from the Ubaid to the Late Chalcolithic period.��Overall, the mineralogical association of the analyzed samples is very similar, suggesting the use of comparable raw material sources through time, with a difference in the composition of the fabrics mainly related to the addition of aggregates as well as to firing temperature, the latter resulting in newly formed phases such pyroxene and gehlenite (Morabito et al. in press). The composition and mineralogy of pottery is compatible with clay sediments found in the surrounding area suggesting that the use of local clay is highly probable.��

Local production is also envisaged by the discovery of firing structures dating to the Ubaid and Late Chalcolithic 1 respectively. In fact, excavations in Step Trench B, brought to light an Ubaid pottery production area with a large rectangular-shaped kiln (nearly cut through toward the east by a later pit), standing over 0.50 m high, with the firing chamber filled with ashy layers and overfired vessels. Immediately to the south of the kiln were a series of small rectangular mudbrick rooms that have been interpreted as pottery manufacturing installations and bins for clay preparation (Fig. 5). The small finds retrieved in association with the pottery workshop mainly consist of few ring scrapers, grinding stones, mortars, and lithic implements that could relate to the preparation of clay and the grinding of pigments (Peyronel et al. 2019). A parallel for the Helawa pottery workshop is represented by the Late Ubaid/LC 1 complex excavated at Tell Kosak Shamali on the Euphrates Rier, where similar small rooms made of mudbricks connected to kilns were brought to light (Nishiaki et al. 1999).��

In the next LC 1 phase the function of the area is maintained, as documented by the occurrence of numerous kiln wasters, overfired vessels and ring scrapers collected from dumping layers associated with pits and a probable kiln laying beyond the excavation area to the north-west.����

Fig. 5. Helawa, Ubaid pottery kiln K.119 (to the right); stone tools and ring scrapers for pottery manufacture (to the left). ©�Ѵ����ʷ�.

Even through the centuries and down to modern times, the area of Helawa/Aliawa seems to have been strictly related to pottery production as suggested by the presence of clay quarries identified by geomorphological investigations in the surroundings of , and the identification at the same site of an industrial area for pottery production dating to the Akkadian period (mid-late mid-3rd millennium BC), with mudbrick platforms and installations for clay preparation and vessels shaping, and fifty large kilns, some of which reaching 2 m in diameter, organized in clusters and connected each other through a sophisticated system of underground ducts. Pottery production is documented also in later periods, in the 2nd millennium BC, as well as in the Islamic age. Nowadays, traditional brick factories are still operational around Mastawa/Aliawa, extracting clay from local quarries, which is mixed with chaff, water and tempered with straw, shaped through rectangular molds, sun dried and ultimately fired in modern kilns.����

Analyses on the mineralogical composition of sherds (XRD, polarized-light optical microscopy) suggest high firing temperatures during the Ubaid period compared to the Late Chalcolithic, when medium-low firing conditions prevail (Morabito et al in press). The clay composition and recipes employed from one period to the next in the manufacturing of clay vessels indicates a shift from the use of mainly mineral-tempered (Fig. 6a) to coarser chaff-tempered pastes (Fig. 6b) that facilitate to the one hand the shaping of vessels and, to the other, their drying and firing, avoiding shrinkage cracks and thermal shock (Skibo, Schiffer and Reid 1989).����

Finally, the observation of both thin sections under polarized microscope and vessel’s surfaces with a Dino-Light digital microscope (Fig. 6) provides information about the shaping techniques and the tools employed by the potters. In particular, diagnostic elements derived by the microscopic observation of the shape and orientation of voids, as well as the presence of surface features (e.g., concentric parallel striations, fissures and ridges) are being noted to identify the shaping techniques employed and the possible use of rotative devices (Baldi and Roux 2016). Data collected for both the Ubaid and Late Chalcolithic periods will be tested against experimental replica.

Fig. 6a) Ubaid (TH.18.B.96/23) and 6b) LC3 (TH.21.A.725/3) sherds from Helawa. Photo taken with Dino-lite® digital microscope (©MAIPE).

References��

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Learn more about the 2025–2026 Mesopotamian Fellowship here.��