Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-27T20:21:14.322Z Has data issue: false hasContentIssue false
  • English
  • Français

Production or Consumption? Glass Beads from the Roman Villa of Aiano, Tuscany

Published online by Cambridge University Press:  18 October 2021

Cristina Boschetti Open the ORCID record for Cristina Boschetti [Opens in a new window] ,
Bernard Gratuze Open the ORCID record for Bernard Gratuze [Opens in a new window] ,
Marco Cavalieri Open the ORCID record for Marco Cavalieri [Opens in a new window] ,
Sara Lenzi Open the ORCID record for Sara Lenzi [Opens in a new window]  and
Nadine Schibille Open the ORCID record for Nadine Schibille [Opens in a new window]
Cristina Boschetti
Affiliation:
Institut de Recherche sur les Archéomatériaux, CNRS/Université d'Orléans, France
Bernard Gratuze
Affiliation:
Institut de Recherche sur les Archéomatériaux, CNRS/Université d'Orléans, France
Marco Cavalieri
Affiliation:
Institut des Civilisations, Arts et Lettres, Université Catholique de Louvain (UCLouvain), Belgium
Sara Lenzi
Affiliation:
Institut des Civilisations, Arts et Lettres, Université Catholique de Louvain (UCLouvain), Belgium
Nadine Schibille
Affiliation:
Institut de Recherche sur les Archéomatériaux, CNRS/Université d'Orléans, France
Rights & Permissions [Opens in a new window]

Abstract

Excavations in the Roman villa of Aiano yielded twenty glass beads, a pendant, and a glass-recycling furnace, originally interpreted as a bead workshop. This article re-assesses the evidence of bead making in light of new data obtained thanks to recent progress in archaeological glass studies. A detailed study of the typology, technology, and chemical composition of the beads clearly excludes local production. Instead, two different forming techniques, four different base glasses (Roman, HIMT, Foy 2.1 and Foy 2.1/HIMT), and numerous colouring and opacifying materials point to a well-established and extensive network of the Roman bead trade, in which Aiano evidently participated. The majority of the beads can be related to the monumentalization of the villa in the fourth to fifth century ad and represent a sample of the ornaments worn by its inhabitants.

Vingt perles en verre, un pendentif et un four de recyclage du verre, interprété dans un premier temps comme celui d'un atelier de fabrication des perles, ont été découverts lors des fouilles de la villa romaine d'Aiano. Dans cet article, l'hypothèse d'une présence d'artisans perliers sur le site de la villa est confrontée à de nouvelles données obtenues grâce aux progrès récents des études effectuées sur les verres archéologiques. L’étude combinée de la typologie des perles, de leur technologie de production et de leur composition chimique met en évidence la présence de deux techniques de façonnage différentes (perles enroulées et tubes étirés et segmentés), et de quatre verres de compositions différentes (Roman, HIMT, Foy 2.1 et Foy 2.1/HIMT). On observe aussi l'emploi de différents matériaux et techniques de coloration et d'opacification (opacification avec l'aide de composés d’étain et d'antimoine et utilisation de deux minerais de cobalt). Ces résultats excluent clairement l'hypothèse d'une production locale des perles et montrent qu'Aiano était intégré au sein d'un large réseau de commerce antique de perles. La plupart des perles qui y ont été trouvées peuvent être attribuées à la phase de monumentalisation de la villa du IVe au Ve siècle, et sont représentatives des éléments de parure portés par ses habitants. Translation by the authors

Ausgrabungen in der römischen Villa von Aiano ergaben zwanzig Glasperlen, einen Anhänger und einen Glasrecyclingofen, der ursprünglich als Perlenwerkstatt interpretiert wurde. Dieser Artikel betrachtet erneut die Beweislage im Licht neuer Angaben und berücksichtigt dabei die jüngste Forschung in archäologischen Glasstudien. Eine detaillierte Untersuchung der Typologie, Technologie und chemischen Zusammensetzung der Perlen schließt eine lokale Produktion eindeutig aus. Stattdessen deutet das Vorkommen zweier unterschiedlicher Formgebungstechniken, vier verschiedener Rohgläser (römisch, HIMT, Foy 2.1 und Foy 2.1/HIMT) und zahlreicher Farbstoffe, Trübungsmittel und Techniken auf ein gut etabliertes und weitverzweigtes Netz des römischen Perlenhandels hin, an dem Aiano offensichtlich beteiligt war. Die Mehrzahl der Perlen können mit der Monumentalisierung der Villa im vierten bis fünften Jahrhundert in Zusammenhang gebracht werden und repräsentieren einen Teil der von den Einwohnern getragenen Ornamente. Translation by the authors

Keywords

Roman glass beadsglass recycling workshopLate Antique TuscanyRoman glass tradeRoman villaperles en verre romainesfour de recyclage du verreToscane à la fin de l'Antiquitécommerce du verre romainvilla romainerömische GlasperlenGlasrecyclingwerkstattToskana in der Spätantikerömischer Perlenhandelrömische Villa
Type
Article
Information
European Journal of Archaeology , Volume 25 , Issue 2 , May 2022 , pp. 196 - 215
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 in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of European Association of Archaeology

Introduction

Glass beads adorning the body were some of the earliest vitreous materials ever produced in the late fourth millennium bc (Moorey, Reference Moorey1994: 190–92). They became increasingly popular during the Late Bronze Age, when glass production began more systematically, and beads were recovered in substantial numbers from temple and palatial complexes in Mesopotamia and Egypt (Shortland, Reference Shortland2000: 81; Hodgkinson, Reference Hodgkinson2017: 75–105). In the eastern Mediterranean, the products of glass workshops were diverse and beads were made alongside vessels, inlays, and figurines (Shortland, Reference Shortland2000: 81). In this early period, beads were important commodities, recognized for qualities that went beyond their aesthetic appeal (Nightingale, Reference Nightingale, Jackson and Wagner2008). The outstanding symbolic value attributed to beads is clearly reflected in the great distances covered by their trade and their role in rituals. For example, in the fourteenth century bc, thousands of Egyptian glass beads were transported by two ships sunk off the Anatolian coast at Uluburun and Cape Kylidonia (Pulak, Reference Pulak1998; Jackson & Nicholson, Reference Jackson and Nicholson2010). At this time, Egyptian and Mesopotamian beads travelled as far as Scandinavia, where they have been recovered in Danish burials (Varberg et al., Reference Varberg, Gratuze and Kaul2015). In Mesopotamia (Moorey, Reference Moorey1994: 192; Feldman, Reference Feldman2006), Mycenaean Greece (Nightingale, Reference Nightingale, Jackson and Wagner2008, with earlier references), and in Egypt (Müller, Reference Müller2018, with references), beads were buried in the foundation deposits of temples, palaces, and tombs. In Egypt and Nubia, the use of beads in building rituals continued without interruptions for nearly two millennia, illustrated by the evidence from Ptolemaic and Roman temples (Then-Obłuska, Reference Then-Obłuska2017), and Coptic churches as late as the seventh century ad (Then-Obłuska, Reference Then-Obłuska2013).

In the eleventh to tenth century bc, when glassmaking appeared for the first time in the western Mediterranean, beads were the only products manufactured in the workshops of Frattesina and other sites identified in the Po valley (Towle et al., Reference Towle, Henderson and Bellintani2001). These western productions remained isolated and probably ceased with the decline of Frattesina at the end of the tenth century bc (Cavazzuti et al., Reference Cavazzuti, Cardarelli, Quondam, Salzani, Ferrante and Nisi2019). Judging by some exceptional eighth-century bc black beads documented in Spain, Anatolia, Slovakia, and Italy (Conte et al., Reference Conte, Arletti, Mermati and Gratuze2016), some western glass making and glass working may have continued into the Iron Age. The dynamics of bead production and trade during the Iron Age are still insufficiently investigated, and the archaeological record lacks identified bead-making workshops. However, the varied compositional make-up of Iron Age bead assemblages and their typological variability seem to reflect a lively international bead trade (Conte et al., Reference Conte, Arletti, Mermati and Gratuze2016, Reference Conte, Matarese, Vezzalini, Pacciarelli, Scarano and Vanzetti2019). Glass beads were highly popular at that time and they were strung on necklaces or bracelets, but they were also sewn onto clothing as evidenced by finds in elite burials excavated in central Italy and Greece (Gleba, Reference Gleba2017).

Until the end of the Iron Age, glass beads were formed exclusively by winding, a simple process involving coiling and tooling a mass of soft glass around a metallic rod (mandrel). Winding was practiced in all the cultures that produced glass beads, in Asia, Europe, and Africa. The Hellenistic period, from the last decades of the fourth century bc, represents a phase of technological innovation for bead making, especially in Egypt and Greece where new and highly specialized techniques were developed. The identification of these forming techniques is relevant, because technological and chemical studies show a link between specialized forming techniques and the area of production (Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a, with references). A first innovation in Hellenistic bead making is the invention of drawing and segmenting. Segmented beads were formed from hollow glass rods that were divided into individual beads with the help of shaping thongs or moulds with indentations (Spaer, Reference Spaer1993). This technique was popular in a variant known as sandwich-gold glass, where a gold leaf was sandwiched between two layers of colourless glass (Spaer, Reference Spaer1993). At the end of the third century bc, a workshop in Rhodes constitutes the first archaeological proof of the production of beads using this technique, which probably originated in Egypt in the fourth century bc (Weinberg, Reference Weinberg1983; Spaer, Reference Spaer1993). Another innovation in Hellenistic Egypt is the mosaic technique, a variant of winding, in which sections of polychrome canes are gathered around the mandrel. This mosaic technique was originally used to make inlays (Bianchi, Reference Bianchi1983) and beads from the second century bc onwards (Liu et al., Reference Liu, Holland and Holland2017). Evidence for the production of wound beads was found in a second-century bc context at Delos (Nenna, Reference Nenna1993). Currently Roman beads are poorly served by research: a comprehensive typology of Roman beads does not exist, and technological studies are lacking entirely. Two fourth- to sixth-century ad workshops identified in Alexandria, where segmentation and winding were practised, are currently the only archaeologically attested contexts of bead making for the Roman and Late Antique period (Rodziewicz, Reference Rodziewicz1984; Rifa-Abou El Nil & Calligaro, Reference Rifa-Abou El Nil, Calligaro, Dinh-Audouin, Olivier and Rigny2020). There is a complete absence of indicators of bead making in the Italian peninsula, in line with the general lack of evidence for Roman glass working, particularly for the Republican and early Imperial periods (Boschetti, Reference Boschetti and Cifarelli2020). Egyptian mosaic and segmented beads continued to circulate throughout the Mediterranean, but there is no comprehensive map of their distribution (Then-Obłuska, Reference Then-Obłuska2018).

Thanks to the identification of bead winding workshops in Scandinavia, Ireland, and the Netherlands, it is clear that glass beads were manufactured in Europe during the Migration period (Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a, with references). Egyptian mosaic and segmented beads were nonetheless still sought after and traded as far as Scandinavia (Callmer, Reference Callmer1977) and the Caucasus (Bezborodov, Reference Bezborodov1959). Beads made with a Mesopotamian compositional signature also appear on the European market in the seventh century ad, but their provenance is still unclear (Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a, with references). The Migration period is a prolific time for glass beads, which were used for jewellery as well as for beautifying textiles (Juwig, Reference Juwig, Juwig and Kost2010; Pion & Gratuze, Reference Pion and Gratuze2016). Interestingly, the tiny glass beads used for decorating clothes were manufactured in India (Pion & Gratuze, Reference Pion and Gratuze2016; Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a), using a complex technique involving drawing, cold cutting, and hot polishing (Francis, Reference Francis1990). Asian beads circulated in Europe until the end of the sixth century, but the origins of this commerce are obscure. A detailed study of Hellenistic and Roman beads would be helpful to establish the beginning of this trade, which could date back to as early as the end of the third century bc (Francis, Reference Francis1988).

Against this background of limited archaeological evidence and fragmentary studies, the discovery in 2008 of a glass-recycling furnace and seven glass beads in the Roman villa of Aiano in Tuscany was enthusiastically identified as a workshop for the production of beads dating to the Migration period, allegedly the only one in Italy (Cavalieri & Giumlia-Mair, Reference Cavalieri and Giumlia-Mair2009). The furnace dates to the sixth century ad, when the abandoned Roman building was reoccupied to host artisanal activities (Deltenre & Orlandi, Reference Deltenre and Orlandi2016). The discussion of the chemical composition of four beads and a group of tesserae and other glasses from Aiano in 2009 was limited to the identification of colourants and opacifiers (Cavalieri & Giumlia-Mair, Reference Cavalieri and Giumlia-Mair2009). Over the last decade, Roman and Late Antique glass studies have improved significantly; it is now possible to identify different base glasses and trace their place of origin by the heavy elements introduced as impurities in the silica source (Freestone et al., Reference Freestone, Degryse, Lankton, Gratuze, Schneider, Rosenow, Meek and Freestone2018, with references). New data obtained during the archaeological campaigns at Aiano since 2009 cast doubt on the identification of bead production in Aiano. After ten years of research, the building sequence is now clear and there are enough elements to understand the relationship between the beads found at Aiano and the history of this complex building.

Here we present a re-assessment of the Aiano beads, examining all the specimens recovered between 2005 and 2019 and discussing their depositional history, typology, forming technique, and chemical composition. The main objective is to place the Aiano beads in a broad Mediterranean and European context and to evaluate critically their previous interpretation as local products. We aim not only to clarify the meaning and function of the beads in Aiano, but also to reflect on the dynamics that regulated the production and circulation of glass beads between Late Antiquity and the early Middle Ages.

The Roman Villa of Aiano

The Roman villa of Aiano is located in present-day Tuscany, in the district called Tuscia et Umbria since the beginning of the fourth century ad (Figure 1). The building occupies a central position in the Elsa river valley, on top of a plateau created by a palaeo-landslide. The structures, investigated between 2005 and 2019, consist of a large central hall with three apses, surrounded by a corridor with five apses or lobes (N). The hall was preceded on the south side by a quadrangular vestibule connected to a wide corridor oriented north-south (R), which looked onto three rectangular rooms on the west side (A, B, C). The eastern wing was organized as a sequence of small rooms. During the sixth-century ad reoccupation of the villa, this sector housed a series of workshops dedicated to the collection and recycling of materials taken from the building. The principal feature of the building's north wing is a large rectangular hall with four pilasters that opened on the east side onto an open area framed by a porch (V). The building was occupied from the end of the third century to the middle of the seventh century ad and the analysis of the features identified six major phases (Cavalieri, Reference Cavalieri, Cimadomo, Palermo, Pappalardo and Pierobon Benoit2020; Cavalieri & Peeters, Reference Cavalieri, Peeters, Cavalieri and Sacchi2020) (Figure 2, Table 1).

Figure 1. Map of Tuscany, with Aiano (Adapted from cartography of DARMC https://darmc.harvard.edu/).

Figure 2. Plan of the Aiano villa, after the 2018 excavation campaign, showing the distribution of the beads, divided by compositional group and forming technique (polychrome beads are classified according to the base glass used for the body) (adapted from a drawing by A. Novellini). © UCLouvain.

Table 1. Chronological phases of the Aiano villa.

The earliest phase (Phase 1) survives only in rooms A and B, in the south-western sector of the site. During Phase 2, the building twice underwent monumental renovations. The first intervention, datable to the second half of the fourth century, was the creation of a hall with six apses, surrounded by a corridor with five lobes, opening to the south onto a rectangular antechamber. The hall probably functioned as a passageway leading to the northern sector of the villa. In a second phase, possibly a few decades later, the former project was radically modified. Three of the six apses of the main hall were demolished, creating a space for three rectangular rooms. The hall was paved with an opus signinum floor decorated with tesserae, which is still in situ. This intervention was crucial in defining the function of the rooms and transforming the central hall into a monumental hall.

At the end of the fifth century (Phase 3), the villa was abandoned, and parts of the structures collapsed. After a relatively short period of abandonment, the site was reoccupied at the beginning of the sixth century. The building now served various productive activities, where all the materials used in the villa (marble, glass, lead, bronze, bricks) were systematically collected and recycled (Deltenre & Orlandi, Reference Deltenre and Orlandi2016). These activities were responsible for the fragmentation and dispersal of the residual material from the earlier phases of the building. At the present stage of the archaeological investigations, it is possible to identify the south and north wing as the two main sectors of artisan activity. Activities in the south wing are clearly visible archaeologically and include a smithy (Room B) and other pyrotechnological activities (Area 5000) (Cavalieri, Reference Cavalieri and Schörner2013: 302). The north wing housed a combination of pyrotechnological activities difficult to interpret and service spaces. Interestingly, the rooms surrounding the three-apsidal hall were characterized by a high level of specialization: Room I was dedicated to the transformation of copper alloys, activity in Room H was probably linked to a nearby pottery kiln (Room F), while Room L yielded traces of gold working (Cavalieri et al., Reference Cavalieri, Baldini, Giumlia-Mair, Montevecchi, Novellini and Ragazzini2009; Cavalieri & Giumlia-Mair, Reference Cavalieri and Giumlia-Mair2009; Cavalieri, Reference Cavalieri and Schörner2013; Deltenre & Orlandi, Reference Deltenre and Orlandi2016). Particularly relevant for our present study is the discovery of a glass-recycling furnace in Room O. The furnace was used to work both cullet and glass mosaic tesserae, an activity clearly connected to Room A, where 6000 mosaic tesserae, partially altered by heat, were found. In this space, the cullet was stored before being recycled, and two pits were used for roasting and washing the tesserae to remove the mortar. Hundreds of fragmentary glass inlays were recovered from a series of small open spaces located next to the corridor (R), probably similarly dedicated to the storage of glass cullet (Cavalieri et al., Reference Cavalieri, Camin and Paolucci2016).

The function of the spaces in the north wing is more difficult to determine, but it is clear that Room U served as storage for fragments of floor mosaics for re-use (Cavalieri et al., Reference Cavalieri, Lenzi, Cantisani and Angelelli2013: 538, 543, figs 2–3). Part of this space also served the daily needs of the craftsmen. There were, for example, a series of structures for cooking and possibly for baking in corridor K. In short, throughout most of the sixth century, the villa at Aiano was an open-air workshop devoted to collecting and transforming materials spoliated from the abandoned building. Similar multi-activity recycling workshops are documented in other Late Antique Tuscan sites (Sebastiani, Reference Sebastiani2016: 66), glass-recycling, for instance, is clearly documented in Spolverino (Sebastiani & Derrick, Reference Sebastiani, Derrick, Duckworth and Wilson2020).

All productive activities came to an end and the building was finally abandoned during Phase 4. The decline of the villa is evident from the second half of the seventh century (Phase 5) in the form of collapsed walls almost everywhere in the building. The only traces of occupation are the tombs of two individuals, possibly pilgrims, buried in rooms Q and Z. Modern agricultural activities are responsible for damaging the features (Phase 6).

The Glass Beads from Aiano: Deposition and Distribution

Twenty glass beads and one pendant were retrieved during the excavation campaigns conducted at Aiano from 2005 to 2019. The beads were all deposited in backfills formed between the sixth and the seventh century, when the artisanal activities came to an end and the area was abandoned (Table 1 and Supplementary Material Table S1). These backfills are characterized by a high degree of residuality. Finds dating to the second half of the fourth century, the time of the monumental renovation of the villa, are accompanied by late fifth- to seventh-century material. Earlier material is less frequent. The beads were scattered across the vast area occupied by the villa, without any significant clustering, and no bead was deposited in fills associated with the glass-recycling furnace excavated in the ambulatio of the five-lobed hall (Room O). An important concentration of glass-working waste was retrieved from Area 7000, located immediately outside the central hall and interpreted as a zone used as dump, collecting the waste generated by the craft activities.

The visual examination of all the glass finds from Aiano ascertained that there is no evidence that could be linked to bead working, such as tools, glass canes, and/or failed beads. The beads are a small group of finished objects, which speaks against a productive site. Some fragments of a ceramic container with holes found near the furnace were described as a brazier used for bead making (Cavalieri & Giumlia-Mair, Reference Cavalieri and Giumlia-Mair2009). This identification was based on the representation of a similar object in a Renaissance woodcut print entitled Der Glasser (Cavalieri & Giumlia-Mair, Reference Cavalieri and Giumlia-Mair2009: 1026–27). A careful examination of the scene, however, reveals that the woodcut print does not actually depict a glass-working scene, but the assembly of a stained-glass window. Moreover, braziers are unsuitable for glass working and the object excavated in Aiano certainly had a different function. The glass-working waste from Area 7000 includes fragments of vessels and tesserae deformed by heat, fragments of refractory material with adhering glass, and masses of tooled coloured glass (Figure 3). These finds are evidence of the recycling of colourless and coloured glass, but it is impossible to ascertain whether this glass was shaped into new objects at Aiano or whether it was moved to secondary workshops as unprocessed glass. As documented during the fourth century ad at Aquileia (Boschetti et al., Reference Boschetti, Mantovani and Leonelli2016) and during the ninth century at San Vincenzo al Volturno (Schibille & Freestone, Reference Schibille and Freestone2013), colourless glass was recycled and coloured by adding mosaic tesserae. A similar recycling process probably took place in Aiano, where the deposits associated with the furnace yielded an exceptional concentration of windowpanes and mosaic tesserae.

Figure 3. Glass lumps and mosaic tesserae deformed from the heat of the furnace retrieved from the dump outside the villa (Area 7000).

Materials and Methods

The technology for forming beads can be easily identified by visual examination and is the main criterion adopted to classify the beads from Aiano. All twenty beads and the pendant were selected for chemical analysis (Figure 4). The cleaned but unprepared samples were analysed by LA-ICP-MS (laser ablation coupled with inductive plasma mass spectrometry) at IRAMAT-CEB in Orléans (France), using a Resonetics M50E excimer 193 nm laser and a Thermo Fischer Scientific ELEMENT XR mass spectrometer. The analyses were conducted with 5 mJ energy, 10 Hz pulse frequency and a beam diameter that ranges from 30 to 100 μm depending on the transition metals and particles present in the glass (Gratuze, Reference Gratuze and Janssens2013).

Figure 4. The Aiano beads, divided by forming technique and base glass composition, with indication of the sample number, cobalt source, yellow and white opacifiers.

Typology and forming technology

The current literature on the typology of beads circulating during the Roman Empire and the early Middle Ages is very limited, but sufficient to place the Aiano beads in a geographical and chronological framework. While the Aiano beads are clearly different from the types circulating in Migration-period Europe (Callmer, Reference Callmer1977; Burgmann, Reference Burgmann2004; Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a), they are reminiscent of Roman and Late Antique types (Mandruzzato & Marcante, Reference Mandruzzato and Marcante2008). From the point of view of the forming technique, the corpus of Aiano beads only contains wound and segmented beads, two of the four forming techniques documented in the ancient Mediterranean (Figure 4). Drawn, cold-cut, hot-polished, and mosaic beads are absent.

The majority of the Aiano beads (n = 17) and the pendant (TCC09) were made by winding. Three small, monochrome beads (TCC01, 05, 015) can be identified with types that were popular from the third to the sixth century and imitate precious stones (Swift, Reference Swift2003). One light blue bead (TCC04) of this group belongs to a type well documented in Egypt and Nubia from the fourth to the sixth century (Then-Obłuska, Reference Then-Obłuska2018; Then-Obłuska & Wagner, Reference Then-Obłuska, Wagner, Wolf and De Pury-Gysel2017). Such beads were often mounted in gold or bronze jewellery in combination with real stones. Seven beads and the pendant TCC09 from Aiano are distinguished by the black glass from which their body was made (TCC06, 07, 11, 12, 13, 17, 18). This type of glass was particularly appreciated for making ornaments from the third to the fifth century (Cosyns, Reference Cosyns2011). The black bead with red, white, and light blue mottled decoration (TCC12) finds parallels in the Late Antique burials of the Fayoum and in the jewellery workshop excavated in the Diana quarter in Alexandria (Boschetti et al., Reference Boschetti, Gratuze and Schibille2020a: 12, with references; Rifa-Abou El Nil & Calligaro, Reference Rifa-Abou El Nil, Calligaro, Dinh-Audouin, Olivier and Rigny2020). Similar beads have been recorded in Italy from the first to the fifth century (Mandruzzato & Marcante, Reference Mandruzzato and Marcante2008: 4, 158). The workshop of the Diana quarter also offers a parallel for the spiral bead TCC18. Jug-shaped pendants, like an exemplar from Aiano (TCC09), are attested in the Levant and Egypt and were quite popular in the Italian peninsula during the second half of the fourth and the first half of the fifth century (Mandruzzato & Marcante, Reference Mandruzzato and Marcante2008: 4, 36–37, 74–75; Bolla, Reference Bolla and Invernizzi2011; Mandruzzato, Reference Mandruzzato and Fontana2017). They are usually interpreted as Christian amulets, and often deposited in burials of women and children (Spaer et al., Reference Spaer, Barag, Ornan and Neuhaus2001: 171; Bolla, Reference Bolla and Invernizzi2011: 33). A possible Egyptian origin can be assumed for the bead TCC21 since its shape and decoration corresponds to Late Antique Egyptian spindle whorls (Spaer et al., Reference Spaer, Barag, Ornan and Neuhaus2001: 259–61).

Interestingly, the few publications on Roman beads tend to identify them as products that circulated locally or on a regional scale (Burgmann, Reference Burgmann2004; Mandruzzato & Marcante, Reference Mandruzzato and Marcante2008). However, looking at the beads from a broad geographic perspective, the scenario changes radically. For example, a bead from Aquileia, identical to the large, spherical black bead TCC07 decorated with crossed white trails and green and yellow eyes, is dated to the fourth to fifth century on the basis of parallels from present-day Austria, which is assumed to be its place of origin (Mandruzzato & Marcante, Reference Mandruzzato and Marcante2008: 64). Other examples of this type were recovered from British burials of the middle of the fifth to the first quarter of the sixth century, where they are thought to be locally produced (Burgmann, Reference Burgmann2004: 77, 92). In the 1970s, Margaret Guido discussed the circulation of this type of bead in Britain and noticed some matching parallels in fourth- to fifth-century continental contexts, classifying this type as an exotic Roman product imported from mainland Europe (Guido, Reference Guido1978: 101–02, 232). A specimen excavated from a third-century burial in Classe, the port city of Ravenna, and associated with black beads decorated with coloured zig-zag trails, similar to Aiano bead TCC06, is evidence of an earlier circulation of this type in Italy (Montevecchi, Reference Montevecchi and Marini Calvani2000). Other wound beads from Aiano, like the melon bead TCC19, or the cylindrical beads TCC02, 03, and 20, belong to very common types, and their date cannot be safely established on typological grounds.

Only three monochrome beads are drawn and segmented (TCC08, 14, 16). The green bead TCC08 is furthermore finished by hot polishing, as occasionally documented in beads of this kind (Spaer, Reference Spaer1993). Drawn beads of this type are Egyptian products, popular in Europe since Late Antiquity, with a major diffusion from the fourth century ad onwards.

Chemical composition

To further refine the chronology and provenance of the glass beads from Aiano, we can draw on the chemical analysis of the glass (Supplementary Material Table S1). Ancient glass can be classified into different primary production groups, according to the nature of the raw materials used by the glassmakers. From the Hellenistic period up to the ninth century ad, the dominant trend in Mediterranean glassmaking was the use of natron as the main fluxing agent (Shortland et al., Reference Shortland, Schachner, Freestone and Tite2006). Indeed, all the beads and the pendant from Aiano are natron type glasses with low MgO and K2O concentrations (<2% wt). Several samples have higher phosphorus and elevated potassium oxides, with lower chlorine contents. These features are markers of pollution probably due to recycling and/or extended secondary working (Schibille & Freestone, Reference Schibille and Freestone2013; Jackson & Paynter, Reference Jackson and Paynter2016). The different compositional groups of first-millennium natron glasses can be distinguished on the basis of the ratios of Al2O3/Si2O and TiO2/Al2O3 that reflect the heavy mineral and feldspar contents of the silica source (Freestone et al., Reference Freestone, Degryse, Lankton, Gratuze, Schneider, Rosenow, Meek and Freestone2018). The glasses used for the Aiano beads are broadly consistent with three major compositional groups (Figure 5). Most samples (n = 26) correspond to Roman glass made and circulating throughout the Roman Empire from the first to the third century (Jackson, Reference Jackson2005; Silvestri et al., Reference Silvestri, Molin and Salviulo2008; Paynter & Jackson, Reference Paynter and Jackson2019). Antimony or manganese were often added directly during the primary production in their capacity as decolourizers. The addition of manganese was typical of Levantine glass making, while antimony was preferred in Egypt. The Na2O/SiO2 and CaO/Al2O3 ratios in Roman glasses can be used to distinguish Egyptian antimony-decolourized from Levantine manganese-decolourized glass because it is currently believed that Roman and Late Antique glass made in Egypt has a higher soda and lower lime content than contemporary Levantine glass (Jackson, Reference Jackson2005; Freestone, Reference Freestone2015, Reference Freestone and Tal2020). With a few exceptions, the Aiano Roman glasses appear to represent a mixture of recycled Roman Sb and Mn glasses (Figure 6).

Figure 5. Base glass characteristics of the Aiano beads, separated as a function of Al2O3/SiO2 and TiO2/Al2O3 ratios.

Figure 6. Na2O/SiO2 and CaO/Al2O3 ratios of the Roman samples from Aiano, compared to different Roman glass reference groups (Roman Sb, Roman Mn, Roman mixed), based on the glass finds from the Iulia Felix shipwreck (IF) (data source: Silvestri, Reference Silvestri2008; Silvestri et al., Reference Silvestri, Molin and Salviulo2008).

A second group (n = 7), with higher TiO2/Al2O3 can be identified as belonging to the so-called Foy 2.1 group, named after Danièle Foy, who identified it (Foy et al., Reference Foy, Picon, Vichy, Thirion Merle, Foy and Nenna2003) (Figure 5). This compositional group is widely distributed in Europe and North Africa from the second half of the fifth to the seventh century and is of Egyptian origin (Foy et al., Reference Foy, Picon, Vichy, Thirion Merle, Foy and Nenna2003; Freestone et al., Reference Freestone, Degryse, Lankton, Gratuze, Schneider, Rosenow, Meek and Freestone2018; De Juan Ares et al., Reference De Juan Ares, Vigil-Escalera Guirado, Cáceres Gutiérrez and Schibille2019; Barfod et al., Reference Barfod, Freestone, Lesher, Lichtenberger and Raja2020). A third group (n = 6), with even higher TiO2/Al2O3 ratios resembles HIMT (High Iron, Manganese, and Titanium) glass made in Egypt during the fourth and fifth centuries (Freestone et al., Reference Freestone, Degryse, Lankton, Gratuze, Schneider, Rosenow, Meek and Freestone2018, with references). However, these samples have exceptionally high iron contents that would have augmented the titanium oxide levels and thus may be closer to Foy 2.1 (Figure 5, Table S1). Finally, one sample, with the highest TiO2/Al2O3, has the typical values of HIMT glass (Figure 5).

The identification of the colouring technology underlying the Aiano beads can serve as an additional chronological marker (Figure 4). The majority of the Roman glasses are opacified with calcium and lead antimonate that were commonly used until the fourth century ad (Boschetti et al., Reference Boschetti, Leonelli, Rosa, Romagnoli, Ángel, Tévar and Schibille2020b, with references). The transition to tin-based compounds is documented systematically from the fourth century, and this change emerged first in the eastern Mediterranean (Tite et al., Reference Tite, Pradell and Shortland2008). This new technology underlies one yellow (TCC9) and two Roman white glasses (TCC 11, 12), and one sample of the Foy 2.1 group (TCC17). The cobalt-bearing raw materials can similarly serve as a temporal marker in so far as the high Co/Ni ratios typical of Roman glasses decrease over time (Gratuze et al., Reference Gratuze, Pactat and Schibille2018). In all, with the exception of two of the Aiano Roman glass beads (TCC05, 21), the cobalt to nickel ratios are indeed high (Figure 7). The later cobalt signature can be detected in all Foy 2.1 samples except one (TCC14) (Figure 7).

Figure 7. Cobalt relative to nickel concentrations distinguish Roman from Late Antique cobalt sources and confirm the chronological separation of the Roman, Foy 2.1, and Foy 2.1/HIMT glasses used in the Aiano beads.

Chronology and Provenance

The relationships between base glass, forming technology, typology, and, in polychrome beads, the combination of different base glasses, colourants, and opacifiers are useful to establish their relative chronology and provenance. The chemical composition is particularly helpful for the chronology of the monochrome wound beads because they are difficult to date on typological grounds. Four beads are made with Roman glass: the colourless melon bead TCC19 and three drop-shaped beads (TCC04, 05, 15). In the opaque green bead TCC04, the association of Roman base glass with calcium antimonate as an opacifier supports a date not later than the fourth century. By contrast, the blue bead TCC05 is opacified by tin oxide and is most likely to be a post-fourth century artefact. The spiral black bead TCC18 is made of Foy 2.1/HIMT glass and can be matched with similar black beads probably made in Egypt during the fourth and fifth centuries (Cosyns, Reference Cosyns2011). A similar date can be proposed for the simple barrel-shaped colourless bead TCC01 made from HIMT glass.

The polychrome wound beads can be divided into two groups. The first group includes six beads (TCC03, 06, 07, 10, 13, 20), all made with recycled Roman glass, antimony-based opacifiers, and Roman cobalt with a high Co/Ni ratio (TCC13). These criteria imply a date probably in the fourth century at the latest. Two beads (TCC06, 07) with typological parallels from the third century, may be residual, originating from the first phase of the villa. A second group, including four beads (TCC02, 11, 12, 21) and the pendant TCC09, combines Foy 2.1 and HIMT glass for the body and recycled Roman glass for the decoration of the beads. The green Roman glass thread applied on the HIMT/Foy 2.1 red bead TCC02 is opacified by calcium antimonate. In the other beads of this group and in the pendant TCC09, the Roman glass is opacified by tin oxide (TCC11, 12) calcium antimonate (21) and lead stannate (TCC09). Roman cobalt is present in the Foy 2.1 translucent body of one mottled bead (TCC11). The Roman blue thread of the bead TCC21, opacified by calcium antimonate, is coloured by a late source of cobalt. Finally, one blue mottled bead (TCC17) is entirely made of Foy 2.1 glass. The translucent blue body is coloured by a post-fourth century cobalt raw material, and the white dots are opacified by tin oxide. This is the only bead where the base glass, the cobalt raw material, and the opacifier point to a date not earlier than the middle of the fifth century. The Egyptian base glass compositions and the typological parallels support the hypothesis that the Aiano beads were imported from Egypt. This interpretation is highly probable especially for the three mottled beads (TCC11, 12, 17), the bead/spindle whorl TCC21, and the jug-shaped pendant TCC09.

The three drawn-segmented beads (TCC8, 14, and 16) are made with Foy 2.1 glass. Both the base glass and the forming technology lead us to identify these beads as Egyptian products, manufactured between the fifth and the seventh century. The Roman cobalt identified in the blue bead TCC14 suggests a date during the earliest phase of circulation of the Foy 2.1 base glass, in the middle of the fifth century. The distribution of the findspots of the beads, divided by chemical composition and forming technology, does not reveal significant clustering. The exception are the three drawn-segmented beads that were found in contexts connected by a direct stratigraphic correlation. These three beads might have been strung together, but there are too few elements to demonstrate this hypothesis (Figure 2).

Conclusions

The re-analysis of the corpus of the Aiano glass beads changes their interpretation, date, and connection to the villa and the glass-recycling infrastructures investigated there. The stratigraphic position of the beads and the lack of archaeological indicators of bead production at Aiano rule out a local production during the reoccupation of the building. The results of the typological, technological, and chemical analyses establish a direct link with the life of the villa during its main period of prosperity. The middle of the fourth to the fifth century ad, to which the majority of the beads and the pendant belong, was the period in which the building underwent a fundamental monumentalization. It can be reasonably assumed that the Aiano beads were ornaments worn by the people who lived in the villa before it was abandoned. A few beads can be dated to as early as the middle of the third century and can be assigned to the first phase of the building. All the drawn beads and at least half the wound beads and the pendant are imports, probably from Egypt. Rather than being local products, the Aiano beads are objects obtained through an exchange network operating at a Mediterranean and European level. Beads travelled exceptionally long distances in the period between the Bronze Age and the Iron Age, and, later, during the Migration period. Contrary to previous perceptions of Roman beads as generally worthless products, produced and consumed locally, the clear identification of exotic beads among the finds from Aiano leads to a necessary re-assessment of the status of Roman glass beads in terms of their aesthetic, economic, and symbolic value. While the international dimension of the bead trade during the Roman and Late Antique period or the extent of its market is currently far from understood, the results obtained for the Aiano group support a model of long-distance exchange.

Supplementary Material

To view supplementary material for this article, please visit https://doi.org/10.1017/eaa.2021.34.

Acknowledgments

This project has received funding from the European Research Council under the European Union's Horizon 2020 research and innovation programme (grant no. 647315 to Nadine Schibille). The ‘Regio VII, The Elsa Valley during the Roman Age and Late Antiquity’ project has received funding from the Belgian Fund for Scientific Research (FSR-FNRS) and the municipality of San Gimignano in Italy. For help with storage in San Gimignano and archaeological and topographical drawing, we would like to thank Dr Gloriana Pace and Dr Alessandro Novellini. For the excavation of the villa of Aiano, we are grateful to the Soprintendenza Archeologia, Belle Arti e Paesaggio of Siena, Grosseto and Arezzo. The funding organizations have had no influence in the study design, data collection, analysis, decision to publish, or preparation of this manuscript.

References

Barfod, G.H., Freestone, I.C., Lesher, C.E., Lichtenberger, A. & Raja, R. 2020. ‘Alexandrian’ Glass Confirmed by Hafnium Isotopes. Scientific Reports, 10: 11322. https://doi.org/10.1038/s41598-020-68089-wCrossRefGoogle Scholar
Bezborodov, M.A. 1959. Glasherstellung bei den slawischen Völkern an der Schwelle des Mittelalters. Wissenschaftliche Zeitschrift der Humboldt-Universität zu Berlin, 8: 187–93.Google Scholar
Bianchi, R.S. 1983. Those Ubiquitous Glass Inlays. Journal of Glass Studies, 25: 2935.Google Scholar
Bolla, M. 2011. Clastidium e l'area Pleba. In: Invernizzi, R., ed. …Et in memoriam eorum. La necropoli romana dell'area Pleba di Casteggio:. Casteggio: Commune di Casteggio, pp. 39269.Google Scholar
Boschetti, C. 2020. Vetro e blu egizio nel Ninfeo di Segni: aspetti decorativi, tipologici e tecnologici. In: Cifarelli, F.M., ed. Il Ninfeo di Q. Mutius a Segni. Rome: Quasar, pp. 5567.Google Scholar
Boschetti, C., Gratuze, B. & Schibille, N. 2020a. Commercial and Social Significance of Glass Beads in Migration-Period Italy: The Cemetery of Campo Marchione. Oxford Journal of Archaeology, 39: 319–42. https://doi.org/10.1111/ojoa.12200CrossRefGoogle Scholar
Boschetti, C., Leonelli, C., Rosa, R., Romagnoli, M., Ángel, M., Tévar, V. & Schibille, N. 2020b. Preliminary Thermal Investigations of Calcium Antimonate Opacified White Glass Tesserae. Heritage, 2: 549–60. https://doi.org/10.3390/heritage3020032CrossRefGoogle Scholar
Boschetti, C., Mantovani, V. & Leonelli, C. 2016. Glass Coloring and Recycling in Late Antiquity: A New Case Study from Aquileia (Italy). Journal of Glass Studies, 58: 6986.Google Scholar
Burgmann, B. 2004. Glass Beads from Early Anglo-Saxon Graves: A Study of the Provenance and Chronology of Glass Beads from Early Anglo-Saxon Graves, Based on Visual Examination. Oxford: Oxbow.Google Scholar
Callmer, J. 1977. Trade Beads and Bead Trade in Scandinavia, ca 800–1000 ad (Acta archaeologica Lundensia Series in 4o, 11). Lund: Gleerup & Bonn: Habelt.Google Scholar
Cavalieri, M. 2013. Quid igitur est ista villa? L'Etruria centro-settentrionale tarda Antichità e alto Medioevo. Nuovi dati e vecchi modelli a confronto sulla villa d'Aiano-Torraccia di Chiusi. In: Schörner, G., ed. Leben auf dem Lande. ‘Il Monte’ bei San Gimignano. Ein römischer Fundplatz und sein Kontext. Vienna: Phoibos, pp. 283319.Google Scholar
Cavalieri, M. 2020. Investigating Transformations through Archaeological Records in the Heart of Tuscany: The Roman Villa at Aiano between Late Antiquity and the Early Middle Ages. In: Cimadomo, P., Palermo, R., Pappalardo, R. & Pierobon Benoit, R., eds. Before/After: Transformation, Change, and Abandonment in the Roman and Late Antique Mediterranean. Oxford: Archaeopress, pp. 97113.Google Scholar
Cavalieri, M. & Giumlia-Mair, A. 2009. Lombardic Glassworking in Tuscany. Materials and Manufacturing Processes, 24: 1023–32. https://doi.org/10.1080/10426910902987119CrossRefGoogle Scholar
Cavalieri, M. & Peeters, A. 2020. Dalla villa al cantiere. Vivere in Toscana tra tarda Antichità ed alto Medioevo: la villa d'Aiano (Siena). In: Cavalieri, M. & Sacchi, F., eds. La villa dopo la villa. Trasformazione di un sistema insediativo ed economico in Italia centro-settentrionale tra tarda Antichità e Medioevo. Louvain: Presses Universitaires de Louvain, pp. 6178.Google Scholar
Cavalieri, M., Baldini, G., Giumlia-Mair, A., Montevecchi, N., Novellini, A. & Ragazzini, S. 2009. San Gimignano (SI). La villa di Torraccia di Chiusi, località Aiano. Dati ed interpretazioni dalla V campagna di scavo, 2009. Notiziario della Soprintendenza per i Beni archeologici della Toscana: 492517.Google Scholar
Cavalieri, M., Camin, L. & Paolucci, F. 2016. I sectilia vitrei dagli scavi della villa romana di Aiano-Torraccia di Chiusi (Siena, Toscana). Journal of Glass Studies, 58: 286–91.Google Scholar
Cavalieri, M., Lenzi, S. & Cantisani, E. 2013. La fine della villa tardoantica di Aiano-Torraccia di Chiusi (San Gimignano, Siena): la sistematica distruzione dei suoi arredi. Nuovi dati archeologici su litotipi e sistemi decorativi. In: Angelelli, C., ed. Atti del XVIII colloquio dell'associazione italiana per lo studio e la conservazioen del mosaico. Tivoli: Ante Quem, pp. 537–44.Google Scholar
Cavazzuti, C., Cardarelli, A., Quondam, F., Salzani, L., Ferrante, M., Nisi, S., et al. 2019. Mobile Elites at Frattesina: Flows of People in a Late Bronze Age ‘Port of Trade’ in Northern Italy. Antiquity, 93: 624–44. https://doi.org/10.15184/aqy.2019.59CrossRefGoogle Scholar
Conte, S., Arletti, R., Mermati, F. & Gratuze, B. 2016. Unravelling the Iron Age Glass Trade in Southern Italy: The First Trace-Element Analyses. European Journal of Mineralogy, 28: 847–51. https://doi.org/10.1127/ejm/2016/0028-2572CrossRefGoogle Scholar
Conte, S., Matarese, I., Vezzalini, G., Pacciarelli, M., Scarano, T., Vanzetti, A., et al. 2019. How Much Is Known About Glassy Materials in Bronze and Iron Age Italy? New Data and General Overview. Archaeological and Anthropological Sciences, 11: 1813–41. https://doi.org/10.1007/s12520-018-0634-6CrossRefGoogle Scholar
Cosyns, P. 2011. The Production, Distribution and Consumption of Black Glass in the Roman Empire During the 1st–5th Century ad: An Archaeological, Archaeometric and Historical Approach (unpublished PhD dissertation, Free University of Brussels).Google Scholar
De Juan Ares, J., Vigil-Escalera Guirado, A., Cáceres Gutiérrez, Y. & Schibille, N. 2019. Changes in the Supply of Eastern Mediterranean Glasses to Visigothic Spain. Journal of Archaeological Science, 107: 2331. https://doi.org/10.1016/j.jas.2019.04.006CrossRefGoogle Scholar
Deltenre, F.-D. & Orlandi, L. 2016. « Rien ne se perd, rien ne se crée, tout se transforme ». Transformation and Manufacturing in the Late Roman Villa of Aiano-Torraccia di Chiusi (5th-7th Century ad) – Villa romana di Aiano-Torraccia di Chiusi. Postclassical Archaeologies, 6: 7190.Google Scholar
Feldman, M. 2006. Diplomacy by Design: Luxury Arts and an ‘International Style’ in the Ancient Near East, 1400–1200 bce. Chicago (IL): University of Chicago Press.Google Scholar
Foy, D., Picon, M., Vichy, M. & Thirion Merle, V. 2003. Caractérisation des verres de la fin de l'Antiquité en Méditerranée occidentale : l’émergence de nouveaux courants commerciaux. In: Foy, D. & Nenna, M.-D, eds. Échanges et commerce du verre dans le monde antique. Actes du Colloque de l'Association française pour l'archéologie du verre, Aix-en-Provence et Marseille, 7–9 juin 2001. Montagnac: Monique Mergoil, pp. 4185.Google Scholar
Francis, P. Jr 1988. Glass Beads in Asia. Part I. Introduction. Asian Perspectives (Honolulu ), 28: 121.Google Scholar
Francis, P. Jr 1990. Glass Beads in Asia, Part II: Indo-Pacific Beads. Asian Perspectives (Honolulu ), 29: 123.Google Scholar
Freestone, I.C. 2015. The Recycling and Reuse of Roman Glass: Analytical Approaches. Journal of Glass Studies, 57: 2940.Google Scholar
Freestone, I.C. 2020. Apollonia Glass and its Markets: An Analytical Perspective. In: Tal, O., ed. Apollonia-Arsuf, Final Report of the Excavations, 2: Excavations Outside the Medieval Town Walls. Winona Lake (IN): Eisenbrauns, pp. 341–48.Google Scholar
Freestone, I.C., Degryse, P., Lankton, J., Gratuze, B. & Schneider, J. 2018. HIMT, Glass Composition and Commodity Branding in the Primary Glass Industry. In. Rosenow, M.P., Meek, A. & Freestone, I.C, eds. Things that Travelled: Mediterranean Glass in the First Millennium ad. London: UCL Pres, pp. 159–90.10.2307/j.ctt21c4tb3.14CrossRefGoogle Scholar
Gleba, M. 2017. Tracing Textile Cultures of Italy and Greece in the Early First Millennium bc. Antiquity, 91: 1205–22. https://doi.org/10.15184/aqy.2017.144CrossRefGoogle Scholar
Gratuze, B. 2013. Glass Characterisation Using Laser Ablation Inductively Coupled Plasma Mass Spectrometry Methods. In: Janssens, K., ed. Modern Methods for Analysing Archaeological and Historical Glass, 1: 201–34. https://doi.org/10.1002/9781118314234.ch9CrossRefGoogle Scholar
Gratuze, B., Pactat, I. & Schibille, N. 2018. Changes in the Signature of Cobalt Colorants in Late Antique and Early Islamic Glass Production. Minerals, 8: 225. https://doi.org/10.3390/min8060225CrossRefGoogle Scholar
Guido, M. 1978. The Glass Beads of the Prehistoric and Roman Periods in Britain and Ireland. London: Thames & Hudson.10.26530/20.500.12657/50812CrossRefGoogle Scholar
Hodgkinson, A. 2017. Technology and Urbanism in Late Bronze Age Egypt (Oxford Studies in Egyptology, 1). Oxford: Oxford University Press.10.1093/oso/9780198803591.001.0001CrossRefGoogle Scholar
Jackson, C.M. 2005. Making Colourless Glass in the Roman Period. Archaeometry, 47: 763–80. https://doi.org/10.1111/j.1475-4754.2005.00231.xCrossRefGoogle Scholar
Jackson, C.M. & Nicholson, P.T. 2010. The Provenance of Some Glass Ingots from the Uluburun Shipwreck. Journal of Archaeological Science, 37: 295301. https://doi.org/10.1016/j.jas.2009.09.040CrossRefGoogle Scholar
Jackson, C.M. & Paynter, S. 2016. A Great Big Melting Pot: Exploring Patterns of Glass Supply, Consumption and Recycling in Roman Coppergate, York*. Archaeometry, 58: 6895. https://doi.org/10.1111/arcm.12158CrossRefGoogle Scholar
Juwig, C. 2010. Die Gewandreliquie der heiligen Bathilde. Überlegungen zur ihrem Bildstatus und Funktionskontext. In: Juwig, C. & Kost, C., eds. Bilder in der Archäologie –Archäologie der Bilder? (Tübinger Archäologische Taschenbücher, 8). Münster, New York, München & Berlin: Waxmann, pp. 197211.Google Scholar
Liu, R.K., Holland, S. & Holland, T. 2017. Ancient Nubian Face Beads: The Problem with Suppositions. Ornament, 40(2): 3439.Google Scholar
Mandruzzato, L. 2017. Vetro. In: Fontana, F., ed. Scavi ad Aquileia III. Aquileia, l'insula tra foro e porto fluviale: lo scavo dell'Università degli Studi di Trieste 1, la strada. Trieste: Editreg, pp. 293301.Google Scholar
Mandruzzato, L. & Marcante, A. 2008. Vetri antichi del Museo Archeologico Nazionale di Aquileia. Ornamenti, oggettistica e vetro pre- e post-romano (Corpus delle Collezioni del Vetro in Friuli Venezia Giulia, 4). Roma: Arbor Sapientiae.Google Scholar
Montevecchi, G. 2000. Corredo funerario, Classe (Ravenna), via Romea sud, podere Giorgioni, tomba 29. In: Marini Calvani, M., ed. Aemilia. La cultura romana in Emilia Romagna dal III secolo a. C. all'età costantiniana. Venezia: Marsilio, pp. 159–61.Google Scholar
Moorey, P.R.S. 1994. Ancient Mesopotamian Materials and Industries: The Archaeological Evidence. Oxford: Clarendon Press.Google Scholar
Müller, M. 2018. Foundation Deposits and Strategies of Place-Making at Tell el-Dab'a/Avaris. Near Eastern Archaeology, 81: 182–90. https://doi.org/10.5615/neareastarch.81.3.0182CrossRefGoogle Scholar
Nenna, M.-D. 1993. La verrerie d’époque hellénistique à Délos. Journal of Glass Studies, 35: 1121.Google Scholar
Nightingale, G. 2008. Tiny, Fragile, Common, Precious: Mycenaean Glass and Faience, Beads and Other Objects. In: Jackson, C. & Wagner, E.C., eds. Vitreous Materials in the Late Bronze Age Aegean. Oxford: Oxbow Books, pp. 64104.Google Scholar
Paynter, S. & Jackson, C. 2019. Clarity and Brilliance: Antimony in Colourless Natron Glass Explored Using Roman Glass Found in Britain. Archaeological and Anthropological Sciences, 11: 1533–51. https://doi.org/10.1007/s12520-017-0591-5CrossRefGoogle Scholar
Pion, C. & Gratuze, B. 2016. Indo-Pacific Glass Beads from the Indian Subcontinent in Early Merovingian Graves (5th–6th Century ad). Archaeological Research in Asia, 6: 5164. https://doi.org/10.1016/j.ara.2016.02.005CrossRefGoogle Scholar
Pulak, C. 1998. The Uluburun Shipwreck: An Overview. The International Journal of Nautical Archaeology 27: 188224. https://doi.org/10.1016/s1057-2414(98)80031-9CrossRefGoogle Scholar
Rifa-Abou El Nil, P. & Calligaro, T. 2020. Un atelier de taille de pierre semi-précieuses à Alexandrie. In: Dinh-Audouin, M.-T., Olivier, D. & Rigny, P., eds. Chimie et Alexandrie dans l'Antiquité. Les Ulis: EDP Sciences, pp. 247–66.10.1051/978-2-7598-2415-1.c015CrossRefGoogle Scholar
Rodziewicz, M. 1984. Les habitations romaines tardives d'Alexandrie à la lumière des fouilles polonaises a Kom el-Dikka. Warsav: PWN, Éditions Scientifiques de Pologne.Google Scholar
Schibille, N. & Freestone, I.C. 2013. Composition, Production and Procurement of Glass at San Vincenzo al Volturno: An Early Medieval Monastic Complex in Southern Italy. PLoS ONE, 8: e7647. https://doi.org/10.1371/journal.pone.0076479CrossRefGoogle Scholar
Sebastiani, A. 2016. Glass and Metal Production at Alberese: The Workshops and the Manufacturing District of Spolverino. Postclassical Archaeologies, 6: 6370.Google Scholar
Sebastiani, A. & Derrick, T.J. 2020. A Regional Economy of Recycling over Four Centuries at Spolverino (Tuscany) and Environs. In: Duckworth, C.N. & Wilson, A., eds. Recycling and Reuse in the Roman Economy. Oxford: Oxford University Pres, pp. 359–82.10.1093/oso/9780198860846.003.0011CrossRefGoogle Scholar
Shortland, A. 2000. Vitreous Materials at Amarna: The Production of Glass and Faience in 18th Dynasty Egypt (BAR International Series 827). Oxford: British Archaeological Reports.10.30861/9781841710389CrossRefGoogle Scholar
Shortland, A., Schachner, L., Freestone, I. & Tite, M. 2006. Natron as a Flux in the Early Vitreous Materials Industry: Sources, Beginnings and Reasons for Decline. Journal of Archaeological Science, 33: 521–30. https://doi.org/10.1016/j.jas.2005.09.011CrossRefGoogle Scholar
Silvestri, A. 2008. The Coloured Glass of Iulia Felix. Journal of Archaeological Science, 35: 14891501. https://doi.org/10.1016/j.jas.2007.10.014CrossRefGoogle Scholar
Silvestri, A., Molin, G. & Salviulo, G. 2008. The Colourless Glass of Iulia Felix. Journal of Archaeological Science, 35: 331–41. https://doi.org/10.1016/j.jas.2007.03.010CrossRefGoogle Scholar
Spaer, M. 1993. Gold-Glass Beads: A Review of the Evidence. BEADS: Journal of the Society of Bead Researchers, 5: 925. https://surface.syr.edu/beads/vol5/iss1/5Google Scholar
Spaer, M., Barag, D., Ornan, T. & Neuhaus, T. 2001. Ancient Glass in the Israel Museum: Beads and Other Small Objects. Jerusalem: Israel Museum.Google Scholar
Swift, E. 2003. Late-Roman Bead Necklaces and Bracelets. Journal of Roman Archaeology, 16: 336–49. https://doi.org/10.1017/s1047759400013167CrossRefGoogle Scholar
Then-Obłuska, J. 2013. Medieval Transcultural Medium: Beads and Pendants from Makurian and Post-Makurian Dongola in Nubia. Polish Archaeology in the Mediterranean, 22: 679720.Google Scholar
Then-Obłuska, J. 2017. Beads and Pendants from the Late Harbor Temple and Harbor Temenos in the Red Sea Port of Berenike: Techniques, Functions and Affiliations. Polish Archaeology in the Mediterranean, 26: 193210.10.5604/01.3001.0012.1826CrossRefGoogle Scholar
Then-Obłuska, J. 2018. Beads and Pendants from the Hellenistic to Early Byzantine Red Sea Port of Berenike, Egypt, Season 2014 and 2015. Polish Archaeology in the Mediterranean, 27: 203–33.10.5604/01.3001.0013.2001CrossRefGoogle Scholar
Then-Obłuska, J. & Wagner, B. 2017. Glass Bead Trade in Northeast Africa in the Roman Period. In: Wolf, S. & De Pury-Gysel, A., eds. Annales du 20e Congrès de l'Association internationale pour l'histoire du verre. Rhaden/Westf: Marie Leidorf, pp. 248–56.Google Scholar
Tite, M., Pradell, T. & Shortland, A. 2008. Discovery, Production and Use of Tin-Based Opacifiers in Glasses, Enamels and Glazes from the Late Iron Age Onwards: A Reassessment. Archaeometry, 50: 6784. https://doi.org/10.1111/j.1475-4754.2007.00339.xCrossRefGoogle Scholar
Towle, A., Henderson, J. & Bellintani, P. 2001. Frattesina and Adria: Report of Scientific Analyses of Early Glass from the Veneto. Padusa, 37: 768.Google Scholar
Varberg, J., Gratuze, B. & Kaul, F. 2015. Between Egypt, Mesopotamia and Scandinavia: Late Bronze Age Glass Beads Found in Denmark. Journal of Archaeological Science, 54: 168–81. https://doi.org/10.1016/j.jas.2014.11.036CrossRefGoogle Scholar
Weinberg, G.D. 1983. A Hellenistic Glass Factory on Rhodes: Progress Report. Journal of Glass Studies, 25: 37.Google Scholar
Figure 0

Figure 1. Map of Tuscany, with Aiano (Adapted from cartography of DARMC https://darmc.harvard.edu/).

Figure 1

Figure 2. Plan of the Aiano villa, after the 2018 excavation campaign, showing the distribution of the beads, divided by compositional group and forming technique (polychrome beads are classified according to the base glass used for the body) (adapted from a drawing by A. Novellini). © UCLouvain.

Figure 2

Table 1. Chronological phases of the Aiano villa.

Figure 3

Figure 3. Glass lumps and mosaic tesserae deformed from the heat of the furnace retrieved from the dump outside the villa (Area 7000).

Figure 4

Figure 4. The Aiano beads, divided by forming technique and base glass composition, with indication of the sample number, cobalt source, yellow and white opacifiers.

Figure 5

Figure 5. Base glass characteristics of the Aiano beads, separated as a function of Al2O3/SiO2 and TiO2/Al2O3 ratios.

Figure 6

Figure 6. Na2O/SiO2 and CaO/Al2O3 ratios of the Roman samples from Aiano, compared to different Roman glass reference groups (Roman Sb, Roman Mn, Roman mixed), based on the glass finds from the Iulia Felix shipwreck (IF) (data source: Silvestri, 2008; Silvestri et al., 2008).

Figure 7

Figure 7. Cobalt relative to nickel concentrations distinguish Roman from Late Antique cobalt sources and confirm the chronological separation of the Roman, Foy 2.1, and Foy 2.1/HIMT glasses used in the Aiano beads.

Supplementary material: File

Boschetti et al. supplementary material

Table S1

Download Boschetti et al. supplementary material(File)
File 53.8 KB