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Mediterranean Early Iron Age chronology: assessing radiocarbon dates from a stratified Geometric period deposit at Zagora (Andros), Greece

Part of: Classical Archaeology

Published online by Cambridge University Press:  26 February 2024

Rudolph Alagich Open the ORCID record for Rudolph Alagich [Opens in a new window] ,
Lorena Becerra-Valdivia Open the ORCID record for Lorena Becerra-Valdivia [Opens in a new window] ,
Margaret C. Miller Open the ORCID record for Margaret C. Miller [Opens in a new window] ,
Katerina Trantalidou Open the ORCID record for Katerina Trantalidou [Opens in a new window]  and
Colin Smith Open the ORCID record for Colin Smith [Opens in a new window]
Rudolph Alagich*
Affiliation:
Department of Archaeology, University of Sydney, Australia
Lorena Becerra-Valdivia
Affiliation:
Oxford Radiocarbon Accelerator Unit, Research Laboratory for Archaeology and the History of Art, School of Archaeology, University of Oxford, UK
Margaret C. Miller
Affiliation:
Department of Archaeology, University of Sydney, Australia
Katerina Trantalidou
Affiliation:
Hellenic Ministry of Culture, Athens, Greece
Colin Smith
Affiliation:
Department of Archaeology and History, La Trobe University, Bundoora, Australia Laboratorio de Evolución Humana, Departamento de Historia, Geografía y Comunicación, Universidad de Burgos, Spain
*
*Author for correspondence ✉ [email protected]
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Abstract

In this article, the authors present an analysis of radiocarbon dates from a stratified deposit at the Greek Geometric period settlement of Zagora on the island of Andros, which are among the few absolute dates measured from the period in Greece. The dates assigned to Greek Geometric ceramics are based on historical and literary evidence and are found to contradict absolute dates from the central Mediterranean which suggest that the traditional dates are too young. The results indicate the final period at Zagora, the Late Geometric, should be seen as starting at least a century earlier than the traditional date of 760 BC.

Keywords

Mediterranean EuropeGreeceEarly Iron AgeGeometric periodradiocarbonchronology
Type
Research Article
Information
Antiquity , Volume 98 , Issue 398 , April 2024 , pp. 454 - 469
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 (https://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), 2024. Published by Cambridge University Press on behalf of Antiquity Publications Ltd

Introduction

The Greek Geometric period, named after the patterns painted on the ceramics produced at the time, spanned the latter part of the Early Iron Age. One of its sub-phases, the Late Geometric, witnessed the beginnings of Greek colonisation in the central Mediterranean and significant cultural developments, such as the introduction of the Greek alphabet (Coldstream Reference Coldstream1977; Powell Reference Powell2002; Hall Reference Hall2014: 68–94). The traditional dates assigned to the Geometric period are based on finds of Greek ceramics (primarily Euboean, Attic and Corinthian) in Near Eastern strata whose destruction was dated by documented historical events. In southern Italy, finds of these types of ceramics in Greek colonies were correlated with the date that the colonies were established, provided by the Greek historian Thucydides writing three centuries after the foundations supposedly took place (Table 1; Coldstream Reference Coldstream1968: 302–31). For example, Thucydides’ foundation date for Megara Hyblaea in Sicily is given as 245 years before its residents were driven out by Gelon of Syracuse (History of the Peloponnesian War 6.4.2; Smith Reference Smith1921), an event recorded by Herodotus as being prior to the Persian defeat in 480 BC (Histories 7.156; Godley Reference Godley1922) and estimated by modern scholarship to be c. 485–480 BC (Evans Reference Evans2016: 2). This gives a date of 730–725 BC for the foundation of Megara Hyblaea, where the earliest Corinthian pottery was recognised by Coldstream (Reference Coldstream1968: 323) as Late Geometric in style. Coldstream (Reference Coldstream1968: 316) dates the transition between Corinthian Late Geometric and the subsequent Early Proto-Corinthian pottery style using a destruction level at Al Mina in Syria dated to 720 BC and utilises the Thucydidean foundation dates of cities such as Megara Hyblaea to corroborate his dating of this transition.

Table 1. Geometric period dates based on the traditional chronology.

LG: Late Geometric; EG: Early Geometric; MG: Middle Geometric; SPG: Sub-Protogeometric.

In the central and western Mediterranean, where sites have been dated using Greek ceramics, the traditional dates have been called into question following radiocarbon analyses suggesting a higher/older chronology than traditionally assigned (Randsborg Reference Randsborg1991; Nijboer et al. Reference Nijboer, van der Plicht, Bietti Sestieri and de Santis2000; Nijboer Reference Nijboer2005; van der Plicht et al. Reference van der Plicht, Bruins and Nijboer2009; Guidi Reference Guidi2018). Such observations are supported by older dates obtained from stratified contexts in the Aegean (Wardle et al. Reference Wardle, Higham and Kromer2014; Gimatzidis & Weninger Reference Gimatzidis and Weninger2020). Nevertheless, arguments to maintain the traditional chronology persist and are mainly based on evidence from Levantine settlements (Gilboa & Sharon Reference Gilboa and Sharon2001; Coldstream & Mazar Reference Coldstream and Mazar2003; Finkelstein & Piasetzky Reference Finkelstein and Piasetszky2006; Fantalkin et al. Reference Fantalkin, Finkelstein and Piasetszky2011, Reference Fantalkin, Kleiman, Mommsen and Finkelstein2020). Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020) recently proposed a revision to the long-standing Geometric period chronology established by Coldstream (Reference Coldstream1968). Their dates, obtained from the tell settlement of Sindos in the north Aegean, revealed that Geometric period phases were up to 150 years older than in the established system. As Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020: 25) themselves admit, resistance from proponents of the established chronology is to be expected and more dates from short-lived samples in stratified contexts in Greece are needed to support any chronological refinement.

Zagora on the island of Andros (Figure 1) provides evidence to illustrate this discussion, with occupation spanning from the Euboean Sub-Protogeometric III and Attic Middle Geometric, through to Late Geometric II. Andros is 11km south-east of Euboea, one of the main ceramic production centres in Greece during the Geometric period and origin of the majority of imported fineware ceramics excavated at Zagora (Cambitoglou Reference Cambitoglou1981).

Figure 1. Map showing location of Zagora (upper); and a site plan showing location of trenches 9 and FW6 (lower; site plan after Coulton, McCallum, Anderson and Wilson, figure by authors).

In this article, we present 10 short-lived radiocarbon dates of cattle and caprine bones recovered from a stratified deposit in trench 9 at Zagora, excavated in 2014, with levels containing material dating from Sub-Protogeometric III/Middle Geometric to Late Geometric I. The objective is to date some of the earliest stratigraphic sequences at Zagora and provide dates for the open-air surfaces in this area, the latest of which was still in use when the settlement was abandoned. One further date is obtained from a hare bone recovered just below the major extension of the fortification wall in trench FW6 excavated in 1969, providing a terminus post quem for this work.

The Late Geometric period is usually avoided for 14C analysis because the traditional dates assigned to it (760–700 BC) are on a flat area of the calibration curve, the Hallstatt Plateau, which produces similar radiocarbon ages between c. 800 BC and 400 BC. The recent study by Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020), however, included early Late Geometric I samples (Late Geometric Ia) and found that they pre-dated the Hallstatt Plateau and were consistent with the 14C results from the central Mediterranean, which prompted the inclusion of Late Geometric I period samples in this study.

Materials and methods

Sampling

Faunal samples were obtained from trench 9 (Figures 2 & 3), which is located in a natural depression in the marble bedrock. It comprises successive fills delimited by three compact surfaces, providing the best recorded and deepest stratigraphy at Zagora. This depression is believed to have been used as a garbage dump prior to the laying of each of the three surfaces (Miller et al. Reference Miller, Paspalas, Beaumont, McLoughlin and Wilson2020). The animal bones within are most likely refuse from human consumption, based on the presence of butchery cut marks on several specimens. An abundance of fineware sherds were recovered from this trench in association with the faunal remains (Miller et al. Reference Miller, Paspalas, Beaumont, McLoughlin and Wilson2020), suggesting the bones in the fill are the remains of cultural episodes such as feasting events. This trench was excavated until bedrock or sterile soil (level 20) was reached. Stratigraphic units 9 and 14 (not illustrated) belong to deposits within surface 2 and level 13, respectively (Figure 2). One further sample was taken from the stratigraphic unit immediately below the fortification wall extension in trench FW6. Only herbivores were sampled to exclude marine reservoir offsets and none of the bones exhibit evidence of being used as tools.

Figure 2. Profile of trench 9 showing stratigraphic levels and location of identified surfaces. Samples studied derive from levels 5–7 and 15–19. Height is in metres above sea level (digitisation by R. Alagich of original trench 9 profile drawing by A. Carr & H. Gwyther).

Figure 3. Trench 9 final photograph 2014 (photograph courtesy of the Australian Archaeological Institute at Athens and the Zagora Archaeological Project).

The ceramics in trench 9 testify to the presence of older residual material in the fills, which highlights a potential risk of associating objects found in the same context. Walls at Zagora were constructed exclusively of stone, so there is little chance that residual bones from decayed mudbrick were deposited in trench fills. The earliest ceramic material recovered from Zagora is roughly contemporary with the earliest material in trench 9 (level 19), suggesting that neither the faunal remains nor ceramics in this level are residual material. Due to resource limitations, samples from trench 9 levels 10–13 were not included in the study. These omitted levels are not considered crucial for our objectives and they are relatively dated to the Middle Geometric/Sub-Protogeometric III periods, so the earliest Late Geometric level from trench 9 will be dated.

Radiocarbon dating and stable isotope analyses

Radiocarbon dating and stable isotope analyses were carried out at the Chronos 14C Facility, University of New South Wales (UNSW), following their protocols (Turney et al. Reference Turney2021). Bone samples were chemically pre-treated following ‘code SFC’, which involved decalcification, acid-base-acid rinses, gelatinisation and syringe filtering (45μm pore size). Stable carbon and nitrogen isotopic compositions were determined using an Elementar precisION® isotope ratio mass spectrometer coupled to an Elementar vario ISOTOPE cube elemental analyser. Isotopic compositions were calibrated relative to the Vienna PeeDee Belemnite (VPDB) and atmospheric N2 (AIR) scales using USGS40 and USGS41. Measurement uncertainty was monitored using one internal standard (L-Alanine, Sigma-Aldrich) with well-characterised isotopic compositions (n=43, δ13C= –19.08±0.13‰, δ15N = –1.64±0.26‰). Precision of replicate standard and sample measurements was ±0.13‰ for δ13C and ±0.19‰ for δ15N. Accuracy, determined from observed and known δ values of standards, was ±0.13 for δ13C and ±0.49 for δ15N. Total analytical uncertainty was estimated to be ±0.18‰ for δ13C and ±0.52‰ for δ15N.

Radiocarbon calibration and Bayesian age modelling

Radiocarbon calibration was undertaken using IntCal20 (Reimer et al. Reference Reimer2020) in OxCal 4.4 (Bronk Ramsey Reference Bronk Ramsey2009a). Bayesian age modelling was performed through the same platform, using chronometric data and known stratigraphic information (Bronk Ramsey Reference Bronk Ramsey2009a). The ‘General’ outlier model was applied to all dates, with each given a 5% prior probability of being an outlier (Bronk Ramsey Reference Bronk Ramsey2009b). This statistical analysis identifies and downweighs outlying age measurements according to their degree of offset—for example, a date identified as an outlier at 95% posterior probability will be largely discounted from the model. Given the lack of chronometric data for levels 8–14, a double boundary was included. This denotes a sequential rather than a contiguous relationship between levels 7 and 15. Stratigraphically, however, only levels 10 to 13 are missing from the right side of trench 9 (see Figure 2). Calibrated dates have been rounded to five years and all modelled/calibrated estimates are noted at 95.4% credible/confidence intervals.

Ceramic chronology of 14C-dated levels in trenches 9 and FW6

Fineware ceramics recovered from the two studied contexts were highly fragmentary in nature. Therefore, a further refinement of their dates into relative chronology sub-divisions was not always possible (McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press). In trench 9 (Figure 2, Table 1), immediately below surface 1 (level 5), Sub-Protogeometric/Middle Geometric ceramic fragments as well as some early Late Geometric pieces were recovered, dating this level to Late Geometric I (McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press). Among these Late Geometric sherds is a rim fragment from a Euboean krater (Inv. 14–499; Figure 4). Below this level and later than surface 2, in levels 6–7, an absence of Late Geometric sherds precludes a Late Geometric date. The recovery of an Attic Middle Geometric skyphos body fragment (Inv. 14–049) and various Sub-Protogeometric III fragments dates these levels to Middle Geometric/Sub-Protogeometric III. However, level 12 contains a Middle Geometric II fragment (Inv. 14–631; Figure 5), possibly from an Attic amphora. This means that levels 6–7 can be dated to Middle Geometric II/Sub-Protogeometric IIIb.

Figure 4. Euboean Late Geometric krater rim fragment recovered from trench 9, level 5 (Inv. 14–499) (photograph courtesy of the Australian Archaeological Institute at Athens and the Zagora Archaeological Project).

Figure 5. Attic or Atticising Middle Geometric II fragment recovered from trench 9, level 12 (Inv. 14–631) (after McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press: fig. 3B).

The levels in between surfaces 2 and 3 (levels 15–17) are primarily dated to Sub-Protogeometric. From level 15, fragments of a skyphos, possibly Euboean (Inv. 14–424 and 14–436; Figure 6), date to Sub-Protogeometric III. A pedestal foot from level 16 (Inv. 14–581) is from the Sub-Protogeometric II–IIIa transition. Level 17 produced a Euboean closed vessel (Inv. 14–320), possibly a small amphora, and a pendant semi-circle skyphos rim and upper-body fragment (Inv. 14–501), both dating to Sub-Protogeometric III.

Figure 6. Sub-Protogeometric III skyphos fragment recovered from trench 9, level 15 (Inv. 14–424) (after McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press: fig. 5E).

Pottery associated with surface 3 includes small, closed vessels with concentric semi-circles (Inv. 14–307) and monochrome cups (Inv. 14–314) dating broadly to Sub-Protogeometric. Recovered from the same surface in the adjoining trench 3 were Middle Geometric cup fragments (Inv. 13–052 and 13–122) and a Euboean cup (Inv. 13–102) dated to Sub-Protogeometric III, assigning this surface a Middle Geometric/Sub-Protogeometric III date.

The fill below surface 3 (level 19) includes monochrome cups, amphora fragments and a closed vessel fragment with opposed diagonals, all possibly dating as early as the Late Protogeometric or as late as Sub-Protogeometric III (McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press). However, this level can be securely dated to Sub-Protogeometric III by the presence of pendant semi-circle skyphoi fragments (Inv. 14–750, 14–450, 14–454, 14–271, 14–273, 14–274, 14–238, 14–255), a small amphora or lekythos (Inv. 14–437), sherds from closed Euboean vessels (Inv. 14–420 and 14–266) and an amphora rim fragment (Inv. 14–259).

Trench FW6, level 5, directly below the fortification wall extension, produced a number of residual Sub-Protogeometric and Middle Geometric sherds. This level is dated by a krater fragment (Inv. 2592; Figure 7) and a skyphos rim fragment (Inv. 2594), which can both only be identified more broadly as originating from Late Geometric period vessels.

Figure 7. Late Geometric krater fragment recovered from trench FW6, level 5 (Inv. 2592) (photograph courtesy of the Australian Archaeological Institute at Athens).

Radiocarbon dates from Zagora

Radiocarbon dating and stable isotope results are shown in Table 2. Bayesian age modelling results show agreement between the chronometric and archaeological data, with no outlying dates (Figure 8). Overall, the dated sequence does not span more than a couple of centuries. The double boundary placed between levels 7 and 15 denotes no temporal gap, as these include zero at the 95.4% confidence interval (see online supplementary material Figure S1). This suggests that the occupation at this point in the sequence was continuous and short. From the bottom of the cultural sequence in trench 9, the model estimates the start of levels 19 (Middle Geometric/Sub-Protogeometric III) to 1015–925 BC, 7 (Middle Geometric II/Sub-Protogeometric IIIb) to 950–890 BC, and 5 (Late Geometric I) to 935–850 BC. With the exception of levels 7 and 5, the distributions do not overlap at the 68.3% confidence interval (see Figure S2), denoting cultural events that were generally temporally distinct, yet in close sequential order. The age of surface 3 is represented by level 18, dated to 1000–925 BC, while surface 2 is represented by level 8, which falls within the range of 955–900 BC. Surface 1 postdates all radiocarbon dated levels, with a terminus post quem of 930–840 BC (estimated end of level 5). UNSW-223 (2762±20 BP or 980–830 BC), extracted from trench FW6 under the fortification wall extension, is relatively dated to Late Geometric I. Given that this date is comparable with UNSW-220 (2764±20 BP or 980–830 BC), evidence suggests that the construction of this extension took place at the same time. At the end of the sequence (levels 7–5), where the calibration curve is non-monotonic, the use of prior information provides more accurate, unimodal ages for the cultural events.

Table 2. Radiocarbon dates from Zagora, including dates calibrated against IntCal20 (Reimer et al. Reference Reimer2020).

LG: Late Geometric; MG: Middle Geometric; SPG: Sub-Protogeometric.

Figure 8. Bayesian age model for Zagora (figure by authors).

Discussion

The radiocarbon dates from Zagora have provided absolute dates for some of the earliest material recovered from the settlement. Dates from the bottom of the fill in trench 9 change the commencement of occupation at Zagora from c. 900 BC (Miller et al. Reference Miller, Paspalas, Beaumont, McLoughlin and Wilson2020; McLoughlin & Paspalas Reference McLoughlin, Paspalas and Athanasoulisin press) to sometime between the last quarter of the eleventh and the third quarter of the tenth century BC. The first of the surfaces in trench 9 was laid sometime between the first and third quarters of the tenth century, suggesting the bottom of the trench was filled to this point soon after refuse began to accumulate here. Surface 2 was laid between 955 and 900 BC and the final surface after 930–840 BC. This final surface is similar in composition and height to the road surfaces uncovered just inside the fortification wall gateway and appears to have been in use until the settlement's abandonment c. 700 BC (Miller et al. Reference Miller, Paspalas, Beaumont, McLoughlin and Wilson2020). The radiocarbon dates suggest that the fortification wall expansion and the laying of the upper surface in trench 9 may have been part of a single episode of rebuilding at the settlement. The width of the fortification wall was more than doubled to approximately 7m at this time (Cambitoglou Reference Cambitoglou1981: 23), suggesting the possibility that a significant threat prompted the residents of Zagora to instigate such major construction.

The dates presented here generally support the chronology revision proposed by Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020) at Sindos (Table 3). This includes their proposed beginning of Late Geometric I which, at 870 BC, fits with our estimate of 935–850 BC. The possibility of an even earlier commencement at Zagora requires further testing because the timing of Late Geometric I is based on one measurement. Future efforts will be affected by the calibration curve shape at this period, however. Our findings also support a substantially longer Greek Late Geometric period than assumed under the traditional chronology—assuming the Late Geometric II period does indeed end c. 700 BC—although this is yet to be tested with absolute dating of well-stratified deposits containing Greek Late Geometric II material.

Table 3. Traditional Aegean chronology for the Sub-Protogeometric III/Middle Geometric and Late Geometric I periods, along with proposed modifications to the chronology by Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020) and modelled dates from Zagora; *earliest date for Sub-Protogeometric III/Middle Geometric at Zagora is a terminus ante quem date for this period.

LG: Late Geometric; MG: Middle Geometric; SPG: Sub-Protogeometric.

Prior to the Late Geometric, much of Zagora was probably open space while during the final Late Geometric phase the settlement was densely occupied (Cambitoglou et al. Reference Cambitoglou, Birchall, Coulton and Green1988; Beaumont et al. Reference Beaumont, Miller and Paspalas2012). The population at Zagora is believed to have doubled each generation during the Late Geometric period (Green Reference Green and Descoeudres1990), which under the traditional chronology spans around 60 years. Increasing the duration of the Late Geometric period to over 150 years would make these changes more gradual and less dramatic than previously thought. In Greece more widely, the population is also believed to have increased rapidly during the Late Geometric period, highlighted by Snodgrass' (Reference Snodgrass1977) calculation of a sevenfold increase in graves per generation in Attica. A longer Late Geometric period allows for a more modest rate of population growth in Greece during this time. The increase in population at Zagora is also reflected in the landscape surrounding the site, where a reduction in available land during the Late Geometric period may have caused farmers to adopt more intensive agricultural practices (Alagich et al. Reference Alagich, Trantalidou, Miller and Smith2021).

Changing the start date of the Late Geometric period to over a century earlier also backdates significant cultural episodes in Greek history, such as the introduction of the Greek alphabet. The earliest definitive evidence for the use of the Greek alphabetic script appears during Late Geometric I and examples of inscriptions on ceramic vessels become numerous throughout Greece and the Mediterranean towards the end of the Late Geometric period (Bartoněk & Buchner Reference Bartoněk and Buchner1995; Kenzelmann Pfyffer et al. Reference Kenzelmann Pfyffer, Theurillat and Verdan2005; Tzifopoulos Reference Tzifopoulos, Besios, Tzifopoulos and Kotsonas2012). There are rare examples of words incised after firing on Middle Geometric period potsherds, but they generally originate from contexts that cannot be securely dated (Kourou Reference Kourou, Clay, Malkin and Tzifopoulos2017). If the traditional chronology is used, it is intriguing that after several centuries of supposed illiteracy the use of writing for trivial purposes (such as jokes) became widespread within a single generation (Papadopoulos Reference Papadopoulos2016). Revising the beginning of the Late Geometric I period to more than a century earlier would allow a longer timespan for the diffusion of writing and support suggestions by Semitic scholars for a transmission of the alphabet during the ninth century BC or even earlier (Sass Reference Sass2005: 133–46). Janko (Reference Janko2015) has argued this point based on the traditional chronology being inconsistent with Greek philological evidence, which better supports the older radiocarbon dates from the central Mediterranean.

Absolute dates from Late Geometric contexts throughout the Mediterranean are rare due to the coincidence of this period with the Hallstatt Plateau under the traditional chronology. Nevertheless, several 14C dates were obtained from animal bones found in association with Late Geometric ceramics at the Phoenician colony of Carthage in Tunisia, which all dated from around the end of the ninth to the beginning of the eighth century BC. This date agrees with classical literature for a late-ninth-century foundation for this city, which is significantly older than the mid-eighth-century foundation previously accepted under the traditional Greek ceramic chronology (Doctor et al. Reference Docter, Niemeyer, Nijboer, van der Plicht., Bartoloni and Delpino2005, Reference Docter and Sagona2008; Maraoui Telmini & Schön Reference Maraoui Telmini and Schön2020). In addition, three dates were obtained from animal bones associated with Late Geometric ceramics at Francavilla Maritima in southern Italy to date early Euboean presence here. The samples produced dates on the Hallstatt Plateau but were narrowed to the first half of the eighth century BC on archaeological grounds (Nijboer Reference Nijboer, Donnellan, Nizzo and Burgers2016: 40). The precise subdivision of the Late Geometric was not provided for these sherds, but our results and those of Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020) imply they were probably either late Late Geometric I or Late Geometric II.

The earliest Phoenician colonial foundations in the western Mediterranean, such as Carthage, are traditionally dated by the presence of Phoenician ceramics associated with Greek Late Geometric vessels, which date these colonies to the middle of the eighth century BC at the earliest (Aubet Reference Aubet and Sagona2008). During this century, the Levant witnessed significant pressure from Assyrian military activity. Under the traditional chronology it was thought that the Phoenician colonial expeditions to the west may have been precipitated by displaced peoples or by the Phoenician need to obtain silver for Assyrian tribute payments (Aubet Reference Aubet1993). This view is now challenged (Aubet Reference Aubet and Sagona2008) based on new radiocarbon dates, particularly from Huelva in Spain where material from contexts containing the earliest Phoenician ceramics produced dates in the early ninth century BC (Nijboer & van der Plicht Reference Nijboer and van der Plicht2006). These revised dates suggest that the migrations to the west were not accelerated by Assyrian aggression but were rather an organic growth of the long-distance trading expeditions instigated during the reign of King Hiram I, a century earlier (Aubet Reference Aubet and Sagona2008). This pre-colonial trading phase and a late-ninth-century foundation of Carthage are in concordance with the proposed earlier commencement of the Greek Late Geometric period.

In northern Italy and central Europe, radiocarbon and dendrochronological data supportive of older Iron Age dates have conflicted with the established chronology from southern Italy, where dates are traditionally assigned using correlations with Greek ceramics (Coldstream Reference Coldstream1968; Morris Reference Morris1996). As discussed by Nijboer (Reference Nijboer2005), the narrow range of dates assigned to Greek Late Geometric ceramics has artificially imposed a similarly narrow range of dates on indigenous ceramics found in the same context without considering that the local vessels may have been part of a much longer tradition. Use of the established chronology therefore results in a “cluttering” of events towards the middle of the eighth century BC (Nijboer Reference Nijboer, Donnellan, Nizzo and Burgers2016: 36), during the Middle Geometric II–Late Geometric I transition, when significant Greek activity in Italy began in earnest (d'Agostino Reference d'Agostino and Tsetskhladze2006). An earlier start to the Late Geometric period would allow for a longer phase of pre-colonial trade before the Greeks established their colonies and a better fit with absolute dates from further north in Italy and central Europe (van der Plicht et al. Reference van der Plicht, Bruins and Nijboer2009; Nijboer Reference Nijboer, Donnellan, Nizzo and Burgers2016). This would not only ‘de-clutter’ the middle of the eighth century in Italy, but also provides a better explanation for the population increases observed in Greece in the period and the diffusion of the Greek alphabet.

Conclusions

The radiocarbon dates reported here are the first from Zagora and among very few obtained from the Geometric period in Greece. Our results date the commencement of the earliest occupation at Zagora to between 1015 and 925 BC. Laying of the final surface in trench 9, an open public space a short distance from the fortification wall gateway, took place sometime after 930–840 BC, at about the same time as the significant expansion of the fortification wall itself. The results from Zagora broadly support the revision of the Greek Geometric period chronology advanced by Gimatzidis and Weninger (Reference Gimatzidis and Weninger2020), who propose that the onset of the Sub-Protogeometric III/Middle Geometric and Late Geometric periods need to be raised by at least a century.

Bayesian modelling suggests that the Late Geometric I period at Zagora started no later than 935–850 BC. Even if the Bayesian modelling were discounted, Late Geometric I ceramics from two secure deposits at Zagora were found in context with animal bones whose non-modelled dates at 95.4% confidence date no later than the third quarter of the ninth century BC. This explains the previously assumed rapid population growth at Zagora and in Greece more widely during the Late Geometric period as instead being one of a more gradual increase. Given Zagora's proximity to the Greek ceramic production centres, this evidence should considerably promote the argument for adopting a higher chronology for the Late Geometric period. This supports the absolute dates from Carthage, Italy and central Europe and better explains some of the historical events and cultural developments, such as the adoption of the Greek alphabet, that took place during the Middle Geometric and Late Geometric periods throughout the Mediterranean. Our results should further encourage researchers to obtain radiocarbon dates from Late Geometric I contexts in Greece and beyond to help refine the boundaries of this important phase of Mediterranean history.

Acknowledgements

The authors would like to thank the Cycladic Ephorate of Antiquities and the Greek Ministry of Culture and Sports for permission to study and analyse the material. We also wish to thank the Archaeological Society at Athens, the Australian Archaeological Institute at Athens (AAIA) and its director Stavros Paspalas and the Zagora Archaeological Project and its directors Lesley Beaumont, Paul Donnelly, Margaret Miller and Stavros Paspalas for approving access to the material for analysis. We thank the Chronos 14Carbon Cycle Facility, University of New South Wales, for supporting the radiocarbon dating. In particular, we extend our gratitude to Chris Marjo and Chris Turney. We also thank the AAIA for access to the ceramic dates in the Zagora excavation database and Beatrice McLoughlin for providing the photograph of trench 9.

Funding statement

This research received no specific grant from any funding agency or from commercial and not-for-profit sectors.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.15184/aqy.2024.16.

References

Alagich, R., Trantalidou, K., Miller, M.C. & Smith, C.. 2021. Reconstructing animal management practices at Greek Early Iron Age Zagora (Andros) using stable isotopes. Archaeological and Anthropological Sciences 13. https://doi.org/10.1007/s12520-020-01249-1CrossRefGoogle Scholar
Aubet, M.E. 1993. The Phoenicians and the West: politics, colonies and trade. Cambridge: Cambridge University Press.Google Scholar
Aubet, M.E. 2008. Political and economic implications of the new Phoenician chronologies, in Sagona, C. (ed.) Beyond the homeland: markers in Phoenician chronology: 179–19. Leuven: Peeters.Google Scholar
Bartoněk, A. & Buchner, G.. 1995. Die ältesten griechischen inschriften von Pithekoussai (2. hälfte des VIII. bis 1. hälfte des VII. Jhs.). Die Sprache Zeitschrift für Sprachwissenschaft 37(5): 129231.Google Scholar
Beaumont, L.A., Miller, M.C. & Paspalas, S.A.. 2012. New investigations at Zagora (Andros): the Zagora Archaeological Project 2012. Mediterranean Archaeology 25: 4366.Google Scholar
Bronk Ramsey, C. 2009a. Bayesian analysis of radiocarbon dates. Radiocarbon 51: 337–60. https://doi.org/10.1017/S0033822200033865CrossRefGoogle Scholar
Bronk Ramsey, C. 2009b. Dealing with outliers and offsets in radiocarbon dating. Radiocarbon 51: 1023–45. https://doi.org/10.1017/S0033822200034093CrossRefGoogle Scholar
Cambitoglou, A. 1981. Guide to the finds from the excavations of the Geometric town at Zagora. Athens: Archaeological Museum of Andros.Google Scholar
Cambitoglou, A., Birchall, A., Coulton, J.J. & Green, J.R.. 1988. Zagora 2: excavation of a geometric town on the island of Andros. Excavation season 1969; study season 19691970. Athens: Athens Archaeological Society.Google Scholar
Coldstream, J.N. 1968. Greek geometric pottery: a survey of ten local styles and their chronology. London: Methuen.Google Scholar
Coldstream, J.N. 1977. Geometric Greece. London: Ernest Benn.Google Scholar
Coldstream, J.N. & Mazar, A.. 2003. Greek pottery from Tel Reḥov and Iron Age chronology. Israel Exploration Journal 53: 2948.Google Scholar
d'Agostino, B. 2006. The first Greeks in Italy, in Tsetskhladze, G.R. (ed.) Greek colonisation: an account of Greek colonies and other settlements overseas, Volume 1: 201–37. Leiden: Brill.CrossRefGoogle Scholar
Docter, R.F., Niemeyer, H.G., Nijboer, A.J. & van der Plicht., J. 2005. Radiocarbon dates of animal bones in the earliest levels of Carthage, in Bartoloni, G. & Delpino, F. (ed.) Oriente e Occidente: metodi e discipline a confronto. Riflessioni sulla cronologia dell'età del Ferro Italiana: 557–77. Pisa-Rome: Istituti Editoriali e Poligrafici Internazionali.Google Scholar
Docter, R.F. et al. 2008. New radiocarbon dates from Carthage: bridging the gap between history and archaeology?, in Sagona, C. (ed.) Beyond the homeland: markers in Phoenician chronology: 379422. Leuven: Peeters.Google Scholar
Evans, R. 2016. Ancient Syracuse: from foundation to fourth century collapse. London: Routledge.CrossRefGoogle Scholar
Fantalkin, A., Finkelstein, I. & Piasetszky, E.. 2011. Iron Age Mediterranean chronology: a rejoinder. Radiocarbon 53: 179–98. https://doi.org/10.1017/S0033822200034469CrossRefGoogle Scholar
Fantalkin, A., Kleiman, A., Mommsen, H. & Finkelstein, I.. 2020. Aegean pottery in Iron IIA Megiddo: typological, archaeometric and chronological aspects. Mediterranean Archaeology and Archaeometry 20(3): 135–47.Google Scholar
Finkelstein, I. & Piasetszky, E.. 2006. 14C and the Iron Age chronology debate: Rehov, Khirbet en-Nahas, Dan, and Megiddo. Radiocarbon 48: 373–86. https://doi.org/10.1017/S0033822200038819CrossRefGoogle Scholar
Gilboa, A. & Sharon, I.. 2001. Early Iron Age radiometric dates from Tel Dor: preliminary implications for Phoenicia and beyond. Radiocarbon 43: 1343–51. https://doi.org/10.1017/S0033822200038583CrossRefGoogle Scholar
Gimatzidis, S. & Weninger, B.. 2020. Radiocarbon dating the Greek Protogeometric and Geometric periods: the evidence of Sindos. PLoS ONE 15. https://doi.org/10.1371/journal.pone.0232906CrossRefGoogle ScholarPubMed
Godley, A.D. 1922. Herodotus Books V–VII (Loeb Classical Library). Cambridge (MA): Harvard University Press.Google Scholar
Green, J.R. 1990. Zagora – population increase and society in the later eighth century BC, in Descoeudres, J.-P. (ed.) ΕΥΜΟΥΣΙΑ: ceramic and iconographic studies in honour of Alexander Cambitoglou (Mediterranean Archaeology Supplement 1). Sydney: Meditarch.Google Scholar
Guidi, A. 2018. Twenty years after “Absolute chronology: archaeological Europe 2500–500 BC”. New data on Italian protohistory. Acta Archaeologica 89: 6375. https://doi.org/10.1111/j.1600-0390.2018.12192.xCrossRefGoogle Scholar
Hall, J.M. 2014. A history of the archaic Greek world: ca. 1200–479 BCE (2nd ed.). Chichester: Wiley-Blackwell.Google Scholar
Janko, R. 2015. From Gabii and Gordion to Eretria and Methone: the rise of the Greek alphabet. Bulletin of the Institute of Classical Studies 58(1): 132. https://doi.org/10.1111/j.2041-5370.2015.12000.xCrossRefGoogle Scholar
Kenzelmann Pfyffer, A., Theurillat, T. & Verdan, S.. 2005. Graffiti d’époque géométrique provenant du sanctuaire d'Apollon Daphnéphoros à Erétrie. Zeitschrift für Papyrologie und Epigraphik 151: 5183.Google Scholar
Kourou, N. 2017. The archaeological background of the earliest graffiti and finds from Methone, in Clay, J.S., Malkin, I. & Tzifopoulos, Y.Z. (ed.) Panhellenes at Methone: Graphê in Late Geometric and Protoarchaic Methone, Macedonia (ca 700 BCE): 2082. Berlin: de Gruyter.CrossRefGoogle Scholar
Maraoui Telmini, B. & Schön, F.. 2020. New pottery contexts and radiocarbon data from early layers on the Byrsa hill (Carthage): the “Astarté 2”-sequence. Rivista di Studi Fenici 48: 65106.Google Scholar
McLoughlin, B. & Paspalas, S.A.. In press. Ninth- and early eighth-century Zagora, Andros: indications of central Aegean networks and engagements, in Athanasoulis, D. (ed.) Πɛρὶ τῶν Κυκλάδων νήσων. Το Αρχαιολογικό Έργο στις Κυκλάδɛς. Αθήνα 22–26 Νοɛμβρίου 2017.Google Scholar
Miller, M.C., Paspalas, S.A., Beaumont, L.A., McLoughlin, B. & Wilson, A.. 2020. Zagora Archaeological Project: the 2014 field season. Mediterranean Archaeology 32/33: 217–26.Google Scholar
Morris, I. 1996. The absolute chronology of the Greek colonies in Sicily. Acta Archaeologica 67: 5159.Google Scholar
Nijboer, A.J. 2005. The Iron Age in the Mediterranean: a chronological mess or ‘trade before the flag’, part II. Ancient West and East 4(2): 255–77. https://doi.org/10.1163/9789047406716_002Google Scholar
Nijboer, A.J. 2016. Is the tangling of events in the Mediterranean around 770–60 B.C. in the conventional absolute chronology (CAC) a reality or a construct?, in Donnellan, L., Nizzo, V. & Burgers, G.-J. (ed.) Contexts of early colonization: 3547. Rome: Palombi.Google Scholar
Nijboer, A.J. & van der Plicht, J.. 2006. An interpretation of the radiocarbon determinations of the oldest indigenous-Phoenician stratum thus far, excavated at Huelva, Tartessos (south-west Spain). Bulletin Antieke Beschaving 81: 3136.CrossRefGoogle Scholar
Nijboer, A.J., van der Plicht, J., Bietti Sestieri, A.M. & de Santis, A.. 2000. A high chronology for the early Iron Age in central Italy. Palaeohistoria, 41/42: 165–76.Google Scholar
Papadopoulos, J.K. 2016. The early history of the Greek alphabet: new evidence from Eretria and Methone. Antiquity 90: 1238–54. https://doi.org/10.15184/aqy.2016.160CrossRefGoogle Scholar
Powell, B. 2002. Writing and the origins of Greek literature. Cambridge: Cambridge University Press.Google Scholar
Randsborg, K. 1991. Historical implications: chronological studies in European archaeology c.2000–500 B.C. Acta Archaeologica 62: 89108.Google Scholar
Reimer, P.J. et al. 2020. The IntCal20 northern hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon 62: 725–57. https://doi.org/10.1017/RDC.2020.41CrossRefGoogle Scholar
Sass, B. 2005. The alphabet at the turn of the millennium. Tel Aviv: Emery and Claire Yass Publications in Archaeology.Google Scholar
Smith, C.F. 1921. Thucydides: History of the Peloponnesian War Books V and VI (Loeb Classical Library). Cambridge (MA): Harvard University Press.Google Scholar
Snodgrass, A.M. 1977. Archaeology and the rise of the Greek state. Cambridge: Cambridge University Press.Google Scholar
Turney, C. et al. 2021. Radiocarbon protocols and first intercomparison results from the Chronos 14Carbon-Cycle facility, University of New South Wales, Sydney, Australia. Radiocarbon 63: 1003–23. https://doi.org/10.1017/RDC.2021.23CrossRefGoogle Scholar
Tzifopoulos, Y. 2012. I enepígrafi keramikí tou ‘Ypogeíou’: Panéllines sti Methóni, in Besios, M., Tzifopoulos, Y.Z. & Kotsonas, A. (ed.) Methoni Pierias I: 305–19. Thessaloniki: Kentro Ellinikis Glossas (in Greek).Google Scholar
van der Plicht, J., Bruins, H.J. & Nijboer, A.J.. 2009. The Iron Age around the Mediterranean: a high chronology perspective from the Groningen radiocarbon database. Radiocarbon 51: 213–42. https://doi.org/10.1017/S0033822200033786CrossRefGoogle Scholar
Wardle, K., Higham, T. & Kromer, B.. 2014. Dating the end of the Greek Bronze Age: a robust radiocarbon-based chronology from Assiros Toumba. PLoS ONE 9. https://doi.org/10.1371/journal.pone.0106672CrossRefGoogle Scholar
Figure 0

Table 1. Geometric period dates based on the traditional chronology.

Figure 1

Figure 1. Map showing location of Zagora (upper); and a site plan showing location of trenches 9 and FW6 (lower; site plan after Coulton, McCallum, Anderson and Wilson, figure by authors).

Figure 2

Figure 2. Profile of trench 9 showing stratigraphic levels and location of identified surfaces. Samples studied derive from levels 5–7 and 15–19. Height is in metres above sea level (digitisation by R. Alagich of original trench 9 profile drawing by A. Carr & H. Gwyther).

Figure 3

Figure 3. Trench 9 final photograph 2014 (photograph courtesy of the Australian Archaeological Institute at Athens and the Zagora Archaeological Project).

Figure 4

Figure 4. Euboean Late Geometric krater rim fragment recovered from trench 9, level 5 (Inv. 14–499) (photograph courtesy of the Australian Archaeological Institute at Athens and the Zagora Archaeological Project).

Figure 5

Figure 5. Attic or Atticising Middle Geometric II fragment recovered from trench 9, level 12 (Inv. 14–631) (after McLoughlin & Paspalas in press: fig. 3B).

Figure 6

Figure 6. Sub-Protogeometric III skyphos fragment recovered from trench 9, level 15 (Inv. 14–424) (after McLoughlin & Paspalas in press: fig. 5E).

Figure 7

Figure 7. Late Geometric krater fragment recovered from trench FW6, level 5 (Inv. 2592) (photograph courtesy of the Australian Archaeological Institute at Athens).

Figure 8

Table 2. Radiocarbon dates from Zagora, including dates calibrated against IntCal20 (Reimer et al. 2020).

Figure 9

Figure 8. Bayesian age model for Zagora (figure by authors).

Figure 10

Table 3. Traditional Aegean chronology for the Sub-Protogeometric III/Middle Geometric and Late Geometric I periods, along with proposed modifications to the chronology by Gimatzidis and Weninger (2020) and modelled dates from Zagora; *earliest date for Sub-Protogeometric III/Middle Geometric at Zagora is a terminus ante quem date for this period.

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