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The Aghia Kyriaki, Melos survey: prospecting for the elusive earths in the Roman period in the Aegean1

Published online by Cambridge University Press:  27 September 2013

E. Photos-Jones
Affiliation:
Glasgow UniversityArchaeology Department and Scottish Analytical Services for Art and Archaeology, Glasgow
A. J. Hall
Affiliation:
Glasgow University Archaeology Department
J. A. Atkinson
Affiliation:
Glasgow University Archaeological Research Division
G. Tompsett
Affiliation:
Glasgow University Archaeological Research Division
A. Cottier
Affiliation:
Glasgow UniversityArchaeology Department and Glasgow University Division of Earth Sciences
G. D. R. Sanders
Affiliation:
American School of Classical Studies, Athens

Abstract

The industrial minerals (IM) of antiquity, the ‘earths’ of the Classical sources, have for long eluded the archaeological record because of the limited material evidence they leave behind in the course of their extraction and processing. The extensive references in Classical and medieval literature and travellers' accounts have never previously been followed up by detailed surveys and by scientific analysis. In the course of April–May 1998 archaeological, topographic and geological surveys were carried out at the Roman site of Aghia Kyriaki, on the island of Melos, with the long term aim of putting the elusive ‘earths’ on the archaeological map of ancient industries. The present article outlines the work so far and highlights the complex factors that may contribute to the identification and characterisation of industrial minerals working in the absence of pyrotechnological waste. Furthermore, since IM processing requires a sustainable low temperature energy source, the hypothesis is put forward that Aghia Kyriaki may have been built on agriculturally inhospitable terrain mainly in order to take advantage of the area's still active geothermal field. If proven, this may constitute evidence for the first use of a ‘soft’ and environmentally friendly energy source during the Roman period in the Aegean.

Type
Articles
Copyright
Copyright © The Council, British School at Athens 1999

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References

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16 J. F. Cherry, ‘Register of archaeological sites on Melos’, in Renfrew and Wagstaff (n. 12), 304, site 78.

17 I. Triandi (pers. comm.). These trenches concentrate in areas Z, X, F, I, AA: they have been incorporated within tile present topographical map.

18 I. Triandi (pers. comm.). Pottery from the site recovered in the course of rescue excavations between 1985 and 1989 is currently being studied, as part of a doctoral dissertation, by S. Raptopoulos.

19 The radiocarbon dates published by Traineau, H. and Dalabakis, P., ‘Mise en évidence d'une éruption phréatique historique sur l'île de Milos (Grèce)’, C.-R. Acad. Sci. Paris. 308 (1989), 24Google Scholar are given as 200BC–AD 200: no σ values are reported.

20 B. A. Sparkes, in Renfrew and Wagstaff (n. 12).

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23 AR 1989–90, 67: A. Delt. 36. Chr. 381.

24 Numbers in parentheses are those given in Cherry (n. 16): Palaiochori (63) is situated on the adjacent bay to the NE: the valley is flatter than Aghia Kyriaki but is also dissected, albeit to a lesser extent, by erosion gullies. There are kaolin quarries at the head of the valley and offshore thermal springs. Amphorae and lckanai were reported, some with stamps, albeit worn out, Soleta (56–7) was discovered through the villa noted by Pittinger (n. 6) at Agios Pandcleimon; it may be the same as the Early Roman villa at the west end of one of the higher terraces. The site is extensive and stretehes along the terraces at the upper reaches oi the coastal plateau to the east of Palaiochori. A deep gully on the west side runs down to the sea to the east of Cape Spathi. Vitrified pottery wasters bloated and warped attest to pottery manufacture on site. There are Early Roman amphorae and basins with impressions COLO, G HN and also considerable quantities of Late Roman pottery: Asprokavo (96) is a small bay within the bay of Melos. It was formerly a coastal lagoon with a beach ridge cutting off the sea water lagoon. A 3 m high section in the dune has revealed pottery, walls, and floors of Early Roman structures including lekanai and amphorae. There is also a Late Roman site with domestic pottery and glass on the headland to the north, presently damaged by a bulldozer track. There are amphorae and lekane fragments as well as wasters. Emporio (95), a nonsite as described, is actually three sites on the edge of the plain with a sparse scatter of pottery with Early Roman chambered tombs in the plam itself On the east side there is Late Roman and Early Byzantine pottery. The site on the hills immediately to the south is Archaic and Frankish (13th-c.). At the west end at the ridge between Emporio and Asprokavo there is Early Roman pottery including sherds of amphorae and lekanai. The offshore remains are claimed to be medieval. Warped, bloated vitreous wasters point to pottery manufacture. At Kanava (24) there are pottery wasters and at Ambourdektakhi (97) and Achivadolimni there are amphorae and basins. At Plathiena (8) there are amphora and lekane fragments: at Tria Pigadhia (42). Kato Komia (43), and Sta Glastria 107 amphorae and basins. See HG. 1.

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29 A. J. Hall, E. Photos-Jones, A. Cottier, D. Turner, and A. McRobb. ‘The geological and geothermal setting of the Roman site at Aghia Kyriaki, Melos, Greece’, paper submitted for publication to the Journal of the Geological Society of London.

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31 Sulphur isotope work on natural and experimentally produced sulphur is now in the process of being investigated. In the last century sulphur was widely mined on Melos, principally m underground mines in the E and SE parts of the island (Theiorycheia. Tria Pigadhia, Paliorema, Firlingo, and Kalamos). Modern production briefly boomed between 1890 and 1905 with the discovery of its efficacy in treating vines alfected by phylloxera when some 300 labourers were employed (Wagstaff m Renfrew and Wagstaff (n. 12). 241) in extracting 125.000 tons of raw material with an average sulphur content of 14% (Stamatakis et al. (n. 2). 61). Formerly it was probably extracted in its pure crystalline form only where the mineral formed on the surface ot rock exposures and in fissures. It is possible that sulphur-rich matrices such as gypsum and clay were processed in kilns to extract the sulphur. Sulphur crystals melt at 113°C: in the process the liquid sulphur would trickle to the bottom of the kiln, from which it could be removed. Pale yellow liquid sulphur becomes increasingly viscous up to 180°C, at which point it acquires a red huc and thereafter decreases in viscosity. In air sulphur ignites and burns with a blue flame to produce sulphur dioxide at 363°C. The liquid could be poured into moulds for transportation or, in its viscous red state, turned into water to its (temporarily) plastic form. Sulphuric acid (oil of vitriol) produced by heating ferrous sulphate and alum exists naturally in water in volcanic regions (Singer, G., Holmyard, E. J., Hall, A. R., and Williams, F. (eds). A History of Technology). iii: From the Renaissance to the Industrial Revolution (Oxford, 1956Google Scholar)): as a medicine, the concentrated acid could be applied to venereal sores and warts and presumably its more dilute form in medicinal baths was moderately efficacious.

32 See Fytikas (n. 27).

33 Fytikas, M., Innocenti, F., Kolios, N., Manetti, P., Mazzuoli, R., Poli, G., Rita, F., and Villari, L., ‘Volcanology and petrology of volcanic products from the island of Milos and neighbouring islets’. Journal of Volcanology and Geothermal Research, 28 (1986), 297317CrossRefGoogle Scholar.

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35 Ibid. Soine hematite was probably also produced more conventionally by oxidation of iron-bearing minerals such as iron-rich illite/smectite and chlorite. The key reactants and products are represented in the (unbalanced) equations:

Fe3+ (sulphate) + H2O→Fe2O3 + H2SO4

FeO(silicate + O2→FE2O3 + Fe-free silicate.

36 D. Davidson and C. Tasker, ‘Geomorphic evolution during the late Holocene’, in Renfrew and Wagstaff (n. 12). 82–94.

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