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On the chemical composition of prehistoric Greek copper-based artefacts from mainland Greece1

Published online by Cambridge University Press:  27 September 2013

Helen Mangou  and
Panayiotis V. Ioannou
Helen Mangou
Affiliation:
Chemistry Laboratory, National Archaeological Museum, Athens, Greece
Panayiotis V. Ioannou
Affiliation:
Department of Chemistry, University of Patras, Greece
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Abstract

170 copper-based objects from various sites in mainland Greece covering the Late Neolithic period and the whole of the Bronze Age have been analysed for their chemical content (twelve elements) by atomic absorption spectroscopy. The results indicate that at all sites during the Late Neolithic and Early Bronze Age relatively pure copper and arsenical copper were used, while during the Middle and Late Bronze Ages bronze dominated. Bronze objects of the Early Bronze Age were probably imported. Lead was not usually used to help casting. Metallographic examination of eight Late Neolithic, Early and Late Bronze Age hammered objects revealed that they have been cold-worked and annealed, most probably through several cycles.

Type
Articles
Information
Annual of the British School at Athens , Volume 94 , November 1999 , pp. 81 - 100
Copyright
Copyright © The Council, British School at Athens 1999

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References

Branigan, K. (1969). ‘Early Aegean hoards of metalwork’, BSA 64: 111.Google Scholar
Branigan, K. (1974). Aegean Metalwork of the Early and Middle Bronze Age (London).Google Scholar
Budd, P., and Ottaway, B. S. (1991), ‘The properties of arsenical copper alloys: implications for the development of eneolithic metallurgy’, in Budd, P. et al. (eds)Archaeological Sciences 1989: Proceedings of a Conference on the Application of Scientific Techniques to Archaeology (Oxbow Monograph 9; Oxford), 132–42.Google Scholar
Caley, E. R. (1949). ‘On the prehistoric use of arsenical copper in the Aegean region’, Hesp. supp. 8: 60–3.Google Scholar
Catling, H. W. (1964). Cypriot Bronzework in the Mycenaean World (Oxford).Google Scholar
Charles, J. A. (1967). ‘Early arsenical bronzes: a metallurgical view’, AJA 71: 21–6.CrossRefGoogle Scholar
Chourmouziades, G. (1979). Τὸ Νεολιθικὸ Διμήνι (Volos).Google Scholar
Cooke, S. R. B. (1975). ‘Analyses of copper/bronze samples: excavations at Nichoria in Messenia 1972–1973’, Hesp. 44: 129–35.Google Scholar
Craddock, P. T. (1976). ‘The composition of copper alloys used by the Greek, Etruscan and Roman civilizations. I. The Greeks before the Archaic Period’. JAS 4: 103–23.Google Scholar
Craddock, P. T. and Meeks, N. D. (1987). ‘Iron in ancient copper’. Archaeometry, 29: 187204.CrossRefGoogle Scholar
Demakopoulou, K. and Konsola, N. (1981). Αρχαιολοϒικό Μουσείο Θήβας. Οδηϒός (Athens).Google Scholar
Deshayes, J. (1970), ‘Dikili-Tash’, BCH 94: 799808.Google Scholar
Diakaki, E. (1986), Αξιολόϒηση των μεταλλικών εμϕανίσεων στην περιοχή Ολυμπιάδος–Στρατωνίον–Ιερισσού του νομού Χαλκιδικής, IGME (Athens).Google Scholar
Dickinson, O. T. P. K. (1977). The Origins of the Mycenaean Civilization (SIMA 49; Göteborg).Google Scholar
Fleming, S. J. (1976). Dating in Archaeology (London).Google Scholar
Gale, N. H. and Stos-Gale, Z. A. (1982). ‘Bronze age copper sources in the Mediterranean: a new approach’. Science, 216: 1119.CrossRefGoogle ScholarPubMed
Goldman, H. (1931). Excavations at Eutresis in Boeotia (Cambridge. Mass.).Google Scholar
Gordon, R. B., and Rutledge, J. W. (1984). ‘Bismuth bronze from Machu Picchu Peru’, Science, 223: 585–6.CrossRefGoogle ScholarPubMed
Grammenos, D. V. (1995), Dimitra: A Prehistoric Site near Serres. Preliminary Report of the Excavations in the Years 1978, 1979, 1980 (Athens).Google Scholar
Iakovidis, S. (1982), ‘The Mycenean bronze industry’, in Muhly, J.D., Maddin, R., and Karageorghis, V. (eds), Acta of the International Archaeological Symposium, Larnaca, Cyprus, 1–6 June, 1981 (Nicosia), 213–30.Google Scholar
IGME (Institute of Geological and Mining Exploration) (1973), Επεξεϒηματικό τεύχος του Μεταλλοϒενετικού χάρτη της Ελλάδος (Athens).Google Scholar
Junghans, S., Sangmeister, E., and Schroeder, M. (1968), Kupfer und Bronze in der frühen Metallzeit Europas, 13 (Berlin).Google Scholar
Kilian, K. (1984), ‘Μυκηναïκά ερϒαστήρια χαλκού στην Τίρυνθα’, Ανθρωπολοϒικά, 6: 55 7.Google Scholar
Knapp, A. B., Muhly, J. D., and Muhly, P. (1988), ‘To hoard is human: Late Bronze Age metal deposits in Cyprus and the Aegean’, RDAC: 233–62.Google Scholar
Lambert, N. (1981), La grotte préhistorique de Kïtsos (Attique) (Paris).Google Scholar
Leute, U. (1987), Archaeometry: An Introduction to Physical Methods in Archaeology and the History of Art (Weinheim).Google Scholar
Mangou, E., and Ioannou, P. V. (1997), ‘On the chemical composition of prehistoric Greek copper-based artefacts from the Aegean region’, BSA 92: 5972.Google Scholar
Mangou, E. and Ioannou, P. V. (1998), ‘On the chemical composition of prehistoric Greek copper-based artefacts from Crete’, BSA 93: 91102.Google Scholar
McGeehan-Liritzis, V., and Gale, N. H. (1988), ‘Chemical and lead isotope analyses of Greek late neolithic and early bronze age metals’. Archaeometry, 30: 199225.CrossRefGoogle Scholar
Muhly, J. D. (1991), The Development of Copper Metallurgy in Late Bronze Age Cyprus (SIMA 90; Göteborg).Google Scholar
Mylonas, G. (1959), Aghios Kosmas: An Early Bronze Age Settlement and Cemetery in Attica (Princeton).Google Scholar
Nebel, M. L., Hutchinson, R. W., and Zartman, R. E. (1991), ‘Metamorphism and polygenesis of the Madem Lakkos polymetallic sulfide deposit Chalkidiki, Greece’, Economic Geology, 86: 81105.CrossRefGoogle Scholar
Pernicka, E. (1987), Erzlagerstatten in der Ägäis und ihre Ausbeutung im Altertum: geochemische Untersuchungen zur Herkunftsbestimmung archäologischer Metallobjekte (Habihtationschrift, Ruprecht-Karls-Universität, Heidelberg).Google Scholar
Petrikaki, M. (1980), ‘Δείψανα πρωτοελλαδικού οικισμού στό Ρούϕ’, A. Delt. 35A: 173–4.Google Scholar
Phelps, W. W., Varoufakis, G. J., and Jones, R. E. (1979). ‘Five copper axes from Greece’. BSA 74: 175 84.Google Scholar
Renfrew, C. (1973). ‘Ἐμπόριο καί τεχνική ἐξειδίκευση’, in Theocharis, D. (cd.). Νεολιθικὴ Ἑλλάς (Athens), 191–2.Google Scholar
Renfrew, C. (1986). ‘Sitagroi in European prehistory’, in Gimbutas, M., Renfrew, C., and Elster, E. S. (eds). Sitagroi: A Prehistoric Village in Northeast Greece I (Los Angeles), 477–85.Google Scholar
Sampson, A. (1985), Μάνικα I. Μία πρωτοελλαδική πόλη στη Χαλκίδα (Chalkis).Google Scholar
Sampson, A.(1993), Σκοτεινή Θαρούνια:το σπήλαιο, ο οικισμός και το νεκροταϕείο (Athens).Google Scholar
Theocharis, D. (1952), ‘Ἀνασκαϕὴ ἐν Ἀραϕῆνι’, PAE 27: 129–51.Google Scholar
Theocharis, D. (1973), Νεολιθική Ἐλλάς (Athens).Google Scholar
Tite, M. S. (1972), Methods of Physical Examination in Archaeology (London).Google Scholar
Tsountas, Ch. (1908), Οἱ Νεολιθικές ἀ κροπό λεις Σέσκλου καὶ Διμηνιοῦ (Athens).Google Scholar
Tylecote, R. F. (1976), A History of Metallurgy (London).Google Scholar
Varoufakis, G. (1967), ‘Ἐξέτασις μεταλλικῶν ἀντικειμένων τοῦ Μυκηναïκοῦ νεκροταϕείου Περατῆς’, Arch. Eph. 7082.Google Scholar
Varoufakis, G. (1973), ‘Μεταλλουρϒικὴ ἔρευνα ἀντικειμένων ἐκ χαλκοῦ ἐκ τοῦ ταϕικοῦ περιβόλου’, in Mylonas, G. E. (ed.). Ὁ Ταϕικὸς Κύκλος B' τῶν Μυκηνῶν (Athens), 363–77.Google Scholar
Walter, H. (1985), Ο κόσμος της αρχαίας Αίϒινας 3000–1000 π.X. (Athens).Google Scholar