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Lead isotope analyses from Tell Abraq, United Arab Emirates: new data regarding the ‘tin problem’ in Western Asia

Published online by Cambridge University Press:  02 January 2015

Lloyd Weeks
Lloyd Weeks*
Affiliation:
Department of Near Eastern Archaeology, Main Quad A14, Sydney University 2006, Australia weeks@acl.archaeology.usyd.edu.au
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Keywords

western AsiaArabiaTell Abraqtinbronzelead isotope analysisprehistory
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Antiquity , Volume 73 , Issue 279 , March 1999 , pp. 49 - 64
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Copyright © Antiquity Publications Ltd. 1999

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References

Agrawal, D.P. 1982. The Indian Bronze Age cultures and their metal technology, in Wendorf, F. & Close, A.E. (ed.), Advances in World Archaeology 1: 21364. New York (NY): Academic Press.Google Scholar
Agrawal, D.P. 1984. Metal technology of the Harappans, in Lal, B.B. & Gupta, S.P. (ed.), Frontiers of the Indus civilization: 1637. New Delhi: Indian Archaeological Society and the Indian History & Culture Society.Google Scholar
Asthana, S. 1993. Harappan trade in metals and minerals: a regional approach, in Possehl, G.L. (ed.), Harappan Civilisation: a recent perspective: 27185. New Delhi: Indian Archaeological Society and the Indian History and Culture Society.Google Scholar
Batchelor, D.A.F. 1992. Styles of metallic mineralization and their tectonic setting in the Sultanate of Oman, Transactions of the Institute of Mining and Metallurgy, Section B — Applied Earth Sciences 101: B108120.Google Scholar
Begemann, F.,Pernicka, E. & Schmitt-Strecker, S.. 1995. Thermi on Lesbos: a case study of changing trade patterns, Oxford Journal of Archaeology 14: 12335.Google Scholar
Begemann, F Schmitt-Strecker, S. & Pernicka, E.. 1989. Isotopic composition of Pb in early metal artefacts: results, possibilities, limitations, in Hauptmann, et al, (ed.): 26978.Google Scholar
Begemann, F Schmitt-Strecker, S. & Pernicka, E.. 1992. The metal finds from Thermi III-V: a chemical and lead-isotope study, Studia Troica 2: 21939.Google Scholar
Berthoud, T., Bonnefous, S. Dechoux, M. & Francaix, J.. 1980. Data analysis: toward a model of chemical modification of copper from ores to metal, in Craddock, P.T. (ed.), Proceedings of the XIXth Symposium on Archaeometry: 87102. London: British Museum. Occasional paper 18.Google Scholar
Briqueu, L.,Mevel, C. & Boudier, F.. 1991. Sr, Nd and Pb isotopic constraints in the genesis of a calc-alkaline plutonic suite in Oman ophiolite related to obduction processes, in Peters, et al. (ed.): 51742.Google Scholar
Caley, E.R. 1971. Analyses of some metal artifacts from ancient Afghanistan, in Brill, R.H. (ed.), Science and archaeology: 10612. Cambridge (MA): M.I.T. Press.Google Scholar
Caley, E.R. 1972a. Results of an examination of fragments of corroded metal form the 1962 excavations at Snake Cave, Afghanistan, in Dupree, (1972): 43.Google Scholar
Caley, E.R. 1972b. Chemical examination of metal artifacts from Afghanistan, in Dupree, (1972): 4450.Google Scholar
Calvez, J.Y. & Lescuyer, J.L.. 1991. Lead isotope geochemistry of various sulphide deposits from the Oman Mountains, in Peters, et al. (ed.): 38597.Google Scholar
Chen, J.H. & Pallister, J.S.. 1981. Lead isotopic studies of the Samail pphiolite, Oman, Journal of Geophysical Research 86(B4): 2699708.Google Scholar
Cleuziou, S. 1992. The Oman Peninsula and the Indus Civilization: a reassessment, Man and Environment 17(2): 93103.Google Scholar
Cleuziou, S. & Berthoud, T.. 1982. Early tin in the Near East: a reassessment in the light of new evidence from Western Afghanistan, Expedition 25: 1419,Google Scholar
Coleman, J.E. 1992. Greece, the Aegean and Cyprus, in Ehrich, (ed.): 24788.Google Scholar
Crawford, H.E.W. 1974. The problem of tin in Mesopotamian bronzes, World Archaeology 6(2): 2426.Google Scholar
Doe, B.R. 1982. The lead and strontium isotope geochemistry of metalliferous sediments associated with Upper Cretaceous ophiolitic rocks in Cyprus, Syria, and the Sultanate of Oman: discussion, Canadian Journal of Earth Sciences 19: 172024.Google Scholar
Du Bray, E.A. 1985. Geology of the Silsilah ring complex, and associated tin mineralization, Kingdom of Saudi Arabia — a synopsis, American Mineralogist 70: 107586.Google Scholar
Du Bray, E.A., Elliot, J.E. & Stuckless, J.S. 1988. Proterozoic peraluminous granites and associated Sn-W deposits, Kingdom of Saudi Arabia, in Taylor, R.P & Strong, D.F. (ed.), Recent advances in the geology of granite-related mineral deposits: 14256. Montreal: Canadian Institute of Mining and Metallurgy. Special volume 39.Google Scholar
Dupree, L. 1972. Prehistoric research in Afghanistan (1959–1966). Philadelphia (PA): American Philosophical Society. Transactions of the American Philosophical Society 62(4).Google Scholar
During-Caspers, E.C.L. 1994. Further evidence for ‘Central Asian’ materials from the Arabian Gulf, Journal of the Economic and Social History of the Orient 37: 3353.Google Scholar
Economic & Social Commission For Asia And The Pacific. 1995. Geology and mineral resources of Aghanistan. New York (NY): United Nations. Atlas of Mineral Resources of the ESCAP Region 11.Google Scholar
Edens, C. 1993. Indus-Arabian interaction during the Bronze Age: a review of evidence, in Possehl, (ed.): 33564.Google Scholar
Ehrich, R.W. (ed.). 1992. Chronologies in Old World archaeology 1. Chicago (IL): University of Chicago Press.Google Scholar
Esin, U. 1969. Kuantitif Spektral Analiz Yardimiyla Anadolu’da Baslangicindan Asur Kolonileri Cagina Kadar Bakir ve Tunc Madenciligi, Istanbul: Tas Matbaasi.Google Scholar
Fleming, S.J. & Pigott, V.C.. 1987. Archaeometallurgy, in Glanzman, W.D. & Ghaleb, A.O., Site reconnaissance in the Yemen Arab Republic, 1984: The stratigraphic probe at Hajar Ar-Rayhami: 17181. Washington (DC): American Foundation for the Study of Man. Wadi Al-Jubah Archaeological Project 3.Google Scholar
Franke-Vogt, U. 1993. The Harappans and the West: some reflections on Meluhha’s relations to Magan, Dilmun and Mesopotamia, University of Kanazawa Bulletin of Archaeology 20: 72101.Google Scholar
Franklin, A.D., Olin, J.S. & Wertime, T.A. (ed.). 1978. The search for ancient tin. Washington, D.C.: Government, U.S. Printing Office.Google Scholar
Gale, N.H. & Spooner, E.T.C.. 1982. The lead and strontium isotope geochemistry of metalliferous sediments associated with Upper Cretaceous ophiolitic rocks in Cyprus, Syria, and the Sultanate of Oman: Reply, Canadian Journal of Earth Sciences 19: 17246.CrossRefGoogle Scholar
Gale, N.H., Spooner, E.T.C. & Potts, P.J.. 1981. The lead and strontium isotope geochemistry of metalliferous sediments associated with Upper Cretaceous ophiolitic rocks in Cyprus, Syria and the Sultanate of Oman, Canadian Journal of Earth Sciences 18: 12901302.CrossRefGoogle Scholar
Gale, N.H. & Stos-Gale, Z.A.. 1982. Bronze Age copper sources in the Mediterranean: a new approach, Science 216(4541): 1119.Google Scholar
Gale, N.H. 1985. Lead isotope analysis and Alashiya-3, Report of the Department of Antiquities, Cyprus 1985: 8399.Google Scholar
Glanzman, W.D. 1987. Metallurgical debris, in Glanzman, W.D. & Ghaleb, A.O., Site reconnaissance in the Yemen Arab Republic, 1984: The stratigraphic probe at Hajar Ar-Rayhami: 1458. Washington (DC): American Foundation for the Study of Man. Wadi Al-Jubah Archaeological Project 3.Google Scholar
Glennie, K.W., Boeuf, G.A. Hughes-Clarke, M.W. Moody-Stuart, M. Pilaar, W.F. & Reinhardt, B.M.. 1974. Geology of the Oman Mountains, Part 1, Verhandelingen van hat Koninklijk Nederlands geologisch mijnbouwkundig Genootschap 31.Google Scholar
Gnos, E.,Immenhauser, A. & Peters, Tj.. 1997. Late Cretaceous/ early Tertiary convergence between the Indian and Arabian plates recorded in ophiolites and related sediments, Tectonophysics 271: 119.Google Scholar
Greenwood, J.E.G.W. & Loney, P.E.. 1968. Geology and mineral resources of the Trucial Oman Range. London: Institute of Geological Sciences, Overseas Division.Google Scholar
Gulson, B.L. 1986. Lead Isotopes in Mineral Exploration. Amsterdam: Elsevier.Google Scholar
Gulson, B.L. & Jones, M.T.. 1992. Cassiterite: potential for direct dating of mineral deposits and a precise age for the Bushveld complex granites, Geology 20: 3558.Google Scholar
Hall, M.E. & Steadman, S.R.. 1991. Tin and Anatolia: another look, Journal of Mediterranean Archaeology 4: 21734.Google Scholar
Hamelin, B. Dupré, B. & Allégre, C.J.. 1984. The lead isoope systematics of ophiolite complexes, Earth and Planetary Science Letters 67: 35166.Google Scholar
Hamelin, B., Dupré, B., Brévart, O. & Allégre, C.J.. 1988. sMetallogenesis at Paleo-spreading centers: lead isotopes in sulfides, rocks and sediments from the Troodos Ophiolite (Cyprus), Chemical Geology 68: 22938.Google Scholar
Hassan, M.A. & Al-Sulaimi, J.S.. 1979. Copper mineralization in the northern part of Oman Mountains near Al Fujairah, United Arab Emirates, Economic Geology 74: 91924.Google Scholar
Hauptmann, A. 1985. 5000 Jahre Kupfer in Oman 1: Die Entwicklung der Kupfermetallurgie vom 3. Jahrtausend bis zur Neuzeit. Bochum: Vereinigung der Freunde von Kunst und Kultur im Bergbau. Der Anschnitt Beiheft 4.Google Scholar
Hauptmann, A. 1987. Kupfer und Bronzen der Südostarabischen Halbinsel, Der Anschnitt 39: 209218.Google Scholar
Hauptmann, A.,Pernicka, E. & Wagner, G.A. (ed.). 1989. Old World Archaeometallurgy. Bochum: Vereinigung der Freunde von Kunst und Kultur im Bergbau. Der Anschnitt Beiheft 7.Google Scholar
Hauptmann, A.,Weisgerber, G. & Bachmann, H.G.. 1988. Early Copper metallurgy in Oman, in Maddin, R. (ed.), The beginning of the use of metals and alloys: 3451. Cambridge (MA): MIT Press.Google Scholar
Hegde, K.T.M. 1978. Sources of ancient tin in India, in Franklin, et al. (ed.): 3942.Google Scholar
Herrmann, G. 1968. Lapis Lazuli: the early phases of its trade, Iraq 30(1): 2157.Google Scholar
Hosler, D. 1995. Sound, colour and meaning in the metallurgy of ancient West Mexico, World Archaeology 27: 10015.Google Scholar
Joannes, F. 1991. L’Etain, de l’Elam a Mari, in Meyer, De L. & Gasche, H. (ed.), Mesopotamie et Elam: 6776. Ghent: Mesopotamian History & Environment. Occasional publication 1.Google Scholar
Kamilli, R.J. & Criss, R.E.. 1996. Genesis of the Silsilah tin deposit, Kingdom of Saudi Arabia, Economic Geology 91: 141434.Google Scholar
Knapp, A.B. & Cherry, J.F.. 1994. Provenience studies and Bronze Age Cyprus: production, exchange and politico-economic change. Madison (WI): Prehistory Press.Google Scholar
Lahiri, N.D. 1995. Indian metal and metal-related artefacts as cultural signifiers: an ethnographic perspective, World Archaeology 27: 11632.CrossRefGoogle Scholar
Lamberg-Karlovsky, C.C. 1967. Archaeology and metallurgical technology in prehistoric Afghanistan, India and Pakistan, American Anthropologist 69: 14562.Google Scholar
Larsen, M.T. 1976. The old Assyrian city-state and its colonies, Copenhagen: Akademisk Forlag.Google Scholar
Larsen, M.T. 1987. Commercial networks in the ancient Near East, in Rowlands, M. Larsen, M.T. & Kristiansen, K. (ed.), Centre and periphery in the ancient world: 4756. Cambridge: Cambridge University Press.Google Scholar
Levy, T.E. & Shalev, S.. 1989. Prehistoric metalworking in the southern Levant: archaeometallurgical and social perspectives, World Archaeology 20: 35272.Google Scholar
Limet, H. 1960. Le travail du metal au pays de Sumer au temps de la IIIe dynastie d’Ur. Paris.Google Scholar
Lippard, S.J., Shelton, A.W. & Gass, I.G.. 1986. The ophiolite of northern Oman. London: Blackwell Scientific Publcations. Geological Society Memoir 11.Google Scholar
Maddin, R. 1989. The copper ingots and tin ingots from the Kas shipwreck, in Hauptmann, et al. (ed.): 99105.Google Scholar
Magee, P. 1996. The chronology of the Southeast Arabian Iron Age, Arabian Archaeology and Epigraphy 7(2): 24052.Google Scholar
Malamat, A. Syro-Palestinian destinations in a Mari tin inventory, Israel Exploration Journal 21: 318.Google Scholar
McKerrell, H. 1978. The use of tin-bronze in Britain and the comparative relationship with the Near East, in Franklin, et al. (ed.): 724.Google Scholar
Mellink, M.J. 1992. Anatolia, in Ehrich, (ed.): 20720.Google Scholar
Meyer, J.,Mercolli, I. & Immenhauser, A.. 1996. Off-ridge alkaline magmatism and seamount volcanoes in the Masirah island ophiolite, Oman, Tectonophysics 267: 187208.Google Scholar
Moorey, P.R.S. 1982. Archaeology and Pre-Achaemenid metalworking in Iran: a fifteen year retrospective, Iran 20: 81101.Google Scholar
Moorey, P.R.S. 1994. Ancient Mesopotamian materials and industries: the archaeological evidence. Oxford: Clarendon Press.Google Scholar
Muhly, J.D. 1973. Copper and tin, Transactions of the Connecticut Academy of Arts and Sciences 43: 155535.Google Scholar
Muhly, J.D. 1978. New evidence for sources of and trade in Bronze Age tin, in Franklin, et al. (ed.): 438.Google Scholar
Muhly, J.D. 1985. Sources of tin and the beginnings of Bronze metallurgy, American Journal of Archaeology 89: 27591.Google Scholar
Muhly, J.D. 1993. Early Bronze Age tin and the Taurus, American Journal of Archaeology 97: 23953.Google Scholar
Muhly, J.D. 1995. Mining and metalwork in ancient Western Asia, in Sasson, J.M. (ed.), Civilizations of the Ancient Near East 3: 150121. New York (NY): Charles Scribner’s Sons.Google Scholar
Muhly, J.D., Begemann, F., Oztunali, Ó Pernicka, E. Schmitt-Strecker, S. & Wagner, G.A.. 1991. The Bronze Age metallurgy of Anatolia and the question of local tin sources, in Pernicka, & Wagner, (ed.): 20920.Google Scholar
Muller-Karpe, M. 1991. Aspects of early metallurgy in Mesopotamia, in Pernicka, & Wagner, (ed.): 10516.Google Scholar
Overstreet, W.C., Detra, D.E. Botinelly, T. Grolier, M.S. Stoeser, D.B. & Schmidt, D.L.. 1988. Mineral resources of the al-Jubah Quadrangle, Yemen Arab Republic, in Overstreet, W. Grolier, M.J. & Toplyn, M.R., Geological and archaeological reconnaissance in the Yemen Arab Republic, 1985: 359418. Washington (DC): American Foundation for the Study of Man. Wadi Al-Jubah Archaeological Project 4.Google Scholar
Peake, H. 1928. The Copper mountain of Magan, Antiquity 2: 4527.Google Scholar
Pedersen, C.H. & Buchwald, V.F.. 1991. An examination of meta! objects from Tell U.A.E Abraq , Arabian Archaeology and Epigraphy 2: 19.Google Scholar
Pernicka, E. 1995. Gewinnung und Verbreitung der Metalle ii prahistorische Zeit, Jahrbuch des Romisch-Germanischen Zentralmuseums, Mainz 37: 21134.Google Scholar
Pernicka, E., Begemann, F. Schmitt-Strecker, S. & Grimianis, A.P,. 1990. On the composition and provenance of metal objects from Poliochni on Lemnos, Oxford Journal of Archaeology 9: 26398.Google Scholar
Pernicka, E., Seeliger, T.C. Wagner, G.A. Begemann, F., Schmitt-Strecker, S. Eibner, C., Óztunali, Ó. & Barany, I.;. 1984. Archaometallurgische Untersuchungen in Nordwestanatolien, Jahrbuch des Rómisch-Germanischei Zentralmuseums, Mainz 31: 533639.Google Scholar
Pernicka, E. & Wagner, G.A. (ed.). 1991. Archaeometry ’90. Basel: Birkhauser Verlag.Google Scholar
Pernicka, E., Wagner, G.A. Muhly, J.D. & Oztunali, O.. 1992. Comment on the discussion of ancient tin sources in Anatolia, Journal of Mediterranean Archaeology 5: 918.Google Scholar
Peters, T., Nicolas, A. & Coleman, R.G. (ed.). 1991. Ophiolite genesis and the evolution of the oceanic lithosphere: 51742. Sultanate of Oman: Ministry of Petroleum and Minerals.Google Scholar
Pigott, V.C. 1996. Bronze I. In Pre-Islamic Iran, in Yarshater, E. (ed.), Encyclopaedia Iranica 4: 45771. London: Routledge. & Kegan Paul.Google Scholar
Possehl, G.L. (ed.). 1993. Harappan civilization. 2nd edition. New Delhi: Oxford and IBH.Google Scholar
Potts, D.T. 1990a. The Arabian Gulf in antiquity 1. Oxford: Clarendon Press.Google Scholar
Potts, D.T. 1990b. A prehistoric mound in the Emirate of Umm al-Qaiwain, U.A.E.: Excavations at Tell Abraq in 1989. Copenhagen: Munksgaard.Google Scholar
Potts, D.T. 1991. Further excavations at Tell Abraq. The 1990 season. Copenhagen: Munksgaard.Google Scholar
Potts, D.T. 1993a. Four seasons of excavation at Tell Abraq (1989–1993), Proceedings of the Seminar for Arabian Studies 23:11726.Google Scholar
Potts, D.T. 1993b. Rethinking some aspects of trade in the Arabian Gulf, World Archaeology 24(3): 42338.Google Scholar
Potts, D.T. 1993c. Tell Abraq and the Harappan tradition in Southeastern Arabia, in Possehl, (ed.): 32333.Google Scholar
Potts, D.T. 1993d. A new Bactrian find from southeastern Arabia, Antiquity 67: 5916.Google Scholar
Potts, D.T. 1994. South and Central Asian Elements at Tell Abraq (Emirate of Umm al-Qaiwain, United Arab Emirates), c. 2200 BC-300 AD, in Parpola, A. & Koskikallio, P. (ed.), South Asian Archaeology 1993 2: 61528. Helsinki: Annales Academiae Scientarium Fennicae Ser. B271.Google Scholar
Potts, T.F. 1994. Mesopotamia and the East. An archaeological and historical study of foreign relations c. 3400–2000BC. Oxford: Oxford Committee for Archaeology. Monograph 37.Google Scholar
Rapp, G. 1978. Trace elements as a guide to the geological source of tin ore: smelting experiments, in Franklin, et al. (ed.): 5963.Google Scholar
Renfrew, C. 1967. Cycladic metallurgy and the Aegean Early Bronze Age, American Journal of Archaeology 71: 120.Google Scholar
Renfrew, C. 1972. The emergence of civilisation. The Cyclades and the Aegean in the third millennium BC. London: Methuen.Google Scholar
Renfrew, C Dixon, J.E. & Cann, J.R.. 1966. Obsidian and early cultural contacts in the Near East, Proceedings of the Prehistoric Society 32: 3072.Google Scholar
Sayre, E.V., Yener, K.A. Joel, E.C. & Barnes, I.L.. 1992. Statistical evaluation of the presently accumulated lead isotope data from Anatolia and surrounding regions, Archaeometry 34: 73105.Google Scholar
Selimkhanqv, I.R. 1978. Ancient tin objects of the Caucasus and the results of their analyses, in Franklin, et al. (ed.): 538.Google Scholar
Smewing, J.D., Abbotts, I.L. Dunne, L.A. & Rex, D.C. 1991. Formation and emplacement ages of the Masirah ophiolite, Sultanate of Oman, Geology 19: 4536.Google Scholar
Stacey, J.S., Doe, B.R. Roberts, R.J. Delevaux, M.H. & Gramlich, J.W.. 1980. A lead isotope study of mineralization in the Saudi Arabian Shield, Contributions to Mineralogy and Petrology 74: 17588.Google Scholar
Stech, T. & Pigott, V.C. 1986. The metals trade in Southwest Asia in the third millennium BC, Iraq 48: 3964.Google Scholar
Stocklin, J., Eftekhar-Nezhad, N. & Taghizadeh, A. 1972. Central Lut reconnaissance, Eastern Iran, Geological Survey of Iran Report 22: Tehran.Google Scholar
Stos-Gale, Z.A. 1989. Lead isotope studies of metal and the metals trade in the Bronze Age Mediterranean, in Henderson, J. (ed.) Scientific analysis in archaeology: 21336. Oxford: Oxford University Committee for Archaeology. Monograph 19.Google Scholar
Stos-Gale, Z.A. 1992. The origin of metal objects from the Early Bronze Age site of Thermi on the Island of Lesbos, Oxford Journal of Archaeology 11(2): 15577.Google Scholar
Stos-Gale, Z.A., Gale, N.H. & Gilmore, G.R.. 1984. Early Bronze Age Trojan metal sources and Anatolians in the Cyclades, Oxford Journal of Archaeology 3(3): 2337.Google Scholar
Stos-Gale, Z.A., Maliotis, G. Gale, N.H. & Annetts, N.. 1997. Lead isotope characteristics of the Cyprus copper ore deposits applied to provenance studies of copper oxhide ingots, Archaeometry 39(1): 83123.Google Scholar
Tadmor, M., Kedem, D. Begemann, F. Hauptmann, A. Pernicka, E. & Schmitt-Strecker, S.. 1995. The Nahal Mishmar Hoard from the Judean Desert: technology, composition, and provenance, ‘Atiqot 27; 95148.Google Scholar
Thorpe, R.I. 1982. The lead and strontium isotope geochemistry of metalliferous sediments associated with Upper Cretaceous ophiolitic rocks in Cyprus, Syria, and the Sultanate of Oman: Discussion, Canadian Journal of Earth Sciences 19: 171019.CrossRefGoogle Scholar
Tosi, M. 1975. Notes on the distribution and exploitation of natural resources in Ancient Oman, Journal of Oman Studies 1: 187206.Google Scholar
Tylecote, R.F. 1978. Early tin ingots and tinstone from Western Europe and the Mediterranean, in Franklin, et al. (ed.): 4952.Google Scholar
Vogt, B. 1995. Asimah: an account of two months rescue excavation in the mountains of Ras al-Khaimah, United Arab Emirates. Dubai: Shell Marketing.Google Scholar
Waetzoldt, H. & Bachmann, H.G.. 1984. Zinn- und Arsenbronzen in den Texten aus Ebla und aus dem Mesopotamien des 3. Jahrtausends, Oriens Antiquus 23: 118.Google Scholar
Weeks, L.R. 1997. Prehistoric metallurgy at Tell Abraq, United Arab Emirates, Arabian Archaeology and Epigraphy 8: 1185.Google Scholar
Weisgerber, G. 1980a. ‘.. .und Kupfer in Oman’ — Das Oman-Projekt des Deutschen Bergbau-Museums, Der Anschnitt 32: 62110.Google Scholar
Weisgerber, G. 1980b. Patterns of Early Islamic metallurgy in Oman, Proceedings of the Seminar for Arabian Studies 13:11525.Google Scholar
Weisgerber, G. 1981. Mehr als Kupfer in Oman — Ergebnisse der Expedition 1981, Der Anschnitt 33: 174263.Google Scholar
Weisgerber, G. 1984. Makan and Meluhha — third millennium BC copper production in Oman and the evidence of contact with the Indus Valley, in Allchin, B. (ed.), South Asian Archaeology 1981: 196201. Cambridge: Cambridge University Press.Google Scholar
Weisgerber, G. 1988. Oman: a bronze-producing centre during the 1st half of the 1st millennium BC, in Curtis, J. (ed.) Bronzeworking centres of western Asia c. 1000–539 BC: 28595. London: Kegan Paul International.Google Scholar
Weisgerber, G. 1991. Archéologisches Fundgut des 2. Jahrtausends v. Chr. in Oman. Moglichkeiten zur chronologischen Gliederung, in Schippmann, K. Herling, A. & Salles, J.-F. (ed.), Golf- Archäologie: Mesopotamien, Iran, Kuwait, Bahrain, Vereinigte Arabische Emirate und Oman: 32130. Buch am Erlbach, Verlag Marie L. Leidorf. Internationale Archdologie 6.Google Scholar
Wertime, T.A. 1978. The search for ancient tin: the geographic and historic boundaries, in Franklin, et al. (ed.): 16.Google Scholar
Willies, L. 1990. An Early Bronze Age tin mine in Anatolia, Turkey, Bulletin of the Peak District Mines Historical Society 11(2): 916.Google Scholar
Willies, L. 1992. Reply to Pernicka et al: Comment on the discussion of ancient tin sources in Anatolia, Journal of Mediterranean Archaeology 5: 99103.Google Scholar
Yener, K.A. & Goodway, M.. 1992. Response to Mark E. Hall, and Sharon R. Steadman, ‘Tin in Anatolia: another look’, Journal of Mediterranean Archaeology 5: 918.Google Scholar
Yener, K.A. & Ózbal, H.. 1987. Tin in the Turkish Taurus mountains: the Bolkardag mining district, Antiquity 61: 22026.Google Scholar
Yener, K.A., Ózbal, H. Kaptan, E. Pehlivan, & A.N. Goodway, M.. 1989. Kestel: an early Bronze Age source of tin ore in the Taurus Mountains, Science 244: 200203.Google Scholar
Yener, K.A. & Vandiver, P.. 1993. Tin processing at Goltepe, an Early Bronze Age site in Anatolia, American Journal of Archaeology 97: 20738.CrossRefGoogle Scholar