Prehistoric Iron Bloomery Debris on a Small Island in Lake Aisetas (Eastern Lithuania)
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Abstract
The archaeological discoveries of metallurgical waste in Lithuania have established that metallurgical activities were commonly connected to settlements. However, recent investigations suggest that even in the case of small-scale production on a homestead industry level, small isolated smelting bloomeries could have existed outside settlements.
The work presented in this article introduces the material acquired from the newly discovered prehistoric site on a small island in Lake Aisetas in Eastern Lithuania. The data was acquired through surface and soil sampling surveys, magnetic susceptibility measurements, and small-scale excavations. Metallurgical waste weighing 150 kg was collected without additional evidence to facilitate archaeological interpretation of the finds and their origins.
This article aims to characterise the metallurgical waste and deduce the nature of the activity and processes that produced these by-products on the island. Through an exploration of recovery circumstances and a macroscopic examination as well as composition and microstructure analysis of the metallurgical waste, this study intends to answer the following questions: what constitutes the metallurgical waste found on the island; what conclusions can be drawn regarding the ironworking techniques, production scope, and chronology; and how favourable was the studied area for early iron production?
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-
Arnoldussen, S. & N.Ø. Brusgaard. 2015. Production in deposition: structured deposition of Iron Age ironworking elements (The Netherlands). Lunula. Archaeologia protohistorica XXIII. 115–124.
-
Becker, F., R.A. Eser, P. Hoelzmann & B. Schütt. 2019. The environmental impact of ancient iron mining and smelting on Elba Island, Italy – A geochemical soil survey of the Magazzini site. Journal of Geochemical Exploration 205. 1–18.
-
Bebermeier, W., M. Brumlich, V. Cordani, H. Eilbracht, J. Klinger, E. Lehnhardt, M. Meyer, S.G. Schmid, B. Schütt, M. Thelemann & M. Wemhoff. 2016. The Coming of Iron in a Comparative Perspective. Journal for Ancient Studies 6. 152–189.
-
Bielenin, K. & I. Suliga. 2008. The ancient slag-pit furnace and the reduction process in the light of a new archaeological concept and metallurgical research. Metallurgy and Foundry Engineering 34, 1. 53–78.
-
Birch, T., R. Scholger, G. Walach, F. Stremke & B. Cech. 2015. Finding the invisible smelt: using experimental archaeology to critically evaluate fieldwork methods applied to bloomery iron production remains. Archaeological and Anthropological Sciences 7. 73–87.
-
Clark, A. 1990. Seeing Beneath the Soil: Prospecting Methods in Archaeology. New York (Routledge).
-
Crew, P. 1991. The experimental production of prehistoric bar iron. Historical Metallurgy 25, 1. 21–36.
-
Dearing, J. 1994. Environmental magnetic susceptibility: using the Bartington system. London (Bartington Instruments).
-
Dungworth, D.B. 2011. The metalworking debris. Nowakowski & Quninnell 2011. 220–244.
-
Dungworth, D.B. 2015. Archaeometallurgy: guidelines for best practice. Historic England.
-
Endzinas, A. 1964. Geležies gamybos raidos ir geografijos Lietuvoje klausimu. Geodezijos darbai 2. 176–205.
-
Georgakopoulou, M. 2014. Metallurgical remains from regional surveys of ‘non-industrial’ landscapes: The case of the Kythera Island Project. Journal of Field Archaeology 39, 1. 67–83.
-
Grandin, L. & E. Hjärthner-Holdar. 2003. Early Iron production in the Red Earth Area, South Central Sweden. Nordbach 2003. 33–36.
-
Grižas, G. 2006. Pašekščių pilkapynas. Archeologiniai tyrinėjimai Lietuvoje 2005 metais. 88–89.
-
Iles, L. 2019. Exploring the impact of iron production on forest and woodland resources: estimating fuel consumption from slag. STAR: science & technology of archaeological research 5, 2. 179–199.
-
Hauptmann, A. 2020. Archaeometallurgy – Materials Science Aspects. Cham (Springer).
-
Hjärthner-Holdar, E., L. Grandin, K. Sköld & A. Svensson. 2018. By Who, for Whom? Landscape, Process and Economy in the Bloomery Iron Production AD 400–1000. Journal of Archaeology and Ancient history 21. 1–50.
-
LaNiece, S., D. Hook & P. Craddock (eds.). 2007. Metals and Mines: Studies in Archaeometallurgy. London (Archetype).
-
Luchtanas, A. 1992. Rytų Lietuva I tūkst. pr. m. erą. Lietuvos Archaeologija 8. 56–85.
-
Malinauskas, Z. & A. Linčius. 1999. Pelkių (limonitinė) geležies rūda Lietuvoje. Lietuvos Archaeologija 18. 111–120.
-
Masiulienė, I. 2018. Žardės-Laistų-Bandužių archeologinis kompleksas: ūkinės-gamybinės veiklos aspektai. The Žardė-Laistai-Bandužiai archaeological complex: aspects of economic-production activity. Klaipėdos (Memel) kraštas: nuo ištakų iki XVII amžiaus. Klaipėda (Memel) region: from origins to the 17th century. Klaipėda (Mažosios Lietuvos istorijos muziejus). 255–268.
-
Mihok, L. & A. Pribulová. 2003. Metallurgy of Iron at the Beginning of the 1st Millenium AD in Slovakia. Nordbach 2003. 163–170.
-
Navasaitis, J. 2003. Lietuviška geležis. Kaunas (Technologija).
-
Navasaitis, J., A. Sveikauskaitė, A. Selskis & E. Matulionis. 2003. Ironmaking Techniques During the Roman Period in Lithuania. Nordbach 2003. 87–96.
-
Navasaitis, J. & A. Selskienė. 2007. Iron smelting techniques in the Virbaliūnai ancient settlement. Archaeologica Baltica 8. 387–394.
-
Nordbach, L. Ch. (ed.). 2003. Prehistoric and Medieval direct iron smelting in Scandinavia and Europe: aspects of technology and society. Proceedings of the Sandbjerg conference, 16th to 20th September 1999. Arhus. Aarhus (Aarhus University Press).
-
Nowakowski, J.A. & H. Quninnell (eds.). 2011. Trevelgue Head, Cornwall: the importance of C K Croft Andrew’s 1939 excavations for prehistoric and Roman Cornwall. Truro (Cornwall County Council).
-
Paynter, S. 2007. Innovations in bloomery smelting in Iron Age and Romano-British England. LaNiece et al. 2007. 202–210.
-
Peets, J. 2003. The power of iron: iron production and blacksmithy in Estonia and neighbouring areas in prehistoric period and the Middle Ages. Tallinn (Institute of History).
-
Pleiner, R. 2000. Iron in Archaeology: The European Bloomery Smelters. Praha (Archeologickẏ ustav AVCR).
-
Podėnas, V. 2016. Alnio, Aiseto ir Galuonio ežerų salų žvalgomieji tyrimai. Archeologiniai tyrinėjimai 2015 metais. 65–71.
-
Rundberget, B., A. Vasks, I.M. Gundersen, R. Brūzis, J.H. Larsen, V. Bebre, I. Doniņa & A. Vīksna. 2018. Bloomery ironmaking in Latvia: a comparative study of Iron Age and medieval technologies. Historical Metallurgy 52, 2. 96–109.
-
Salatkienė, B. 2008. Iron metallurgy in Lithuania. An analysis of archaeological finds (Part 1). Archaeologica Baltica 9. 61–76.
-
Salatkienė, B. 2009. Geležies metalurgija Lietuvoje. Archeologijos duomenys. Šiauliai (Šiaulių universiteto leidykla).
-
Selskienė, A. 2007. Paplienijos piliakalnio papėdės gyvenvietės geležies metalurginio šlako tyrimai. Lietuvos archeologija 32. 51–70.
-
Simniškytė, A. & V. Podėnas. 2016. Aiseto ežero salos žvalgomieji tyrimai. Archeologiniai tyrinėjimai 2015 metais. 411–415.
-
Smith, P.K. 2004. Iron production in Viking age and Early Medieval Iceland. De Re Metallica: The Uses of Metal in the Middle Ages. AVISTA Studies in the History of Medieval Technology, Science and Art 4. 183–206.
-
Spazier, I. 2003. The Germanic Iron-Smelting Complex at Wolkenberg in Lower Lausacia, Southern Brandenburg. Nordbach 2003. 37–42.
-
Stenvik, L.F. 2003. Recent Results from Investigations of Iron Production in Northern Europe. Nordbach 2003. 77–82.
-
Thelemann, M., E. Lehnhardt, W. Bebermeier & M. Meyer. 2015. Iron, Humans and Landscape – Insights from a Micro-Region in the Widawa Catchment Area, Silesia. Journal of Ancient Studies 4. 109–138.
-
Thelemann, M., W. Bebermeier, P. Hoelzmann & E. Lehnhardt. 2017. Bog iron ore as a resource for prehistoric iron production in Central Europe – A case study of the Widawa catchment area in eastern Silesia, Poland. Catena 149, 1. 474–490.
-
Tvauri, A. 2012. The Migration Period, Pre-Viking Age, and Viking Age in Estonia. Estonian archaeology 4. Tartu (Tartu University Press).
-
Tylecote, R.F. 1987. The early history of metallurgy in Europe. London & New York (Longman).
-
Vodyasov, E. 2018. Ethnoarchaeological research on indigenous iron smelting in Siberia. Сибирские исторические исследования 2. 164–180.
-
Volungevičius, J. & P. Kavaliauskas. 2009. Lietuvos pedologinio rajonavimo problema. Žemės ūkio mokslai 16, 1–2. 1–13.
-
Žalnierius, A., J. Navasaitis & D. Balčiūnas. 2007. The Iron Smelting Site in Virbaliūnai Ancient Settlement. Archaeologia Baltica 8. 377–386.
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Prehistoric Iron Bloomery Debris on a Small Island in Lake Aisetas (Eastern Lithuania)
In: Acta ArchaeologicaSearch for other papers by Andra Simniškytė in
Current site
Google Scholar
PubMed
Search for other papers by Aušra Selskienė in
Current site
Google Scholar
PubMed
Abstract
The archaeological discoveries of metallurgical waste in Lithuania have established that metallurgical activities were commonly connected to settlements. However, recent investigations suggest that even in the case of small-scale production on a homestead industry level, small isolated smelting bloomeries could have existed outside settlements.
The work presented in this article introduces the material acquired from the newly discovered prehistoric site on a small island in Lake Aisetas in Eastern Lithuania. The data was acquired through surface and soil sampling surveys, magnetic susceptibility measurements, and small-scale excavations. Metallurgical waste weighing 150 kg was collected without additional evidence to facilitate archaeological interpretation of the finds and their origins.
This article aims to characterise the metallurgical waste and deduce the nature of the activity and processes that produced these by-products on the island. Through an exploration of recovery circumstances and a macroscopic examination as well as composition and microstructure analysis of the metallurgical waste, this study intends to answer the following questions: what constitutes the metallurgical waste found on the island; what conclusions can be drawn regarding the ironworking techniques, production scope, and chronology; and how favourable was the studied area for early iron production?
| All Time | Past 365 days | Past 30 Days | |
|---|---|---|---|
| Abstract Views | 374 | 134 | 14 |
| Full Text Views | 57 | 2 | 0 |
| PDF Views & Downloads | 117 | 6 | 0 |
