Archaeometallurgical study has many uses in both the chemical and anthropological fields. Analysis contributes valuable insights into many archaeological questions, from technological choice to social organisation. Any project concerned with the relationship that the human species has had to the metals known to us is an example of archaeometallurgical study.
There are various methodological approaches to archaeometallurgical studies. The same methods used in analytical chemistry may be used to analyze artifacts. Chemical analysis methods may include the analysis of mass, densityorchemical composition. Most methods are non-destructive in nature, such as X-ray spectroscopy, or micro-destructive (requiring removal of only a tiny portion of the sample). Non-destructive methods can be used on more artefacts than destructive ones, but because they operate at the surface of the metal, corrosion and other surface effects may interfere with the results. Options that include sampling include various forms of mass spectrometry and a variety of chemical tests.
One of the methods of archaeometallurgy is the study of modern metals and alloys to explain and understand the use of metals in the past. A study conducted by the department of Particle Physics and Astrophysics at Weizmann Institute of Science and the department of Archaeology at the University of Haifia analyzed the chemical composition and the mass of different denominations of Euro coinage. They concluded that even with modern standards and technology, there is a considerable variation within the "same" denomination of coin.[1] This simple conclusion can be used to further analyze discoveries of ancient currency.
The specific study of the non-ferrous metals used in past. Gold, silver and copper were the first to be used by ancient humans. Gold and copper are both found in their 'native' state in nature, and were thus the first to be exploited as they did not need to be smelted from their ores. They could be hammered into sheets or decorative shapes. The extraction of copper from its ores may have developed due to the attractive colouring and value of ores such as malachite.
The specific study of the ferrous compounds (those including iron, Fe) used in the past. Iron metal was first encountered in meteorites, and was later extracted from iron ores to create wrought iron which was never fully molten, and later, cast iron. Iron combined with carbon formed steel, allowing people to develop superior tools and weapons from the Iron Age to the industrial revolution.
After initial sporadic work, archaeometallurgy was more widely institutionalised in the 1960s and 70s, with research groups in Britain (The British Museum, the UCL Institute of Archaeology, the Institute for Archeo-Metallurgical Studies (iams)), Germany (Deutsches Bergbau Museum) and the US (MIT and Harvard).
Specialisations within metallurgical focus on metallography of finished objects, mineralogy of waste products such as slag and manufacturing studies.
Bayley, Justine; Crossley, David; Ponting, Matthew, eds. (2008). Archaeometallurgy in Global Perspective: Methods and Syntheses. London: The Historical Metallurgy Society, Occasional Publication No 6. ISBN978-0-9560225-0-9.
Hauptmann, Andreas (2020). Archaeometallurgy–Materials Science Aspects. Cham, Switzerland: Springer. ISBN978-3-030-50366-6.
Hauptmann, Andreas (2007). The Archaeometallurgy of Copper: Evidence from Faynan, Jordan. Heidelberg: Springer. ISBN978-3-540-72237-3.
Hošek, Jiří; Cleere, Henry; Mihok, L'ubomír, eds. (2011). The Archaeometallurgy of Iron: Recent Developments in Archaeological and Scientific Research. Prague: Academy of Sciences of the Czech Republic, Institute of Archaeology. ISBN978-80-87365-41-0.
S. Kalyanaraman (2011) "Indian Hieroglyphs", Sarasvati Research Center, Herndon, VA
Roberts, Benjamin W.; Thornton, Christopher P., eds. (2014). Archaeometallurgy in Global Perspective:Methods and Syntheses. New York: Springer. ISBN978-1-4614-9016-6.
