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Metallurgy during the Copper Age in Europe

April 12, 2024

The Copper Age, also called the Eneolithic or the Chalcolithic Age, has been traditionally understood as a transitional period between the Neolithic and the Bronze Age, in which a gradual introduction of the metal (native copper) took place, while stone was still the main resource utilized. Recent archaeology has found that the metal was not introduced so gradually and that this entailed significant social changes, such as developments in the type of habitation (larger villages, launching of fortifications), long-distance trade, and copper metallurgy.

Reconstruction of Ötzi's copper axe (c. 3300 BCE)

Some of the earliest Copper Age artifacts were found in the 5th and 6th millennia BCE archaeological sites of the Vinča culture such as Majdanpek, Jarmovac and Pločnik (including a copper axe from 5500 BCE). Somewhat later, in the 5th millennium BCE, metalwork is attested at Rudna Glava mine in Serbia, and at Ai Bunar mine in Bulgaria.[1]

3rd millennium BCE copper metalwork is attested in places like Palmela (Portugal), Cortes (Navarre), and Stonehenge (England). However, as often happens with the prehistoric times, the limits of the age cannot be clearly defined and vary between different sources.

Inception of metallurgy in Europe edit

The theory that metallurgy was imported into Europe from the Near East has been practically ruled out. A second hypothesis, that there were two main points of origin of metallurgy in Europe, in southern Spain and in West Bulgaria, is also doubtful due to the existence of sites outside the centers of diffusion where metallurgy was known simultaneously with, or before, those in the ‘original’ nuclei, such as Brixlegg (Tyrol, Austria), while sites closer to the supposed origins of metallurgy, such as in the north of Spain, show fewer metal artifacts than sites in the south and practically no evidence of production.[2]

Currently, the general opinion is that the development of metallurgy took place independently in different places, at different times, with various techniques. One fact that supports this interpretation is that, although the final products (beads, rings, sickles, swords, axes, etc.) are quite similar throughout Europe, the method of production is not. Thus the use of crucibles was the technique utilized in the south of Spain, whereas central Europe employed a slagging process, but Cabrierés (France) used a primitive oxidizing non-slagging process,[3] while in the British Isles the absence of debris, slag or ceramic suggests another technique.[4]

Consequently, the way in which metallurgy was initiated differs considerably depending on the region. There are areas in which copper seems to play a crucial role (i.e., the Balkans), whereas other areas show no interest in it at all. Then there are societies that use copper artifacts, but do not practice metallurgy,[5] and there are other ones that fully adopt some of the cultural innovations but ignore the rest.[who?] One example of the latter is Basque country in northern Spain, where splendid large dolmens are present along the Ebro river, but metal is rather infrequent, and when it does appear between the trapping, it is more often bronze or arsenical copper than copper.[6] According to radiocarbon dating, the Pre-Bell Beaker Chalcolithic with copper metallurgy began on the Iberian Peninsula in the last third of the IV millennium cal. BC, in the Northern Iberian Plateau in 3000 cal. BC and the Bell Beaker Chalcolithic appeared around 2500 cal. BC.[7][8][9]

Reasons to use copper edit

Copper is the eighth most abundant metal in the Earth's crust, is available all over the world, and is one of the few that can appear in a pure state.[10] It is not complicated to work with, and a bare hammering can be enough to transform a nugget into a bead. The eye-catching look of native copper makes it easy to recognize, and even flashier if converted into jewelry, a possible motivation for humankind to start metallurgy with it. An evolutive technological process has been described,[11] although there are authors like Javinovic,[12] who think that it is not necessary to pass through the first stages to reach the last one.

Converting copper edit

 
Sample of native copper.

To start with, the raw material must be obtained. Copper can be found in over 160 different minerals,[10] but mining activities are entailed to obtain them in large quantities if a reasonable amount of copper is wanted. Some of the most commonly exploited minerals are cuprite, malachite, azurite, chalcopyrite, chrysocolla and tennantite; e.g. malachite was extracted in Rudna Glava (Serbia), Cabrierés (France) or Chinflón (Riotinto, Spain). In fact, one of the possible explanations about what Ötzi the Iceman, the ancient mummy found in the Alps who lived around 3300 years BCE, was doing at 3,210 metres (10,530 ft) of altitude is that he could have been prospecting for new ores of minerals.[13]

Secondly, the mineral is separated from the gangue. This is only possible by smelting or beneficiation. To do so, it is necessary to use a furnace that is able to reach at least 1,089 °C (1,992 °F).

Lastly, a wide range of specific tools and resources have to be available, such as furnaces, moulds, crucibles, mauls, etc.

  • Stage A: Although native copper nowadays is frequently displayed in museum showcases of mineral collections, it once occurred copiously during prehistoric times. In Cyprus or Crete, collecting the mineral was once as easy as simply picking it up from the ground. In fact, native copper is no longer as easy to find in that state these days. The treatment of this native mineral was also uncomplicated through cold-hammering. This only permitted the production of a limited range of artifacts like awls, pins, or beads. In larger objects, the metal cracks when it is cold-hammered.
  • Stage B: Annealing the metal on an open fire (200–300 °C or 390–570 °F is hot enough) reduces its hardness considerably and gives in malleability. This permits the manufacture of slightly more sophisticated objects, like bracelets, but is still a rather limited technique.
  • Stage C: In the first two steps, the material used was native copper that does not actually need specialized technology. Probably, due to the situation that native copper was increasingly difficult to find, copper ore is used in this third step. This is a very significant development. In fact, this is truly the beginning of the metallurgy, as the mineral has to be smelted to separate the copper from the gangue, requiring technology.

Early mining in Europe edit

 
Polished chrysocolla.

Minerals of copper were known from ancient times. In Crete, little fragments of malachite and azurite were powdered and used as make up or to decorate ceramic as early as 6000 BCE.[5]

Therefore, the minerals were not collected because people were looking for copper but for virtues like those mentioned or simply because of its brightness and colour, but this knowledge of the minerals is critical since they already knew how to recognize them and where to collect them when, later, they started the systematic search for ores.

Numerous examples of mines are known all over Europe,[14] from the east: Rudna Glava (Serbia), Ai Bunar (Bulgaria); to the west: Mount Gabriel (Ireland), Great Orme, Alderley Edge (United Kingdom); crossing Central Europe: Mitterberg (Salzach, Austria), Neuchâtel (Switzerland), Cabrierés (France); to the south: Riotinto, Mola Alta de Serelles (Spain); and the Mediterranean: Corsica, Cyprus, and the Cyclades islands. It is remarkable that, usually, it is not a single mine but a complex, with a variable, large number of mineshafts, as in Rudna Glava (30) or Mount Gabriel (31).

Techniques and tools edit

The techniques observed in all of them are quite similar. Basically they used the thermic alteration or firesetting (Mohen 1992, Craddock 1995, Eiroa et al. 1996, Timberlake 2003). This consists of applying fire to the rock and then pouring water over it: the rapid changes of temperature will cause cracks within the rocks that can be totally broken with the help of mauls and picks. Then the useful masses were selected, crushed and transported to the production centre that could be in the surrounding area (Mitterberg) or far away (Rudna Glava).

The mines were exploited in extremely efficient and clever ways, according to the technology available (Jovanovic 1980, Craddock 1995, Timberlake 2003). The entire convenient mineral was collected and the abandoned shafts carefully refilled with gangue and rocks (Mohen 1992; 85). For example, at Mount Gabriel, it was estimated that they extracted the astonishing number of 32,570.15 tonnes (35,902.44 tons) of rock, gangue and ore. The usable amount of copper was 162.85 tonnes and the final smelting finished metal was 146.56 tonnes (Jackson 1980; 24). The entire process was thoroughly described in 1744 by Lewis Morris, Crown Mineral Agent for Cardiganshire, and, incidentally, antiquarian.[15]

Their method seems to be this. They make a great fire of wood in the bottom of their rakes which were always open up on that account, and when the rock was sufficiently hot they cast water upon it, which shiver’d it; and then with stone wedges, which they drove in with other stones, they work’d their way through the hardest rocks, tho’ but slowly.

The tools employed are mainly presented in Lewis' observations, but other ones have been recovered in archaeological context:

  • Stone tools: The most frequent find are the stone hammers, normally made of hard rocks accessible to the mine, beach or river pebbles.[16] There is no standardization of these mauls but is common a system of hafting, usually a groove carved in the middle for where a rope was tied to the handle, like the twisted hazel recovered in Copa Hill.[17]
  • Antler and bone tools: Picks and scrapes made of bone and antlers have been found in the majority of the mines.[18]
  • Wood: Evidence of wooden tools are more infrequent. Nevertheless in places like Ai Bunar or Mount Gabriel were recovered shovels and wedges. A rudimentary system of stairs or scaffoldings can be supposed (Mohen 1992).
  • Metal: The use of any metallic tool is rather strange and extraordinary. It seems that the copper was not used for the miners' tools. However copper chisels and discarded axes could be utilized as wedges.[19]
  • Other evidence: The presence of coal and charcoal, crucial for the firing (fire-setting) and furnace (fuel), is habitual. Leather sacks (at Ai Bunar) and shoulder baskets (at Copa Hill) were used to transport the crushed mineral.

Society edit

 
Elite male tomb, Varna culture (Bulgaria), 4500 BCE

The information available about the people of the Copper Age has not substantially increased along with the number of archaeological sites. Several ideas have been proffered, one of the most followed is that the metal itself did not bring abrupt transformation into the people's life,[20] or even more that early copper does not produce anything useful at all,[21] meaning with this that with the copper, they produced mainly jewellery and, overall, weapons that obviously were not within reach of the majority of the population but only to privileged individuals. In other words, the real importance of the metal is not utilitarian but social. This is a suitable explanation about the rising of Great Cultures of Metal such as Vinča culture (Ex-Yugoslavia) Tiszapolgar and Unetice culture (Central Europe), Remedello and Rinaldone (Italy), Montagne Noire (France), El Argar and Targas (Spain), etc.

As the period moved forward, especially around the 3rd millennium, new and complex realities would appear strongly linked to the metal, like the impressive fortified villages of Los Millares (Spain), Vila Nova de Sao Pedro (Portugal) or the more modest cairn next to Copa Hill in the United Kingdom destinated to control the centres of extraction, or the equally and generalized cultural phenomenons of Megalithism, Rock Art, Bell Beakers Vessels that are known from Scandinavia to the South of Spain and from Scotland to Turkey.

See also edit

Notes edit

  1. ^ Radivojević, Miljana; Roberts, Benjamin W. (2021). "Early Balkan Metallurgy: Origins, Evolution and Society, 6200–3700 BC". Journal of World Prehistory (34). Retrieved 11 June 2022.
  2. ^ Pérez Arrondo 1987, pp. 159–180.
  3. ^ Bourgarit et al. 2003, p. 431–440.
  4. ^ Craddock 1995, pp. 23–31.
  5. ^ a b Mohen 1992, p. [page needed].
  6. ^ Almuzara 1984, pp. 51–156.
  7. ^ Marcos Saiz (2006), pp. 225–270.
  8. ^ Marcos Saiz (2016), pp. 686–696.
  9. ^ Marcos Saiz & Díez (2017), pp. 45–67.
  10. ^ a b Atkinson 1987, p. 3.
  11. ^ Coghlan 1975, pp. 162–165.
  12. ^ Mohen 1992, p. 52.
  13. ^ Peroni 1996, p. 336.
  14. ^ Bartelheim et al. 2002, pp. 33–82.
  15. ^ Timberlake 2003, p. 22.
  16. ^ Jovanovic 1980, p. [page needed].
  17. ^ Timberlake 2003, p. 32-33.
  18. ^ Craddock 1995, p. [page needed].
  19. ^ Craddock 1995, p. 97.
  20. ^ Cunliffe 1998, p. 170.
  21. ^ Renfrew 1986, p. 146.

References edit

  • Atkinson, R. Lesley (1987). Copper and copper mining. Princes Risborough: Shire. ISBN 0-85263-895-7.
  • Almuzara, Ana Cava (1984). "La industria lítica en los dólmenes del País Vasco meridional" [The lithic industry in the dolmens of the southern Basque Country]. Veleia: Revista de prehistoria, historia antigua, arqueología y filología clásicas (in Spanish). No. 1. ISSN 0213-2095.
  • Bourgarit, David; Mille, Benoît; Ambert, Paul; Prange, M.; Hauptmann, Andreas (2003). Chalcolithic Fahlore Smelting at Cabrières:Reconstruction of Smelting Processes by Archaeometallurgical Finds. Archaeometallurgy in Europe : International Conference : 24-25-26 September 2003, Milan, Italy : proceedings (pdf) (2nd ed.). Milano: Associazione Italiana di Metallurgia. ISBN 88-85298-50-8.
  • Bartelheim, Martin; Eckstein, K.; Huijsmans, M.; Krauß, R.; Pernicka, Ernst (2002). Kupferzeitliche Metallgewinnung in Brixlegg, Österreich [Chalcolithic Metal Extraction in Brixlegg, Austria]. Archaeometallurgy in Europe : International Conference : 24-25-26 September 2003, Milan, Italy : proceedings (pdf) (in German). Vol. 1. Milano: Associacione Italiana di Metallurgia.
  • Coghlan, Herbert Henery (1975). Notes on the Prehistoric Metallurgy of Copper and Bronze in the Old World, Including an examination of specimens from the Pitt Rivers Museum and bronze casting in ancient moulds by E. Voce and contributions by P.R.S. Moorey and T.K. Penniman. Vol. 26 (2nd ed.). Oxford: Pitt Rivers Museum, University of Oxford. doi:10.1017/S0003598X00023942. ISBN 0-902793-12-8. ISSN 0003-598X.
  • Cvekic, Ljilja (2007) Prehistoric women had passion for fashion.
  • Craddock, P.T. (1986). "Bronze Age Metallurgy in Britain". Current Anthropology. 9 (4): 106–109.
  • Craddock, Paul T. (1995). Early metal mining and production. Edinburgh: Edinburgh University Press. ISBN 0-7486-0498-7.
  • Cunliffe, Barry W. (1998). Prehistoric Europe : Prehistoric Europe: An Illustrated History. Oxford: Oxford University Press. ISBN 0-19-288063-2.
  • Eiroa, J.J. et alii (1999): Nociones de tecnología y tipología en Prehistoria. Barcelona. Ariel.
  • Jackson, J.S. (1980). "Bronze Age copper mining in Counties Cork and Kerry, Ireland". In Craddock, P.T. (ed.). Scientific studies in early mining and extractive metallurgy. London: British Museum. pp. 9–30.
  • Jovanovic, B. (1980). "Primary copper mining and the production of copper". In Craddock, P.T. (ed.). Scientific studies in early mining and extractive metallurgy. London: British Museum. pp. 31–40.
  • Marcos Saiz, F. Javier (2006). La Sierra de Atapuerca y el Valle del Arlanzón. Patrones de asentamiento prehistóricos. Editorial Dossoles. Burgos, Spain. ISBN 9788496606289.
  • Marcos Saiz, F. Javier (2016). La Prehistoria Reciente del entorno de la Sierra de Atapuerca (Burgos, España). British Archaeological Reports (Oxford, U.K.), BAR International Series 2798. ISBN 9781407315195.
  • Marcos Saiz, F.J.; Díez, J.C. (2017). "The Holocene archaeological research around Sierra de Atapuerca (Burgos, Spain) and its projection in a GIS geospatial database". Quaternary International. 433 (A): 45–67. Bibcode:2017QuInt.433...45M. doi:10.1016/j.quaint.2015.10.002.
  • Mohen, Jean-Pierre (1992). Metalurgia prehistórica : introducción a la paleometalurgia [Prehistoric metallurgy: introduction to paleometallurgy] ([1a. ed.] ed.). Barcelona: Masson. ISBN 84-311-0605-0.
  • Mohen J.P, Peroni, R, Katinchorov R. and Tasié R, Eccedy I. and Kovacs T, Merpert J.M, Briard J., Thrane H., Kaelas L. (1996) Europe in the Copper Age, in History of humanity: scientific and cultural development Vol.2, From the third millennium to the seventh century BC, edited by Dani A.H., J.-P. Mohen. London: Routledge; Paris: UNESCO, pages 320-391.
  • Moreno A, et al. (2003) Metallurgical control and social power. The Bronze Age Communities of High Guadalquivir in Archeometallurgy in Europe (International Conference) vol. 1 Milano: Associacione Italiana di Metallurgia, pages 625-634.
  • Ortiz T., L. et al. (1990): El hábitat en la Prehistoria en el valle del Río Rojo (Álava) "Cuaderno de Sección Prehistoria-Arqueología", núm. 3, San Sebastián.
  • Pérez Arrondo, Carlos Lázar (1987). El fenómeno megalítico en la margen derecha del Ebro [The megalithic phenomenon on the right bank of the Ebro] (1. ed.). Madrid: Ministerio de Cultura, Dirección General de Bellas Artes y Archivos, Subdirección General de Arqueología y Etnología. ISBN 84-505-6553-7.
  • Peroni, Renato (1996). L'Italia alle soglie della storia [Italy on the threshold of history] (in Italian) (1.] ed.). Rome: Laterza. ISBN 88-420-5018-0.
  • Renfrew, C. (1986). "Varna and the emergence of wealth in prehistoric Europe". In Appaduri, Anjuin (ed.). The social life of things. Cambridge University Press.
  • Ruiz-Taboada, A. & Montero-Ruiz, I., "The oldest metallurgy in western Europe" in Antiquity by Crawford, Osbert Guy Stanhope, 73(282), Princeton University Press for the Research Institute on International Change, Columbia University, 1999, pages 897-903.
  • Shennan, S., "Cost, benefit and value in the organization of early European copper production" in Antiquity by Crawford, Osbert Guy Stanhope, 73(280), Princeton University Press for the Research Institute on International Change, Columbia University, 1999, pages 352-363.
  • Tasić, Nikola (1995). Eneolithic cultures of central and west Balkans. Belgrade: Draganić. ISBN 86-441-0117-X.
  • Timberlake, Simon (2003). "Early mining research in Britain: The Developments of the Last Ten Years". In Craddock, P. T; Lang, Janet (eds.). Mining and metal production through the ages. British Museum. pp. 22–42.

April 12, 2024
metallurgy, during, copper, europe, copper, also, called, eneolithic, chalcolithic, been, traditionally, understood, transitional, period, between, neolithic, bronze, which, gradual, introduction, metal, native, copper, took, place, while, stone, still, main, . The Copper Age also called the Eneolithic or the Chalcolithic Age has been traditionally understood as a transitional period between the Neolithic and the Bronze Age in which a gradual introduction of the metal native copper took place while stone was still the main resource utilized Recent archaeology has found that the metal was not introduced so gradually and that this entailed significant social changes such as developments in the type of habitation larger villages launching of fortifications long distance trade and copper metallurgy Reconstruction of Otzi s copper axe c 3300 BCE Some of the earliest Copper Age artifacts were found in the 5th and 6th millennia BCE archaeological sites of the Vinca culture such as Majdanpek Jarmovac and Plocnik including a copper axe from 5500 BCE Somewhat later in the 5th millennium BCE metalwork is attested at Rudna Glava mine in Serbia and at Ai Bunar mine in Bulgaria 1 3rd millennium BCE copper metalwork is attested in places like Palmela Portugal Cortes Navarre and Stonehenge England However as often happens with the prehistoric times the limits of the age cannot be clearly defined and vary between different sources Contents 1 Inception of metallurgy in Europe 2 Reasons to use copper 2 1 Converting copper 3 Early mining in Europe 4 Techniques and tools 5 Society 6 See also 7 Notes 8 ReferencesInception of metallurgy in Europe editThe theory that metallurgy was imported into Europe from the Near East has been practically ruled out A second hypothesis that there were two main points of origin of metallurgy in Europe in southern Spain and in West Bulgaria is also doubtful due to the existence of sites outside the centers of diffusion where metallurgy was known simultaneously with or before those in the original nuclei such as Brixlegg Tyrol Austria while sites closer to the supposed origins of metallurgy such as in the north of Spain show fewer metal artifacts than sites in the south and practically no evidence of production 2 Currently the general opinion is that the development of metallurgy took place independently in different places at different times with various techniques One fact that supports this interpretation is that although the final products beads rings sickles swords axes etc are quite similar throughout Europe the method of production is not Thus the use of crucibles was the technique utilized in the south of Spain whereas central Europe employed a slagging process but Cabrieres France used a primitive oxidizing non slagging process 3 while in the British Isles the absence of debris slag or ceramic suggests another technique 4 Consequently the way in which metallurgy was initiated differs considerably depending on the region There are areas in which copper seems to play a crucial role i e the Balkans whereas other areas show no interest in it at all Then there are societies that use copper artifacts but do not practice metallurgy 5 and there are other ones that fully adopt some of the cultural innovations but ignore the rest who One example of the latter is Basque country in northern Spain where splendid large dolmens are present along the Ebro river but metal is rather infrequent and when it does appear between the trapping it is more often bronze or arsenical copper than copper 6 According to radiocarbon dating the Pre Bell Beaker Chalcolithic with copper metallurgy began on the Iberian Peninsula in the last third of the IV millennium cal BC in the Northern Iberian Plateau in 3000 cal BC and the Bell Beaker Chalcolithic appeared around 2500 cal BC 7 8 9 Reasons to use copper editCopper is the eighth most abundant metal in the Earth s crust is available all over the world and is one of the few that can appear in a pure state 10 It is not complicated to work with and a bare hammering can be enough to transform a nugget into a bead The eye catching look of native copper makes it easy to recognize and even flashier if converted into jewelry a possible motivation for humankind to start metallurgy with it An evolutive technological process has been described 11 although there are authors like Javinovic 12 who think that it is not necessary to pass through the first stages to reach the last one Converting copper edit nbsp Sample of native copper To start with the raw material must be obtained Copper can be found in over 160 different minerals 10 but mining activities are entailed to obtain them in large quantities if a reasonable amount of copper is wanted Some of the most commonly exploited minerals are cuprite malachite azurite chalcopyrite chrysocolla and tennantite e g malachite was extracted in Rudna Glava Serbia Cabrieres France or Chinflon Riotinto Spain In fact one of the possible explanations about what Otzi the Iceman the ancient mummy found in the Alps who lived around 3300 years BCE was doing at 3 210 metres 10 530 ft of altitude is that he could have been prospecting for new ores of minerals 13 Secondly the mineral is separated from the gangue This is only possible by smelting or beneficiation To do so it is necessary to use a furnace that is able to reach at least 1 089 C 1 992 F Lastly a wide range of specific tools and resources have to be available such as furnaces moulds crucibles mauls etc Stage A Although native copper nowadays is frequently displayed in museum showcases of mineral collections it once occurred copiously during prehistoric times In Cyprus or Crete collecting the mineral was once as easy as simply picking it up from the ground In fact native copper is no longer as easy to find in that state these days The treatment of this native mineral was also uncomplicated through cold hammering This only permitted the production of a limited range of artifacts like awls pins or beads In larger objects the metal cracks when it is cold hammered Stage B Annealing the metal on an open fire 200 300 C or 390 570 F is hot enough reduces its hardness considerably and gives in malleability This permits the manufacture of slightly more sophisticated objects like bracelets but is still a rather limited technique Stage C In the first two steps the material used was native copper that does not actually need specialized technology Probably due to the situation that native copper was increasingly difficult to find copper ore is used in this third step This is a very significant development In fact this is truly the beginning of the metallurgy as the mineral has to be smelted to separate the copper from the gangue requiring technology Early mining in Europe edit nbsp Polished chrysocolla Minerals of copper were known from ancient times In Crete little fragments of malachite and azurite were powdered and used as make up or to decorate ceramic as early as 6000 BCE 5 Therefore the minerals were not collected because people were looking for copper but for virtues like those mentioned or simply because of its brightness and colour but this knowledge of the minerals is critical since they already knew how to recognize them and where to collect them when later they started the systematic search for ores Numerous examples of mines are known all over Europe 14 from the east Rudna Glava Serbia Ai Bunar Bulgaria to the west Mount Gabriel Ireland Great Orme Alderley Edge United Kingdom crossing Central Europe Mitterberg Salzach Austria Neuchatel Switzerland Cabrieres France to the south Riotinto Mola Alta de Serelles Spain and the Mediterranean Corsica Cyprus and the Cyclades islands It is remarkable that usually it is not a single mine but a complex with a variable large number of mineshafts as in Rudna Glava 30 or Mount Gabriel 31 Techniques and tools editThe techniques observed in all of them are quite similar Basically they used the thermic alteration or firesetting Mohen 1992 Craddock 1995 Eiroa et al 1996 Timberlake 2003 This consists of applying fire to the rock and then pouring water over it the rapid changes of temperature will cause cracks within the rocks that can be totally broken with the help of mauls and picks Then the useful masses were selected crushed and transported to the production centre that could be in the surrounding area Mitterberg or far away Rudna Glava The mines were exploited in extremely efficient and clever ways according to the technology available Jovanovic 1980 Craddock 1995 Timberlake 2003 The entire convenient mineral was collected and the abandoned shafts carefully refilled with gangue and rocks Mohen 1992 85 For example at Mount Gabriel it was estimated that they extracted the astonishing number of 32 570 15 tonnes 35 902 44 tons of rock gangue and ore The usable amount of copper was 162 85 tonnes and the final smelting finished metal was 146 56 tonnes Jackson 1980 24 The entire process was thoroughly described in 1744 by Lewis Morris Crown Mineral Agent for Cardiganshire and incidentally antiquarian 15 Their method seems to be this They make a great fire of wood in the bottom of their rakes which were always open up on that account and when the rock was sufficiently hot they cast water upon it which shiver d it and then with stone wedges which they drove in with other stones they work d their way through the hardest rocks tho but slowly The tools employed are mainly presented in Lewis observations but other ones have been recovered in archaeological context Stone tools The most frequent find are the stone hammers normally made of hard rocks accessible to the mine beach or river pebbles 16 There is no standardization of these mauls but is common a system of hafting usually a groove carved in the middle for where a rope was tied to the handle like the twisted hazel recovered in Copa Hill 17 Antler and bone tools Picks and scrapes made of bone and antlers have been found in the majority of the mines 18 Wood Evidence of wooden tools are more infrequent Nevertheless in places like Ai Bunar or Mount Gabriel were recovered shovels and wedges A rudimentary system of stairs or scaffoldings can be supposed Mohen 1992 Metal The use of any metallic tool is rather strange and extraordinary It seems that the copper was not used for the miners tools However copper chisels and discarded axes could be utilized as wedges 19 Other evidence The presence of coal and charcoal crucial for the firing fire setting and furnace fuel is habitual Leather sacks at Ai Bunar and shoulder baskets at Copa Hill were used to transport the crushed mineral Society edit nbsp Elite male tomb Varna culture Bulgaria 4500 BCEThe information available about the people of the Copper Age has not substantially increased along with the number of archaeological sites Several ideas have been proffered one of the most followed is that the metal itself did not bring abrupt transformation into the people s life 20 or even more that early copper does not produce anything useful at all 21 meaning with this that with the copper they produced mainly jewellery and overall weapons that obviously were not within reach of the majority of the population but only to privileged individuals In other words the real importance of the metal is not utilitarian but social This is a suitable explanation about the rising of Great Cultures of Metal such as Vinca culture Ex Yugoslavia Tiszapolgar and Unetice culture Central Europe Remedello and Rinaldone Italy Montagne Noire France El Argar and Targas Spain etc As the period moved forward especially around the 3rd millennium new and complex realities would appear strongly linked to the metal like the impressive fortified villages of Los Millares Spain Vila Nova de Sao Pedro Portugal or the more modest cairn next to Copa Hill in the United Kingdom destinated to control the centres of extraction or the equally and generalized cultural phenomenons of Megalithism Rock Art Bell Beakers Vessels that are known from Scandinavia to the South of Spain and from Scotland to Turkey See also editCopper Copper Age Copper metallurgy in Africa Metallurgy Native copperNotes edit Radivojevic Miljana Roberts Benjamin W 2021 Early Balkan Metallurgy Origins Evolution and Society 6200 3700 BC Journal of World Prehistory 34 Retrieved 11 June 2022 Perez Arrondo 1987 pp 159 180 Bourgarit et al 2003 p 431 440 Craddock 1995 pp 23 31 a b Mohen 1992 p page needed Almuzara 1984 pp 51 156 Marcos Saiz 2006 pp 225 270 Marcos Saiz 2016 pp 686 696 Marcos Saiz amp Diez 2017 pp 45 67 a b Atkinson 1987 p 3 Coghlan 1975 pp 162 165 Mohen 1992 p 52 Peroni 1996 p 336 Bartelheim et al 2002 pp 33 82 Timberlake 2003 p 22 Jovanovic 1980 p page needed Timberlake 2003 p 32 33 Craddock 1995 p page needed Craddock 1995 p 97 Cunliffe 1998 p 170 Renfrew 1986 p 146 References editAtkinson R Lesley 1987 Copper and copper mining Princes Risborough Shire ISBN 0 85263 895 7 Almuzara Ana Cava 1984 La industria litica en los dolmenes del Pais Vasco meridional The lithic industry in the dolmens of the southern Basque Country Veleia Revista de prehistoria historia antigua arqueologia y filologia clasicas in Spanish No 1 ISSN 0213 2095 Bourgarit David Mille Benoit Ambert Paul Prange M Hauptmann Andreas 2003 Chalcolithic Fahlore Smelting at Cabrieres Reconstruction of Smelting Processes by Archaeometallurgical Finds Archaeometallurgy in Europe International Conference 24 25 26 September 2003 Milan Italy proceedings pdf 2nd ed Milano Associazione Italiana di Metallurgia ISBN 88 85298 50 8 Bartelheim Martin Eckstein K Huijsmans M Krauss R Pernicka Ernst 2002 Kupferzeitliche Metallgewinnung in Brixlegg Osterreich Chalcolithic Metal Extraction in Brixlegg Austria Archaeometallurgy in Europe International Conference 24 25 26 September 2003 Milan Italy proceedings pdf in German Vol 1 Milano Associacione Italiana di Metallurgia Coghlan Herbert Henery 1975 Notes on the Prehistoric Metallurgy of Copper and Bronze in the Old World Including an examination of specimens from the Pitt Rivers Museum and bronze casting in ancient moulds by E Voce and contributions by P R S Moorey and T K Penniman Vol 26 2nd ed Oxford Pitt Rivers Museum University of Oxford doi 10 1017 S0003598X00023942 ISBN 0 902793 12 8 ISSN 0003 598X Cvekic Ljilja 2007 Prehistoric women had passion for fashion 1 Craddock P T 1986 Bronze Age Metallurgy in Britain Current Anthropology 9 4 106 109 Craddock Paul T 1995 Early metal mining and production Edinburgh Edinburgh University Press ISBN 0 7486 0498 7 Cunliffe Barry W 1998 Prehistoric Europe Prehistoric Europe An Illustrated History Oxford Oxford University Press ISBN 0 19 288063 2 Eiroa J J et alii 1999 Nociones de tecnologia y tipologia en Prehistoria Barcelona Ariel Jackson J S 1980 Bronze Age copper mining in Counties Cork and Kerry Ireland In Craddock P T ed Scientific studies in early mining and extractive metallurgy London British Museum pp 9 30 Jovanovic B 1980 Primary copper mining and the production of copper In Craddock P T ed Scientific studies in early mining and extractive metallurgy London British Museum pp 31 40 Marcos Saiz F Javier 2006 La Sierra de Atapuerca y el Valle del Arlanzon Patrones de asentamiento prehistoricos Editorial Dossoles Burgos Spain ISBN 9788496606289 Marcos Saiz F Javier 2016 La Prehistoria Reciente del entorno de la Sierra de Atapuerca Burgos Espana British Archaeological Reports Oxford U K BAR International Series 2798 ISBN 9781407315195 Marcos Saiz F J Diez J C 2017 The Holocene archaeological research around Sierra de Atapuerca Burgos Spain and its projection in a GIS geospatial database Quaternary International 433 A 45 67 Bibcode 2017QuInt 433 45M doi 10 1016 j quaint 2015 10 002 Mohen Jean Pierre 1992 Metalurgia prehistorica introduccion a la paleometalurgia Prehistoric metallurgy introduction to paleometallurgy 1a ed ed Barcelona Masson ISBN 84 311 0605 0 Mohen J P Peroni R Katinchorov R and Tasie R Eccedy I and Kovacs T Merpert J M Briard J Thrane H Kaelas L 1996 Europe in the Copper Age in History of humanity scientific and cultural development Vol 2 From the third millennium to the seventh century BC edited by Dani A H J P Mohen London Routledge Paris UNESCO pages 320 391 Moreno A et al 2003 Metallurgical control and social power The Bronze Age Communities of High Guadalquivir in Archeometallurgy in Europe International Conference vol 1 Milano Associacione Italiana di Metallurgia pages 625 634 Ortiz T L et al 1990 El habitat en la Prehistoria en el valle del Rio Rojo Alava Cuaderno de Seccion Prehistoria Arqueologia num 3 San Sebastian Perez Arrondo Carlos Lazar 1987 El fenomeno megalitico en la margen derecha del Ebro The megalithic phenomenon on the right bank of the Ebro 1 ed Madrid Ministerio de Cultura Direccion General de Bellas Artes y Archivos Subdireccion General de Arqueologia y Etnologia ISBN 84 505 6553 7 Peroni Renato 1996 L Italia alle soglie della storia Italy on the threshold of history in Italian 1 ed Rome Laterza ISBN 88 420 5018 0 Renfrew C 1986 Varna and the emergence of wealth in prehistoric Europe In Appaduri Anjuin ed The social life of things Cambridge University Press Ruiz Taboada A amp Montero Ruiz I The oldest metallurgy in western Europe in Antiquity by Crawford Osbert Guy Stanhope 73 282 Princeton University Press for the Research Institute on International Change Columbia University 1999 pages 897 903 Shennan S Cost benefit and value in the organization of early European copper production in Antiquity by Crawford Osbert Guy Stanhope 73 280 Princeton University Press for the Research Institute on International Change Columbia University 1999 pages 352 363 Tasic Nikola 1995 Eneolithic cultures of central and west Balkans Belgrade Draganic ISBN 86 441 0117 X Timberlake Simon 2003 Early mining research in Britain The Developments of the Last Ten Years In Craddock P T Lang Janet eds Mining and metal production through the ages British Museum pp 22 42 Retrieved from https en wikipedia org w index php title Metallurgy during the Copper Age in Europe amp oldid 1213427906, wikipedia, wiki, book, books, library,

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