A F Harding, European Societies in the Bronze Age (chapter 6)


CAMBRIDGE WORLD ARCHAEOLOGY
EUROPEAN SOCIETIES
IN THE BRONZE AGE
A. F. HARDING
Department of Archaeology
University of Durham
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European societies in the Bronze Age / A. F. Harding.
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1. Bronze Age Europe. 2. Europe Antiquities. I. Title.
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chapter 6
METALS
Of the various materials and industries that were current during the Bronze
Age, metals occupy a special place: not so much because they were especially
important to the population of the period as a whole; more because of the
association of the name with the assumed production of metal objects on a
wide scale. During the 1500 years over which the Bronze Age lasted, metal-
lurgical technology developed from the use of unalloyed copper and gold for
simple objects that were hammered to shape or made in open moulds, to the
creation of a large and varied repertory using a variety of metals. From the
middle of the second millennium, very large numbers of objects were made,
principally in tin-bronze but also in other alloys of copper, and in gold. Thanks
to recent experimental and analytical work, most of the processes involved,
and the places where they were conducted, are well understood. But many
questions remain concerning the way in which metals were regarded and
utilised in other than functional terms, how the objects into which they were
made operated in the society and economy of the period, and what status was
accorded those who carried out the work of procuring the materials and pro-
ducing the objects.
A number of general accounts of metallurgical processes are available,
though none is written purely from a Bronze Age point of view, or with the
situation in Europe principally in mind. The works of R. F. Tylecote are com-
monly cited, but other valuable general accounts are those by Coghlan,
Mohen, Ottaway and Craddock.1
The natural occurrence of metals
Distribution maps of ore sources for copper, tin, lead and gold, the metals
mainly used in the Copper and Bronze Ages, are an essential preliminary to
any enquiry about the methods and role of metallurgy in those periods.
However, they present at best a partial picture since they cannot show the
multiplicity of small surface sources which for early metalworkers would
have represented the first port of call for ore supplies. Most such sources have
1
Tylecote 1986; 1987; Mohen 1990; Ottaway 1994; Craddock 1995. In more specialist matters
the works of Drescher, Hundt and Northover deserve special mention.
198 metals
Fig. 6.1. Major sources of copper in Europe. The highly gener-
alised picture presented here does not imply that these were the
only, or even the main, sources exploited in the Bronze Age.
disappeared, having been totally worked out or obliterated by much larger-
scale operations in the Roman and medieval periods.
Nevertheless, a map of raw material sources does have the merit of indi-
cating some major options open to ancient metallurgists, assuming that they
possessed the necessary technology to tap these resources. Europe possesses
(or possessed) some major copper deposits, some of them exploited into his-
toric times (or in rare cases to the present day) (fig. 6.1). Various parts of the
Balkan peninsula (Bulgaria, Serbia, Albania), the Carpathians (Transylvania,
Slovakia), the Alps (Austria), central Europe (the Harz and Ore Mountains of
Germany) and western Europe (France, Spain, Britain and Ireland, and also
Heligoland) have, or once had, significant deposits. Mention is sometimes
made of deposits in Sweden, where commercial exploitation occurred in the
last century, but there is no indication that these deposits were known and
exploited in ancient times.
The best way to determine which sources were used at different times and
for different groups should be through compositional analysis of ores and fin-
ished products. In spite of recent work it is still only possible to provide good
correlations of ores with objects in a limited number of instances, principally
The natural occurrence of metals 199
in the Mediterranean area. Early attempts using spectrographic analysis rep-
resented pioneering efforts to solve the problem and are a major source of
data for later workers, but have been found wanting in terms of the crucial
link between source and product.2 Thus, while it is possible to identify impu-
rity patterns and alloy types, tying metals down to particular ore sources is
another matter altogether. For this, more advanced (and expensive) tech-
niques, notably that of lead isotope analysis, are necessary.3
In practice, it is likely that many small sources of copper were exploited
in prehistory, which today are regarded as insignificant. In the Alpine valleys
of Switzerland, Austria and the Trentino, for example, there are many such
small deposits, their location often only discovered by chance since they are
far too small to have been worth working commercially in recent centuries
(fig. 6.2). In the region around Monte Bego in the Ligurian Alps, too, there
are many deposits of both oxide and sulphide ores, and it has been suggested
that their exploitation might have been a main reason for the presence of so
much activity in the region, as seen in the rock art.4 The same is probably
true for south-east Spain, home to the Argaric Bronze Age.5 Many deposits
are listed for Slovakia.6 Similarly, in upland parts of Britain and Ireland there
are indications of small deposits, sometimes associated with other minerals,
which have produced evidence of working in prehistoric times, but preserve
no exploitable ore today  the Mount Gabriel-type mines in south-west Ireland
are a good example of this. This presents something of a problem for the
archaeologist seeking to understand the nature of ancient copper-working. In
such circumstances, it is reasonable to concentrate on those areas where quan-
tity and quality of information are fairly good, while exercising caution when
attempting to transfer the results to other areas or types of working. In fact,
the best available evidence for ancient copper-working in the Old World comes
not from Europe but from Timna in southern Israel, where the long-term
explorations of Rothenberg and his collaborators have shed light on the whole
process of the mining, smelting and refining of copper, from the Chalcolithic
to the Islamic periods;7 by comparison, European results are meagre.
The case of gold is different.8 Most Bronze Age gold was probably extracted
through placer mining, for instance panning in gold-bearing streams. Ore
extraction may have taken place at certain major sources, notably the
Wicklow Mountains of eastern Ireland and the Muncii Metalici of western
2
Pittioni 1957; Junghans, Sangmeister and Schröder 1960; 1968.
3
There has been debate in recent years about the significance of lead isotope results (Budd et
al. 1996 with further refs.; Gale forthcoming).
4
Mohen and EluÅre 1990 1.
5
Montero Ruiz 1993.
6
Bátora 1991, 106f.
7
Rothenberg 1972; 1990.
8
Lehrberger 1995.
200 metals
Fig. 6.2. Copper ore sources in the Swiss Alps (Fahlerz and sul-
phide ores) (after Bill 1980). Stippled area: land over 1500 m.
Transylvania. Spectrographic analysis by Hartmann has successfully charac-
terised these two major gold sources, though not the host of smaller ones.9
Small placer deposits were probably present in other areas, for instance in
Cornwall, where alluvial gold occurs in small quantities along with tin. New
analytical techniques show good results in identifying these alluvial deposits
in terms of their elemental associations or  fingerprints .10
Tin sources in Europe are extremely few.11 Cornwall was the largest, and
certainly exploited by the Romans. That prehistoric exploitation is also prob-
able is seen from the find of cassiterite pebbles from St Eval, Trevisker, and
tin-smelting slag from the barrows at Caerloggas, St Austell.12 The Wicklow
Mountains of Ireland have been thought to have had tin deposits that could
be recovered by placer working as there is some documentation of cassiterite
in gold streams there, but it remains uncertain whether this could really
reflect ancient tin extraction in the area.13 Brittany, Iberia, Tuscany and
9
Hartmann 1970.
10
Taylor et al. 1996.
11
Muhly 1973, 248ff.; Penhallurick 1986.
12
ApSimon and Greenfield 1972, 309, 350; Shell n.d. [1980]; Tylecote in Miles 1975, 37 8.
13
Budd et al. 1994 for a sceptical view.
The natural occurrence of metals 201
Sardinia all have small quantities of tin, as do parts of western Serbia;14 the
Ore Mountains (Erzgebirge) in the Czech German border area also have it,
but it is disputed whether or not it could have been exploited with a Bronze
Age technology.15 What is not in doubt is that Bronze Age sites lie not far
from the known tin sources, notably in the Elster valley.16 Placer mining of
tin may well have been carried on there, and this might have supplied the
major central European bronze industries, for instance those in Germany,
Poland, Bohemia and Austria; perhaps also those of Scandinavia. Whether
they could also have supplied smiths further east, for instance in Hungary
and Romania, is more doubtful.
Through much of Europe, it is unknown how the bronzesmiths who turned
out such enormous quantities of bronzework, containing typically 5 10% of
tin, acquired their supplies. Even if one supposes that the tin of the Erzgebirge
was accessible, the distances involved were considerable. On the other hand,
Cornwall  the only source for which good evidence for Bronze Age exploita-
tion exists  cannot realistically have supplied smiths throughout continen-
tal Europe and Scandinavia. Claims have also been made for tin sources in
Yugoslavia, which would have the merit of being well situated from the point
of view of supply routes to either the Aegean or the Hungarian plain and
northwards.17 Much remains to be elucidated in this area, crucial both for
technological understanding and for a realistic appreciation of the transport
and exchange patterns. This puzzle applies also to the great cultures of the
East Mediterranean, for instance Minoan and Mycenaean Greece, Egypt and
the cities of the Levant, and is not definitively solved to this day.18
Lead is much more widely found, notably in the form of galena. It com-
monly contains significant amounts of silver, and the extraction of that silver
by the technique of cupellation (raising argentiferous smelted lead to red heat
in an open dish and blowing air across the surface) may have been a main
reason for interest in lead, though it was also much used in its own right.19
14
Durman 1997; Balkan sources are under-researched and could prove to be extremely impor-
tant.
15
Muhly 1973, 256; Taylor 1983; Waniczek 1986; Bouzek, Kouteckż and Simon 1989.
16
Bouzek et al. 1989, favoured also by Waniczek 1986.
17
McGeehan-Liritzis and Taylor 1987.
18
Texts from cities such as Mari (Middle Bronze Age) or Ugarit (Late Bronze Age) make frequent
reference to a material, annaku, that was being moved from the east in great caravans, and
the consensus has been that this represents tin. The discovery of a large amount of tin on the
Ulu Burun ship confirms the hypothesis that tin was in circulation around the Mediterranean
in the Late Bronze Age, though it does not in itself indicate where that tin had come from
(Maddin 1989). Recent work has suggested the Taurus Mountains of southern Turkey (Yener
and Özbal 1987; Yener and Vandiver 1993), the eastern desert of Egypt (Muhly 1985; 1993)
and Afghanistan (Cleuziou and Berthoud 1982; Stech and Pigott 1986).
19
This technique may have been used in the Rio Tinto mines in southern Spain (Blanco and
Luzon 1969; Craddock et al. 1985/1992).
202 metals
Metal types and alloys
Identifying metal types and the objects for which they were used is impor-
tant because of the possibility of tying down the routes and processes by
which metals were moved around. The attribution to specific ore sources
must be distinguished from the identification of a particular metal composi-
tion, which will only rarely be attributable to an ore source. Such work usu-
ally depends on compositional analysis.20 The question of metal types, in the
sense of ore compositions, is complicated by the fact that finished artefacts
were rarely, after the initial period of metal production, made of copper alone.
Other minerals were added, to facilitate casting, improve hardness or even to
bulk out the copper metal in order to make it go further. Alloying, by means
of the addition of arsenic, tin or lead to the copper, means that the compo-
sition of finished objects will be a further stage removed from that of the ore.
Where small amounts of a mineral were added, it can even lead to doubt as
to whether its presence was intentional or simply an impurity in the copper
ore.
In general, it is not in doubt that the metals used proceeded from pure cop-
per through copper arsenic and copper tin alloys to copper tin lead during
the course of the Bronze Age.21 Since tin and lead were usually added in sub-
stantial quantities (several per cent, or more in the case of some Late Bronze
Age lead-bronzes) it is not hard to detect their presence and to deduce that
the addition was for specific purposes. The addition of arsenic and/or anti-
mony is a more difficult matter, however, since both minerals are naturally
present in many copper ores as impurities. Where, as is often the case with
Early Bronze Age objects, arsenic is present in quantities of 1% or more, the
consensus used to be that it was intentionally added to the metal during
smelting on the basis that it improves the hardness of the finished product
(fig. 6.3).22 On the other hand, it has been persuasively contended that the
extraction and smelting of arsenical minerals in the Bronze Age is highly
unlikely, and that the presence of arsenic in copper objects reflects the use
of secondary copper ores containing arsenates, which can easily be reduced
to form copper arsenic alloys.23 But it has been shown in a variety of con-
texts that arsenic content varies according to artefact type, there usually being
more in objects with a cutting edge and less in axes and ornaments;24 simi-
larly, sickles from Late Bronze Age hoards in Slovenia have been shown to
have less tin (3 4%) than axes (6 7%), probably a deliberate alloying proce-
20
Such as the enormous corpus of material assembled in the 1960s by the Stuttgart analysis
team (Junghans, Sangmeister and Schröder 1960; 1968, etc.).
21
Tylecote 1986, 26; Northover 1980/1991.
22
Charles 1967.
23
Budd et al. 1992.
24
Ottaway 1994, 134.
Metals and types of alloys 203
Fig. 6.3. Left: The effect on hardness after cold working of adding
8% tin to copper (after Tylecote 1987c); hardness on the vertical
axis. Continued hammering to reduce thickness barely makes
pure copper any harder after the initial stages, whereas the
copper tin alloy continues to increase in hardness. Right:  Phase
diagram of a copper tin alloy (stages through which the metal
passes with increasing temperature, at different admixtures of tin).
Although pure copper becomes forgeable very quickly, it does not
become liquid until well over 1000° C is achieved. By contrast,
the admixture of 10% tin does nothing for the forging qualities
but reduces the melting temperature to around 800° C (after
Mohen 1990).
dure to make the tools more malleable for frequent resharpening.25 In fact, it
has been claimed that most British Irish ore sources would have produced
more or less pure copper, so that metal objects with significant impurities
represent the mixing of pure and impure metal sources, in other words a
much more developed circulation system than has usually been considered
likely.26
The interpretation of compositional analyses is fraught with difficulties,27
25
Trampu~ Orel et al. 1996.
26
Ixer and Budd 1998.
27
One of the more acute criticisms of the Stuttgart analyses has been that the results fly in the
face of archaeological sense, largely because the statistical treatment utilised in the original
publications does not take archaeological data into account: Waterbolk and Butler 1965; Härke
1978.
204 metals
but sensible results can be obtained from this great corpus of information.28
It has long been clear that a very pure copper (named E00) was prevalent in
the earliest period of metalworking, another was commonly used for the pro-
duction of ingot rings (C2 or  Ösenring metal ), while a multi-impurity metal
with high levels of nickel and antimony and moderate to high arsenic and
silver was very widely found ( Singen metal ).29 More detailed applications
can show how such metals were used at the site level. At Vż%0ńapy-Opatovce
different metal types were used preferentially for specific artefact types, for
instance 89% of the rings are of Singen metal, and 52% of the willow-leaf
ornaments are of so-called VO metal.30
Northover has identified a series of impurity groups and alloy types in the
artefacts of Bronze Age Britain and north-west Europe, seeing them moving
within  metal circulation zones .31 Initially the bulk of metalworking and
metal emanated from Ireland, mainly for axes, with some coming in from the
Continent in the form of daggers and halberds. This pattern then gave way,
in the developed Early Bronze Age, to one in which local ores were exploited
more intensively in Scotland and Wales, notably with metal types A, B and
C (fig. 6.4). With the Acton Park phase (Middle Bronze Age I), there was a
dramatic change: the north Welsh sources began to supply much of lowland
Britain (copper with 9 12% tin and increasingly the addition of lead, the intro-
duction of impurity groups M1 and M2). In the next, Taunton, phase (Middle
Bronze Age II), the dominant composition group had a consistently high tin
content (13 17%); at the end of the Middle Bronze Age (Penard phase), two
new impurity patterns (P and R) appear, with tin alloys in the region of 8 11%.
Such metal is widespread also in France and Germany, and seen also in the
Langdon Bay wreck.32
The Late Bronze Age metal types are very different. Of particular
importance was metal type S, with major impurities of arsenic, antimony,
cobalt, nickel and silver, and in some areas  notably that of the Wilburton
industry33  a high lead content indicating intentional alloying. Northover s
analyses suggest that this S metal, which cannot be British because of its
impurities, may be Alpine or Carpathian, certainly central European; it is
28
e.g. Coles 1969 for Scotland; D. and M. Liversage 1989 for Denmark; 1990 for Slovakia;
Liversage 1994 for the Carpathian Basin.
29
Waterbolk and Butler 1965, 237ff. graphs 8 9; Krause 1988, 183ff.
30
The discussion by D. and M. Liversage (1990) of the published analyses from the Vż%0ńapy-
Opatovce cemetery (To%0Å„ík 1979) shows that around 65% were of Singen metal, having the
characteristic impurity patterns for antimony and nickel (> 0.75%), arsenic (0.14 1.4%), and
silver (0.23 0.75%); 20% (38/169) were of another type (moderate arsenic, low antimony, sil-
ver and nickel), and a third group (10 analyses) was similar to Singen metal but with low
arsenic. Ten other low-impurity objects do not fall into any group.
31
Northover 1980a; 1982a.
32
Muckelroy 1981.
33
Northover 1982b. In addition to the dominant S group, Group H, with arsenic as the main
impurity, occurs mainly in the later hoards (e.g. Selbourne) and in hoards of scrap metal such
as the great Isleham hoard (Britton 1960).
Metals and types of alloys 205
Fig. 6.4. Metal types in the  Developed Early Bronze Age of the
British Isles, showing the way in which local ores were exploited
in western regions (after Northover 1982a).
widely found in Europe at this time (fig. 6.5). It introduced a large amount of
lead into circulation, which continued to have an effect into the following
phases, including the Carp s Tongue metalwork phase.
206 metals
Fig. 6.5. Metal types in the Wilburton phase, showing the sug-
gested movement of S metal from the Continent (Alps or
Carpathians) into Britain, where lead was added in local indus-
tries. Hatched zones indicate concentrations of Wilburton metal-
work (after Northover 1982a).
Ore to metal
The first step in the set of complex processes referred to as metallurgy was
the location and extraction of the raw materials. In some parts, for instance
at Ergani Maden in Turkey, gossans (iron oxides emanating from sulphide
deposits) appear on the earth s surface, and would have acted as an indicator
that other minerals were present lower down.34 A knowledge of ore types and
34
Tylecote 1976, 8. O Brien points out that in the British Isles many copper mines were in areas
that had already experienced millennia of hard rock extraction for axe production, so that
prospectors would have had an intimate knowledge of the local rock types.
Ore to metal 207
their attendant geology is necessary for understanding how ores may have
been located and worked, but it does not answer all the questions that arise.
In Europe many of the surface deposits which were the first target of Copper
and Bronze Age miners have long since been worked out, and the extent to
which deeper deposits were then exploited is controversial. So a reconstruc-
tion based on practices in other parts of the world, or on medieval European
practice, may indicate likelihoods and possibilities, but it cannot be regarded
as definitive.
It is generally assumed that copper ore bodies would initially be noted where
they appear on the earth s surface in their oxidised form, that is as ores such
as malachite or azurite, which have a brightly coloured appearance, or, in
more southerly areas where glacial action has not been a factor, where the
gossan lay above sulphidic copper ores. Sometimes the sulphur-bearing ores
such as chalcopyrite, or the products of the enrichment zone between the
oxide and sulphide ores (the best known being the Fahlerz grey ores), can
appear in oxidised form on the surface, as is the case in parts of south-west
Ireland. Although not coloured blue or green as the oxidised ores are, shiny
grey or gold patches or chunks within the dull rock matrix, sometimes a cen-
timetre or more across, indicate that the rock is of special interest. Many cop-
per ores occur in polymetallic deposits, along with small quantities of other
metals such as silver or nickel. Large quantities of iron are usually present
within many of the ore bodies, and although separation of the iron from the
copper was a primary concern, such iron was not suitable for the production
of iron objects.
Direct traces of prehistoric exploitation are discernible in a tiny minority
of known sources in Europe, almost all of them relating to copper. They are
known and have been investigated in Russia,35 Bulgaria,36 Serbia,37 Slovakia
35
Recent work has shown that a vast mining area at Kargaly, in the south-western periphery of
the Urals, was exploited in the Bronze Age (Chernykh 1996 and elsewhere). Although so far
only relatively small areas have been investigated, the amount of recovered material is colos-
sal. Chernykh estimates that the Kargaly mining area would have produced not less than 1.5 2
million tonnes of extracted mineral.
36
Chernykh (1978a) located numerous copper sources in south-east Bulgaria; few have evidence
for date. There is little indication of Bronze Age exploitation; a little Late Bronze Age pottery
at the Eneolithic mines of Aibunar (Stara Zagora) (Chernykh 1978b) is paralleled at Gorno
Aleksandrovo (Sliven), while there is Early to Middle Bronze Age pottery at Tymnjanka (Stara
Zagora).
37
North-east Serbia, particularly around Bor where the Rudna Glava mines have produced much
evidence of Eneolithic working, is prolific; there are also extensive Roman and medieval work-
ings, which have obliterated many of the traces of earlier work. There seems to be no direct
evidence of Bronze Age exploitation (Jovanović 1982 with full bibliography).
208 metals
(fig. 6.6),38 Austria (see below), France,39 Spain,40 Britain41 and Ireland;42 the
absence of the other sources listed above does not mean that they were not
exploited, only that direct field evidence has not yet been forthcoming.
Exploitation of all these sources was probably relatively small-scale in com-
38
The mines at `pania Dolina, near Banska Bystrica, and Slovinky, district of Spiaská Nová Ves,
central Slovakia, have been investigated under rescue conditions (To%0Å„ík and Bublová 1985;
To%0Å„ík and %7Å„ebrák 1989). Both oxides and sulphide ores are present. Rescue excavations recov-
ered large numbers of waisted and other stone tools, along with pottery of Eneolithic charac-
ter and a little attributable to the Lausitz culture.
39
At CabriÅres, Hérault (Vasseur 1911; Ambert et al. 1984; Ambert 1995; 1996), the veins of
Pioch Farrus and Roque Fenestre were utilised in the Copper and Early Bronze Ages. The ores
are varied; Fahlerz was abundant, along with malachite, and was probably used in preference
to the sulphide ores present at greater depths.
40
The province of Huelva, and especially the area inland from Huelva itself around Chinflon
and the Rio Tinto, was one of the richest metal sources in classical antiquity, producing sil-
ver, copper and other metals. The copper is largely sulphidic, but there are indications that
oxides must also have been present (Rothenberg and Blanco-Freijeiro 1981). Oxide ores would
quickly have been worked out, and Bronze Age miners must then have found a way of pen-
etrating the very hard gossan cap to the secondary enrichment zone underneath with its cop-
per, silver and gold. Major working of these ores did not take place until the Early Iron Age,
when numerous shafts and galleries were dug, but the presence of Late Bronze Age material
indicates the possibility of an earlier start for some of this working.
Radiocarbon dates indicating mine-working in the Copper Age and earliest Bronze Age have
also been recovered from the mines of El Aramo (Riosa) and El Milagro in northern Spain
(Blas Cortina 1996 with full references).
41
At the Great Orme s Head (Llandudno), Cwmystwyth, Dyfed, and other sites in north and cen-
tral Wales a number of traces of Bronze Age mining have been found, those at the Great Orme s
Head being the most extensive. Here excavation has revealed a complex set of workings that
extended up to 27 m deep and more than 100 m long (James 1988; Lewis 1990; Dutton 1990;
Jenkins and Lewis 1991; Dutton and Fasham 1994). The dolomitised limestone with interbed-
ded mudstones contains crystals and thin veins of chalcopyrite, with oxidisation to form mala-
chite at the surface. Stone tools, mainly in the form of mauls, have been found in some quantity,
and were evidently used to smash the softer rock faces and drive the shafts back. In places where
harder rock intervened, fire-setting was probably used. Radiocarbon dates on charcoal and bone
taken from spoil indicate an Early to Middle Bronze Age date. At Cwmystwyth, where chal-
copyrite is present, sectioning of waste tips in 1986 produced hammer stones and antler, and
charcoal which also gave radiocarbon dates in the Early to Middle Bronze Age (Timberlake and
Switsur 1988; Timberlake 1990b); comparable dates have been obtained from Parys Mountain
on Anglesey, and Nantyreira north of Cwmystwyth (Timberlake 1990a; 1991).
At Alderley Edge, Cheshire (Craddock and D. Gale 1988; D. Gale 1990), malachite and azu-
rite occur, and have been worked into relatively recent times. An early phase of extraction used
a  pitting technique with stone hammers (many waisted); distinctive peck marks appear on the
rock where such pits are present. Although there is no dating evidence for this phase of activ-
ity, a Bronze Age date has been suggested, based on parallels for the stone hammers and a radio-
carbon date of 1888 1677 cal BC (1Ã) on a wooden shovel from the mines (Garner et al. 1994).
42
At Mount Gabriel, Co. Cork, Derrycarhoon, and other sites in south-west Ireland an exten-
sive field research programme has been carried out (O Brien 1994). There are two groups of
prehistoric mines in Cork and Kerry: those located on sedimentary copper beds, like Mount
Gabriel, and those working richer vein-style mineralisations, like Ross Island, Killarney
(O Brien 1995). At Mount Gabriel there are thirty-two workings (individual shafts or shaft sys-
tems), which were driven along mineralised copper-bearing strata; similar workings are pres-
ent at other spots in the Mizen and Beara peninsulas. The ores are sulphide, mainly chalcocite,
chalcopyrite and boerite, with surface oxidation to produce  staining in the form of malachite
and azurite; there is no Fahlerz at Mount Gabriel. Radiocarbon dates for waterlogged wood
and for charcoal removed from adjacent spoil tips confirm Bronze Age mining from c. 1700
to 1400 BC (Jackson 1968; 1980; 1984; O Brien 1990; 1994, 178ff.). Recent excavations at Ross
Island confirm the extraction of Fahlerz and chalcopyrite in the period 2400 1900 BC. The
early production of arsenical copper in this site, linked to the users of Beaker pottery, con-
tinued into the earliest phase of insular tin-bronze production (O Brien 1995).
Ore to metal 209
Fig. 6.6. Extraction area at `pania Dolina-Piesky, central Slovakia,
showing shafts and waste heaps (after To%0Å„ík and Bublová 1985).
210 metals
parison with that of the major East Mediterranean sources: most notably
Cyprus, but also Laurion in Attica and, further afield, Timna and parts of the
eastern desert of Egypt. The evidence for the importance of Cypriot copper
in the economies of the eastern Mediterranean is overwhelming, and finds
its most dramatic representation in the Ulu Burun shipwreck, full of copper
and tin ingots. The existence of major supplies of raw materials to the east
was inevitably a factor for the inhabitants of Greece and therefore for other
parts of Europe from which she might have obtained metal.
The lack of direct evidence of working, then, does not mean that sources
were not worked. Particularly in the case of the Carpathians the conclusion
(based on the distribution of metalwork products) seems unavoidable that pre-
historic working took place; the absence of prehistoric mine shafts cannot be
used as an argumentum ex silentio. Similarly, the Harz Mountains are com-
monly cited as the nearest copper sources to Scandinavia, where the Bronze
Age metal industries were rich. But direct evidence of their exploitation does
not begin until the third century AD,43 though finds of Bronze Age pottery
near the Harzburg in the northern Harz has suggested Bronze Age interest in
the area, and excavation of smelting sites has produced stone tools, hearths
and furnaces very similar to those in the Austrian Alps.44 Copper was cer-
tainly being extracted on Heligoland in the medieval period, and could well
have started much earlier.45 No prehistoric workings are known, but the find-
ing of flat copper disc-like ingots in shallow water south of the island, dated
to the medieval period by radiocarbon determinations on charcoal inclusions
in the discs, the proximity of the island to the German and Danish coast (the
presence of Early Bronze Age sites on the island shows that it was in the cul-
tural orbit of Schleswig-Holstein), and the fact that no other copper source
lies so close to the north German/Scandinavian Bronze Age cultures, make
this probable.46
By far the greatest volume of Bronze Age copper mine-working in Europe
comes from the Austrian Alps, particularly the Mitterberg area west of
Bischofshofen in the Salzach valley south of Salzburg, but also from several
other parts of the north and east Tyrol; adjacent parts of Italy, Switzerland
and Slovenia also have deposits and in some cases traces of mining.47 Although
no mines have yet been found in the Trentino, it is likely from the number
of slag and other finds of metallurgical debris that they were (and perhaps
still are) present.48 The Libiola mines in Liguria are known to have been
worked in the Chalcolithic, since a wooden axe haft from them has given a
43
Klappauf et al. 1991; Kurzynski 1994.
44
Nowothnig 1965; Preuschen 1965.
45
Lorenzen 1965.
46
Stühmer et al. 1978; Hänsel 1982.
47
Ter~an 1983; Drovenik 1987.
48
Lunz 1981, 11ff.; Perini 1988.
Ore to metal 211
radiocarbon date in this period.49 At the Mitterberg, the work of the mining
engineers K. Zschocke and E. Preuschen between the world wars uncovered
numerous traces of prehistoric shafts and waste heaps in the course of mod-
ern exploitation of the copper that is still present.50 Unfortunately, their work
is familiar to most modern readers only through secondary sources, though
it remains a classic of the mining literature.
The ore mainly represented at the Mitterberg is chalcopyrite, a sulphide.
The veins of ore run for many kilometres through this mountainous region,
the main lode 1 2 m thick, some others less than this. To extract the ore
from the quartz matrix, fire-setting was used in conjunction with picks and
hammers to create Pingen, large pit-like features up to 10 m across that in
some cases turn into shafts or adits. These apparently reached considerable
lengths  100 m or more  and elaborate arrangements had to be made, by
the use of pit-props, to stow the waste. Rows of Pingen run across the moun-
tainside, sometimes with parallel rows in close proximity. Outside the shafts,
a number of separating areas have been found, relying partly on hand sepa-
ration and partly on water-dependent devices involving wooden constructions;
remains of post-and-plank constructions were found during excavation
together with sediments of various particle sizes, suggesting that water sep-
aration was used to concentrate ore or metal (fig. 6.7). Not far away, slag-
heaps attest to the fact that smelting took place locally, usually a little lower
down the mountain on more level ground, close to water. Analysis of this
slag shows that much of it is fayalite with a very low copper content, attest-
ing to an efficient extraction process. Datable artefacts and radiocarbon dates
from the excavations indicate a lifespan for the Mitterberg mines throughout
the Bronze Age, but so far no detailed chronology is available.
Estimates of the amount of copper extracted have been attempted on a num-
ber of occasions. Even allowing for orders of magnitude discrepancies, the
quantities of copper obtained from the Mitterberg area alone are very large,
amounting to many hundreds of tonnes. Zschocke and Preuschen calculated
that over 18,000 tonnes of raw copper could have been produced in prehis-
tory, assuming a concentration of copper in the quartz matrix of around 2.5%,
a 10% loss in preparatory roasting, and a 25% loss in smelting. One cannot
know that all this copper was produced in the Bronze Age, and even if it
were, the time over which the mines were demonstrably worked  perhaps
1000 years  would produce a yearly average of only 18 tonnes. Zschocke and
Preuschen further calculated that one team, consisting of 180 people, could
produce 315 kg of smelted copper per day; at that rate, 18 tonnes could be
produced in a mere 57 days. Even allowing for very great variability in extrac-
49
Barfield 1996.
50
Zschocke and Preuschen 1932; Pittioni 1951. Recent work (Eibner-Persy and Eibner 1970;
Eibner 1972; 1974; Gstrein and Lippert 1987) has confirmed many of these findings.
212 metals
Fig. 6.7. Extraction shafts (Pingen) and adjacent processing areas
at the Mitterberg (after Eibner-Persy and Eibner 1970).
tion rates across those 1000 years, there is nothing inherently unlikely in the
figures suggested. Indeed, if two teams were working 6 days a week through-
out the year, yearly extraction could have reached nearly 200 tonnes. In prac-
tice, the availability of wood might well have become a problem: each team
would require an estimated 20 m3 of wood daily, a major constraint on the
progress of the work, especially as it would have to be brought from pro-
gressively further away as time went on. Furthermore, winter conditions must
have made extraction difficult if not impossible.
A number of features are common to all of these mines:
1. Assessment of value. To be worth working, the metal content of an ore
source had to be sufficiently large for the labour expended in extracting it not
to become excessive, or not to exceed that involved in exploiting other com-
parable sources or in obtaining metal by exchange from other areas. It also
had to be present in a form that could actually be extracted using available
Ore to metal 213
technology. The main criterion must have been that the nodules or concen-
trations of metal should be large enough to be both easily visible and suc-
cessfully separable from the parent rock by physical means. It is evident from
what ancient miners left behind that there was a limit beyond which they
did not go in this respect: the sites of many ancient mines exhibit rocks that
contain small flecks of metal, large enough to see but too small to be suc-
cessfully extracted.51
2. Extraction. For detaching large chunks of rock the technique of fire-setting
was often used, depending on the depth and complexity of the workings. The
lighting of a fire against a rock surface would, by means of the differential
expansion of the crystals within the rock, cause cracks to form or to expand.
If sudden cooling by means of quenching with water was also adopted, the
effect would be still more marked. The remains of charcoal layers in mining
waste suggest that fire was frequently used in this way, and the rounded
undercutting of rock faces indicates the application of this technique, which
has been reproduced experimentally.52 After the fire had cooled, picks could
be inserted into the cracks and leverage exerted on the blocks of stone. Stone
hammers and mauls were also used, the waisted shape being particularly char-
acteristic (fig. 6.8); on occasion the pock-marks can be seen on surviving rock
surfaces in mine shafts, as at Alderley Edge.53 By these means an opening
would be formed in the rock, and if the metalliferous area continued down-
wards or inwards into a hillside, in time a shaft or tunnel would be formed.
These were commonly no more than a metre or so across, suggesting that
children must have been used to work the shafts.
Fire-setting would become progressively more laborious once the shaft had
reached more than a certain distance from the surface, and the problems of
smoke and lack of ventilation would hinder access to it for anything but ini-
tial kindling. For the same reason, quenching and other operations would be
difficult. In spite of this, evidence for ancient fire-setting was found in the
Mitterberg at considerable depths, and historical sources show that it can
indeed be carried out at depths of 100 m or more. The cramped, dark, damp
and dangerous conditions in which ancient mining for metals took place can
only be imagined.
51
A heap of silver ore (jarosite) in a Roman gallery at Rio Tinto was left unsmelted; the con-
centration is estimated at 120 ppm (0.012%). Ores containing more than 3000 ppm were avail-
able (Craddock et al. 1985, 207). Muhly (1993, 252) considers that the reported concentration
of tin in the the Bolkardag ores of 3400 ppm (0.34%) would be too small for Early Bronze Age
metallurgists even to detect, let alone utilise. The acceptable lower limits clearly vary with
ore and matrix type, minerals involved and technology available.
52
Pickin and Timberlake 1988; Timberlake 1990.
53
Craddock 1986, 108.
214 metals
Fig. 6.8.  Mining tools from copper mines, and tongs, hammers
and anvils from metalworking sites. 1. Rio Corumbel, Site 52C
(after Rothenberg and Blanco-Freijeiro 1981) 2, 5 6. `pania Dolina-
Piesky (after To%0Å„ík and Bublová 1985); 3. Great Orme (after
Dutton and Fasham 1994); 4. Cwmystwyth (after Timberlake
1990b); 7, 9 11. Bishopsland (after Eogan 1983); 8. Wollishofen
(after Ehrenberg 1981); 12. Fresné-la-MÅre (after Ehrenberg 1981);
13. Siniscola (after Lo Schiavo 1978); 14. Heathery Burn (after
Britton and Longworth 1968).
Ore to metal 215
3. Lighting, ventilation and drainage. In order to continue mining to greater
depths, a variety of devices were necessary to facilitate the work. The light-
ing of fires may have served to draw in air, while light could have been pro-
vided by a bowl of fat or oil with a wick floating in it, or by pine splints
(which have actually been found in a number of sites, including Mount
Gabriel). In either case, smoke would have been a constant irritant, the light
given off inconstant, and the danger of burning the operator considerable.
Removal of water from the shaft end or bottom would also become a major
consideration, depending on local conditions. By the very nature of the ter-
rain where many mines are situated, rainfall and groundwater would have
been abundant, and the digging of a hole in the ground likely to trap water.
It is possible that mining took place mainly at times of the year when such
problems would be minimised, but even so some shafts would very likely
have had to be abandoned, at least temporarily, because water had collected
in them.
The Austrian mines have produced a variety of wooden implements that
seem to have served the needs of the Bronze Age miner, not only shovels but
also pointed posts and planks (shaft lining or supports for stowage of waste),
parts of carrying packs or buckets, troughs, pipes or channels, kindling sticks
and notched poles that probably served as ladders. Considerable timber needs
are implied (as also by the fire-setting technology) as well as labour to work
and transport the wood. The recent finds of wood at Mount Gabriel and other
sites give some idea of the wealth of information still to be recovered.
4. Beneficiation. Fire-setting, particularly where stone hammers are also used
to pound the heated surfaces, tends to produce highly comminuted rock frag-
ments, which would aid the manual concentration of mineralised rock out-
side the mine. Where larger rock pieces were produced, however, it had to be
broken up into small lumps, or  cobbed , using heavy stone hammers. Such
hammers have been found on many sites and are often a prime indicator of
 primitive working on a site (fig. 6.8).54 In addition to hammers, a variety of
pounders, mortars, millstones and anvils were used for breaking up and grind-
ing the ore. At the Mitterberg, water-processing was used in addition to hand-
sorting.
5. Roasting and smelting. Chemical knowledge in prehistory was purely
empirical in nature and the technology built up on a trial-and-error basis; the
majority of what survives in the archaeological record represents the suc-
cesses, while the failures were destroyed by remelting. The first step would
have been to break up the ore and convert sulphide to oxide by a simple roast-
ing in an open bonfire. Ores from the surface oxidation zone would have
54
Pickin 1990; D. Gale 1991; 1990.
216 metals
needed this stage much less than those from deeper deposits, from which sul-
phur compounds as well as other undesirable elements had to be removed.
Smelting was the next stage, the process of producing a chemical alteration
in the ore to concentrate the metal in one place by removing the unwanted
elements. Molten metal does form, but it collects at the bottom of the fur-
nace and cannot be poured. The difference between specific gravities of cop-
per and waste products means that the former will sink to the bottom in the
form of globules of pure copper, leaving the latter above; this waste can be
tapped (allowed to run off), from a tap or valve in the furnace side solidify-
ing to form the slag that characterises ancient smelting localities. The com-
position of the slag depends on the type of ore that was used in the first place:
it is common for copper slags to be high in iron, reflecting the fact that sul-
phide ores commonly occur in a matrix of iron-bearing rock or have been
fluxed with iron oxide. The flux (added material to facilitate the chemical
reaction) was an important element in this process; its precise nature would
have depended on the nature of the ore. Wood ash, which would have devel-
oped from the charcoal, is itself a fluxing agent, and in some cases the addi-
tion of anything else may not have been necessary.
Slag is the commonest indicator of ancient metallurgical activity, since it
is produced at some stage in most ore-to-metal operations and is almost inde-
structible. In the Mitterberg area, for instance, there are many large slag-
heaps. The remains of slag on numerous Late Bronze Age settlements in
southern Germany show that smelting took place on site, probably in cru-
cibles, as is shown by large graphite or stone and clay containers.55 On the
other hand, there is no slag in the British Isles that demonstrably accompa-
nies Early Bronze Age workings of the sort known at Mount Gabriel and else-
where, and some attention has been paid to the question of how the ore
reduction could have been carried out without slagging.56 It has been sug-
gested that early smelting would have taken place at low temperatures and
concentrated on arsenate copper ores such as olivenate.57 Such ores can look
similar to copper carbonates and often occur in the same places. Unlike them,
however, they can be smelted in a bonfire to produce a copper arsenic alloy
that might then have been melted in a crucible.
In order to raise temperatures to 1083°, the melting point of copper, an
enclosed furnace would have been necessary, and a forced draught using
bellows would have introduced oxygen. The form and attributes of such
furnaces can be reconstructed since the technical requirements are well
understood, but few installations from archaeological sites survive. A site
55
Jockenhövel 1986, 219.
56
Craddock 1986.
57
Budd et al. 1992; Budd 1993. On the other hand, the recent work at Ross Island suggests that
shallow pit furnaces were being used in Beaker times to smelt the sulphide and Fahlerz ores
present on the site; there is no sign that the model suggested by Budd is correct for this site.
Ore to metal 217
interpreted as a smelting furnace on Kythnos consisted of a series of small
round stone structures; an excavated example contained a clay-lined bowl
with fragments of slag and copper.58 Numerous sites at Timna illustrate sim-
ilar constructions, dating from various prehistoric and historic periods.59
Experiments based on recovered smelting ovens at Mühlbach in Salzburg
province have suggested that the ovens were originally 1 m high, and that
two batteries of ovens were used so that two ovens could be in operation
simultaneously. Not far away lay a roasting bed, for the preliminary treat-
ment of the sulphide ores that were commonest at the Mitterberg.60 A smelt-
ing place was recently recovered at Bedollo in the Trentino, consisting of a
series of six pits in line, with a stone wall providing a surround for them.61
The production of charcoal is an aspect of metalworking that is often
ignored.62 Charcoal was the ideal fuel for furnaces prior to the advent of coke
because it promotes a strongly reducing atmosphere in the furnace, consist-
ing as it does of almost pure carbon, and on burning creates an oxygen-starved
atmosphere, essential if oxygen compounds are to be removed from the metal
being worked. The forcing of air into an enclosed charcoal-burning furnace
raises the temperature rapidly; charcoal has a calorific value about twice that
of dried wood. To make charcoal, cut timber is ignited in a sealed heap or pit
and allowed to smoulder; only sufficient oxygen is admitted at the start to
get the fire going, after which the process continues without the addition of
oxygen. By this means combustion is incomplete, no ash results, and almost
everything except carbon is removed from the wood. Considerable quantities
of timber would have been needed in the most prolific metal-production areas.
It has been estimated that to produce 5 kg of copper metal one would need
at least 100 kg of charcoal, which would in turn have required some 700 kg
of timber, a considerable requirement in terms of labour.
Charcoal has been found in many mining and smelting areas, for instance
at the Great Orme mines.63 This is probably the end-product of fire-setting;
it is possible that the process resulted in the production of charcoal which
could then be used for smelting and metal production.
58
Hadjianastasiou and MacGillivray 1988.
59
Rothenberg 1972, 65ff.; 1985; 1990, 8ff. Furnace IV in Area C, Site 2, for instance, was a round
bowl-shaped affair set in the ground with a thick layer of clay mortar forming its wall and
bottom, holes set into it for the insertion of tuyÅres, and on the opposite side the slag tap-
ping pit, a rectangular depression with a lining of large stone slabs; around the upper rim,
large flat stones formed a working area for the smelters.
60
Herdits 1993.
61
ierny et al. 1992. This find confirms a number of earlier finds of slag-heaps and smelting
places in South Tyrol and the Trentino going back to the Chalcolithic (Dal Ri 1972; Perini
1988; `ebesta 1988/1989; Fasani 1988; Storti 1990 1).
62
Horne 1982; Hillebrecht 1989.
63
Dutton and Fasham 1994, 280f.
218 metals
Ingots
The smelting operation produced copper in agglomerated, relatively pure
form. This may have been in the form of  prills of copper (irregular elongated
masses not unlike icicles,  frozen as the dripping metal cooled and solidi-
fied), which would be added direct to a crucible or, where simple bowl fur-
naces were used for smelting, the copper would have collected in a concave
depression at the bottom of the furnace to form a lump of copper that was
flat on top and curved underneath, the so-called plano-convex ingot. Many
hoards of bronze in Europe contain whole or fragmentary ingots of this kind.
Axe-shaped ingots were also used. In the Mediterranean in the Late Bronze
Age, a specialised form was used, the  ox-hide ingot (so called supposedly
because the shape resembles a hide, but more likely because the four han-
dles that project from a basically rectangular block enabled easy porterage).
Originally these ingots were thought to be exclusively an East Mediterranean
phenomenon, occurring as they do in Crete and mainland Greece, in Cyprus
and parts of the Levant, on the two ships wrecked at Cape Gelidonya and
Ulu Burun off the south Turkish coast, and in miniature form or representa-
tions in Cyprus and Egypt.64 There are also a number of such ingots, or frag-
ments, in Sardinia and Sicily,65 though in Italy, as elsewhere in Europe, the
normal form was the plano-convex ingot. Fragments of an ox-hide ingot were
recently identified in a hoard from Unterwilflingen-Oberwilflingen in south-
west Germany (Ostalbkreis, Baden-Württemberg),66 and a miniature example
has recently been found on a settlement site in Romania. Only one produc-
tion site is known, at Ras Ibn Hani in Syria, where a sandstone mould is set
into the ground in a part of the palace devoted to industrial activities. It is
highly likely, however, that such ingots were also made in Cyprus, where a
number of sites (Enkomi, Kition, Athienou) have major metalworking instal-
lations. The presence of such ingots in Sardinia has, therefore, caused much
interest and not a little controversy.67 Most surprisingly, the Sardinian ox-
hide ingots appear to be made of Cypriot copper (though other ingots and fin-
ished artefacts are most probably of local copper), a striking case of coals to
Newcastle.
In Europe, an unusual kind of hoard appears, that containing objects which
from their form are usually called  loop neck-rings (Ösenhalsringe) or some-
times just  loop rings (Ösenringe) after the loops or eyelets formed at each
end of the ring, but they are better described as ring ingots.68 A less com-
monly found form is the Rippenbarren or rib ingot. Both ingot forms occur
64
Buchholz 1959; Bass 1967; N. Gale 1989.
65
Lo Schiavo, Macnamara and Vagnetti 1985, 10ff.
66
Primas 1997.
67
Lo Schiavo 1989; N. Gale 1989, with refs.
68
Bath-Bílková 1973; Menke 1978 9; Eckel 1992.
Ingots 219
in such large numbers  sometimes several hundred in a single find  that it
is highly unlikely that they really served a purpose as personal ornaments
(except where they appear in graves).69 Instead, it seems most likely that they
represent a means of transporting metal about, their form intended for easy
carrying by inserting a pole through the middle. No moulds for ring ingots
are known, but they could readily have been cast into simple grooves in stone
 perhaps even in living rock  and then hammered into their ring shape.
They may well have been manufactured close to the smelting sites or else in
valley settlements after transport of the pure copper in plano-convex form
down from the mountain. The distribution of ingots northwards from the
eastern Alps, with especially dense concentrations in southern Bavaria, Lower
Austria and Moravia, is very striking and seems likely to be connected with
the known production of copper in the Austrian mines.
Attempts have been made over many years to tie these objects down to ore
sources.70 Examination of the analyses of the copper carried out by the
Stuttgart laboratory suggested that two main copper types were involved. One
 accounting for over 75% of all analysed pieces  has relatively high impu-
rities; the other is of very pure copper and accounts for around 15% of analysed
pieces.71 What cannot at present be demonstrated is any correlation between
the two distinctive copper types and any particular source area. Indeed, a
number of hoards contain metal of both types, made into identical objects.
This may suggest that the two metal types relate rather to stages and meth-
ods of working than to different origins for the metal. The two different met-
als look different today and would have handled differently in the workshop;
smiths cannot have failed to be aware of different properties resulting from
different treatment during and after smelting.
Ingots were one form in which metal circulated, though even here there
are stages which are not properly understood. For instance, breaking ingots
up for use was no simple matter. Fragments are commonly found, indicating
that ingots must have been heated to a high temperature first.72 But as well
as ingots, much scrap metal undoubtedly circulated. Hoards of broken objects
are commonly supposed to represent such circulation (though ritual expla-
nations have also been proposed: below, p. 361). Although much metal was
consigned to the ground for good during the course of the Bronze Age, much
must have been reused. The fact that metal objects can be melted down and
made into new artefacts is, after all, one of the great advantages of a metal
technology over a stone-based technology.
69
It is necessary to record, however, that some authorities do indeed believe that the rings were
in the process of being made into ring ornaments, and were not  pure ingots : Butler n.d. [1980].
70
Pittioni et al. (1957) identified the high impurity metal of the ingots, and believed that this
represented copper that had been brought in from the east (Ostkupfer), meaning the Carpathian
ring in general and Slovakia in particular.
71
Butler n.d. [1980]; Harding 1983.
72
Tylecote 1987b.
220 metals
From metal to object
While smelting usually took place in the immediate vicinity of the mining
sites, bronze-working could occur almost anywhere; there are indications
from various settlements, for instance, of working being carried out on site.
Working near ore sources would probably be that of  primary metal, while
that on settlements might well include recycled metal, melted down from
bronze scrap. The furnace would be constructed much as already described,
though it would not need to be so large as a smelting furnace, nor would it
need a tapping hole or pit, or a bowl-shaped base to collect the copper. Instead,
pieces of copper would be put in a crucible and the crucible heated in a char-
coal fire in a clay-lined furnace, with forced air being introduced to raise the
temperature to the required point.
No archaeological finds of bellows or blowpipes seem to be known from
Bronze Age Europe, but the majority would have been of organic materials
and are thus unlikely to survive. Pot bellows, a broad open pottery vessel
with a nozzle in the wall and a skin stretched over the top, might be a pos-
sibility, as is the case in the Near East,73 but they have yet to be certainly
identified. Experiments in both smelting and refining have demonstrated the
efficiency of pot bellows, but conventional blacksmith s bellows deliver a
higher air flow and would leave few, if any, non-organic parts in the archae-
ological record.74
TuyÅres, clay nozzles through which the bellows were inserted into the fur-
nace, are known from various sites and come in a large version believed to
be for smelting furnaces75 and a small, conical version, perhaps for the inser-
tion of a blowpipe such as is shown on Egyptian tomb paintings, for melting
furnaces (fig. 6.9).76 These small conical tuyÅres are known from a number of
finds in central and eastern Europe, for instance from Ún%1Å‚tice and related
Early Bronze Age groups, and from the Timber Grave culture grave at
Kalinovka in south Russia (below, p. 239).77 TuyÅres can be straight or curv-
ing, in certain examples even turning a right angle. Many more examples are
known from the Near East and Cyprus than Europe;78 there a hemispherical
 small tuyÅre (perforated lump of clay) is distinguished from a tubular, built-
in tuyÅre, the latter always very fragmentary and therefore unlikely to sur-
vive in a European climate. In the Aegean area, the best example is that from
the bronze workshop in the Unexplored Mansion at Knossos.79
73
Davey 1979.
74
Merkel 1983; 1990.
75
e.g. Fort Harrouard: Mohen and Bailloud 1987, 128f. pl. 5, 15; pl. 98, 19; Velem St Vid: von
Miske 1908; 1929.
76
Hundt 1974, 172 fig. 27; 1988; Tylecote 1981; Jockenhövel 1985.
77
Jockenhövel 1985.
78
For instance the series studied at Timna by Rothenberg (1990, 29ff.); see Tylecote 1971.
79
Catling in Popham 1984, 220 pl. 199, i; 207, 5; described as a  bellows nozzle .
From metal to object 221
Fig. 6.9. TuyÅres from Bronze Age metalworking sites.
1 3. Kalinovka; 4. Bogojeva; 5. Tószeg (after Hundt 1988);
6. Mierczyce; 7. Lago di Ledro; 8. Nowa Cerekwia (after
Jockenhövel 1985); 9. Knossos, Unexplored Mansion (after Catling
in Popham 1984); 10. Fort Harrouard (after Mohen and Bailloud
1987); 11. Ewanrigg (after Bewley et al. 1992); 12. Bad Buchau,
Wasserburg (after Kimmig 1992); 13. Löbsal (after Pietzsch 1971).
222 metals
An interesting recent find was of a  connecting rod of clay from an Early
Bronze Age cemetery at Ewanrigg, Cumbria (fig. 6.9, 11).80 This clay tube,
some 17 cm long and 3.7 cm in diameter with an irregular internal perfora-
tion 1.2 cm in diameter, is thought to have served as an intermediate piece
between bellows and tuyÅre; its slightly rounded end would have connected
somewhat flexibly with the tuyÅre, and its presence would have provided an
additional means of preventing hot gas from the furnace being drawn back
into the bellows, at the same time as representing an additional source of
fresh cold air for the bellows.
An extensive range of tools was needed for casting and working the metal:
crucibles, moulds, tongs, hammers, blocks, anvils and others.81 These are
found relatively rarely, though they must have been common enough in the
smith s toolkit. Crucibles were commonly made of a coarse sand clay mix-
ture, less often of stone, and could be narrow and deep or shallow and broad,
sometimes with a pouring lip. A suitable method of holding the crucible for
lifting and pouring metal no doubt also presented problems: Egyptian paint-
ings appear to illustrate pairs of staves being used for the purpose, but since
even green wood would flame rapidly under such intense heat it may be that
these are metal bars, or conceivably wood covered in metal sheet.
Metal tongs are known but occur infrequently (fig. 6.8, 13 14);82 examples
are found in Cyprus, Crete and the Levant but may have been rather for hold-
ing hot metal objects during hammering.83
Anvils are well known, especially in western Europe (fig. 6.8, 7, 8, 12).84
The basic distinction is between simple, beaked and complex anvils (those
with multiple spikes or  beaks and facets). Many of these tools are relatively
small (less than 8 cm across) and could have been carried around; others,
including large stones sometimes used for the purpose, must have been fix-
tures. Some have holes for hole-punching or swages (grooves) in which metal
could be beaten into wire or thin bars, and there are two wire-drawing blocks
in the Isleham (Cambridgeshire) hoard.85 A small anvil from Lichfield,
Staffordshire, contained particles of gold in its surface layer and was proba-
bly used for beating out gold sheet. It also includes a swage groove on one
end, perhaps for creating bar bracelets.86
The counterpart to the anvil is the hammer, of which six different forms
80
Bewley et al. 1992, 343ff., fig. 13.
81
Coghlan 1975, 92ff.; Mohen 1984 5.
82
e.g. Siniscola, Sardinia: Lo Schiavo 1978, 86 7 pl. 27, 2; Lo Schiavo, Macnamara and Vagnetti
1985, 23 5 fig. 9; Heathery Burn cave: Britton 1968.
83
Catling 1964, 99 A1 fig. 11, 4 pl. 10a; Catling in Popham 1984, 206 7, 219f., pl. 199; Vagnetti
1984. Catling (in Popham 1984, 215) suggests that tweezers or pincers may also have been
used to hold hot furnace materials.
84
Ehrenberg 1981; examples from central Europe: Hralová and Hrala 1971, 19ff.
85
EluÅre and Mohen 1993, 20.
86
Needham 1993; another stone with gold traces comes from a settlement at Choisy-au-Bec
(Oise) (EluÅre 1982, 176 fig. 164).
From metal to object 223
are known in central Europe.87 Many occur in the large hoards of the early
Urnfield period (fig. 6.8, 9 11),88 on sites interpreted as locations for metal-
working, such as the Breiddin, Powys, Wales,89 and on Swiss lake sites,
although metalworking installations have not been recovered there.90
Socketed hammers are associated by Jockenhövel with the practice of beat-
ing metal sheet into objects such as vessels, helmets, shields and the like;
they must have had predecessors in stone.91 Used in conjunction with an anvil
or swage block, thin sheet could be produced, decorated with delicate pat-
terns. There must also have been larger anvils (probably of stone) and sledge-
hammers for fashioning large objects where fineness of work was not a
consideration, but these seem not to survive in continental Europe; examples
are known from Cyprus and Sardinia.92
Bronze Age mould technology is reasonably well understood, though dupli-
cating the results of ancient smiths is not always successful. In general there
was a progression from simpler to more complex types, from open moulds
cut on to the surface of a stone block to two-piece moulds, each half the mir-
ror image of the other, and from stone to clay (depending on area). Multiple
mould finds in stone illustrate something of the range which was possible:
they are especially common in the north Pontic area, as in the great hoard
of Majaki (Kotovsk, Odessa), with 13 moulds for spearheads, daggers, sock-
eted axes, rings and pins;93 the strange collection from Pobit Kamk (Razgrad)
in Bulgaria is even more remarkable, containing moulds for socketed and
shaft-hole axes, for a large dagger and an extraordinary halberd with spirally
curved blade, and a collection of small objects that may have been pommels
or hilt attachments to swords, daggers or knives.94 Both of these finds belong
to the local Late Bronze Age. Somewhat earlier is the large find of 41 stone
moulds from Soltvadkert (Kiskörös) east of the Danube in central Hungary.95
As well as tools (socketed and flanged axes) there are pins, bracelets, pen-
dants and beads represented in this find. The stone is sandstone, which must
have come either from across the Danube in Transdanubia or from the
Carpathians to the east. Another plentiful source of stone moulds is Sardinia.96
87
Hralová and Hrala 1971; Jockenhövel 1982a; Lo Schiavo, Macnamara and Vagnetti 1985, 22f.
88
Examples include those from Surbo (Apulia) (Macnamara 1970), Lengyeltóti, Hungary (Wanzek
1992) and Fresné-la-MÅre (Calvados) (Coghlan 1975, 95ff. fig. 23; see too Larnaud, Jura: Chantre
1875 6, 110ff.; Vénat (St-Yrieix, Charente): Coffyn et al. 1981, 118f. pl. 22, 1 3, and other sites
in the Charente basin (Gomez 1984) or Breton hoards (Briard 1984)). Sets of hammers, an anvil
and other tools from the Bishopsland (Co. Kildare) hoard: Eogan 1983, 36, 226 fig. 10.
89
Coombs in Musson 1991, 133f.
90
Auvernier: Rychner 1979, pls. 125 6; 1987, 74 pl. 29, 5 8.
91
Hundt 1975.
92
Lo Schiavo et al. 1985, 22 fig. 7, 6 7. Catling (1964, 99) suggests that massive wooden mal-
lets covered in metal sheet could have been used as sledge-hammers, or perhaps such ham-
mers could have had metal inserts of some kind.
93
BoØ
ckarev and Leskov 1980, 15ff. pls. 4 7.
94
Hänsel 1976, 39ff. pls. 1 3; Chernykh 1978a, 254ff. figs. 67 8.
95
Mozsolics 1973, 80f. pls. 108 9; Gazdapusztai 1959; Kovacs 1986.
96
Becker 1984.
224 metals
In contrast to these stone mould finds, in the west of Europe there are large
collections of fragmentary clay moulds, especially in the British Isles.97 In the
Swiss lake sites, stone moulds are commonest but clay ones do occur.98 These
moulds are fragmentary because they have to be broken after the metal has
been poured in order to get the object out; they are intended for use once
only, in contrast to moulds of stone or metal. They would have been made
by pressing clay round a  master object or pattern, taking on the exact form
of the pattern and enabling great homogeneity between different pieces to be
achieved. Interestingly, wooden patterns for the production of clay moulds
are known from Ireland.99
Clearly there was a balance to be struck between the labour of making clay
moulds afresh each time a casting was required and the more time-consuming
process of fashioning stone moulds for multiple usage. If suitable clay was
available, this was the more appropriate material for mass production of
objects and may have had desirable properties for successful castings. There
does not seem to have been a functional difference between stone and clay,
but clay had two intrinsic advantages: more complex forms could be cast and
standardised manufacture was possible, since each clay mould was the neg-
ative of the same master and hence the bronze product was the clone of that
master. On the other hand, at Dainton different clays were used in moulds
for different object classes, though whether this is connected with metallur-
gical practice or with different episodes of work is impossible to say.
Moulds were also made of metal, on the face of it a curious practice. A
number of studies of these have been made, and it has been demonstrated
experimentally that they can be used for successful casting.100 The inner sur-
faces of the mould would need to be coated in graphite or some similar
medium onto in order to prevent the newly poured metal from adhering to
the mould.
A variety of techniques were used to produce hollow castings, complex
objects and other specialities. In some instances debris from these operations
survives: cores, valves, chaplets or  core-prints (small rods to pin a core in
position inside a mould) and other devices. Cores and gates are present among
the mould debris at Jarlshof, Shetland.101
In the Late Bronze Age, a number of highly elaborate bronze objects were
made using the technique of lost wax casting (cire perdue). The principle of
97
Hodges 1954; Collins 1970; Mohen 1973: as at Dainton (Devon) (Needham 1980), Rathgall
(Raftery 1971), Fort Harrouard (Mohen and Bailloud 1987, 130ff.); see too Peńa Negra (Gonzalez
Prats 1992).
98
Rychner 1979, pl. 131, 5 6; 1987, pl. 33, 1 5, pl. 34, 2; Weidmann 1982.
99
Hodges 1954, 64ff. fig. 3. A group of objects from a bog at Tobermore, Co. Derry, are of the
form of Late Bronze Age bronzes (leaf-shaped spearheads and socketed axes). On certain
bronzes the grain of the wooden model is still visible.
100
Drescher 1957; Mohen 1978; Rychner 1979, pl. 137, 7; 1987, 78ff., pl. 35, 1; Tylecote 1986,
92; Voce in Coghlan 1975, 136ff.
101
Curle 1933 4, 282ff.
From metal to object 225
this method is that a form or pattern is made in wax or wax around a clay
core; fine details can be modelled in the soft material that are much harder
to create on stone or even on clay. The form is then covered in clay and fired,
during which the wax runs out, leaving a cavity. Molten metal can then be
poured into the cavity and the outer clay walls broken away to reveal a metal
version of the original wax form. Numerous objects were made by this tech-
nique, not only those with elaborately moulded appendages but also, it seems,
those with intricate surface decoration. The highly regular spiral decoration
on objects of Periods II and III in Scandinavia was executed by creating the
design on wax rather than punching it onto finished objects.102 Other objects
for which this was true include the great ceremonial trumpets or lurs of
Scandinavia, and the rather similar horns of Ireland. Detailed study of some
of these has shown that lures are cast in lost-wax moulds in several separate
pieces.103 On some of the lures, slots or holes can be seen where core-
supporters were present and have dropped out; such holes were probably filled
with plugs of resin or wax, or had extra metal cast on. The sections were
then joined with locking joints, of which the most interesting are the so-
called maeander joints, made by incorporating a dove-tailed end to the base
of each section. A further piece of lost-wax casting then enabled the sections
to be joined together and the length to be adjusted so that each lure was
exactly the same as its partner (they appear in pairs, the bells facing in oppo-
site directions).104 The mouthpiece and bell, with elaborately decorated plate
or disc, were then cast on and the whole object polished to remove casting
traces and other imperfections. In the case of the Irish horn, holes were usu-
ally cut into the wall of the instrument, great care being taken to achieve
regularity both of diameter and of positioning so as to achieve the desired
musical results.
A suggestion to account for the relative lack of moulds in some parts of
Bronze Age Europe is that moulds were made from a special casting sand
(sand with an admixture of gum, oil or fine clay to enable it to stick
together).105 To make a bivalve mould by this process, two hollowed-out pieces
of wood  such as a tree-trunk or branch  would be needed. One would be
filled with sand and the pattern pressed into it (after being dusted with
graphite or a similar substance to prevent it sticking in the sand), the second
placed on top and more sand inserted from a hole in the upper surface. Then
the two parts would be separated, the shape of the pattern now imprinted in
the sand. The addition of an end piece to retain the metal when it has been
102
RÅ‚nne 1989a.
103
Basic studies by Schmidt (1915), Broholm, Larsen and Skjerne (1949) and Oldeberg (1947) for
the Nordic area, and Holmes (n.d. [1980]) for Ireland.
104
On some lures a tubular ring was used to strengthen the joint. A locking device, consisting
of a triangular projection that slotted under the ring-band to ensure that the sections did not
come apart, also appears (Schmidt 1915, 103 4).
105
Coghlan 1975, 50f.; Goldmann 1981.
226 metals
poured completes the process. Such moulds can apparently be used without
the need for channels for the escape of gas (the gas percolates through the
sand) and do not need preheating. If this technique really was suitable for the
casting of bronze objects, all that would be needed would be a supply of suit-
able sand and clay.
The technique of casting on, also known as  running on (in German Über-
fangguss), was used to fabricate objects made in more than one piece, to repair
broken objects, or to add pieces on to existing objects (for example, the solid
bronze hilt to a sword).106 A separate mould would be made and the original
cast object inserted into it and heated before the metal was poured. In spite
of the technical difficulties, very many successful castings of this type were
made, especially handles, hilts and other attachments. Evidence for its use is
noted on Wilburton hoard material in Britain.107 A striking case of casting on
to effect a repair can be seen in two swords from Kosovo, where rapiers were
remodelled into flange-hilted swords by the addition of cast-on hilts.108 In like
manner, casting faults could be repaired by skilful casting on to fill gaps, as
with the circular additions to the blade of a solid-hilted sword from Kuhbier,
Kr. Ost-Prignitz.109
Decoration and finishing
After the casting of an object and its successful extraction from its mould, it
had to be finished. In the case of simple tools such as axes, this might con-
sist of no more than the removal of the most intrusive evidence of the cast-
ing process, such as the flashes and projecting seams where the metal ran
into the venting holes and the gap between the mould halves. This was pre-
sumably done by hammering, though filing or grinding with a stone may have
been equally effective.110 Hammering would have been carried out to increase
the hardness of objects, and hot forging to sharpen cutting edges. After this,
the surface would probably have been finished by using a stone for fine grind-
ing and polishing, and a high sheen could have been imparted by a polisher
of wool, initially with an abrasive agent such as fine sand, followed by oil or
wax. Many bronzes retain their sheen to the present day: the arts of the Bronze
Age smith were effective and durable.
At Hesselager, Gudme district (Funen), a grave contained a collection of
stone objects that have been interpreted as polishers or grinders for metal-
finishing.111 These are similar to the collections from Ommerschans and
106
Drescher 1958; Coghlan 1975, 64f.
107
Northover 1982b, 94.
108
Harding 1995, 21 pl. 4.
109
Born and Hansen 1991.
110
Coghlan 1975, 104ff.; bronze files would more likely have been used for working wood: e.g.
Velem St Vid (von Miske 1908, 132).
111
Randsborg 1984.
Decoration and finishing 227
Lunteren in the Netherlands and seem to represent the portable equipment
of a metal-finisher.112 The Lunteren find includes a group of stones which
may include touchstones for determining the purity of gold objects. The pol-
ishing stones are repeated in the find from Ordrup (north-west Zealand).113
The decoration of objects, for instance with line ornament, bosses or dots,
could be achieved either through the casting (by creating the decoration on
the mould) or through working the metal after casting by incision or punch-
ing on to the surface, or by pushing the thin metal into a wooden form
(repoussée work). A range of punches, chisels, scribers and gravers are known
which account adequately for most of the ornamentation seen.114 The meth-
ods used to create decoration on the surface of bronze objects are of consid-
erable interest. Bronze chisels and punches are of limited use on copper and
of no use at all on bronze, as experiments have shown.115 The possibility that
iron punches were in use at least by the time of the Late Bronze Age has
been raised, since marks of such tools on bronze objects have been recog-
nised.116 Bronze tools leave marks that are broad, shallow and rounded in the
middle, while iron produces sharp, narrow and angular marks. The marks of
iron punches can be recognised on bronzes of Ha A2 and B1, though not on
those of Br D and only doubtfully on those of Ha A1. The finding of an iron
punch on a Middle Bronze Age trackway in Holland is taken as corroborat-
ing evidence for the existence of such punches long before the start of the
Iron Age.117
Tools such as these were not only used for creating new objects in the first
place; they were also used to repair broken pieces. On a sword from Croatia,
for instance, a broken blade was repaired by sawing through the midrib, fil-
ing off the rib and inserting a rivet which was then hammered down to fill
the missing rib area. In spite of these attentions, the blade broke again a lit-
tle further down.118
Drills must have been available for some of the fine work, and possible
drill bits have been identified in the metalwork from the Unexplored
Mansion.119 No such examples are known from continental Europe, and
punching or casting is considered to have been the standard method of
112
Butler and Bakker 1961; Butler and van der Waals 1966, 63f.
113
RÅ‚nne 1989b.
114
Maryon 1937 8, 1938; Wyss 1971; Coghlan 1975, 98ff.; Bouzek 1978; Mohen 1984 5. The
hoards from Larnaud (Jura), Génelard (Sâone-et-Loire) and Fresné-la-MÅre (Calvados) include
many of these tools, and other collections come from Swiss lake sites (Rychner 1979, pl. 126,
1 17; 1987, pl. 29, 9 10) and Ireland (Tylecote 1986, 103). The Génelard hoard has a curious
set of what are believed to be moulds, though they look more like punches, for making but-
tons and ornaments with concentric circles (EluÅre and Mohen 1993).
115
Drescher 1956 8; Coghlan 1975, 99f.
116
Bouzek 1978.
117
Casparie 1984; Charles 1984. The small but slowly rising number of iron objects lends some
weight to this notion (Harding 1993).
118
Harding 1995, 34 pl. 11.
119
Catling, in Popham 1984, 214; Deshayes 1960, i 46f., ii 10 11 pl. 2.
228 metals
perforating bronzework.120 Experiments showed that drill bits of bronze rap-
idly wear out; iron bits would have done the job but have not been found.
Holes needed to be bored in order to take rivets, a common joining technique
(seen, for instance, on buckets and cauldrons of the Late Bronze Age), and for
the insertion of wire, which is found in a number of hoards and other finds.
Riveting was a standard feature in the attachment of hafts and handles, for
instance the hilts of swords and daggers or the handles of sickles. A curious
feature of solid-hilted swords is that they often have skeuomorphic rivet
designs on the hilts, the appearance of a rivet where there was none. Smiths,
it seems, expected to provide rivets on sword hilts and carried on doing so
even when there was no need.
Other metals
Not much is known about silver in pre-Iron Age Europe.121 Native silver is
rare and most silver must have been obtained by cupellation from lead, so it
is not surprising that silver objects are rare in Bronze Age Europe. The famous
sources in Greece (Siphnos, Laurion), Early Bronze Age artefacts in Egypt,
Crete and Troy122 and Late Bronze Age objects in the Shaft Graves of Mycenae
find little echo in lands to the north; there are a few finds of Copper Age date
scattered through Europe.123 Daggers from Usatovo belong to the Early Bronze
Age, parallel with early Troy, while the silver dagger, spearheads and pin from
the Borodino hoard also suggest Aegeo-Anatolian connections; its date is dis-
puted, but must lie in the second millennium BC.124 The famous hoard from
Per_inari (Ploie_ti) contains, in addition to the well-known gold sword, four
silver axes,125 and a silver dagger in the Hungarian National Museum pre-
sumably belongs to the same horizon. Silver pendants are present at the
Zimnicea cemetery (Teleorman) in southern Romania and other Romanian
sites.126 Two silver rings were found in graves at Singen in southern
Germany.127 Much the most spectacular, however, are the finds from the west,
notably the diadems, rings and beads of the Argaric Bronze Age in southern
Spain128 and the silver cups from barrows at Saint-Adrien (Côtes-du-Nord) and
120
Coghlan 1975, 104.
121
Mozsolics 1965 6, 34ff.; Primas 1996.
122
Branigan 1968; Gale and Stos-Gale 1981.
123
e.g. spiral ornament from the megalithic grave MVI at Petit Chasseur, Sion, Switzerland
(Primas 1996), and a shaft-hole axe from the tumulus at Mala Gruda (Tivat, Montenegro)
(Parović-Peaikan and Trbuhović 1971).
124
Harding 1984, 200ff.
125
Mozsolics 1965 6, 5ff., 50.
126
Alexandrescu 1974, 85; Oarca de Sus in the Slaj depression: Kacsó 1987, 69f., fig. 23.
127
Krause 1988, 88f., fig. 46.
128
Siret and Siret 1887, 147, 152ff., 223ff., 259ff., pls. 20, 27, 29 34, 36, 43 5, 63, 68; Hook et
al. 1987; Pingel 1992, 36ff.; Montero Ruiz 1993, 53ff.
Other metals 229
Saint-Fiacre en Melrand (Morbihan).129 A silver bead recently turned up on a
destroyed burial mound in southern England, the first Bronze Age silver find
from Britain.130
By contrast, gold finds are relatively common. From the time of the Varna
cemetery, gold seems to have occupied an important place in the scheme of
values prevalent in Europe  dangerous though it is to attempt judgements
of value for remote periods of the past. A number of recent accounts of the
development of gold-working in the Bronze Age are available, from which it
is clear that the amounts of gold varied enormously from region to region
and period to period, presumably a reflection of both availability and fashion,
as well as (in the case of hoard finds of gold) factors other than utilitarian.131
The beaten sheet goldwork seen in the Early Bronze Age of the west on
lunulae, discs and diadems was in technological terms the equivalent to the
gold of Varna or other Eneolithic finds in eastern Europe. To make a lunula,
a bar of gold metal was beaten out thin using stone or metal hammers, and
decoration added by the repoussée technique. The trick of decorating dagger
pommels in Wessex and Brittany with minute gold pins is also noteworthy.132
But more complicated forms were also possible, as is shown by the group of
sheet-gold vessels of Early Bronze Age date, the earliest probably a golden
Beaker from Eschenz (Switzerland), soon followed by cups from Fritzdorf
(Bonn) and Rillaton (Cornwall).133 In the Carpathian Basin, too, there are gold
cups, discs and small ornaments, but also a series of massive bracelets and
shaft-hole axes, as seen in the finds from bufalu and Biia,134 and gold came
to be used for similar prestige objects in the German area (for instance in the
Leubingen barrow). The Argaric Bronze Age of south-eastern Spain produced
a range of mostly small gold objects,135 both in sheet and in more solid form,
and small objects were present in the west of Spain at the same period; an
extraordinary hoard from Caldas de Reyes (Pontevedra) contains vessels, arm-
rings and a diadem.136
In later stages of the Bronze Age, a bewildering variety of techniques was
used to create the extraordinary range of magnificent showpieces that sur-
vive in the treasuries of European museums. Sheet gold-working continued,
as can be seen from the Mold cape,137 and from the large and varied reper-
toire of highly decorated cups and other vessels,138 including the so-called
129
Briard 1975; 1978; other silver finds from Brittany are ring-headed pins and spirally wound
armrings: Gallay 1981, 87 table 53 (Pleudaniel), 93 table 56 (Quimperlé).
130
Bradley 1997, 28.
131
Hardmeyer 1976; Taylor 1980; EluÅre 1982; Hartmann 1982; Pingel 1992; Eogan 1994.
132
Taylor 1980, 47ff.; EluÅre 1982, 45ff.
133
Hardmeyer and Bürgi 1975.
134
Mozsolics 1965 6.
135
Including hilt-plates on swords: Almagro Gorbea 1972.
136
Pingel 1992, 55ff.
137
Powell 1953.
138
Eogan 1981; EluÅre 1982, 102ff.
230 metals
 crowns from Avanton, Ezelsdorf and Schifferstadt.139 Such cups came to
occupy a central place in the provision of  service sets , such as the magnif-
icent collections from Messingwerk near Eberswalde in Brandenburg,140 or
Mariesminde on Funen.141 Many of these may have had ritual functions. Bar-
working became extremely common after the Early Bronze Age, gold bars
being hammered into various shapes (flat bands, bars that were square or
round in cross-section, sometimes with raised flanges), where appropriate
twisted, and then bent to the desired form. By this means, elaborate bracelets,
earrings and neckrings were created. Gold sheet was also used to encase
objects made of other materials, a technique that started in the Early Bronze
Age but was revived later on. In the latest part of the Irish Bronze Age, new
forms appear:  lock-rings , gorgets,  dress-fasteners and  sleeve-fasteners ,
bracelets with flaring terminals, and many other forms.142 The extraordinary
penannular lock-rings are made out of two circular pieces of gold plate or
individual gold wires soldered together and are held together by binding strips
round the edge.143 The gorgets are large penannular ornaments decorated with
ridges, bosses and rope patterns, with a disc terminal soldered to each end.
The multitude of splendid ornaments produced in Ireland and other areas
indicates both the proficiency of goldsmiths and the ready availability of gold.
Unfortunately, little is known about the contexts in which this gold was used
and deposited. Iberia also saw a rich development of gold-working, with the
hoard of Villena-Rambla del Panadero (Alicante) containing elaborately dec-
orated vessels, armrings and other objects.144
Lead was important for the bronze-worker, not only in its own right for
making objects but also as an alloying material and as a material for fittings
and repairs. Because of its weight and relative malleability, it was well suited
for making small fittings and attachments on bronze and other objects, for
instance in the attachment of hilt-plates and pommels to swords, and also
for repairs and to remove imperfections in bronze.145 It was used in the haft-
ing of implements, for instance swords: the cavity in the grip of a number of
solid-hilted swords (Vollgriffschwerter) was filled with the metal, no doubt to
improve the balance of the sword which would otherwise be far too light for
the size of the blade.146 This practice remained somewhat unusual, however,
and is not present on many of the examples investigated. Lead was used to
fill spaces left by cores in casting.147 At the nuraghe of Antigori in southern
139
Schauer 1986; Gerloff 1995.
140
Kossinna 1913; Schuchhardt 1914.
141
Brłndsted 1962, 167ff., 298.
142
Eogan 1994.
143
Eogan 1969.
144
Soler García 1965; Pingel 1992, 207ff. table 70.
145
Schmidt 1915, 92ff.
146
Wüstemann 1992.
147
As with a double-looped palstave from Spain (Harrison and Craddock 1981).
Other metals 231
Sardinia, lead rivets or clamps were used to mend both local nuragic and
imported Mycenaean pottery.148 It was also used to make small objects, for
instance a block and a sword pommel at Runnymede,149 and small irregular
oblong beads, as in a unique find from Peeblesshire, southern Scotland.150 At
Auvernier there is a circular weight with a lifting loop,151 and at Antigori a
small double-axe was of lead, either votive or a toy.152 Two lead earnings were
found in grave 351 at Jelaovce, Slovakia, belonging to the Ún%1Å‚tice-Mad arovce
phase. At present, this is the earliest known lead find from Europe.153
Somewhat larger lead objects are also occasionally found, notably socketed
axes,154 and some of the Late Bronze Age Breton socketed axes have a high
lead content.155 As discussed in chapter 9, these axes may have had a votive
function, though it has also been suggested that the addition of lead was a
way of eking out copper in times of scarcity.
Inevitably, there was more lead metal in circulation than it is possible to
reconstruct from the surviving material. Some of this was in the form of
ingots, as from Fort Harrouard and sites in Brittany.156 Something of the abun-
dance of lead can be seen from a number of moulds that have either lead
adhering to them or lead traces present on the surfaces. The former, along
with the socketed axes, suggests that lead patterns may have been used in
the production process, or even that casting by  lost lead may have been prac-
tised; the latter probably reflect the use of lead in alloyed copper rather than
that of lead on its own.
Small objects of tin are also found, albeit rarely, for instance tin beads on
a necklace at Odoorn (Drenthe) and Sutton Veney (Wiltshire) and tin pins on
the dagger hilt from Bargeroosterveld (Drenthe) and the wooden vessels from
Guldhłj in Jutland.157 Its use as a decorative material on pottery in the north
Alpine area and elsewhere recalls a similar use on Mycenaean pottery;158 in
the Swiss German area, its presence does not seem to be related to any par-
ticular pottery production tradition or grave deposition pattern. An example
is that on the pottery from sites on the Lac du Bourget (Savoie).
148
Ferrarese Ceruti 1979, 248.
149
Needham and Hook 1988.
150
Hunter and Davis 1994.
151
Rychner 1979, pl. 130, 11.
152
Ferrarese Ceruti 1979, 248 pl. 1; reinterpreted as a boat model by Lo Schiavo 1986b.
153
J. Bátora, pers. comm.
154
Tylecote 1987c, 93.
155
de Lisle 1881; Briard 1965.
156
Briard 1990 1.
157
Shell n.d. [1980]; Primas 1985.
158
Primas 1985, 558; Fischer 1993; Immerwahr 1966.
232 metals
Metalworking sites
One of the most frustrating aspects of the study of European Bronze Age met-
allurgy is the almost total lack of sites with satisfactory evidence for the
processes of metalwork production. This is probably because furnaces were
slight affairs, consisting of pits with clay lining and superstructure, all above-
ground elements being destroyed at the end of the firing. Pits containing evi-
dence of such firing may, therefore, be all that survives, and unless they
contain specific indications that metallurgy took place in them (for example
through the finding of slag or metal waste) they can easily be interpreted as
something quite different. With modern excavation techniques, a number of
sites have been shown to have hosted metallurgical operations, even without
the survival of the furnace.
The remains of a furnace were found at Taltitz near Plauen in the Vogtland
of Saxony.159 In an area with many traces of Urnfield settlement, and with
both copper and tin sources close at hand, a series of pit concentrations, each
50 100 m across, led up a small side valley of the river Elster. At the north-
ernmost was found a pair of pits of sub-rectangular shape with flat floor and
steeply sloping sides, about 50 cm long and 30 cm wide, connected by a flat
channel; between the pits the floor was strongly reddened in a circular shape.
A broadening of the channel in the middle exhibited particularly strong signs
of heat, but there was no sign of slagging or sintering, which makes it likely
that this was a casting and not a smelting furnace.160
A sizeable number of Danish Late Bronze Age settlements also produced
mould and crucible fragments and bronze waste.161 It has been suggested that
Urnfield settlements can be divided into  production and  user sites in the
context of metallurgy. Many did not practise metallurgy themselves but were
dependent on neighbouring sites which did. In many others, only everyday
items were produced, such as sickles, axes and small ornaments. Fortified
sites played an especially important role in this, not only supplying them-
selves but also serving as regional recycling centres. If they also practised
crucible smelting, almost all necessary processes could have happened on
them.
Notable assemblages of metalworking debris, some with the remains
of furnaces, come from many sites, such as Fort Harrouard (Sorel-Moussel,
159
Simon 1992.
160
Comparable remains have been found at other German sites, notably Parchim (Becker 1989)
and Dresden-Coschütz (Pietzsch 1971), where bronze waste was found near the metalwork-
ing site, along with moulds, finished bronzes, bun ingots, scrap hoards and a chisel for sur-
face bronze-working. Copper ore is present in the immediate vicinity of this site too; analysis
of the slags on the site, however, ruled out the possibility that the ovens there were used for
smelting ores rather than for secondary working of copper metal. The situation in the upper
Saale valley and Orla basin in eastern Thuringia is similar, with workshop sites lying close
to copper-bearing rocks (e.g. Pössneck-Schlettwein: Simon 1982).
161
Levy 1991.
Metalworking sites 233
Eure-et-Loir)162 and other sites in central France;163 Auvernier and Hauterive-
Champréveyres, Lake Neuchâtel, and a number of other sites on the
Swiss lakes;164 the Wasserburg at Bad Buchau, Württemberg;165 Karlstein
(Berchtesgaden, Bavaria);166 Säckingen (Waldshut, southern Baden);167 Nieder
Neundorf (Niesky) and other fortified settlements of the Billendorf group in
eastern Germany;168 Velem St Vid in western Hungary;169 Hallunda, Botkyrka,
Södermanland, Sweden;170 Fiavé and Ledro, north Italy;171 and sites in Spain
(for instance Cerro Virtud (Almeria),172 El Ventorro, Madrid,173 Peńa Negra,
Alicante174 and sites of the Argaric Bronze Age175), Corsica and Sardinia (as at
162
Mohen and Bailloud 1987, 126ff. Numerous locations on this important site had traces of
metallurgical activity, both from the old, poorly recorded excavations and from the new work
in the 1980s; most date to the Early and Middle Bronze Age. These concentrate on the periph-
ery of the site, and some indicate specialisation in the production of particular forms: spear-
heads in  locus 1 , the  smith s house ; daggers, bracelets, pins and axes elsewhere; swords in
a large find made in 1984 (Mohen 1984). Fired clay structures found in both old and new
excavations are interpreted as the bases of smithing furnaces; in at least one case, the tuyÅre
slot was evident.
163
Charente and adjacent areas: caves of Queroy at Chazelles and of Perrats at Agris (Bourhis
and Gomez 1985), as well as the site at Bois-du-Roc at Vilhonneur (Coffyn et al. 1981, 29f.;
Gomez 1984). At the latter was the base of a furnace with slag from bronze-casting, at the
former clay tuyÅre and crucible fragments and moulds.
164
Wyss 1971, 123; Rychner 1987; Rychner-Faraggi 1993.
165
Moulds, hammers and a tuyÅre were found, but no sign of any metalworking location inside
the settlement itself. This has led observers to suggest that such workshops must have lain
outside the site, far enough away to avoid sparks from the furnace endangering the wooden
buildings but near enough for workers to retreat inside the palisade in time of danger
(Jockenhövel 1986; Kimmig 1992).
166
Menke 1968. Three mould fragments, for flanged axe, ingot and dagger blade, were found
with a fragment of a  tongue ingot (Zungenbarren), slag, clay fragments with slag adhering,
and pieces of ore.
167
Gersbach 1969, 38ff.; Jockenhövel 1986b, 223, 232: a large Urnfield settlement lies on an
island in the Rhine, where industrial waste is spread over a wide area, including slag, ingot
pieces, smelting crucibles, moulds, funnels and other metal waste.
168
Buck 1982: of 12 stockades certainly belonging to the Billendorf group, five have produced
evidence for bronze-working. At Nieder Neundorf a post-built house contained numerous clay
mould fragments, and both inside and nearby were tuyÅres and crucibles. Also on the site
were pins complete with runners and miscastings.
169
von Miske 1908; 1929: this site lies near sources of copper, with malachite and azurite obtain-
able on the surface on the I rottkö (Geschriebenstein) mountain, part of the Günsergebirge
range that straddles the border. On the site were found numerous bronze-working imple-
ments, including stone hammers, crucibles, tuyÅres, bun ingots, moulds, a range of bronze
hammers and chisels, a saw and various punches. Unfortunately, the excavation techniques
of the time did not permit the recovery of working installations, which must undoubtedly
have been present.
170
Jaanusson 1981; Jaanusson and Vahlne 1975; Jaanusson, Löfstrand and Vahlne 1978: in Site
13 a large building (the  workshop ) contained the foundations of six furnaces, with a further
six outside. Large furnaces were placed in a pit lined with stones, small ones rested directly
on the ground. Fired, partly vitrified, clay floors and parts of the collapsed domes were pres-
ent. In their vicinity were fragments of crucibles, clay moulds and a few bronze rods. Similar
but less extensive evidence came from Sites 69 and 76.
171
Metalworking equipment has been found in both these pile sites in north Italy, including cru-
cibles, tuyÅres and moulds. At both sites, crucibles of clay with a socket for the insertion of
a wooden handle were found (Perini 1987, 34ff.; Rageth 1974, 175ff. pls. 89 91).
172
Delibes de Castro et al. 1996 (late Neolithic).
173
Priego Fernández del Campo and Quero Castro 1992 (Beaker date).
174
Gonzalez Prats 1992 (Late Bronze Age).
175
El Argar: Siret and Siret 1887, 127f., pl. 27; Lull 1983; Montero Ruiz 1993.
234 metals
Terrina IV (Aléria) and Monte d Accoddi).176 Sites in Britain and Ireland have
also produced metalworking remains in recent years, though none has given
such extensive evidence as the continental examples listed above. These
include the Breiddin hillfort, Powys, Wales;177 Mucking North Ring;178
Dainton, Devon;179 Grimes Graves;180 Jarlshof;181 Lough Gur;182 Dun Aonghasa
(Inis Mór, Aran Islands);183 Rathgall, Co. Wicklow;184 and Killymoon, Co.
Tyrone.185
The organisation of metal production
All these metallurgical processes involve specialist knowledge, but also an
input of labour. But metal production is not a  public operation like the erec-
tion of megalithic tombs or standing stones; for space reasons, most opera-
tions can have involved only a limited number of people. At the same time,
the number of those involved in servicing the industry (woodmen, animal
176
At Aléria crucibles, slag and tuyÅres, along with an awl of arsenical copper, were found; the
copper may have come from the local source at Linguizetta (Lo Schiavo 1986, 232).
177
Musson 1991, 57ff., 147ff. fig. 60: crucible and mould fragments, fragments of copper alloy
melting slag and broken bronzes from Area B3 4 5 in the hillfort interior, from which were
recovered hearths and a complex of pits, furnace bases and working-hollows of Late Bronze
Age date.
178
Needham in Bond 1988: clay mould fragments and part of a crucible, with a little bronze
scrap, from the ditch of a Late Bronze Age circular enclosure. Similar material comes from
Springfield Lyons, Essex (not yet published).
179
Needham 1980: a large assemblage of metalworking debris in and around a pit beside mound
2. Crucible fragments, moulds for spearheads, swords and rings, and a little bronze waste,
were represented. The crucibles, which were of two distinct classes and included legged vari-
eties, gave evidence of use over a period of time because of relining and wall heightening.
180
Needham in Longworth et al. 1991: a few crucible fragments and around 150 clay mould frag-
ments were found in the Middle Bronze Age midden in the top of Shaft X. The moulds were
all, where recognisable, for basal-looped spearheads and represent certain evidence that clay
moulds were in use by the Middle Bronze Age.
181
Curle 1933 4; Hamilton 1956, 21f., 28f.: one of the houses of the Late Bronze Age settlement
produced in its last phase of use a crucible fragment, 200 mould fragments with 44 gate
pieces, other valve and casing fragments, the core for a socketed knife and a knife into which
it fitted.
182
Ó Ríordáin 1954, 400 3, 420 2: clay and stone moulds and crucibles were found in House I,
Site D, along with a few small bronzes; in Site F, a large collection of clay moulds and some
bronze waste occurred in, and was possibly associated with, a stone-walled house. A crucible
fragment and bronzes also occurred in Site C.
183
Recent excavations produced settlement evidence as well as clay moulds for Late Bronze Age
swords, spearheads, axes, pins, bracelets and other objects, and crucible fragments, in a hut
whose walls extend under, and thus predate, the stone fortification wall, which is usually
attributed to the Iron Age (Cotter 1994).
184
Raftery 1971: more than 400 clay mould fragments, including those for swords, spearheads
and tools, and lumps and bars of bronze, occurred in an area with nine large hearths near the
round-house in the innermost area of the fort; a large mould fragment was found in one of
the hearths.
185
This consisted of an area of grey ashy soil deriving from three mounds full of baked clay and
charcoal (Hurl 1995). Bronze and gold objects, spindle-whorls, polished stone axes, saddle
querns, clay moulds and stone hammers and polishers were found, the datable objects belong-
ing to the Dowris phase.
The organisation of metal production 235
handlers and others) would have meant that the workforce was far from
negligible. Estimates have been made of the number of workers who might
have serviced the Mitterberg production, a figure of 180 allegedly accounting
for all those needed for transport, haulage and timber erection as well as min-
ing, in a  mining-unit comprising three open-casts ; a figure of 500 600 was
suggested for the whole Salzburg mining region.186 Shennan uses ethnographic
and historical sources, and an estimate of 10 tonnes output of copper per
annum, to suggest that 270 400 people could have been involved in the pro-
duction at the Mitterberg, making allowance for those not engaged in the
activity and for time spent on other activities such as food production.187 The
figure compares well with his estimate of a population on the settlement site
of the Klinglberg at St Veit near Bischofshofen of 40 100; the Klinglberg is
one of three such sites in the area. It is certainly possible, however, in view
of limitations on space in the mines themselves, that the numbers involved
were smaller still. The mode of operation at Mount Gabriel was probably also
distinctly limited. If, in contradiction of the inflated figures produced by
Jackson, these mines were worked for around 200 years, producing as little
as 15 kg of copper per annum (enough for around 46 bronze axes), the scale
of production was potentially much smaller than would appear at first sight.188
Was the access to ore sources controlled? There is little or no sign that the
maintenance of life was centralised, at least in the earlier stages of the Bronze
Age, but one can argue that from an early stage there were defined notions
of territoriality which would include control of resources, while the input of
labour and energy involved in initiating mining was such that control would
not have been relinquished lightly. By contrast, the  direct access model
would envisage that human groups could have come to a mine and exploited
it as and when they wanted, on a seasonal basis. It must be a task for Bronze
Age research in the coming years to try to understand by what means deci-
sions to undertake mining operations were taken, and how the procurement
of a given quantity of ore then led to the production of a given number and
type of axes or other products. What transactions occurred between the pro-
duction of raw copper and the conversion into objects? Were the miners and
the smiths one and the same?
Shennan has attempted to answer some of these questions as a consequence
of his excavation of the settlement site of St Veit-Klinglberg in the Salzach
valley of central Austria.189 Analysis of metal waste ( casting cake ) on the
site, and of the slag temper in pottery, showed that more than one metal
source was being exploited by the occupants of the Klinglberg, either through
186
Zschocke and Preuschen 1932; Pittioni 1951.
187
Shennan 1995, 300ff.
188
O Brien 1994, 195ff., 235ff.; Jackson n.d. [1979].
189
Shennan 1995.
236 metals
exchange with other neighbouring groups or by Klinglbergers spending time
away from their home base. What is more, cereals found on the site suggest
that foodstuffs were imported and therefore that productive workers were
devoting their time to mining rather than agriculture. This fits a picture of
rapid expansion of work in the Mitterberg mines, with deeper sulphide ores
coming into use for the first time in the Early Bronze Age. By the Middle
Bronze Age, settlement sites considerably larger than the Klinglberg are
known, reflecting an increase in productive effort by a further order of
magnitude.
If little is known about miners, there is not much more known about
smiths, artefacts being the main source of evidence with which to reconstruct
their mode of operation. Childe s model has been widely adopted, implicitly
or explicitly, in many works dealing with the Bronze Age.190 According to this
model, the smith was an itinerant specialist, his skills restricted in distribu-
tion and therefore carefully guarded. As smithing was a full-time occupation,
the rest of society provided for the smith in return for the products of his
craft. He was itinerant  peripatetic would be a better description  in the
sense that he travelled from village to village, setting up his workshop and
casting his products in each place as he came to it; he did not operate from
a central workshop.
There are a number of reasons why Childe and others adopted this model.
First, there seemed to be no evidence for permanent workshops from which
smiths might have operated. Bronze Age villages were invariably small-scale
and dependent on agriculture, with no sign of an industrial component to
their economies. Second, the relative scarcity of raw materials in many parts
of Europe meant that special access to supplies had to be organised; for a
peasant farmer it would be better to leave this in the hands of a specialist
who could move between suppliers and users as required. Third, and most
important, was the evidence of bronze hoard deposition, where hoards of bro-
ken or miscast bronze objects were collected together, apparently for remelt-
ing and recasting into new objects. Such finds were thought to be the
stock-in-trade of a smith, travelling between communities and recovering his
stock at each stop. Alternatively, the metal might have belonged not to the
smith but to the village or community. In this case, the metal would not
need to be transported about, but the failure to recover the stock is no less
puzzling. The problem is that this model is rarely, if ever, supported by ethno-
graphic evidence.191 Although smiths could sometimes be peripatetic, their
travels were determined not by free enterprise on their part but as part of a
wider settlement system under the control of a local chief; other examples
190
Childe 1930, 44f.
191
Rowlands 1971.
The organisation of metal production 237
show that smiths are resident within communities and practise their craft on
a seasonal or part-time basis. Certainly there is nothing to suggest that the
pattern of hoard deposition that is seen in the Bronze Age finds any reflec-
tion in recent practice in Africa or Asia.
Detailed analysis of individual bronze objects, in particular that relating to
smithing traditions and  industries , sheds some light on the matter. Ideally
one would seek to show which products were made by which smith, and over
what time-scale. Since that is probably too ambitious a task, one should per-
haps settle for indications that a particular working tradition, in other words
a workshop, was responsible for certain objects.
In the case of the Middle Bronze Age metalwork of southern England, the
restricted distribution of bronze types suggests that production was local in
nature and probably seasonal.192 Some of the hoards of palstaves, for instance,
contain large numbers of  blanks of the same sub-type, indicating that a sin-
gle operation would have been responsible for the production of a large num-
ber of identical pieces. This, together with the evidence for fixed facilities for
hot-working, suggests that permanent workshops were the norm. A study of
the so-called Stogursey socketed axe (formerly known as the south Welsh
axe), characterised by a decoration of three ribs, a simple moulding round the
mouth, and a side loop that is placed high up on the axe, shows that they
are found thinly scattered in southern England and rather more densely in
south Wales.193 Stone moulds for such axes occur on five widely separated
sites between Cornwall and Surrey; two different sorts of stone have been
used, one restricted to Cornwall, the other found in central southern England.
Local production of these axes thus probably took place in Devon and
Cornwall, in central Wessex and probably also in Somerset, but in south
Wales, where axes are most prolific, there are no mould finds and thus no
direct evidence for production.194
Attempts have been made to identify Hungarian workshops on the basis of
objects coming from identical moulds and on similar decoration on different
objects.195 Two daggers from the Kelebia find, apparently from the same
mould, the swords from Apa and HajdÅ›sámson, the decoration on the ends
of disc-butted axes and many other examples make it highly likely that a sin-
gle production location, and perhaps also a single artist, was responsible for
their creation. Further, the finding of a number of hoards of unfinished objects
together with objects from the same mould, such as the socketed axes in
192
Rowlands 1976.
193
Needham 1981a; 1990.
194
At Petters Sports Field, a mould of this type was of non-local stone and perhaps introduced
to the Thames Valley by a smith working in the Bulford Helsbury tradition of central and
south-western England.
195
Mozsolics 1967, 102ff; 1973, 84ff.
238 metals
the hoard from Drajna de Jos (Prahova, southern Romania), illustrates the
point.196
Production centres of some sort clearly did exist. What may be questioned
is the scale of the enterprise, along with the location of the activity. As shown
above, most smithing operations seem, from the scanty traces which they
left, to have been on an extremely modest scale, the furnaces and the crucibles
being rather small and thus likely to have serviced very limited amounts of
metal at one time. Where there are no traces of metalworking at all, one is
forced to rely instead on the distribution patterns of the objects produced, the
general principle being that the production workshop should lie in the cen-
tre of the distribution, or where it clusters most thickly. Particular tricks in
the formation of the hilt suggest the existence of workshops for the produc-
tion of Early Bronze Age swords in the Nordic area, centring on Denmark.197
The distribution of solid-hilted antenna swords of the Tarquinia type is con-
centrated massively in north Italy, where the rich centres of the emerging
Iron Age were able to commission and absorb large quantities of prestige met-
alwork;198 it would be amazing if these particular swords had been produced
anywhere other than Etruria. On the other hand, when one takes all the dif-
ferent sub-varieties of antenna sword into account, the picture is somewhat
different: although Italy still looms large, other types are distinctly trans-
Alpine in distribution, most notably the Zürich and Lipovka types.199
But bronze types of the same general form can have an extremely wide dis-
tribution, even if detailed sub-types are restricted to a narrow area. This raises
the question of how such knowledge was transmitted from area to area; how
smiths came to produce such closely similar objects in widely separated parts
of Europe. Of many examples which could be examined, one of the most
remarkable is the flange-hilted sword of the early Urnfield period.200 Almost
identical forms are found from the East Mediterranean, the Balkans, Italy,
central Europe and western Europe. In part, the necessity of weapon mod-
ernisation may be responsible (one cannot afford to let one s armoury become
obsolete, either in the Bronze Age or today), in that the warriors who actu-
ally wielded these swords presumably demanded weaponry that could com-
pete with that of their rivals. But if one is to deny the existence of peripatetic
smiths, as the discussion above has suggested, the knowledge of bronze forms
in different areas must spread by movement of the actual objects. The cur-
rency of bronze swords and hanging bowls in Denmark showed very differ-
ent amounts of wear or resharpening, which may be due in part to the length
196
Petrescu-Dîmbovica 1978, 111f., no. 103, pl. 66.
197
Ottenjann 1969.
198
Müller-Karpe 1961, pl. 101.
199
Ibid. pl. 97.
200
Harding 1984, 162ff.; Bouzek 1985, 119ff., both with full refs.
The organisation of metal production 239
of time they were in circulation.201 This differs in different parts of Denmark,
suggesting that there was differential access to supplies according to the local
conditions in various parts of the country.
The custom and community of bronze-smithing thus documented demands
explanation. Whether, as has sometimes been suggested, smiths had a  men-
tal template in their production processes which resulted in the remarkable
standardisation of forms which is seen, whether the exchange of moulds or
patterns was responsible, or whether the copying of metalwork seen else-
where is involved, the end result was often extraordinary.
In all this, the position of the smith himself remains uncertain, and his
identity and mode of functioning shadowy. The smith is in many traditional
societies a valued, if feared, craftsman (almost all ethnographic examples are
of men), essential for the well-being of a community in many spheres  war-
fare, agriculture, carpentry, as well as the production of  non-essential items
such as jewellery or religious goods. In weapon and agricultural tool produc-
tion, societies depended in a very direct way on his labours. When one
attempts to understand these matters, it is ethnographic examples from recent
or historical times, usually relating to iron-working, that provide the main
source of evidence and, suggestive though these may be, there is no guaran-
tee that they are at all relevant to the Bronze Age. The elements of skill and
restricted knowledge that the smith s art involves, and the processes by which
this knowledge could be passed on to others, have often been stressed.202
Ethnography tends to indicate that this is usually done in the context of kin-
based social structures and that, the more developed the level of social hier-
archisation, the more likely it will be that craft specialisation will apply.
As an epitaph for the smith, we may recall those graves that contained
pieces of equipment belonging to the metalworking process. A famous exam-
ple comes from Kalinovka in south Russia, but there is a series of graves in
central Europe with ore pieces, tuyÅres, crucibles, ingots or bars from Urnfield
and early Hallstatt contexts.203 At Kalinovka kurgans 8 and 55 (Dubovka,
Volgograd), two kurgans (barrows) of the Poltavka phase of the earliest Timber
Grave culture contained conical tuyÅres, crucibles, moulds and grindstones,
apparently the graves of smiths.204 The collection of stone polishers from a
grave at Hesselager on Funen has already been mentioned.205 The significance
of these graves may indicate the occupation of the deceased and the intimate
connection of smithing tools with particular individuals. Their presence may
imply special status for the smith, or that aspects of the smithing process
were connected with votive acts (see chapter 9). Given the important role
201
Kristiansen 1977; 1978.
202
e.g. Williamson 1990.
203
Jockenhövel 1982b.
204
Shilov 1959a; 1959b; Gimbutas 1965, 546ff.
205
Randsborg 1984.
240 metals
that the smith must have played, it would not be surprising to find special
treatment accorded him in death, as perhaps in life.
Epilogue: the change to iron
During the later stages of the Bronze Age, increasing numbers of iron objects
were being produced, especially in the eastern half of Europe but also in the
south, where East Mediterranean influences have been suspected.206 A few
pieces in iron were indeed present much earlier, in the Early Bronze Age, as
with the famous dagger from a well at Gánovce in Slovakia.207 It is commonly
supposed that this iron must have come from Anatolia, though nothing is
known of the processes by which this could have occurred. Certainly there
is no indication of a local iron-producing industry in Europe at this time. A
case has, however, been made, based on the evidence of the finely incised
lines on some Urnfield bronzework, that iron tools for decorating bronze were
in use much earlier than has otherwise been supposed.208 Since the earliest
examples of a phenomenon are the hardest to recover archaeologically, there
is nothing inherently unlikely in this argument.
By the late Urnfield period, there was a significant number of iron objects
in use, both in eastern and southern Europe and also in the centre and north.209
In Sweden, finds of iron slag on Late Bronze Age sites (from Period IV onwards)
indicate local working, taken to mean that iron technology was adopted by
local bronze-smelters, by means of contact and exchange of ideas with  for-
eign metalworkers , clear indication that the preferred model for the intro-
duction of iron-working is the  immigrant model of Alexander.210 Iron in the
north is here seen as a functional, not a prestige, metal from the start, being
used for minor cutting tools. Its ready availability led to its widespread adop-
tion and the falling-off of long-distance trade routes which had brought cop-
per metal to parts of Europe distant from the mining areas.
The process of transition to a full iron-using technology was a gradual one,
and there are few signs that iron had any great impact on Bronze Age
economies. At the same time, it has been suggested that the main reason for
the enormous number of bronze hoards of the latest, Ewart Park, phase in
Britain was the introduction of iron, and the consequent dumping of bronze
(see chapter 10).211 Certainly by Ha C, iron became the dominant metal for
everyday use and was also in use for weapons and some ornaments. The
206
Pleiner 1980; 1981; Waldbaum 1980; Delpino 1993.
207
Vl%0Å„ek and Hajek 1963; Taylor 1989.
208
Bouzek 1978; Drescher (1956 8) used similar arguments.
209
László 1977; ović 1980; Bouzek 1978; 1985; Kimmig 1981; Furmánek 1988; Bukowski 1989;
Hjärthner-Holdar 1993.
210
Hjärthner-Holdar 1993; Alexander 1981; the other models are peaceful introduction and war-
like introduction.
211
Burgess 1979.
Epilogue: the change to iron 241
decline of bronze was only the most obvious of the many elements of ma-
terial culture that underwent a major transformation in the eighth and sev-
enth centuries BC, and which would naturally be the subject of a book
describing the ensuing period, the Age of Iron.


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