chapter
5
Methods, Means, and Results when Studying European Bone Industries
Alexandra Legrand
Université de Paris I, France
Isabelle Sidéra
Centre national de la recherche scientifique (CNRS), France
function, it is a major design system criterion, as
Chippendale suggested (1986). This explains the
special attention given to technological study.
Introduction
What are the subjects of study, the methods, criteria
and results in technological and use-wear studies?
The examination of about ten thousand bone tools,
provided by Neolithic and Chalcolithic sites from
Bulgaria to France, including those of the Aceramic
Neolithic in Cyprus, will be taken into account to
answer these questions. This is done in a continuous
effort to study new collections with the aim of testing
and enlarging our knowledge about these artifacts.
Technology
Technological categorization is the first method to be
implemented (see Billamboz 1977; Christidou 2001a;
Legrand 2005b; Louwe Kooijmans et al. 2001;
Murray 1979; Poplin 1974; Sidéra 1993a, 2005; and
Stordeur 1974, for example). It proceeds in three
principal steps: 1) technical identification (sawing,
knapping, grinding etc.), 2) cutting procedures
(metapodial divided in two, three or four parts), and 3)
characterizing technical methods (fig. 1). Measuring
the ratio between the investment in débitage and the
degree of shaping may be added to make the
technical portrait of a given assemblage (Sidéra 2000,
2001; Stordeur-Yédid 1976). The use of microscopy
is always necessary to understand which techniques
are employed and how traces overlap. This also
enables the reconstruction of the manufacturing
processes. Technical methods, which are to say,
characterized stable manufacturing processes
involving different techniques, are most important.
Because of the strong morphological and technical
homogeneity of Neolithic bone artifacts, technical
methods appear to be efficient criteria for integrating
bone assemblages into the cultural range (Sidéra
2004, in press). This provides feedback for
archaeological interpretation. Questions such as
cultural practices, innovation, relationships between
different traditions and transfers from one culture to
another can thus be addressed with greater
accuracy. Secondly, as technology is the link
between raw material, morphology, styles and
Figure 1: Manufacturing methods for metapodials. 1) Southern
France Middle Neolithic (Montbolo) method: both sides are sawed
from one extremity of the bone to the other, after which each halves
are grinded. Archaeological artifacts from Corbères-les-Cabanes
“grotte de Montou” (Pyrénées orientales, France: F. Claustre-CNRS
excavations). 2) Aceramic Neolithic of Cyprus method: both sides are
partially sawed, then knapped, and then each halves are grinded.
Photos by I. Sidéra.
The awl manufactured on a half ruminant metapodial,
which preserves the distal epiphysis as a handle,
gives a good illustration of the interaction between
techniques and methods. It is a very common tool,
which spread from the Near Eastern Aceramic
Neolithic to the Western European Chalcolithic (see
awl in fig. 1). The techniques employed to make it
and, as a result, the morphology of this type of awl,
have a small range of variation within the chronologies
and cultures. There is little or no stylistic variation.
Methods are much more characteristic than
techniques and morphology in this case. In southern
France Middle Neolithic, for example, most awls of
this type are sawed on both sides from one extremity
to the other (Sidéra in press), whereas in Cypriot
67
BONES AS TOOLS: CURRENT METHODS AND INTERPRETATIONS IN WORKED BONE STUDIES
conditions. In addition, we led some of the
experiments in collective program and found that
cooperation is necessary for success.
Aceramic Neolithic, they are often partially sawed and
then knapped with a chisel and a hammer (fig. 1)
(Legrand 2005a). At the end of the Linear Pottery
Culture, in the Paris basin, the method of sawing one
side and knapping the other was just introduced and
it developed to produce the same type (Sidéra
1993a). These methods have been reproduced and
their results were compared with the original artifacts.
The main problem is to acquire long lasting used
artifacts, close to the original, which are often
extremely modified by use. Time dimension cannot be
measured by wear and this constitutes a major
problem. As a solution, ethnographic artifacts can be
studied, but as their exact function and duration of
use is not often clear, they are not always available.
Experimentation
Experiments are currently targeted on either
manufacture or functional questions (Barge 1982;
Camps-Fabrer H. et al. 1977; Ettos 1985 and 1991;
Nandris and Camps-Fabrer 1993; Maigrot 2001;
Schibler 2001; Sénépart 1991) or, as Keeley argued,
“real time" experimentations (1980). For clarifying
initial usage conditions, precise contextual and
environmental information such as fauna, vegetation
or sources of raw materials need to be taken into
account (Campana 1989; Lemoine 1997; Meneses
Fernandez 1993; Sidéra 1993a). Bone artifact copies
are also needed for use in specified tasks: perforating
bark (fig. 2.1), scraping skin to make leather, digging
wood (fig. 2.2), weaving a belt (fig. 2.3), etc.
Parameters such as the nature of the bone (fresh, dry
or heat-treated), hide state (rough or tanned), wood
state (fresh or dry) and wood textures and density
(tough or soft) can change the results. All of these
experiments aim to document; 1) the most frequent
archaeological artifacts; 2) the types of tools and
materials rarely explored, such as needles, awls and
soft vegetal fibers (Legrand 2003, in press); and 3) the
greatest variety of material worked, the different kind
of tools available to illustrate the largest range of usewear traces (Peltier 1986; Peltier and Plisson 1986).
We have tested 120 tools and objects in such
Functional Approach
Since the 80's, functional analysis based on
experimentation is common, serving different goals. A
majority of studies deals with the description and
characterization of individual tools or bone surface
alterations (Aimar et al. 1998; Christidou 1999;
d'Errico 1991, 1993, 1996; d'Errico and Villa 1997;
d'Errico et al. 1985, 1995; Ettos 1991; Meneses
Fernandez 1993, 1994; Olsen 1989, 2001; Stordeur
1983; Stordeur and Anderson-Gerfaud 1985). Fewer
studies tend to undertake whole assemblages with
the view of answering historical, anthropological and
cultural questions at the same time (Campana 1989;
Legrand 2005b; Lemoine 1997; Maigrot 2003; Sidéra
1989). For all these purposes, both low and high
power analysis are used. Their efficiency depends
either on the development of use-wear or on the
functional end shape of the tools and naturally, on the
previous questions. The criteria used in the different
optical methods for gathering information about the
nature of the material worked and about artifacts,
their use, and hafting, as well as their respective
contribution, complementary and interaction, will be
discussed below.
Figure 2: 1) Perforating bark with a bone awl by indirect percussion; 2) digging wood with an antler axe; 3) weaving with a bone awl. 1, 3:
Experimentations and photos by A. Legrand. 2: Experimentations and photos by I. Sidéra.
68
METHODS, MEANS, AND RESULTS WHEN STUDYING EUROPEAN BONE INDUSTRIES – LEGRAND AND SIDÉRA
Macro-wear
or sharpening can be deduced, depicted and
measured at this scale of magnification. For example,
because of their limited and concave active edge,
tools like scrapers, which have worked narrow
materials such as wood or bone - we know of some
ethnographic tools in Papua New Guinea - have been
easily identified in the European Neolithic period (fig.
3) (Sidéra 1995). Concavity also marks pottery
scrapers (fig. 4), as it modifies the course of some tips
(fig. 5).
The low power examination is first executed with the
naked eye and with a stereomicroscope at the most
common magnification range of 10x to 80x, but
sometimes up to 130x. Concepts and analytical
criteria have been specifically investigated during the
1980's (Campana 1989; Maigrot 1997 and 2003;
Meneses Fernandez 1994; Sidéra 1989, 1993a,
2000; Stordeur 1983, 1989). According to S. A.
Semenov (1964), who founded use-wear analysis, the
principle consists of marking all deformations
occurring on artifacts: “volume alterations" (Sidéra
1993a). The plastic property of bone and its softness,
compared to stone, lead to a rapid and characteristic
recording of a given work. This involves a proper
methodology, which differs significantly from the lithic
use-wear analysis process. Different traces such as
scratches, new surface aspects (polish or coloration)
and flaking appear during the first minutes of the
tool’s use. Later, smoothing and deformations of the
contours occur according to the material worked, its
nature and shape, and kinematics. These
deformations, which come from either wear, shaping
Functional diagnostic elements such as smooth
contour shapes and cutting edge profile are useful
when observed at 20x to 80x magnifications (Sidéra
in progress) (fig. 6). Let us cite some examples
yielded by a Linear Pottery site; Cuiry-lès-Chaudardes
in the North of France. Two types of hide scrapers
made of bone were identified (Sidéra 1989 and
1993b). There, we dealt with a similar type of tool,
with the exception of their bevelled shape (fig. 7). The
first one is flat-sided, bevelled, sharp-edged, with
numerous short, broad, straight scratches which
correspond to frequent resharpening (fig. 7.1). It was
used for fleshing hides, which were perhaps laid
Figure 3: Archaeological pig tusk scraper from Mareuil-les-Meaux (Seine-et-Marne, France: R. Cottiaux–INRAP excavations). Progressive
enlargement of the end part of the tool. At naked eye and at 5x magnifications, see the concave and notched appearance of the active edge.
From 35x to 63x magnifications, numerous and developed crossed and perpendicular striations and a micro-smoothing appear on the edge.
Drawing and photos by I. Sidéra.
69
BONES AS TOOLS: CURRENT METHODS AND INTERPRETATIONS IN WORKED BONE STUDIES
use mode, has to be investigated as well. Different
types were distinguished, involving specific traces
localized on either the bottom or the entire length of
the tool (fig. 10). We noticed that the proportion of the
archaeological hafted artifacts is quite stable, about
20% in all European Neolithic cultures. Only the types
of artifacts differ. Antler tine picks and hide skin
scrapers were mainly hafted in the Early Neolithic of
Northern France (Linear Pottery Culture). This was
due to functional constraints for pick antlers, used to
dig soil, and economical factors for hide working
which represented an important investment for this
culture. Later, in the Middle Neolithic Chasséen and
M i c h e l s b e r g , as woodworking increases and
diversifies, a real variety of hafted instruments appears
(fig. 11). Hafts are mainly tenons, directly fastened on
the tools, and previously perforated (fig. 11.1, 11.2,
11.4, 11.6, 11.7). Riveting also comes into view at the
beginning of the Middle Neolithic Cerny (Sidéra 2000,
2001: fig. 3.7 to 3.9) (fig. 11.3).
down on a block of wood (fig. 7.A). The second type
is a convex-sided, bevelled tool, which was highly
smoothed and lightly polished, with thin, long and
curved scratches (fig. 7.4). It was used with a
pendulum movement during a later step of the work,
probably to soften the hide stretched on a frame (fig.
7.B). In both cases, the bevelled forms result not only
from use but also from shaping and resharpening,
whilst respecting the original shape (fig. 7.1).
Figure 4: Archaeological bone pottery scraper from Corbères-lesCabanes “grotte de Montou” (Pyrénées orientales, France: F.
Claustre-CNRS excavations). At 40x magnifications numerous, broad,
long and straight striations appear perpendicularly to the edge.
Drawing and photos by I. Sidéra.
All these interactions between manufacture, use and
resharpening are complex and need to be understood
to achieve a functional interpretation. Thus, the
restoration of the wear process, by means of a chaîne
d'usure based on the valuation of the degree of use
of a number of artifacts of the same type, allows us to
understand the use mode of the artifact (Sidéra
1993a, 2002) (fig. 8). The contour deformations are
often accompanied by other volume alterations like
different types of smoothing, chipping, crushing and
surface alterations such as polish and striations (fig.
9). Finally, surface and volume deformations ought
not to be separated. Let us return to the examples of
the wood and pottery scrapers to illustrate this point.
The main difference between them are the notches
and chips visible along the edge for the wood or bone
scraper, and the long, numerous and parallel
striations which cross perpendicularly the edge of the
pottery scraper (fig. 3 and 4).
Figure 5: Archaeological perforating tool from
Cuiry-lès-Chaudardes (Aisne, France, ERA 12
excavations). Deformation of the awl tip due
to use and resharpening and materializing the
course of the tip. Photos by I. Sidéra.
The handling mode, important for defining the artifact
70
METHODS, MEANS, AND RESULTS WHEN STUDYING EUROPEAN BONE INDUSTRIES – LEGRAND AND SIDÉRA
Figure 6: Archaeological flesher, up and low sides and profile. See the shape profile characterized by a symmetric smoothed micro-bevel and a
sharpened extremity. Drawing and photos by I. Sidéra.
Figure 7: Archaeological and experimental hide scrapers. 1) Archaeological ribbon flesher type 1, flat-sided bevel with sharp-egded and
numerous striations due to resharpening from Cuiry-lès-Chaudardes (Aisne, France, ERA 12 excavations; 2) experimental and used replica of
the flesher with short, broad and straight striations on the active end; 3) experimental and used replica of the convex-sided bevel with thin, long
and curved striations on the active end; 4) Archaeological long bone softener type 2, convex-sided bevel from Cuiry-lès-Chaudardes (Aisne,
France, ERA 12 excavations archaeological. A) Flesher use mode. B) softener use mode. Photos and experimentation by I. Sidéra. Drawings by
G. Deraprahamian.
Low power examination is not always efficient for
functional interpretation. The case of awls is the most
significant. The macroscopic features observed on
their active end show a slight difference from one awl
to another and thus do not reveal the nature of the
material worked and the tool action. It must be
remembered that low power examination is most
efficient on well-worn artifacts, which display a
tangible volume deformation and well-developed
traces.
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BONES AS TOOLS: CURRENT METHODS AND INTERPRETATIONS IN WORKED BONE STUDIES
and continuous chain of analysis. It uses the most
common reflexion microscope with magnifications of
100x and 200x as lithic use-wear analysis specialists
do, or SEM microscopy sometimes combined with
residue analysis (see for example Aimar et al. 1998;
Christidou 1999, 2001b; d'Errico et al. 1995; Legrand
2003, 2005b; Lemoine 1997; Olsen 2001; Peltier
1986; Stordeur and Anderson-Gerfaud 1985). Our
equipment includes a reflexion microscope (Nikon
Eclipses ME600) connected to a computer to acquire
images via digital cameras (KS300 software and
Axiocam, Zeiss) (fig. 12).
Figure 8: Chaîne d’usure realized on a series of archaeological
perforated deer canines from Val-de-Reuil (Eure, France). From Sidéra
2002, figure 10 p. 224.
Figure 9: Different macro-wear on cutting edges from Drama
(Bulgaria, Pr Lichardus, Sarreebruck University excavations). 1)
chipping, smoothing, polishing and striations; 2) crushing with
separation of bone fibers. Photos by I. Sidéra.
Figure 11: Reconstructions of different kinds of tool hafting. 1, 2, 4, 6
and 7) Hafts are mainly tenons directly fixed in perforated axes or
scrapers; 3) haft is fixed by riveting; 5) the adze is attached to the
haft. Drawing by D. Thébault.
Figure 10: Hafting reconstructions and traces. Archaeological mattock
from Boury-en-Vexin (Oise, France, R. Martinez-INRAP excavations)
with “festons” all along the tool. These traces are due to the hafting
apparatus, probably an envelope made of bark or hide, fastened
around the tool with thongs, made to protect the mattock from
breaking. The friction of the envelope has produced the feston, whose
development is perhaps due to the inententional deep initial shaping
traces. At the same time these traces reflect the long duration of this
tool. Photos by I. Sidéra. Drawing by D. Thébault.
Figure 12: High power equipment with image processing. Photo by I.
Sidéra.
We will illustrate the significance of high power
analysis through the examination of two experimental
awls, both replicas of artifacts coming from the
Khirokitia bone assemblage (Aceramic Neolithic, 7th
millennium B.C cal., Cyprus) (Legrand 2005b;
Micro-wear
High power examination is part of a complementary
72
METHODS, MEANS, AND RESULTS WHEN STUDYING EUROPEAN BONE INDUSTRIES – LEGRAND AND SIDÉRA
Stordeur 1984). One awl was used to perforate fresh
sheep hide (tool number 1), the other to perforate wet
bark (tool number 2). Use-times were respectively 65
and 10 minutes. In both cases, indirect percussion
was used. Microscopic descriptions are largely
inspired by the terminology employed by R.
Christidou (1999). Other criteria such as use wear
were also considered (Legrand 2005b, in press;
Sidéra and Legrand 2006).
and polishing of the tip and the same usedevelopment in three zones (fig. 13-1 and 14-1). The
first zone is the tip area. It is characterized by the
absence of manufacturing traces down to 2 mm from
the tip of tool number 1 and approximately 7 mm
from the tip of tool number 2. Numerous usestriations, which cross the polished surface, become
clearly visible with a 32x magnification (fig. 13-2 and
14-2). They are longitudinal, quite long and parallel to
the long axis of the awl. Some micro-pits are also
observed. 2) Further down from the tip, use
characteristics are the same as the ones described
When observed with the naked eye and at 15x
magnifications, both awls exhibit the same smoothing
Figure 13: Macroscopical and microscopical features on experimental awl (number 1) created by fresh hide working. 1) whole awl and
enlargement of the tip. 2) First zone of use on the tip. 3) Second zone. 4) Third zone of use. Experimentations and photos by A. Legrand.
73
BONES AS TOOLS: CURRENT METHODS AND INTERPRETATIONS IN WORKED BONE STUDIES
above, except for the presence of smoothed
manufacturing traces perpendicular to the long axis of
the awl (fig. 13-3 and 14-3). On the third zone, the
intensity of smoothing and polishing decreases as
one gets closer to the limit of the use, which is
located at 40 mm from the tip on tool 1 and 19 mm
from the tip on tool 2. Wear affects only high points of
the surface, and rough-bottomed manufacturing
traces are clearly visible (fig. 13-4 and 14-4).
examination of the tip of tool number 1 shows an
irregular topography due to the variety in dimension
and direction of the depressions, striations, micro-pits
and craters. At 200x magnification, the high points
are smoothed and varnished with a domed profile (fig.
13-2). Numerous fine (1 μm), short or long, superficial
and continuous striations are observed. Other
striations are broad (3 μm), long, deep and
continuous. Their bottom end is rough but more or
less unaffected by polish. In both cases, striations
show smoothed edges. Some circular roughbottomed craters (from 9μm to 27μm in diameter) are
also observed. These can be similar to the broad
This wear development is still clear at high
magnifications but differences in use-wear patterns
appear between both awls. At 100x magnification, the
Figure 14: Macroscopical and microscopical features on experimental awl (number 2) created by fresh bark working. 1) whole awl and
enlargement of the tip. 2) First zone of use on the tip. 3) Second zone. 4) Third zone of use. Experimentations and photos by A. Legrand.
74
METHODS, MEANS, AND RESULTS WHEN STUDYING EUROPEAN BONE INDUSTRIES – LEGRAND AND SIDÉRA
striations, more or less polished with smoothed
edges. All these depressions, which cross the high
points, give them a certain grainy aspect.
Conclusion
Dealing with numerous criteria and a variety of
investigations, the functional approach needs
cooperation between scholars. Wear analysis is
based on a sum of analytical criteria which lead
progressively to the identification of the function of the
bone tools. We now try to collaborate on a
continuous magnification chain of examination, based
on experiments. Understanding interactions between
macro- and micro wear analysis will bring, we hope,
in the future, a use-wear analysis model, which will
enable us to identify the majority of bone artifact
functions. Macro-wear analysis deals mainly with
"volume deformations" and, thus, with well-used
artifacts involving use-wear processes. High power
analysis is necessary if “volume deformation” is lightly
developed. As a result, surfaces must be enlarged for
observing polish and striations details. This is
particularly true for tools such as awls, needles,
hooks, spoons, etc. which are worn by friction.
Sometimes chemical analysis can help to identify a
tools function. Computer use is valuable for this
purpose and has changed our way of working. It
permits us to quantify micro-phenomena and create
image banks. This will involve more frequent contact
between researchers than in the past and will be of
great benefit to technological and use-wear research.
Further from the tip, the micro-wear features are quite
similar to those observed on the tip area (fig. 13-3).
Use-striations, micro-pits and craters can affect the
highest smoothed manufacturing striations. Craters
are more numerous than in the first zone.
In the last zone, rough-bottomed manufacture
striations are very evident. They cannot be confused
with those resulting from use due to their width and
depth. The high points are smoothed and are still
crossed by numerous longitudinal use-striations (fig.
13-4). However, craters have disappeared.
At 100x magnification, the tip of tool number 2 shows
a regular topography due to a flat, bright and grainy
surface covered by a dense network of unidirectional
striations. At 200x magnifications, these are relatively
fine (1 μm), long, superficial and continuous (fig. 142). Only few transverse, superficial and fine striations
are present. Frequent micro-pits and craters with
various dimensions (from 9μm to 34μm) are observed.
The smaller craters are partially affected by the polish,
but all have smoothed edges.
Further down from the tip, where manufacturing
striations appear, the surface is marked by the same
micro use-wear (fig. 14-3). However, rough-bottomed
craters with smoothed edges seem to be more
numerous than in the tip area.
Acknowlegements
Thanks to Graham Williams for reviewing the English of our
paper.
Then, in the last worn zone, the topography appears
irregular because of deep, large and rough-bottomed
manufacture striations and depressions, which cover
the major part of the surface (fig. 14-4). The same
longitudinal use-striations cross the highest points,
which are quite smoothed and varnished.
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