Fragments of oenochoe GV132-01/US26-obj.10
Christian. Degrigny (HE-Arc CR, Neuchâtel, Neuchâtel, Switzerland) & Sandra. Gillioz (HE-Arc CR, Neuchâtel, Neuchâtel, Switzerland) & Valentin. Boissonnas (HE-Arc CR, Neuchâtel, Neuchâtel, Switzerland)
Base of an oenochoe (Fig. 1) developing locally green corrosion products covered or not with sediments. Dimensions: L = 82 mm; W = 74 (after degradation) ; T =6,5 mm; WT = 30,9 g.
Place Simon-Goulart, Genève, Geneva, Switzerland
Service cantonal d’archéologie, Genève, Geneva
Service cantonal d’archéologie, Genève, Geneva
The schematic representation below gives an overview of the corrosion layers encountered on the oenochoe base from visual macroscopic observation.
The sample was cut from the edge shown in Fig. 2. Its dimensions are L = 6.5 mm, W = 1.5 mm. The sample contains some remaining metal covered with a crust and a voluminous pustule corrosion (Fig. 4).
Cold worked with repeated annealing and final cold working
HECR 1455 – S2
HE-Arc CR, Neuchâtel, Neuchâtel
Musée cantonal d’archéologie et d’histoire, Lausanne, Vaud
2013, metallography and chemical analyses
Metallography (etched with ferric chloride reagent), SEM-EDS.
The remaining metal is a tin bronze (Table 1). The etched metal shows a structure of polygonal grains with twinned and strain lines (Fig. 8).
Table 1: Chemical composition of the metal. Method of analysis: SEM-EDS, Lab of Electronic Microscopy and Microanalysis, IMA (Néode), HEI Arc.
Polygonal grains with twinned and strain lines
Intergranular corrosion is observed on the edges of the remaining metal (Fig. 7).The sample shows two forms of corrosion: multi-layered pustule corrosion at the left extremity of the sample (Fig. 8, area 1) and a corrosion crust covering the metal (Fig. 8, area 2). The multi-layered pustule corrosion has an average thickness of about 1.1 mm (L) and 0.79 mm (W) (Fig. 9). It is composed of a sandwich of 7 corrosion products, mainly green, grey, red and blue in dark field. Microscopic observation allows us to highlight new corrosion products that were not detected during the first visual examination (Fig. 9):
CP1. Light grey layer, containing mainly Sn, O, some Fe, P and a small amount of Pb combined with dark green layer, containing mainly Cu, O and P (Fig. 10, Fig. 12 and table 2)
CP2. Blue layer, containing mainly Cu, Cl, O (Fig. 10, Fig. 12 and table 2)
CP3. Red layer, containing mainly Cu and O combined with black layer containing mainly Sn and O (Fig. 10, Fig. 12 and table 2)
CP4. Brown layer containing mainly Cu, Sn and O (Fig. 10, Fig. 12 and table 2)
CP5. Dark grey layer containing mainly Cu, Sn and O (Fig. 10, Fig. 12 and table 2)
Superior markers such as contextual Fe and P are present in several layers. Their penetration illustrates the cracking of the primary corrosion layer during the formation of the pustule. The P-enrichment in some corrosion layers may be due to an environment rich in organic material (for example bones). The multi-layered pustule corrosion type has developed similarly to the process presented by Formigli (1975) and Scott (2002).
The corrosion crust on the metal has an average thickness of about 70 μm (Fig. 11). It consists of two sub-layers. The inner corrosion layer (CP2) is thin and dark brown in dark field or light grey in bright field. It has penetrated into the metal structure in some areas (Fig. 7). In dark field, the outer corrosion layer (CP1) is constituted of a heterogeneous light brown corrosion crust (Fig.11). The inner brown corrosion layer is enriched in Sn and O but also contains P, while the outer light brown corrosion layer is mainly composed of Pb and O but also contains P and Fe (Fig. 12). The outer light brown layer is probably due to the presence of a soft solder used to assemble the base to the body.
|Dark green layer||++||nd||+++||+++||+||+||+|
|Dark grey layer||++||++||++||nd||nd||nd||nd|
|Light brown layer (crust)||nd||nd||++||+||+||+++||nd|
|Dark brown layer (crust)||nd||+++||++||+||+||+||nd|
Table 2: Chemical composition of the multi-layered pustule corrosion from Figs. 8, 9 and 10 in dark field. SEM-EDS, Lab of Electronic Microscopy and Microanalysis, IMA (Néode) (+++: high concentration, ++ medium concentration, + low concentration, nd: not-detected).
Fig. 8: Micrograph of the metal sample (same as Fig. 7, 30° rotated), unetched, dark field, showing the location of the multi-layered pustule corrosion (area 1 to compare to Fig. 12) and the corrosion crust (area 2 to compare to Fig. 13). The area selected for elemental chemical distribution (Fig. 10) is marked by a red rectangle,
Multiform (warty - uniform) - pitting
Both Formigli (pustules) and type I (Robbiola) otherwise
The schematic representation of corrosion layers of Fig. 3 integrating additional information based on the analyses carried out is given in Fig. 14. The addition of "e" and "i" within the coding refers to the location of the strata which are either internal ("i") or in contact with the atmosphere ("e").
The metal of the oenochoe’s base is a tin bronze. The polygonal and twinned grains with strain lines show that the base has been repeatedly cold worked and annealed with a final cold work. The metal is either well preserved or heavily corroded with the formation of pustules that go through the whole thickness of the metal. The limit of the original surface corresponds to the top surface of the dark brown layer. In the presence of a pustule it is highly deformed but discernible by the tin enriched surface. The corrosion is multiform. The well preserved and only lightly corroded areas are of Robbiola type 1 (Robbiola 1998), the pustules however are of the Formigli type (Formigli 1975).
References on object and sample
1. Gillioz, S. (2012) Oenochoé GV132-01/US.26-obj.10, Genève, Place Simon-Goulart, rapport d’intervention. Haute Ecole ARC, Neuchâtel, 2013, non-publié.
2. Gillioz, S. (2012) Oenochoé GV132-01/US.26-obj.10, Genève, Place Simon-Goulart, rapport d’intervention. Haute Ecole ARC, Neuchâtel, 2013, non-publié.
References on analytic methods and interpretation
3. Formigli, E. (1975) « Die Bildung von Schichtpocken auf antiken Bronzen ». Arbeitsblätter, Heft 1, 51-74.
4. Robbiola, L., Blengino, J-M., Fiaud, C. (1998) Morphology and mechanisms of formation of natural patinas on archaeological Cu-Sn alloys, Corrosion Science, 40, 12, 2083-2111.
5. Scott, D. A. (2002) Copper and bronze in Art, corrosion, colorants, conservation. Getty publications, Los Angeles, 337.