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Journal of Failure Analysis and Prevention

, Volume 11, Issue 3, pp 178–185 | Cite as

Case Histories of Ancient Silver Embrittlement

  • R. J. H. Wanhill
Case History---Peer-Reviewed

Abstract

This article discusses six cases of ancient silver embrittlement. The diagnostic techniques and results are surveyed, followed by the most likely explanations of embrittlement. There are two basic types of embrittlement: corrosion-induced, and microstructurally induced, which can act synergistically. Corrosion-induced embrittlement takes several forms, including what appears to be intergranular and transgranular stress corrosion cracking. The main intrinsic factor facilitating corrosion-induced embrittlement is retained cold-work in the silver. Microstructural embrittlement is characterized by intergranular fracture, most probably due to low-temperature segregation of lead to the grain boundaries. Knowledge of the details of embrittlement can be essential for optimizing the restoration and conservation of damaged artifacts.

Keywords

Ancient silver Embrittlement Case histories 

Introduction

Ancient silver artifacts are rare and valuable exhibits in many museums. Some are apparently in excellent condition, but others may have been badly damaged and embrittled during many centuries of burial. Preservation of these artifacts depends, or should depend, on a detailed understanding of the types of damage and embrittlement.

Since 1994, the NLR has investigated four cases of ancient silver embrittlement [1, 2, 3, 4, 5, 6, 7], one as a re-assessment [7], and reviewed two cases investigated by others [8, 9, 10, 11]. Experience and insight gained from the investigations enables presenting the most likely explanations of embrittlement for all six cases. This is the main topic of this article.

The Artifacts

Five of the ancient silver artifacts are illustrated in Figs. 15. The Gundestrup Cauldron, Egyptian Vase, and Roman Kantharos (drinking cup) are about 2000 years old. The Byzantine Paten (altar plate) and Romanesque Kaptorga (small container for relics and amulets) date from the 7th and 10th centuries AD, respectively. The sixth artifact is a Sasanian King’s Head [11], dating from the 4th century AD. The Kaptorga and Head are the subjects of the reviewed cases mentioned above [8, 9, 10, 11].
Fig. 1

Gundestrup Cauldron, diameter, 60 cm: National Museum of Denmark, Copenhagen

Fig. 2

Egyptian Vase, height, 9.6 cm: Allard Pierson Museum, Amsterdam

Fig. 3

Byzantine Paten, inner diameter, 20 cm: The Menil Collection, Houston

Fig. 4

Roman Kantharos, inner and outer cups, top diameter, 12.7 cm: Museum Het Valkhof, Nijmegen

Fig. 5

Romanesque Kaptorga, maximum width, 4.6 cm: Institute of Archaeology, Prague

The artifacts are very different in form and origin. This is advantageous for the consistency of some of the explanations of the types of embrittlement.

Diagnostic Techniques

Table 1 lists the diagnostic techniques (besides visual observation) used for examining small (usually millimeter-size) samples from the artifacts. Limitations were imposed by the available samples and techniques. Fractography could not be done on the metallographic samples from the Cauldron and Paten; chemical analyses other than EDX were not possible for the Vase and Kaptorga; and EBSD was available only for the Cauldron. Also, only a sample from the Kantharos inner cup was available.
Table 1

Diagnostic techniques used to examine the ancient silver artifacts

Techniques

Cauldron

Vase

Paten

Kantharos

Kaptorga

Head

X-ray radiography

 

 

  

Optical metallography

    

Vickers microhardness, HV

 

   

SEM metallography

 

 

Electron backscatter diffraction (EBSD)

     

SEM fractography

 

 

 

EDX chemical analysis

 

 

Chemical analysisa

 

 

aEPMA (Cauldron, Paten); XRF (Kantharos); semi-quantitative spectrography (Head)

Survey of the Results

Tables 2 and 3 depict the survey of the results of the investigations. The results are discussed in the two main sections of this article later, where links between the types of embrittlement, artifact microstructure, and composition are indicated. For the Kaptorga, the possible contribution of the burial environment, a grave, is also considered.
Table 2

Survey of the results of the investigations of samples from the ancient silver artifacts

Observations

Cauldron

Vase

Paten

Kantharos

Kaptorga

Head

Corrosion embrittlement

 Intergranular

3 samples

 

 

 Transgranular

1 sample

    

Microstructural embrittlement

 

 

  

Annealed microstructure

1 sample

 

 

Retained cold-work

3 samples

   

Discontinuous precipitation of copper

1 sample

 

  

b.d.

Chemical compositiona, wt.%

 Cu

1.76–4.64

0.9

5.33

0.45–0.63

3.3–3.5

~5

 Au

0.29–0.36

0.8

0.58

0.58–0.63

2.3–2.5

0.1–1

 Pb

0.39–0.64

0.7

0.86

0.16–0.25

n.d.

0.05–0.5

 Bi

0.07–0.13

n.d.

0.06

n.d.

n.d.

0.01–0.1

Surface corrosion product mainly AgCl

 

  

aMain elements, balance Ag; n.d. = not detectable; b.d. = barely detectable

Table 3

Gundestrup Cauldron samples

Observations

361

363

365

366

Corrosion embrittlement

 Intergranular

 

 Transgranular

  

 

Annealed microstructure

   

Retained cold-worka

 

Discontinuous precipitation of copper

   

Copper content, wt.%

4.64

1.76

2.17

3.44

aIncreasing retained cold-work in the order 361 < 363 < 365

Corrosion-Induced Embrittlement

Intergranular Corrosion and Cracking

Tables 2 and 3 show that corrosion-induced intergranular embrittlement was observed in samples from the Cauldron, Paten, Kaptorga and Head [4, 5, 6, 8, 9, 10, 11]. This type of embrittlement has been attributed to segregation of copper to grain boundaries, either during cooling from final annealing during fabrication, or during long-term burial at ambient temperatures [9, 12, 13, 14, 15]. In particular, the eminent metallurgist C. S. Smith was of the opinion that the so-called discontinuous precipitation of copper seems to be very detrimental [12]. This precipitation can cause the grain boundaries to appear irregular and meandering, particularly in ancient silver.

The unembrittled sample 366 from the Cauldron and the embrittled Paten and Head samples showed evidence of discontinuous precipitation, see Figs. 68. However, the embrittled samples from the Cauldron and Kaptorga did not. Hence, this type of precipitation is not needed for corrosion-induced intergranular embrittlement, and in the case of the Cauldron, it was innocuous.
Fig. 6

EBSD inverse pole figure color-coded map of the sample 366 from the Gundestrup Cauldron, showing fully annealed grains, annealing twins, and extensive discontinuous precipitation of copper (delineated by the black dots) at the grain boundaries

Fig. 7

SEM metallographs of the Byzantine Paten sample, showing (a) intergranular corrosion and cracking and (b) discontinuous precipitation of copper at the grain boundaries [4, 5]: courtesy of Ineke Joosten, Netherlands Institute for Cultural Heritage, Amsterdam

Fig. 8

Optical metallograph of a sample from the Sasanian King’s Head [11], showing slightly distorted annealing twin boundaries, deformation twins, and barely detectable discontinuous precipitation of copper at grain boundaries. The black particles are probably copper oxide originating from the time when the metal was cast [11]

For the Cauldron, the EBSD examination demonstrated a strong link between the amount of retained cold-work, degree of embrittlement and the presence or absence of discontinuous precipitation [4, 5, 6]. Figures 6 and 9 show examples from the two extremes, samples 365 and 366. The annealed sample 366, Fig. 6, was undamaged even though precipitation was present at many grain boundaries. However, the heavily cold-worked sample 365, Fig. 9, showed severe intergranular and transgranular corrosion, with no evidence of precipitation. The intermediately cold-worked samples 361 and 363 also showed intergranular corrosion, though less severe, and again without precipitation [4, 5]. It appears that cold-work suppressed the precipitation, since the annealed sample 366 contained less copper (3.44 wt.%) than sample 361 (4.64 wt.%), see Table 3. In this respect, it is noteworthy that precipitation in the cold-work-containing Head (84 HV vs. 43 HV fully annealed) was barely detectable, Fig. 8, even though the copper content was about 5 wt.% [11].
Fig. 9

EBSD inverse pole figure color-coded map of sample 365 from the Gundestrup Cauldron, showing retained cold-work and extensive corrosion-induced intergranular and transgranular fracture (the internal black-dotted areas)

Although the Cauldron results show retained cold-work is important, it is not always needed for corrosion-induced intergranular embrittlement. The Kaptorga has a fully annealed microstructure (without discontinuous precipitation, as mentioned above) but has been severely embrittled and highly fragmented [8, 9, 10]. Figure 10 shows an SEM metallograph and fractograph of samples showing (a) corrosion pitting at grain boundaries, linking to form cracks, and (b) corrosion-induced “clean” intergranular fracture being slowly destroyed by general corrosion. By analogy with clean intergranular stress corrosion cracking (SCC) followed by general corrosion in an aluminium–lithium alloy [16], the Kaptorga intergranular fracture has been suggested to be SCC also [6].
Fig. 10

SEM metallograph and fractograph of samples from a Romanesque Kaptorga, showing (a) corrosion pitting at grain boundaries, linking to form cracks, and (b) corrosion-induced “clean” intergranular fracture being slowly destroyed by general corrosion: courtesy of Jiří Děd and Jarka Vaníčková, Institute of Chemical Technology, Prague

Since the Kaptorga silver was fully annealed [9], SCC would have had to result from external crushing forces combined with a particularly adverse environment. Both are distinct possibilities resulting from the grave burial: besides the weight of the soil, especially on hollow artifacts like the Kaptorga, the groundwater in graves can be very saline owing to human decomposition [17]. Support for these possibilities comes from another grave burial artifact, the Khan Cup, which was highly fragmented owing to “crystalline” fracture [18].

Transgranular Corrosion and Cracking

Tables 2 and 3 show that corrosion-induced transgranular embrittlement was observed in samples from the Cauldron (365) and Vase. The Vase has so far proven to be unique in undergoing synergistic corrosion-induced (transgranular) and microstructural (intergranular) embrittlement [1, 2, 3, 4, 5]. This synergy has been very damaging, but it has enabled the transgranular corrosion and cracking to be well characterized. This is because microstructural embrittlement caused intergranular break-up of the samples and revealed the internally-developing processes of corrosion-induced embrittlement from initiation to complete fracture.

The Vase underwent corrosion and cracking along slip lines and deformation twin boundaries owing to retained cold-work; and also corrosion along segregation bands, which were the much-modified remains of high-temperature solute element segregation (coring) during solidification. Examples are shown in Figs. 11 and 12, whereby the fractograph shows crystallographic cracking mainly along slip planes, followed by general corrosion destroying the fracture surfaces. As in the case of corrosion-induced intergranular embrittlement of the Kaptorga, Fig. 12 suggests a process of SCC, in this case transgranular.
Fig. 11

SEM metallograph of an Egyptian Vase sample showing corrosion along slip lines, deformation twins, and segregation bands. The diamond-shaped “shadow” is from a microhardness indent

Fig. 12

SEM fractograph of an Egyptian Vase sample showing crystallographic corrosion mainly along slip planes, followed by general corrosion partly destroying the fracture surfaces at the left-hand side of the fractograph

More evidence for transgranular SCC was obtained from intergranular break-up of the samples. Figure 13 illustrates (a) the beginning of slip plane corrosion (pitting, most probably at emergent dislocations), (b) cracking, and (c) the resulting crystallographic fracture into blocks. The 90° “dog-leg” crack in Fig. 13b is significant, as are the high-angle narrow sides of the blocks in Fig. 13c. Given that the slip plane cracks are on {111} planes, the “dog-leg” crack cannot be on a {111} plane, but must be on either a {110} or {112} plane. The high-angle block sides are also likely to be on one of these planes. As explained in Ref. [6], these observations favor the strain-enhanced dissolution model of SCC proposed by Lichter et al. [19].
Fig. 13

SEM fractographs of an Egyptian Vase sample showing (a) slip line corrosion, (b) slip plane dissolution and cracking, and (c) crystallographic fracture topography

Rationale Linking Intergranular and Transgranular Cracking

The case history evidence may be interpreted to provide an overall rationale for corrosion-induced intergranular and transgranular cracking. Intergranular pitting and cracking is probably SCC caused by local strains (and compositional variations, particularly copper) at and near grain boundaries. The local strains derive from external forces (Kaptorga) and/or retained cold-work (Cauldron, Paten, and Head).

More retained cold-work (Cauldron, sample 365, Vase) increases the tendency for transgranular SCC, which is caused mainly by local strains because of dislocation pile-ups on slip planes. However, there is some contribution from local strains on “dog-leg” crystallographic planes and deformation twin boundaries.

Microstructural Embrittlement

Table 2 shows that microstructural embrittlement was observed in samples from the Vase and Kantharos inner cup. This type of embrittlement is fortunately less common than corrosion-induced embrittlement, since it occurs throughout the artifacts, leaving them particularly susceptible to fragmentation. (However, see the comments in the next section of this article concerning the brittleness of the Vase, Kantharos inner cup and Kaptorga.)

Microstructural embrittlement is characterized by zero-ductility intergranular fracture, with sharply defined cracks and grain boundary facets, and bodily displaced grains [1, 2, 3, 4, 5, 6]. Examples are given in Figs. 14 and 15. In particular, the bodily displaced grains demonstrate the severity of this type of embrittlement.
Fig. 14

SEM fractograph of an Egyptian Vase sample showing brittle intergranular fracture with bodily displaced grains owing to microstructural embrittlement. Some slip line corrosion is also present (part of the synergistic embrittlement)

Fig. 15

SEM fractograph (backscattered electron mode) of a Kantharos inner cup sample showing brittle intergranular fracture with bodily displaced grains owing to microstructural embrittlement: courtesy of Ineke Joosten, Netherlands Institute for Cultural Heritage, Amsterdam

Embrittlement is most probably caused by low-temperature ageing, whereby an impurity element, or elements, segregates to grain boundaries throughout the artifact. The available evidence, including the Vase and Kantharos compositions listed in Table 2, indicates lead to be the most likely perpetrator [20, 21], though this has yet to be verified directly, e.g., by Auger spectroscopy. Other impurity elements might be involved, notably bismuth [11, 21], though apparently not for the Vase and Kantharos, see Table 2.

Remedial Measures: Comments from the Case Histories

Restoration and conservation of embrittled silver has been discussed in many publications, e.g. Refs. [1, 2, 4, 6, 7, 8, 11, 14, 18, 21, 22, 23]. The modern view is to consider both technical and ethical aspects. Preference is therefore given to reversible remedial measures that respect an artifact’s integrity, meaning veracity rather than wholeness. However, the second meaning, wholeness, can dictate the remedial measures: non-reversible consolidation is essential for preserving severely embrittled and fragmented artifacts [8, 10, 18, 22, 23].

Detailed case histories can be important in resolving the issue of reversible versus non-reversible restoration. Looking to the six case histories discussed in this article, the Cauldron, Paten, and Head are in generally good condition. Further conservation measures, if any, would likely be limited to periodic cleaning and possible application of removable protective coatings. Even so, the choice of cleaning methods and coatings requires careful consideration [4, 6, 11, 22, 24].

In contrast, the Vase, Kantharos inner cup and Kaptorga have been severely embrittled. From a fundamental point of view, one would expect the Kaptorga to be less fragile than the Vase and Kantharos inner cup. Any non-cracked areas of the Kaptorga should have retained the high ductility of annealed silver now that it is removed from the burial environment, but the Vase and Kantharos inner cups are now intrinsically brittle. In practice, however, the intergranular cracking in the Kaptorga has been so extensive that the fragments continued to break up even during careful handling before restoration [8]. Hence, all three artifacts were very fragile before restoration, and they have been non-reversibly restored.

The Vase restoration is old (and crude by modern standards), involving extensive use of an organic filler material. The Kantharos (both cups) has been restored by impregnation with an epoxy resin [7]. However, the tight cracks shown in Fig. 15 were free of resin, which suggests that the restoration has been only partly successful. The Kaptorga has been very carefully restored using an external and removable backing of silk and acrylic lacquer, followed by an internal backing of fine glass cloth and epoxy resin [8]. The external backing was then removed with acetone. This is a similar technique to that used for the Khan Cup [18].

Concluding Remarks

Ancient silver artifacts are rare and valuable museum exhibits. Consequently, it is difficult to obtain samples from the embrittled artifacts for detailed investigations. However, the case histories discussed in this article demonstrate that modern diagnostic techniques applied to small samples can tell much about the types of embrittlement and the conditions of the sampled artifacts. This knowledge can be essential for optimizing the preservation of these and other damaged artifacts.

Notes

Acknowledgments

The author is indebted to several colleagues for providing information and assistance with obtaining and analyzing samples from the artifacts discussed in this article: Ron Leenheer, Allard Pierson Museum, Amsterdam; Peter Northover, Oxford University, Oxford; Joanna Cook, The Menil Collection, Houston; Ronny Meijers, Museum Het Valkhof, Nijmegen; Jiří Děd and Jarka Vaníčková, Institute of Chemical Technology, Prague; Ineke Joosten, Netherlands Institute for Cultural Heritage, Amsterdam; and Jean-Paul Steijaert and Tim Hattenberg, NLR.

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Copyright information

© ASM International 2011

Authors and Affiliations

  1. 1.National Aerospace Laboratory NLREmmeloordThe Netherlands

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