Overview
ABSTRACT
The corrosion of ferrous archaeological artifacts must be understood and modeled in different fields (conservation, civil engineering) for predicting the behavior of metallic materials in the very long term. Archaeological ferrous alloys are low-alloyed steels and diverse corrosion media exist (soil, atmosphere, marine environments, and mortars). Specific characterization techniques must be implemented to study ancient corrosion systems with thick corrosion layers. Corrosion rates are controlled by the nature of these layers (composition, structure and morphology) and can be very slow in some cases (1µm/year).
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Read the articleAUTHORS
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Philippe DILLMANN: CNRS Research Director, LAPA, SIS2M UMR3299 CEA/CNRS and IRAMAT UMR5060 CNRS
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Delphine NEFF: CEA Engineer, LAPA, SIS2M UMR3299 CEA/CNRS and IRAMAT UMR5060 CNRS
INTRODUCTION
Since the 19th century, the corrosion of iron and other metals has been extensively and finely studied in a large number of environments, but only for processes developing over relatively short periods compared with the durations involved in the alteration of archaeological objects. Moreover, the thick layers of corrosion products formed after several centuries of exposure to different archaeological environments have been described by restorers and conservation scientists in some detail, but often with limited analytical resources, giving a good grasp of the heterogeneities and variability that archaeological corrosion systems can present on a macroscopic scale, but offering few elements for understanding the mechanisms, particularly on micro and nanometric scales. However, it is clear that only a well-considered combination of these two approaches can provide a clear picture of such corrosion systems, which are sometimes highly complex and whose alteration kinetics are controlled by mechanisms operating at different scales, the synergies of which need to be understood.
In recent years, mainly for ferrous metals but also for other materials, the need has arisen to attempt a more detailed approach to the corrosion of archaeological objects, based on an understanding of the mechanisms involved. In conservation/restoration circles, this has been motivated by the search for specific information, and the need for reliable diagnostics and optimization of object stabilization treatments. In particular, the location in corrosion products of the object's former surface, on which primordial archaeological information can be found, is the subject of extensive research. What's more, the conservation of ferrous objects in museums or historical monuments requires a thorough understanding of the corrosion products formed in previous centuries and their evolution in relation to that of the environment. Finally, for ferrous objects, particularly those stored in marine environments, it is essential to carry out a stabilization treatment to remove chloride ions from the system prior to any museum display or storage, in order to avoid any dramatic effect of renewed corrosion, which could lead to the ruin of objects removed from their environment in just a few years. These sometimes lengthy treatments need to be optimized, and the empirical approach alone is not enough. To these motivations linked exclusively to the heritage field, a more recent problem has been added, which has been at the origin of significant advances in recent years in the field of understanding the nature of corrosion products developed on archaeological objects. Indeed, in contexts linked to nuclear engineering, the storage and disposal of long-lived radioactive waste is becoming a crucial issue. In France (law no. 91-1381) and other...
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KEYWORDS
nuclear | Civil engineering | cultural heritage artefacts conservation | Corrosion | materials characterisation
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Corrosion of ferrous archaeological objects
Bibliography
Websites
"Les liaisons tumultueuses de la rouille et du béton, des cathédrales aux centrales nucléaires", lecture by Valérie L'Hostis, Christophe Gallé, Alain Millard, researchers at the Direction de l'énergie nucléaire and Philippe Dillmann, researcher at the Direction des sciences de la matière, center CEA de Saclay :
Events
EURROCORR Congress. Annual. European Congress on Corrosion. A session dedicated to heritage objects
Norms and standards (non-exhaustive list)
- Corrosion of metals and alloys – Key terms and definitions - ISO 8044 - 1999
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