The role of relative humidity in the corrosion rate of copper in the presence of cuprous chloride: a risk-based approach

Thunberg, Johanna, Emmerson, Nicola ORCID: https://orcid.org/0000-0001-5277-0865 and Watkinson, David ORCID: https://orcid.org/0000-0002-5696-9780 2020. The role of relative humidity in the corrosion rate of copper in the presence of cuprous chloride: a risk-based approach. Presented at: European Corrosion Congress 2020, Virtual, 7-11 September 2020.

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Abstract

Museums worldwide house collections of archaeological copper alloy (CuA) objects that are potentially unstable due to incorporation of cuprous chloride (CuCl) formed in the burial environment. With sufficient atmospheric moisture, post-excavation hydrolysis of CuCl, a process often referred to as ‘bronze disease’, forms voluminous basic copper chlorides (Cu2(OH)3Cl). These disrupt overlying patinas, degrading the artistic, aesthetic and technological value of collections. To prevent the formation of Cu2(OH)3Cl and corrosion of unstable archaeological CuA objects, relative humidity (RH) levels around artefacts are often controlled to below published thresholds. Maintaining RH can be time consuming and resource-intensive, therefore a thorough understanding of the risk to unstable objects in a given environment is critical to produce sustainable management procedures tailored to preservation aims and budgets. Current guidelines for safe storage provide a range of RH targets without quantified evidence of corrosion risk relative to RH. This lack of definitive guidance has led to highly variable practices internationally in the management of desiccation for collections. This paper presents the results of AHRC SWWDTP funded doctoral research which is building an understanding of the risk associated to unstable objects at different RH levels. To simulate post-excavation corrosion processes occurring in unstable objects, Cu and CuCl powder mixtures have been subjected to the RH range 20-90% and their corrosion rates measured quantitatively using the Cardiff University oxygen consumption technique1,2,3. X-ray Diffraction and Raman spectroscopy have been used to examine the composition of the powders and the corrosion products formed. The results provide insight into the corrosion process of unstable objects and illustrate the efficacy of using RH to control post-excavation corrosion. A solid baseline for undertaking further measurements has been formed which will inform future management guidelines.

Item Type:	Conference or Workshop Item (Paper)
Status:	In Press
Schools:	History, Archaeology and Religion
Subjects:	A General Works > AM Museums (General). Collectors and collecting (General) C Auxiliary Sciences of History > CC Archaeology Q Science > Q Science (General)
Date of First Compliant Deposit:	10 March 2021
Last Modified:	28 Nov 2022 12:02
URI:	https://orca.cardiff.ac.uk/id/eprint/139447

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