Use of Bacteria To Stabilize Archaeological Iron

Lucrezia Comensoli; Julien Maillard; Monica Albini; Frederic Sandoz; Pilar Junier; Edith Joseph

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Use of Bacteria To Stabilize Archaeological Iron

Lucrezia Comensoli ^[1] ; Julien Maillard ^[3] ; Monica Albini ^[1] ; Frederic Sandoz ^[1] ; Pilar Junier ^[1] ; Edith Joseph ^[2]
1. [1] University of Neuchâtel
  
  University of Neuchâtel
  
  Neuchâtel, Suiza
2. [2] Haute Ecole Arc Conservation-Restauration, HES-SO, Neuchâtel, Switzerlandd
3. [3] Laboratory for Environmental Biotechnology Lausanne, Switzerland
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Localización: Applied and Environmental Microbiology, ISSN 0099-2240, Vol. 83, Nº 9, 2017
Idioma: inglés
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Resumen
- Iron artifacts are common among the findings of archaeological excavations.
  
  The corrosion layer formed on these objects requires stabilization after their recovery, without which the destruction of the item due to physicochemical damage is likely. Current technologies for stabilizing the corrosion layer are lengthy and generate hazardous waste products. Therefore, there is a pressing need for an alternative method for stabilizing the corrosion layer on iron objects. The aim of this study was to evaluate an alternative conservation-restoration method using bacteria. For this, anaerobic iron reduction leading to the formation of stable iron minerals in the presence of chlorine was investigated for two strains of Desulfitobacterium hafniense (strains TCE1 and LBE). Iron reduction was observed for soluble Fe(III) phases as well as for akaganeite, the most troublesome iron compound in the corrosion layer of archaeological iron objects. In terms of biogenic mineral production, differential effi- ciencies were observed in assays performed on corroded iron coupons. Strain TCE1 produced a homogeneous layer of vivianite covering 80% of the corroded surface, while on the coupons treated with strain LBE, only 10% of the surface was covered by the same mineral. Finally, an attempt to reduce iron on archaeological objects was performed with strain TCE1, which led to the formation of both biogenic vivianite and magnetite on the surface of the artifacts. These results demonstrate the potential of this biological treatment for stabilizing archaeological iron as a promising alternative to traditional conservation-restoration methods.