Abstract
The corrosion of bronzes was examined in the context of single-acid versus mixed-acid (as in urban acid rain) solutions. Two bi-component bronzes (copper with either 3% Sn or 7% Sn) that closely represent those of historic artifacts were immersed for five weeks in conditions designed to replicate those experienced by statues and ornaments in cities where rainfall and humidity constantly produce an electrolyte layer on the surfaces of bronzes. Ions, acids, and particles of pollutants can dissolve in this layer, resulting in a variety of harsh corrosion processes. The kinetics of corrosion and the properties of the resulting patinas were monitored weekly by electrochemical impedance spectroscopy and open-circuit potential measurements. The sizes and appearances of the corrosion products were monitored and used to estimate the progress of the corrosion, whose crystalline structures were visualized using scanning electron microscopy with energy dispersive spectroscopy, identified by X-ray diffraction, and characterized by spectrocolorimetry. The electrochemical measurements demonstrated that greater damage (in terms of color change and corrosion product formation) did not correspond to deficiencies in protection. The mixed-acid solution did not corrode the bronzes, as would be expected from the additive effects of the single acids. The postulated mechanisms of metal dissolution appear to be specific to a particular bronze alloy, with the tin component playing an important role.
Highlights
Corrosion is a complex process involving many factors
Open circuit potential measurements of bronzes with 3% Sn and 7% Sn were recorded at weekly intervals during extended immersion tests in various acid solutions (artificial acid rain, 0.1 M sulphuric acid, and 0.1 M nitric acid)
In a solution of synthetic acid rain a more stable patina formed on the 7% Sn bronze than on the 3% Sn sample
Summary
Corrosion is a complex process involving many factors. Composition, morphology, and surface inclination are the main factors affecting the corrosion of an object [1,2,3,4,5,6,7,8,9]. Environmental parameters, such as humidity, temperature, rain, and air quality, play a role [10,11,12,13,14,15,16]. Investigations have been conducted during the analysis of degraded monuments undergoing restoration [21,22,23,24,25,26,27], and various relationships have been identified between the compositions of artifacts, their level of corrosion, and the monument environment, e.g., indoor, outdoor, urban, marine, or rural [28,29,30,31,32,33]
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