Corrosion mechanism of SS316L exposed to NaCl/Na2CO3 molten salt in air and argon environments

Molten salts are potential energy storage media for solar thermal power, but can be highly corrosive. To investigate molten salt corrosion mechanisms, the oxidation state and structure of SS316L exposed to salt in air and argon environments was investigated using SEM and XANES techniques. It was det...

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Bibliographic Details
Published in:Corrosion science 2022-02, Vol.195, p.109966, Article 109966
Main Authors: Bell, S., Jones, M.W.M., Graham, E., Peterson, D.J., van Riessen, G.A., Hinsley, G., Steinberg, T., Will, G.
Format: Article
Language:English
Subjects:
Argon
Basicity
Chromium
Corrosion
Corrosion mechanisms
Energy storage
Molten salt corrosion
Molten salts
Oxidation
Oxidation state
Potential energy
Sodium carbonate
Solar heating
Synchrotron
Valence
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Summary:Molten salts are potential energy storage media for solar thermal power, but can be highly corrosive. To investigate molten salt corrosion mechanisms, the oxidation state and structure of SS316L exposed to salt in air and argon environments was investigated using SEM and XANES techniques. It was determined that iron formed mixed Fe2+ and Fe3+ states in both environments, with lower oxidation states deeper into the corrosion. Cr2+ was the primary oxidation state present in the scale for chromium. Reduced salt basicity with lower oxygen concentration favoured the lower oxidation state, whilst Cr3+ ions were dissolved by the salt. •SS316L was corroded in both air and argon environments, argon environments were more aggressive.•Cross sections were analysed with SEM-EDS, XANES and XFM.•Fe2+ and Fe3+ oxidation states were present in both environments.•Cr2+ was the only oxidation state detected in argon, due to reduced salt basicity.•In air, Cr3+ was detected close to the metal but dissolved into the salt leaving a Cr2+ outer layer.
ISSN:0010-938X
1879-0496
DOI:10.1016/j.corsci.2021.109966