Corrosion performance of austenitic stainless steel SS304 in molten nitrate salts and Raman microscopy for stability analysis in thermal energy storage applications

In the present work, the corrosion performance of stainless austenitic steel SS304 in contact with three different molten nitrate salts was studied under long-term isothermal conditions. The microstructure and corrosion products during 2000 h corrosion test were analyzed by SEM/EDX as well as XRD after immersion in Solar Salt (60 wt.% NaNO3 - 40 wt.% KNO3), Hitec (7 wt.% NaNO3 - 53 wt.% KNO3 - 40 wt.% NaNO2) and the quaternary salt 45 wt.% KNO3 - 34 wt.% NaNO2 - 15 wt.% LiNO3 - 6 wt.% NaNO3. Additionally, deeper analyzes with the current commercial salts were carried out in order to provide experimental data not only for the metal/salt interaction but also for the chemical interaction salt/atmosphere. The melting behavior and maximum thermal stability of Solar Salt and Hitec were analyzed by differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA). The melting and degradation temperature are discussed as well as the thermal stability of both salts monitored by Raman microscopy, which is an appropriate technique that confirmed the equilibrium alteration by decreasing the nitrite ion content over time. This work allows us to understand not only the hightemperature corrosion behavior of a potential container material but the chemical changes and thermal stability in molten salt mixtures. The results providing here may help to improve the understanding of material compatibility as well as the optimization of the engineering design with molten salts for thermal energy storage technologies.

Automated summary

This study investigated the corrosion performance of stainless austenitic steel SS304 in contact with three different molten nitrate salts under long-term isothermal conditions. The analysis of microstructure and corrosion products, as well as further studies with current commercial salts, provided experimental data for metal/salt interaction and chemical interaction salt/atmosphere. The results may contribute to improving understanding of material compatibility and engineering design optimization with molten salts for thermal energy storage technologies.