Decreased Metal Dusting Resistance of Ni-Cu Alloys by Fe and Mn Additions

A.S. Ulrich, S. Kasatikov, T. König, A. Fantin, J.T. Margraf, M.C. Galetz

High Temperature Corrosion of Materials (2024), DOI: 10.1007/s11085-024-10263-w

ulrich2024

a Schematic drawing of the interplay between CO and the metallic surface. The C-atom interacts with the electronic surface states of Ni, while the O-atom interacts with an oxide forming element. b Proposed mechanism enhancing MD attack for Mn- and Fe additions to Ni-Cu alloys. The interplay of oxide and carbide formation is visualized.
Reprinted from High Temperature Corrosion of Materials with permission from Springer according to the Creative Commons license.

Ni-Cu alloys are promising for application at temperatures between 400–900 °C and reducing atmospheres with high C-contents. Typically, under such conditions, metallic materials in contact with the C-rich atmosphere are degraded by a mechanism called metal dusting (MD). Ni-Cu-alloys do not form protective oxide scales, but their resistance is attributed to Cu, which catalytically inhibits the C-deposition on the surface. Adding other alloying elements, such as Mn or Fe, was found to enhance the MD attack of Ni-Cu alloys again. In this study, the effect of the Mn and Fe is divided into two affected areas: the surface and the bulk. The MD attack on binary Ni-Cu alloys, model alloys with Fe and Mn additions, and commercial Monel Alloy 400 is experimentally demonstrated. The surface electronic structure causing the adsorption and dissociation of C-containing molecules is investigated for model alloys. Analytical methods such as scanning electron microscopy combined with energy-dispersive X-ray spectroscopy, electron probe microanalysis combined with wavelength-dispersive X-ray spectroscopy, X-ray diffraction analysis, and near-edge X-ray absorption fine structure measurements were used. The results are correlated to CALPHAD calculations and atomistic simulations combining density functional theory calculations and machine learning. It is found that the Cu content plays a significant role in the surface reaction. The effect of Mn and Fe is mainly attributed to oxide formation. A mechanism explaining the enhanced attack by adding both Fe and Mn is proposed.

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