<p>Friction surfacing (FS) is a solid-state coating process, where a consumable stud material is deposited onto to a substrate through frictional heating and plastic deformation, obtaining a deposited layer with a significantly refined microstructure. In the present study, the corrosion behavior of FS AA5083 was investigated by comparing the substrate, the deposited layer material, and the consumable stud material. The corrosion performance was evaluated using immersion tests, open circuit potential (OCP) monitoring, and cyclic polarization in chloride containing solutions with different pH values. The electrochemical response was correlated with grain size and residual stress state. The deposited layer exhibited a predominantly equiaxed and refined grains relative to both, the substrate and the stud base material. Immersion tests revealed significant pit nucleation in all conditions, with the deposited layer showing the highest pit density. However, cyclic polarization results indicated that the deposited layer developed the highest pitting potential, suggesting an enhanced ability for repassivation after initial attack. These results demonstrate that, the corrosion response of friction-surfaced AA5083 is governed by a balance between microstructural refinement, localized dissolution, passive film stability, and repassivation behavior, rather than by grain size alone, highlighting the complex interplay between microstructure and localized corrosion behavior in friction-surfaced aluminum alloys.</p>

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Microstructural and residual stress effects on the electrochemical response of friction surfaced AA5083

  • Eduardo Antunes Duda,
  • Zina Kallien,
  • Tárique Hernandez Schneider,
  • Benjamin Klusemann,
  • Carlos Eduardo Fortis Kwietniewski,
  • Tiago Falcade

摘要

Friction surfacing (FS) is a solid-state coating process, where a consumable stud material is deposited onto to a substrate through frictional heating and plastic deformation, obtaining a deposited layer with a significantly refined microstructure. In the present study, the corrosion behavior of FS AA5083 was investigated by comparing the substrate, the deposited layer material, and the consumable stud material. The corrosion performance was evaluated using immersion tests, open circuit potential (OCP) monitoring, and cyclic polarization in chloride containing solutions with different pH values. The electrochemical response was correlated with grain size and residual stress state. The deposited layer exhibited a predominantly equiaxed and refined grains relative to both, the substrate and the stud base material. Immersion tests revealed significant pit nucleation in all conditions, with the deposited layer showing the highest pit density. However, cyclic polarization results indicated that the deposited layer developed the highest pitting potential, suggesting an enhanced ability for repassivation after initial attack. These results demonstrate that, the corrosion response of friction-surfaced AA5083 is governed by a balance between microstructural refinement, localized dissolution, passive film stability, and repassivation behavior, rather than by grain size alone, highlighting the complex interplay between microstructure and localized corrosion behavior in friction-surfaced aluminum alloys.