Materials & Design (Jan 2024)

True active surface area as a key indicator of corrosion behavior in additively manufactured 316L stainless steel

  • Seongkoo Cho,
  • Steven F. Buchsbaum,
  • Monika Biener,
  • Justin Jones,
  • Michael A. Melia,
  • Jamie A. Stull,
  • Hector R. Colon-Mercado,
  • Jonathan Dwyer,
  • S. Roger Qiu

Journal volume & issue
Vol. 237
p. 112559

Abstract

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Laser powder bed fusion (LPBF) additively manufactured (AM) 316L stainless steels (SS) possess much more complex surfaces than their wrought counterparts which affects the corrosion behavior. Surface roughness, a typical metric for assessing corrosion of conventionally manufactured metals, is often ineffective as an independent parameter in characterizing corrosion of the AM metals for their higher surface roughness ranging from 5 to 50 µm. This study experimentally shows that the true active surface area (ATA) is a proper parameter for quick assessment of localized corrosion response of AM 316L SS. Through the potentiodynamic polarization testing on surrogates under full immersion in 0.6 M NaCl solution, the pitting corrosion susceptibility was evaluated. While no consistent correlation to surface roughness was displayed, the pitting breakdown potential (Ep) showed a clear statistical trend at 1/ATA0.5. In addition, normalization of the polarization resistance with the ATA reveals the corresponding surface roughness did not significantly affect the change in open-circuit corrosion phenomenon. This correlation fits well with a previously reported stochastic pitting model on metal surfaces. The results suggest that the importance of ATA as a predictor for predisposition to corrosion in AM 316L SS extends far beyond what has been established for wrought materials.

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