Corrosion propagation behavior of new metallic rebar materials in simulated concrete environments and engineering implications

The radial (depth) and lateral (length) corrosion propagation behavior of 316LN stainless steel, 2101 LDX duplex stainless steel, and MMFX-2 compared to plain carbon steel were characterized in saturated Ca(OH)₂ solution. Pit growth was ohmically controlled for all materials but repassivated more readily at high potentials for 316LN and 2101 LDX stainless steels. Conversely, pit growth on carbon steel propagated at all applied anodic potentials and did not repassivate until deactivation by cathodic polarization. Stainless steel showed the highest resistance to lateral corrosion propagation from an active site during microelectrode array testing. 2101 LDX duplex stainless and MMFX-2 showed similar radial propagation behavior and corrosion morphology, which was intermediate of carbon steel and stainless steel. Based on an existing concrete cracking model it is expected that corrosion resistant rebar materials would require a greater depth of corrosion attack than carbon steel before damaging concrete via corrosion product formation. copyright The Electrochemical Society.