Abstract
Addition of 0.05 wt% C to a model Fe–15Cr–16Ni–0.25Ti quaternary model alloy leads to a reduction in neutron-induced swelling at 430 °C. The transient regime of swelling is prolonged by carbon addition, most strongly at lower dpa rates. Contrary to the swelling behavior observed in carbon-free Fe–15Cr–16Ni and Fe–15Cr–16Ni–0.25Ti model alloys irradiated in the same experiment, Fe–15Cr–16Ti–0.25Ti–0.05C does not exhibit a strong dependence of swelling on dpa rate. It appears that carbon’s role, while not yet well-defined, operates via a solute-based or TiC complex mechanism rather than by a precipitate-based mechanism. A model is proposed whereby carbon stabilizes loop microstructures against unfaulting, where unfaulting is known to be a prerequisite to formation of the glissile dislocation network needed to establish a high swelling rate. This stabilization is proposed to counteract the tendency of loop unfaulting to occur more strongly at low dpa rates.
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