Mn-Ni-Si intermetallic precipitates (MNSPs) that are observed in some Fe-based alloys following thermal aging and irradiation are of considerable scientific and technical interest. For example, large volume fractions (f) of MNSPs form in reactor pressure vessel low alloy steels irradiated to high fluence, resulting in severe hardening induced embrittlement. Nine compositionally-tailored small heats of low Cu RPV-type steels, with an unusually wide range of dissolved Mn (0.06-1.34 at.%) and Ni (0.19-3.50 at.%) contents, were irradiated at ≈ 290°C to ≈ 1.4x10 20 n/cm 2 at an accelerated test reactor flux of ≈ 3.6x10 12 n/cm 2 -s (E > 1 MeV). Atom probe tomography shows Mn-Ni interactions play the dominant role in determining the MNSP f, which correlates well with irradiation hardening. The wide range of alloy compositions results in corresponding variations in precipitates chemistries that are reasonably similar to various phases in the Mn-Ni-Si projection of the Fe based quaternary. Notably, f scales with ≈ Ni 1.6 Mn 0.8 . Thus f is modest even in advanced high 3.5 at.% Ni steels at very low Mn (Mn starvation); in this case Nisilicide phase type compositions are observed.
Highlights Novel method developed for automatically detecting edge clusters in atom probe datasets Application to simulated data and its effect on measurement accuracy is assessed Successfully applied to real dataincluding datasets with complex shapes
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