Helium Causing Disappearance of ½ a<111> Dislocation Loops in Binary Fe-Cr Ferritic Alloys

Abstract

Single and dual-beam self-ion irradiations were performed at 500 °C on ultra-high purity Fe14%Cr alloy to ~0.33 displacements-per-atom (dpa), and 0 or 3030 atomic-parts-per-million (appm) helium/dpa, respectively. Using transmission electron microscopy, we reveal that helium can drastically modify the dislocation loop Burgers vector in Fe-Cr alloys. Helium co-implantation caused complete disappearance of a/2&lt;111&gt; type dislocation loops, and the microstructure consisted of only a&lt;100&gt; loops. Conversely, a/2&lt;111&gt; type loops were predominant without He co-implantation. The total loop density remained largely unaffected. The results strikingly contrast literature asserting that helium stabilizes a/2&lt;111&gt; type loops in bcc Fe alloys, based on low temperature irradiations. Collectively analyzing the results with literature suggests that the small positive interaction between helium and self-interstitial atoms (SIA) in Fe, predicted by atomistic simulations, maybe insufficient to holistically explain the dislocation loop microstructure development in presence of helium. Helium-SIA positive binding inadvertently implies elevated a/2&lt;111&gt; loop fraction and higher loop densities that the present results contradict. Helium induced high cavity density causing a preferential loss of highly glissile &lt;111&gt; clusters, leaving the matrix saturated with &lt;100&gt; type clusters is proposed as a potential mechanism. Further, the in-situ irradiations combined with Burgers vector analysis strengthened the evidence of Cr-induced dislocation loop mobility reduction that appears to stabilize the a/2&lt;111&gt; type loops and causes higher loop densities in Fe-Cr alloys.