Details

Autor(en) / Beteiligte

• Bergner, F.
• Gillemot, F.
• Hernández-Mayoral, M.
• Serrano, M.
• Török, G.
• Ulbricht, A.
• Altstadt, E.

Titel

Contributions of Cu-rich clusters, dislocation loops and nanovoids to the irradiation-induced hardening of Cu-bearing low-Ni reactor pressure vessel steels

Ist Teil von

• Journal of nuclear materials, 2015-06, Vol.461, p.37-44

Ort / Verlag

Elsevier B.V

Erscheinungsjahr

2015

Link zum Volltext

Quelle

Elsevier ScienceDirect Journals

Beschreibungen/Notizen

• [Display omitted] •TEM and SANS were applied to estimate mean size and number density of loops, nanovoids and Cu-rich clusters.•A three-feature dispersed-barrier hardening model was applied to estimate the yield stress increase.•The values and errors of the dimensionless obstacle strength were estimated in a consistent way.•Nanovoids are stronger obstacles for dislocation glide than dislocation loops, loops are stronger than Cu-rich clusters.•For reactor-relevant conditions, Cu-rich clusters contribute most to hardening due to their high number density. Dislocation loops, nanovoids and Cu-rich clusters (CRPs) are known to represent obstacles for dislocation glide in neutron-irradiated reactor pressure vessel (RPV) steels, but a consistent experimental determination of the respective obstacle strengths is still missing. A set of Cu-bearing low-Ni RPV steels and model alloys was characterized by means of SANS and TEM in order to specify mean size and number density of loops, nanovoids and CRPs. The obstacle strengths of these families were estimated by solving an over-determined set of linear equations. We have found that nanovoids are stronger than loops and loops are stronger than CRPs. Nevertheless, CRPs contribute most to irradiation hardening because of their high number density. Nanovoids were only observed for neutron fluences beyond typical end-of-life conditions of RPVs. The estimates of the obstacle strength are critically compared with reported literature data.