Characterizing accelerated precipitation in proton irradiated steel

TL;DR

This study demonstrates that proton irradiation can effectively simulate neutron irradiation effects in steel, revealing precipitate formation and embrittlement at much higher dose rates, with implications for reactor material testing.

Contribution

It provides a quantitative link between proton and neutron irradiation effects on steel precipitates, highlighting the role of dose rate and composition in embrittlement.

Findings

Proton irradiation reproduces neutron irradiation precipitation effects.

Precipitate volume fraction scales with dose to the power 0.25-0.30.

Carbon influences precipitate size alongside nickel, manganese, and temperature.

Abstract

Ion irradiation provides a promising substitute to neutron tests for investigating the effects of radiation on materials for fission and fusion reactor plants. Here we show proton irradiation can quantitatively reproduce precipitation that leads to embrittlement in reactor pressure vessel steels, at dose rates 10,000 times greater than experienced in fission reactor operation. Small-angle neutron scattering (SANS) is used to characterize precipitate size distributions in copper-containing steels irradiated to average doses of approx. 7 mdpa with 5 MeV protons. Comparing our results with the literature on reactor pressure vessel steels containing at least 1 at.% nickel, we find a power-law scaling of dose with exponent 0.25--0.30 accounts for the effects of dose rate on precipitate volume fraction over 6 orders of magnitude in dose rate. In conjunction with dose rate, carbon is identified as performing a leading role in determining precipitate sizes, adding to the known effects of nickel, manganese and irradiation temperature. We discuss the composition of precipitates inferred from SANS, taking previous atom probe tomography studies into consideration.