Abstract
With the rising global demand for low-cost clean energy, nuclear fission and fusion systems willbecome increasingly important sources for both economic and environmental reasons. These new
advanced systems will operate at a higher efficiency compared to previous models. This will require
materials to be long-lasting durable and have excellent high-temperature performance (up to 700°C)
under adverse conditions. Qualities such as resistance to oxidation, resistance to swelling, and low
levels of radioactivation will be critical for any material used in nuclear reactor components,
specifically for fuel cladding or structural elements surrounding the reactor core. Materials research
historically focused on austenitic stainless steels, superalloys, or ferritic-martensitic (F-M) steels.
This study focuses on three FM steels, HT-9, HCM12A, T91, and one ODS alloy, MA956. In order to
understand the effects of irradiation, charged particle irradiation is used to imitate the damage on
these candidate materials. To better understand the effects of irradiation, the dispersed barrier
hardening, solid solution strengthening, and grain size dependence (Hall-Petch) models are used to
quantify the strengthening caused by irradiation induced micro-, and nano-structure features.
Coupled with nanoindentation, transmission electron microscopy (TEM), and atom probe
tomography (APT), irradiation induced features can be numericized, and evaluated on the significant
changes they contribute to the overall change in strength of the material.