Effect of CrAl and Cr coatings on the fatigue behavior of zirconium alloy: In-situ SEM study and CPFEM analysis

Accident-tolerant fuel (ATF) coatings were recognized as one of the most promising nuclear materials for short-term commercial deployment, yet their comprehensive impact on the fatigue performance of zirconium alloy substrates remained poorly understood. This study systematically investigated the effects of representative ATF coatings (CrAl and Cr) fabricated through different processes on the fatigue life and failure mechanisms of zirconium alloy using integrated in-situ SEM testing at 400 °C and crystal plasticity finite element modeling (CPFEM). The results revealed that CrAl coatings imposed a deleterious effect on fatigue resistance, while both magnetron-sputtered (MS) Cr and multi-arc ion plated (AIP) Cr coatings demonstrated a significant enhancement in fatigue endurance. The fatigue degradation of coated systems was innovatively categorized into four sequential stages: coating crack initiation, coating crack propagation, substrate crack initiation, and substrate crack propagation. Stage-specific analysis revealed that while brittle cracking in CrAl coatings accelerated fatigue degradation in the zirconium alloy substrate through interface stress concentration, the superior ductility and deformation compatibility of Cr coatings effectively suppressed substrate crack nucleation. A predictive fatigue life prediction framework was formulated through CPFEM simulations, incorporating coating-induced alterations to deformation mechanisms and fracture behavior in zirconium alloys.