Short-term oxidation behavior of Cr-coated Zr-1Nb in severe accident environments: steam and air

This study examines Cr-coated Zr-1Nb alloy cladding oxidation in steam/air (600–1200 °C), simulating accident scenarios. Thermogravimetry and static air tests revealed Cr coatings form granular oxides in air and coral/worm-like structures in steam (H₂ release-driven). Cr³⁺ migration governs oxidation kinetics. At 1000 °C air (>40 min), weight gain deviates from parabolic kinetics due to ZrN/ZrO₂ phase transitions, causing porous oxide formation. Air yields thinner Cr₂O₃ layers than steam at 800–1000 °C, as Cr₂O₃ reacts with O₂ to form volatile CrO₃. At 1200 °C air (>40 min), Cr₂O₃ thinning occurs due to dominant volatilization over diffusion. Results confirm Cr coatings delay Zr substrate oxidation during LOCAs by suppressing rapid degradation under extreme heat, enhancing accident tolerance. The balance between Cr₂O₃ thickening induced by diffusion and thinning induced by volatilization defines protective efficacy, validating the role of Cr in accident-tolerant fuel cladding.