Effect of Sn on generalized stacking fault energy surfaces in zirconium and its hydrides

• Published in: arXiv.org
• Main Authors: Chakraborty, P, Mouton, I, Gault, B, Tehranchi, A, Neugebauer, J, Hickel, T
• Format: Paper Journal Article
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 19.09.2022
• Subjects: Alloying elements; Defects; Depletion; Enthalpy; Hydrogen embrittlement; Mathematical analysis; Nuclear fuel elements; Nuclear reactors; Nuclear safety; Phases; Physics - Materials Science; Service life; Stacking fault energy; Zircaloys (trademark); Zirconium base alloys; Zirconium hydrides
• ISSN: 2331-8422
• DOI: 10.48550/arxiv.2209.09147

Hydrogen embrittlement in Zr alloy fuel cladding is a primary safety concern for water based nuclear reactors. Here we investigated the stabilisation of planar defects within the forming hydrides by Sn, the primary alloying element of Zircaloy-4 used in the cladding. In order to explain formation of hydrides and planar defects observed in our experiments, we performed atomic-scale ab initio calculations focusing on the solute interactions with generalized stacking faults in hcp \(\alpha\)-Zr and fcc zirconium hydrides. Our calculations showed that an increase in Sn concentration leads to a stabilisation of stacking faults in both \(\alpha\)-Zr and hydride phases. However, the solution enthalpy of Sn is lower in the \(\alpha\)-Zr as compared to the other hydride phases indicative of two competing processes of Sn depletion/enrichment at the Zr hydride/matrix interface. This is corroborated by experimental findings, where Sn is repelled by hydrides and is mostly found trapped at interfaces and planar defects indicative of stacking faults inside the hydride phases. Our systematic investigation enables us to understand the presence and distribution of solutes in the hydride phases, which provides a deeper insight into the microstructural evolution of such alloy's properties during its service lifetime.