Theoretical study on the surface poisoning of high-entropy alloys during hydrogen storage cycles: the effect of metal elements and phases

High-entropy alloys offer promising hydrogen storage properties and design versatility but suffer from compromised capacity and stability in practical industrial applications owing to surface poisoning caused by trace impurities or unexpected contact with air. Theoretical simulations provide a rapid and efficient platform for estimating anti-poisoning performance, particularly concerning alloys versus metal elements in various phases. This work explores the surface poisoning behavior of two typical high entropy materials: BCC-phase V 35 Ti 30 Cr 25 Fe 10 and Laves-phase ZrTiVNiCrFe, along with pure metals V, Ti, Cr, and Fe as well as single AB 2 (A = Zr, Ti, B = V, Ni, Cr, and Fe) compounds, at various phase stages during hydrogen storage cycles using density functional theory (DFT) simulations. Results show that surfaces of V 35 Ti 30 Cr 25 Fe 10 and ZrTiVNiCrFe with a hydrogen uptake of 100% can facilitate O 2 adsorption over dissociation, especially when O 2 adsorbs on Fe sites, and formation of hydroxyl. The O 2 poisoning behavior of high-entropy alloys was roughly estimated using the molar ratio weighted sum of constituent components, with the maximum deviation of 15.92% between predicted values and calculated values. This study sheds light on anti-poisoning mechanisms and aids in designing resilient high-entropy alloys. The Fe element in fully hydrated V 35 Ti 30 Cr 25 Fe 10 and ZrTiVNiCrFe facilitates O 2 poisoning resistance. The O 2 poisoning behavior of high-entropy alloys could be roughly estimated using the molar ratio weighted sum of constituent components.