Publications Details

A combined experimental and machine learning exploration of Ti2-xZrxMnCrFeNi high entropy Laves hydrides

Enblom, Veronica; Clulow, Rebecca; Ha, Tae J.; Witman, Matthew D.; Way, Lauren E.; Han, Sung J.; Brant Carvalho, Paulo H.B.; Stavila, Vitalie; Suh, Jin Y.; Sahlberg, Martin; Fadonougbo, Julien O.

A series of high entropy AB2-type Ti2-xZrxMnCrFeNi alloys (x = 0.6, 0.7, 0.8, 0.9, 1.0, 1.1 and 1.2) were synthesized to investigate their potential for hydrogen storage and chemical compression. The influence of the Ti/Zr ratio was explored in terms of structural, microstructural and thermodynamic properties. The storage capacity together with the reaction enthalpy and entropy changes of the synthesized high entropy alloys were compared to predictions from Machine Learning (ML) to investigate changes in these properties across the explored composition space. The results revealed that a decreasing Zr content consistently lowered the hydride formation enthalpy and increased the plateau pressure from 8 to >90 bar H2 at 25 °C, in good agreement with ML predictions. Selected compositions (x = 1.0 and 1.2) demonstrated reversible hydrogen storage capability over 150 cycles, with capacities of 1.34–1.40 wt % H2 and remarkable reaction kinetics (<4 min) at ambient temperature. These experimental and computational findings highlight the potential of this Laves-HEA system as tuneable, stable, and cost-effective materials suitable for long-term operations in stationary hydrogen storage and compression applications.