Solidification microstructure-dependent hydrogen generation behavior of Al-Sn and Al-Fe alloys in alkaline medium

This work deals with the development of quantitative correlations of hydrogen evolution performance with solidification microstructural and thermal parameters in Al-1Sn, Al-2Sn, Al-1Fe, and Al-1.5Fe [wt.%] alloys. The cellular growth as a function of growth and cooling rates is evaluated using power type experimental laws, which allow determining representative intervals of microstructure length scale for comparison purposes with the results of immersion tests in 5 wt%NaOH solution. For both Al alloys systems, hydrogen evolution becomes slower as the alloy solute content increased. However, for a given alloy composition, whereas a more homogeneous distribution of Sn-rich particles promotes faster hydrogen generation using Al-Sn alloys, coarsening of Al6Fe IMCs (intermetallic compounds) fibers favors hydrogen production using Al-Fe alloys. When solidification conditions that result in a range of cellular spacings within 16 and 19 mm are considered, the specific hydrogen production of the Al-1wt.%Fe alloy is higher than that of the other studied alloys. (C) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

This study investigates the quantitative correlations of hydrogen evolution performance with solidification microstructural and thermal parameters in various Al alloys. Results show that hydrogen evolution becomes slower with increased alloy solute content, and the distribution of Sn-rich particles affect hydrogen generation in Al-Sn alloys while coarsening of Al6Fe IMCs fibers favor hydrogen production in Al-Fe alloys. The specific hydrogen production of the Al-1wt.%Fe alloy is higher than other studied alloys under certain solidification conditions.