Litcius/Paper detail

Enhanced initial hydrogenation of TiFe-based hydrogen storage alloys containing C

Kyubin Hwang, Taejun Ha, S. Lee, Si-Won Jin, Young‐Kook Lee, Young‐Su Lee, Yunseok Kim, Jae-Hyeok Shim

2025Journal of Alloys and Compounds7 citationsDOIOpen Access PDF

Abstract

The hydrogen storage properties of TiFe-based AB-type alloys containing up to 6 at% C were evaluated, with particular emphasis on the effect on the initial hydrogenation properties. The addition of C formed substoichiometric TiC 1-x particles with a dendritic morphology as the secondary phase in the TiFe-phase matrix. Interestingly, the initial hydrogenation of the alloys with TiC particles was significantly enhanced at 50 ℃, whereas the alloy without C was not hydrogenated. Moreover, the initial hydrogenation was kinetically accelerated with increasing loading of TiC particles. The hydrogen storage capacity tended to increase with increasing TiC content in the pressure-composition-isotherm curves of the alloys measured after initial hydrogenation. No significant degradation in the hydrogen storage capacity of the alloys containing C was observed during the hydrogen sorption cycles. The initial hydrogenation started around the TiC particles, where primary cracks were caused by volume expansion induced by the formation of hydride phases. The TiC particles provide pathways for hydrogen diffusion into the TiFe matrix along the interphase boundaries between these particles and the matrix, and through the particles with vacant C sites during the initial hydrogenation. The study shows that the addition of carbon, a common impurity in raw materials for the fabrication of TiFe-based hydrogen storage alloys, is very effective in enhancing the initial hydrogenation, which is a chronic problem for these alloys. • Carbon addition forms TiC particles with a dendritic shape in TiFe-based alloys. • Initial hydrogenation kinetics of the alloys is significantly enhanced with TiC particles. • No significant degradation is observed during hydrogen sorption cycles of the alloys. • The initial hydrogenation starts at TiC particles with crack formation in the TiFe matrix. • TiC particles provide hydrogen diffusion pathways into the matrix during initial hydrogenation.

Topics & Concepts

Hydrogen storageMaterials scienceHydrogenAlloyHydrideChemical engineeringDiffusionSorptionCarbon fibersFabricationInterphaseImpurityDegradation (telecommunications)Titanium alloyPhase (matter)KineticsCatalysisMetallurgyTransition metalTitanium carbideMatrix (chemical analysis)Volume (thermodynamics)TitaniumInorganic chemistryCarbon capture and storage (timeline)Melt spinningCapacity lossHydrogen Storage and MaterialsCatalysis and Hydrodesulfurization StudiesCatalysts for Methane Reforming