Effect of graphite as a co-dopant on the dehydrogenation and hydrogenation kinetics of Ti-doped sodium aluminum hydride

• Published in: Journal of alloys and compounds Vol. 395; no. 1; pp. 252 - 262
• Main Authors: Wang, Jun, Ebner, Armin D., Prozorov, Tanya, Zidan, Ragaiy, Ritter, James A.
• Format: Journal Article
• Language: English
• Published: Lausanne Elsevier B.V 31.05.2005; Elsevier
• Subjects: Aluminum; Complex hydrides; Exact sciences and technology; Graphite; Hydrogen spillover; Hydrogen storage; Lubrication; Micro-grinding; Physics; SEM; Sodium aluminum hydride; Titanium chloride; XPS; Micro-grinding; Hydrogen storage; Aluminum; Graphite; Sodium aluminum hydride; Complex hydrides; Titanium chloride; SEM; XPS; Lubrication; Hydrogen spillover; Catalysts; Doping; Hydrides; Hydrogenation; Titanium additions; Titanium; Powders; TDS; Ball mill; Aluminium; Desorption; Irreversible processes; Sodium; Dehydrogenation; Aluminium additions; Kinetics; Codoping
• ISSN: 0925-8388; 1873-4669
• DOI: 10.1016/j.jallcom.2004.11.053

The synergistic effect of graphite as a co-dopant on the dehydrogenation and hydrogenation kinetics of Ti-doped NaAlH 4 has been observed for the first time. According to temperature programmed desorption curves obtained at 2 °C/min, the dehydrogenation temperature in the 90–150 °C range decreased by as much as 15 °C for NaAlH 4 co-doped with 10 wt.% graphite (G) and up to 4 mol% TiCl 3 compared to similarly doped and ball milled samples without graphite. Constant temperature desorption curves at 90 and 110 °C obtained for NaAlH 4 co-doped with 2 mol% TiCl 3 and 10 wt.% G also, respectively, revealed improvements in the dehydrogenation kinetics of 6.5 and 3.0 times that of a similarly prepared sample without graphite. In contrast, graphite as a single dopant was essentially inactive as a catalyst. The effects of graphite persisted through dehydrogenation/hydrogenation cycling, and through the addition of aluminum (Al) powder, which was added to mitigate irreversible kinetic and capacity losses during cycling. A sample of NaAlH 4 co-doped with 2.0 mol% TiCl 3, 10 wt.% G and 5 wt.% Al exhibited perhaps the best dehydrogenation and hydrogenation rates to date. The observed phenomena were interpreted in terms of some of the unique properties of graphite: graphite might be playing a dual role by serving as a mixing agent manifested through lubrication phenomena (i.e., graphene layer slippage and breakage), and as a micro-grinding agent manifested through the formation of carbide species, both during high energy ball milling. In these capacities, graphite may have caused the Ti particles to be more finely ground and hence more dispersed over the surfaces of the NaAlH 4 particles and also the graphite particles themselves. Graphite might also be imparting an electronic contribution through the interaction of its facile π-electrons with Ti through a hydrogen spillover mechanism, whereby it back donates some electrons to Ti, which further facilitates hydrogen bond formation and cleavage through this Ti species. Research is continuing with graphite as a co-dopant.