Intermetallic iron aluminide (FeAl) in the submicrometer range is an emerging material for industrial applications due to its improved ductility and enhanced properties. In addition, preparing high-surface-area FeAl powder is highly desired due to its catalyst applications. The chemical synthesis of FeAl is feasible for mass production. However, previous synthesis methods require extensive use of toxic chemicals, organic solvents, and specialized environment-controlled facilities. To achieve a cleaner synthesis of FeAl powder with a high surface area, herein, we propose a new synthesis route. First, an Fe–Al oxide precursor, FeAl2O4, was prepared from iron and aluminum nitrates. Then, the oxide precursor was reduced to FeAl using CaH2 in molten LiCl at 600°C–700 °C. The reduction at 700 °C resulted in a single-phase intermetallic FeAl without any impurity phase, whereas at 600 °C and 650 °C, a trace of Al(OH)3 was detected under X-ray diffraction, indicating an incomplete reduction. N2 adsorption–desorption analyses and scanning and transmission electron microscopy with energy-dispersive X-ray spectroscopy confirmed the formation of submicrometer FeAl particles. The surface area of the prepared FeAl powder was as high as 88 m2/g, which is three times higher than that reported for Fe3Al nanoparticles prepared via a physical approach. We further performed a screening-level lifecycle assessment to evaluate the prospective environmental impact of the FeAl synthesis route. The cumulative energy demand and global warming potential associated with 1-kg-FeAl synthesis were 566 MJ and 41 kg CO2e, respectively, which are about half of those for existing LiAlH4-based methods. Therefore, the proposed synthesis route is promising for environmentally friendly synthesis of FeAl particles.
Read full abstract