Catalytic Activity of Methane Oxidation on Nickel-doped Lanthanum Strontium Titanate Perovskite from Three Synthesis Methods

Abstract

BackgroundThree perovskites of nickel-doped lanthanum strontium titanate (LSTN) were made and compared for their activity toward methane oxidation. MethodThe perovskite was synthesized separately via solid-state reaction, citrate complexation, and microwave-assisted methods. Significant FindingsThe perovskite from solid state reaction gave the highest activity of syngas production in repetitive redox cycles without any deterioration, demonstrating a great potential for use in chemical looping technology. Nevertheless, the material required activation in methane, as evidenced in studies of temperature-programmed surface reaction. On the contrary, the perovskite from the complexation method behaved completely different while the microwave-synthesized one gives the poorest activity. The variation of the activity was correlated with the distinct structure from different synthesis routes, which influences where a metal phase resides and how the metal anchors onto host oxides. The information obtained here would be of great benefit in making good material with desirable properties for catalysis and potential applications.