The alloy also reduces the energy required to generate oxygen from water, making the catalyst bifunctional.
The researchers published their study in Nano Research Energy.
“What really limits the development and practical application of water electrolysis technology is electrocatalytic materials,” said Yifu Zhang, senior author of the study and researcher in the School of Chemistry at Dalian University of Technology. “At present, common catalysts, such as precious metals, are mostly single-function catalysts, which limits the practical application of water electrolysis for hydrogen production. Therefore, the research and development of efficient, stable, cheap and environmentally friendly bifunctional electrocatalytic materials is a primary goal in the field of electrocatalysis.”
Transition metal silicide alloys are unique compounds that are commonly used in energy-related fields, are cheaply produced and show promise as potential electrocatalysts. These alloys are made from transition metals, which are excellent catalysts that freely donate and accept electrons in chemical reactions, and silicone atoms, which enhance the stability, heat resistance and accessibility of alloy transition metal atoms when electricity is applied.
Iron and nickel, two transition metals, are well-suited for use in a transition metal silicide for water splitting. “Nickel silicide has been deeply studied for its low resistance and high metal activity, especially in electrochemical fields. In addition, many recent studies have shown that Fe-Ni based materials have considerable potential in the field of electrochemical water splitting. The aim of this work was to develop a low-cost, environmentally friendly route to prepare iron nickel silicide as a bifunctional electrolytic water catalyst (EWS),” said Zhang.
The research team manufactured FeNiSi in two steps. First, natural clay magadiite, a source of silicon, iron chloride and nickel chloride were heated under pressure to create a ferric-nickel silicate. The ferric-nickel silicate was then combined and heated with magnesium and sodium chloride (table salt) to develop the ordered structure of the FeNiSi alloy. Importantly, this was the first time a metallic silicide alloy had been manufactured using this type of chemical reaction, using metallic silicates as a reaction material.
Electron microscopy and X-ray characterization techniques revealed that the manufacturing process created many pore structures in the final FeNiSi alloy, increasing its surface area and overall electrocatalytic performance. The FeNiSi alloy lowers the potential required to split oxygen and hydrogen from water by 308 mV for the oxygen evolution reaction (OER) and 386 mV for the HER, respectively, at a current of 10 mA·cm⁻². The electrocatalyst also demonstrated sufficient durability after 15 hours of use.
The research team looks forward to FeNiSi and other transition metal silicates contributing to the synthesis of clean hydrogen gas for future energy needs.
“This work not only provides an easy method for the synthesis of intermetallic silicide with considerable porous structures but also allows the intermetallic silicide to be considered as a bifunctional electrocatalyst for EWS. Low-cost and efficient intermetallic silicide electrocatalysts will provide new opportunities for renewable energy conversion,” said Zhang.
Other contributors include Xuyang Jing, Yang Mu, Zhanming Gao and Xueying Dong from the School of Chemistry at Dalian University of Technology in Dalian, China; Changgong Meng from the School of Chemistry and the College of Environmental and Chemical Engineering at Dalian University of Technology; and Chi Huang from the College of Chemistry and Molecular Sciences at Wuhan University in Wuhan, China.
