Solid-state synthesis of CdFe2O4 binary catalyst for potential application in renewable hydrogen fuel generation

Abdullah M Asiri,Sher Bahadar Khan,Shaik M Zakeeruddin,Khalid A Alamry,Michael Grätzel,Waheed A Adeosun,Hadi M Marwani

doi:10.1038/s41598-022-04999-1

Abdullah M Asiri, Sher Bahadar Khan + Show 5 more

Open Access

https://doi.org/10.1038/s41598-022-04999-1

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Abstract

Clean energy is highly needed at this time when the energy requirements are rapidly increasing. The observed increasing energy requirement are largely due to continued industrialization and global population explosion. The current means of energy source is not sustainable because of several reasons, most importantly, environmental pollution and human health deterioration due to burning of fossil fuels. Therefore, this study develops a new catalyst for hydrogen and oxygen evolution by water splitting as a potential energy vector. The binary metal oxide catalyst CdFe2O4 was synthesized by the solventless solid-mechanical alloying method. The as-prepared catalyst was well characterized by several methods including field emission scanning electron microscopy (FESEM), X-ray diffraction spectroscopy (XRD), X-ray photoelectron spectroscopy (XPS), Fourier Transform infrared red spectroscopy (FTIR), energy dispersive X-ray spectroscopy (XEDS). The as-prepared catalyst, CdFe2O4 was successfully applied for water electrolysis at a moderate overpotential (470 mV). Specifically, the onset potential for the oxygen and hydrogen evolution reactions (OER and HER) were 1.6 V/RHE and 0.2 V/RHE respectively (vs. the reversible hydrogen electrode). The electrode potential required to reach 10 mA/cm-2 for OER (in alkaline medium) and HER (in acidic medium) was 1.70 V/RHE (corresponding to overpotential η = 0.47 and − 0.30 V/RHE (η = − 0.30 V) respectively. Similarly, the developed OER and HER catalyst displayed high current and potential stability for a period of 12 h. This approach is seen as the right track of making water electrolysis for hydrogen energy feasible through provision of low-energy requirement for the electrolytic process. Therefore, CdFe2O4 is a potential water splitting catalyst for hydrogen evolution which is a clean fuel and an antidote for world dependence on fossil fuel for energy generation.

Highlights

Clean energy is highly needed at this time when the energy requirements are rapidly increasing
The environmental problems combined with dwindling fossil fuel supply has called for a sustainable and clean energy source
In another study by Djara et al, lanthanum series based composite was exploited for overall water splitting application

Summary

Introduction

Clean energy is highly needed at this time when the energy requirements are rapidly increasing. In this work, a binary non-noble metal-based catalyst ( CdFe2O4) was developed to provide cheap, effective and stable water splitting catalysts In this new approach increased active sites exposure of Cd/Fe2O4 as well as synergistic effect between the two transition metals is believed to have aided the charge transfer process, involved in the OER reaction to proceed at low over-potentials. The insight into this binary material ( Fe2O3/CdO) was conceived as a result of excellent catalytic and conductivity of the constituent composite. The synthesized CdFe2O4 displayed good stability over an electrolysis period of 12 h

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