Sustainable Furfural Biomass Feedstocks Electrooxidation toward Value-Added Furoic Acid with Energy-Saving H2 Fuel Production Using Pt-Decorated Co3O4 Nanospheres
Received date: 03 Oct 2022
Revised date: 17 Nov 2022
Copyright
Here, furfural oxidation was performed to replace the kinetically sluggish O2 evolution reaction (OER). Pt-Co3O4 nanospheres were developed via pulsed laser ablation in liquid (PLAL) in a single step for the paired electrocatalysis of an H2 evolution reaction (HER) and furfural oxidation reaction (FOR). The FOR afforded a high furfural conversion (44.2%) with a major product of 2-furoic acid after a 2-h electrolysis at 1.55 V versus reversible hydrogen electrode in a 1.0-M KOH/50-mM furfural electrolyte. The Pt-Co3O4 electrode exhibited a small overpotential of 290 mV at 10 mA cm-2. As an anode and cathode in an electrolyzer system, the Pt-Co3O4 electrocatalyst required only a small applied cell voltage of ∼1.83 V to deliver 10 mA cm-2, compared with that of the pure water electrolyzer (OER||HER, ∼1.99 V). This study simultaneously realized the integrated production of energy-saving H2 fuel at the cathode and 2-furoic acid at the anode.
Talshyn Begildayeva , Jayaraman Theerthagiri , Seung Jun Lee , Ahreum Min , Gyeong-Ah Kim , Sivakumar Manickam , Myong Yong Choi . Sustainable Furfural Biomass Feedstocks Electrooxidation toward Value-Added Furoic Acid with Energy-Saving H2 Fuel Production Using Pt-Decorated Co3O4 Nanospheres[J]. Energy & Environmental Materials, 2024 , 7(2) : 12563 . DOI: 10.1002/eem2.12563
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