Selective Facet Engineering of Ni<sub>12</sub>P<sub>5</sub> Nanoparticle for Maximization of Electrocatalytic Oxidative Reaction of Biomass Chemicals

Ganguly, Souradip; Kaishyop, Jyotishman; Khan, Tuhin Suvra; Aziz, SK Tarik; Dutta, Arnab; Loha, Chanchal; Ghosh, Sirshendu

doi:10.1021/acssuschemeng.4c00269

Cited by 2 publications

(1 citation statement)

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“…Enlightened from above studies, in this research, we introduce several Fe–Co-based double perovskite oxides (A 2 FeCoO 6 ) tuning the A-site with lanthanides (A = Nd, Eu, Gd, and Dy) as highly active trifunctional electrocatalysts for water oxidation and oxygenation of alcohols toward value-added products for energy-saving H 2 production in basic medium (pH = 14) . Small molecule activation-assisted H 2 generation is a promising strategy to generate H 2 at low energy budget. , As anticipated, the best catalyst comes out to be Eu 2 FeCoO 6 , which shows significant lower oxidation potential for benzyl alcohol oxidation of 1.43 V vs RHE compared to water oxidation potential (1.493 V vs RHE) at 20 mA cm –2 in a 1 M NaOH (pH = 14) electrolyte medium. Moreover, the best catalyst, Eu 2 FeCoO 6 , exhibited a potential advantage as high as 70 mV at 20 mA cm –2 for 0.1 M benzyl alcohol oxidation compared to that of OER.…”

Section: Introductionmentioning

confidence: 96%

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

Ganguly,

Datta,

Loha

et al. 2024

Energy Fuels

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In the global development of alternative and sustainable fuels, H 2 has gained prime research interest as combustion of it results in energy with zero carbon footprint. In this context, non-noble metal-based double perovskite oxides with their wide tunable structure gained interest from researchers as an effective electrocatalyst for water oxidation in alkaline medium. However, their low catalytic efficacy and durability limit their application for the industrial scale. Here, we present several Fe−Co-based double perovskite oxides tuning their Asite with lanthanides for overall water splitting and hybrid electrolysis for energysaving H 2 production. The best Fe−Co-based double perovskite oxide, Eu 2 FeCoO 6 , demonstrates very high trifunctional electrocatalytic activity for oxygen evolution reaction (OER) and small alcohol molecule oxidation, along with hydrogen evolution reaction (HER). Overpotentials (η 10 ) of 220 mV for the OER and 238 mV for the HER were attained at 10 mA cm −2 current density in 1 M NaOH (pH = 14). Also, Faradaic yields of 85 and 89% were achieved for ethanol oxidation (EtOR) and benzyl alcohol oxidation (BnOR), respectively, with the best catalyst. Moreover, in a two-electrode electrolyzer with 0.1 M benzyl alcohol (as an electrolyte) and Eu 2 FeCoO 6 as a bifunctional catalyst (both as the cathode and anode, Eu 2 FeCoO 6 (−)∥Eu 2 FeCoO 6 (+)), a cell potential of 1.75 V was enough for oxygenation of benzyl alcohol along with the production of H 2 . A 150 mV advantage in cell potential was gained in BnOR-aided H 2 generation compared with overall water oxidation.

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Section: Introductionmentioning

confidence: 96%

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

Ganguly,

Datta,

Loha

et al. 2024

Energy Fuels

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A Two‐Dimensional Cu‐Based Nanosheet Producing Formic Acid Via Glycerol Electro‐Oxidation in Alkaline Water

Das,

Jain,

Banerjee

et al. 2024

ChemPlusChem

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The sluggishness of the complementary oxygen evolution reaction (OER) is reckoned as one of the major drawbacks in developing an energy‐efficient green hydrogen‐producing electrolyzer. An array of organic molecule oxidation reactions, operational at a relatively low potential, have been explored as a substitute for the OER. Glycerol oxidation reaction (GOR) has emerged as a leading alternative in this context. Additionally, the GOR generates several value‐added organic compounds following oxidation that enhance the cost viability of the overall electrolysis reaction. In this study, a low‐cost, room temperature operable, and energy‐efficient synthetic methodology has been developed to generate unique two‐dimensional CuO nanosheets (CuO NS). This CuO NS material was embedded on a carbon paper electrode, which showcased excellent glycerol electro‐oxidation performance operational at a moderately low applied potential. Formic acid is the major product of this CuO NS‐driven GOR (Faradaic efficiency ~80%), as it is formed primarily via the glyceraldehyde oxidation pathway. This CuO NS material was also active for oxidizing other abundant alcohols like ethylene glycol and diethylene glycol, albeit at a relatively poor efficiency. Therefore, this robust CuO NS material has displayed the potential to be used in large‐scale electrolyzers functioning with HER/GOR reactions.

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Selective Facet Engineering of Ni₁₂P₅ Nanoparticle for Maximization of Electrocatalytic Oxidative Reaction of Biomass Chemicals

Cited by 2 publications

References 40 publications

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

A Two‐Dimensional Cu‐Based Nanosheet Producing Formic Acid Via Glycerol Electro‐Oxidation in Alkaline Water

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Selective Facet Engineering of Ni12P5 Nanoparticle for Maximization of Electrocatalytic Oxidative Reaction of Biomass Chemicals

Cited by 2 publications

References 40 publications

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides

A Two‐Dimensional Cu‐Based Nanosheet Producing Formic Acid Via Glycerol Electro‐Oxidation in Alkaline Water

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Selective Facet Engineering of Ni₁₂P₅ Nanoparticle for Maximization of Electrocatalytic Oxidative Reaction of Biomass Chemicals