Sukhwa Hong scite author profile

The oxygen evolution reaction (OER) is crucial for producing sustainable energy carriers. Herein, Ir (5 mol.%) doped inverse-spinel NiFe 2 O 4 (Ir-NFO) nanoparticles deposited on Ni foam (NF) by scalable solution casting are considered a promising OER electrocatalyst for industrial deployments. The Ir-NFO/NF (with minimal lattice distortion by uniform Ir doping) provides an OER overpotential of 251 mV (intrinsically outperforming NFO/NF and benchmarking IrO 2 /NF) and extraordinary robustness over 130 days at 100 mA cm −2 . In situ X-ray absorption spectroscopy reveals oxidation only for Fe on NFO, whereas concurrent generation of higher-valent Ni and Fe occurs on Ir-NFO during OER. Density functional theory calculations further demonstrate that Ir substitutes the sublayer Ni octahedral site and switches the main active reaction center from Fe Oh Fe Td bridge site (FeOFe) on NFO to Ni Oh -Fe Td bridge site (NiOFe active motif ) on Ir-NFO for a co-catalytic OER. This study sheds new light on precious-metal doped Ni-Fe oxides, which may be applicable to other binary/ternary oxide electrocatalysts.

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Ni–Fe Oxides/TiO₂ Heterojunction Anodes for Reactive Chlorine Generation and Mediated Water Treatment

Rahman

Hong

Lee

et al. 2023

ACS Appl. Mater. Interfaces

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Reactive chlorine-mediated electrochemical water treatment necessitates selective chlorine evolution reaction (ClER) versus parallel oxygen evolution reaction (OER) in mild pH (7–10), with minimal deployments of precious electrocatalysts. This study reports Ni0.33Fe0.67O y /TiO2 heterojunction anode prepared by a straightforward sol–gel coating with thermal decomposition at 425 °C. The ClER current efficiency (CE, 70%) and energy efficiency (2.3 mmol W h–1) were comparable to benchmarking Ir7Ta3O y /TiO2 at 30 mA cm–2 in 50 mM NaCl solutions with near-neutral pH. Correlations of ClER CE of variable Ni x Fe1–x O y /TiO2 (x: 0.33, 0.8–1) with the flat-band potential and p-band center, as experimental descriptors for surface charge density, nominated the outer TiO2 to be the active ClER center. The underlying Ni0.33Fe0.67O y , characterized as biphasic NiFe2O4 and NiO, effectively lowered the O binding energy of TiO2 by electronic interaction across the junction. The OER activity of Ni0.33Fe0.67O y superior to the other Fe-doped Ni oxides suggested that the conductive OER intermediates generated on Ni0.33Fe0.67O y could also facilitate the ClER as an ohmic contact. Stability tests and NH4 + degradation in synthetic and real wastewater confirmed the feasibility of Ni0.33Fe0.67O y /TiO2 heterojunction anode for mediated water treatments in mild pH.

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Electrochemical Chlorine Evolution by Bi–Ti Oxide with a Heterojunction on Ir–Ta Oxide: Insights from the Effects of Layer Configurations

et al. 2023

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When coated on top of Ir-based dimensionally stable anodes, binary Bi−Ti oxides could enhance the chlorine evolution reaction (ClER) efficiency for chlor-alkali and mediated water treatment. However, the underlying mechanism and the effects of Bi necessitated further clarification. This study prepared Bi x Ti 10-x O y heterojunction layers on an existing Ir 7 Ta 3 O z anode by thermal decomposition (425 °C) of TiOSO 4 and Bi(NO 3 ) 3 under varied Ti:Bi ratios and precursor matrix (inorganic versus organic solvents). Plain material characterizations (scanning electron microscopy and X-ray diffraction) were performed together with voltammetry and potentiostatic electrolysis (in 50 mM NaCl, 50 mM HCOONa, and 0.1 M NaClO 4 ). The top Bi x Ti 10−x O y was nominated as the Cl − binding site with Ir 7 Ta 3 O z as the ohmic contact. Bi 12 TiO 20 and β-Bi 2 O 3 (formed at x > 5) on the outer layer could elevate the reactivity of surface bound hydroxyl radicals and the ClER selectivity. However, relatively loosely packed and thick overlayers (due to glycolate and isopropanol in precursor) aggravated the current and energy efficiency of ClER as well as the anodic stability.

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Sukhwa Hong

Extensive Active-Site Formation in Trirutile CoSb₂O₆ by Oxygen Vacancy for Oxygen Evolution Reaction in Anion Exchange Membrane Water Splitting

Enhanced chlorine evolution from dimensionally stable anode by heterojunction with Ti and Bi based mixed metal oxide layers prepared from nanoparticle slurry

Active Motif Change of Ni‐Fe Spinel Oxide by Ir Doping for Highly Durable and Facile Oxygen Evolution Reaction

Ni–Fe Oxides/TiO₂ Heterojunction Anodes for Reactive Chlorine Generation and Mediated Water Treatment

Electrochemical Chlorine Evolution by Bi–Ti Oxide with a Heterojunction on Ir–Ta Oxide: Insights from the Effects of Layer Configurations

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Sukhwa Hong

Extensive Active-Site Formation in Trirutile CoSb2O6 by Oxygen Vacancy for Oxygen Evolution Reaction in Anion Exchange Membrane Water Splitting

Enhanced chlorine evolution from dimensionally stable anode by heterojunction with Ti and Bi based mixed metal oxide layers prepared from nanoparticle slurry

Active Motif Change of Ni‐Fe Spinel Oxide by Ir Doping for Highly Durable and Facile Oxygen Evolution Reaction

Ni–Fe Oxides/TiO2 Heterojunction Anodes for Reactive Chlorine Generation and Mediated Water Treatment

Electrochemical Chlorine Evolution by Bi–Ti Oxide with a Heterojunction on Ir–Ta Oxide: Insights from the Effects of Layer Configurations

Contact Info

Product

Resources

About

Extensive Active-Site Formation in Trirutile CoSb₂O₆ by Oxygen Vacancy for Oxygen Evolution Reaction in Anion Exchange Membrane Water Splitting

Ni–Fe Oxides/TiO₂ Heterojunction Anodes for Reactive Chlorine Generation and Mediated Water Treatment