Electronegativity-Induced Valence State Augmentation of Ni and Co through Electronic Redistribution between Co-Ni<sub>3</sub>N/CeF<sub>3</sub> Interfaces for Oxygen Evolution Reaction

Gaur, Ashish; John, Joel Mathew; Pundir, Vikas; Kaur, Rajdeep; Bagchi, Vivek

doi:10.1021/acsaem.2c03656

Cited by 14 publications

(11 citation statements)

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“…Superhydrophilic catalysts facilitate the rapid transfer of ions from the electrolyte to the electrode surface, thereby accelerating the mass transport process and ultimately enhancing electrocatalytic performance. 56 To delve deeper into the structural and mechanistic aspects of the OER activity within both the pristine CoFeLDH and the structure with oxygen vacancies (O v ), we conducted DFT (density functional theory) calculations. The structures constructed for DFT calculations are presented in the SI, Figure S10, and the differences between pristine and vacancy structures are shown in Figure 6a.…”

Section: Resultsmentioning

confidence: 99%

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Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Krishankant,

Aashi,

Jain

et al. 2024

ACS Appl. Energy Mater.

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Harnessing the potential of oxygen vacancies (O v ) in metal oxides presents a promising avenue for expediting reaction kinetics in water oxidation. In this context, layered double hydroxides (LDH) offer a versatile platform for developing costeffective electrocatalysts with exceptional performance, thanks to their distinctive lamellar morphology. In this study, we unveil the augmented electrochemical efficiency of CoFeLDH by deliberately inducing an optimal oxygen vacancy (O v ) under ambient conditions for the oxygen evolution reaction (OER). The transformation of CoFeLDH nanorods (CoFeLDH) into O v -rich CoFeLDH (CoFeLDH-O v ) takes place through a chemical reduction process at room temperature. The effect of O v within the catalyst is substantiated through qualitative analyses, such as Xray photoelectron spectroscopy (XPS), photoluminescence (PL), and electron paramagnetic resonance (EPR). The resulting catalyst, CoFeLDH-O v , exhibits an overpotential of 220 mV at a current density of 30 mA/cm 2 in a 1 M KOH electrolyte, indicating an enhanced electroactivity when compared to CoFeLDH (without O v defects). The catalyst also reveals excellent stability for more than 500 h at a higher current density of 50 mA/cm 2 . To validate the catalyst's conducive nature, density functional theory (DFT) calculations are performed, revealing iron (Fe) as the prominent active site within the catalyst. By means of comprehensive experimental and theoretical analyses, the substantial influence of O v on the electronic structure of the LDH system is demonstrated, which, in turn, facilitates facile charge transfer and strengthens the efficiency of the oxygen evolution reaction (OER).

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Section: Resultsmentioning

confidence: 99%

“…The contact angle was measured at 0°, confirming the superhydrophilic nature of the catalyst surface. Superhydrophilic catalysts facilitate the rapid transfer of ions from the electrolyte to the electrode surface, thereby accelerating the mass transport process and ultimately enhancing electrocatalytic performance …”

Section: Resultsmentioning

confidence: 99%

Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Krishankant,

Aashi,

Jain

et al. 2024

ACS Appl. Energy Mater.

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“…[42] The presence of a localized charge distribution at the interface results in the generation of an electro/nucleophilic area, which enhances the adsorption of intermediates. [43] Conversely, the presence of an electron-rich site significantly boosts the ability of hydrogen adsorption and also enhance other electroreduction process, whereas the presence of electron-deficient site significantly boosts the OER. [44][45][46][47] Despite the involvement of several electron transfers and the generation of complicated intermediates, the rational design of electrocatalysts using heterojunction engineering simplifies the process and significantly enhances its kinetic efficiency.…”

Section: Introductionmentioning

confidence: 99%

“…Heterojunctions provide a localized charge distribution at the interface as a result of an inherent electric field created by the disparities in work function of the materials involved [42] . The presence of a localized charge distribution at the interface results in the generation of an electro/nucleophilic area, which enhances the adsorption of intermediates [43] . Conversely, the presence of an electron‐rich site significantly boosts the ability of hydrogen adsorption and also enhance other electroreduction process, whereas the presence of electron‐deficient site significantly boosts the OER [44–47] .…”

Section: Introductionmentioning

confidence: 99%

Electronic Redistribution Through the Interface: A Prodigy that Enhances Electrocatalysis

Gaur,

Sharma,

Bagchi

2024

ChemCatChem

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Efficient design approaches have been developed to create electrocatalysts with the aim of enhancing both the number of active sites and the inherent activity of each individual active site. There is a requirement for more universally applicable approaches to thoroughly understand the activity of electrocatalysts. Heterojunctions have a notable positive impact on electrode surfaces, especially for compounds that have groups capable of donating or withdrawing electrons. Heterojunctions generate a confined distribution of electric charge at the boundary due to an intrinsic electric field caused by the differences in work function between the materials present. The existence of a concentrated charge distribution at the interface leads to the creation of an electro/nucleophilic region, which increases the attraction of intermediary substances. On the other hand, the existence of a site with an abundance of electrons greatly enhances the capacity for hydrogen adsorption and also improves other electroreduction processes. Conversely, the presence of a site with a deficiency of electrons greatly enhances the oxygen evolution reaction (OER). This review summarizes the electron redistribution phenomenon happening after the strong contact between two interfaces. We have explained the charge distribution phenomenon in semiconductor‐semiconductor heterojunctions and metal‐semiconductor heterojunctions.

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“…The primary reason for their poor activity is the excessive e g -orbital lling of nickel, which limits OER performance. [37][38][39] This excess e g -orbital lling also affects the activity of the formed oxyhydroxide. This issue can be addressed by adding a second component to Ni 3 N's original single component to create a cooperative interface.…”

Section: Introductionmentioning

confidence: 99%

Strong coupling effect induced surface reconstruction of CeF₃–Ni₃N to form CeF₃–NiOOH for the oxygen evolution reaction

Kaur¹,

Gaur²,

Sharma³

et al. 2023

Sustainable Energy Fuels

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Electronegativity-Induced Valence State Augmentation of Ni and Co through Electronic Redistribution between Co-Ni₃N/CeF₃ Interfaces for Oxygen Evolution Reaction

Cited by 14 publications

References 50 publications

Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Electronic Redistribution Through the Interface: A Prodigy that Enhances Electrocatalysis

Strong coupling effect induced surface reconstruction of CeF₃–Ni₃N to form CeF₃–NiOOH for the oxygen evolution reaction

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Electronegativity-Induced Valence State Augmentation of Ni and Co through Electronic Redistribution between Co-Ni3N/CeF3 Interfaces for Oxygen Evolution Reaction

Cited by 14 publications

References 50 publications

Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Unfolding the Electrocatalytic Efficiency of Ultrastable CoFeLDH Nanorods by Creating Oxygen Vacancies for OER

Electronic Redistribution Through the Interface: A Prodigy that Enhances Electrocatalysis

Strong coupling effect induced surface reconstruction of CeF3–Ni3N to form CeF3–NiOOH for the oxygen evolution reaction

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Product

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Electronegativity-Induced Valence State Augmentation of Ni and Co through Electronic Redistribution between Co-Ni₃N/CeF₃ Interfaces for Oxygen Evolution Reaction

Strong coupling effect induced surface reconstruction of CeF₃–Ni₃N to form CeF₃–NiOOH for the oxygen evolution reaction