Highly Effective OER Electrocatalysts Generated from a Two-Dimensional Metal–Organic Framework Including a Sulfur-Containing Linker without Doping

Li, Tang-Ming; Hu, Bingqian; Han, Jinghua; Lu, Wenxian; Yu, Fan; Li, Bao

doi:10.1021/acs.inorgchem.2c00493

Cited by 10 publications

(3 citation statements)

References 63 publications

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“…1,2 The global energy crisis and serious environmental pollution have prompted researchers to explore clean energy and energy storage equipment to protect the global environment while developing the economy. [3][4][5] Excellent energy storage equipment can not only solve the sustainability problem of intermittent clean energy sources such as hydrogen energy, wind energy, solar energy, and tidal energy, [6][7][8] but can also improve effective utilization and save energy. In recent years, fuel cells, rechargeable batteries, supercapacitors and other types of excellent energy storage equipment have been widely used in industry, such as automotive, electronics, medicine and other industries.…”

Section: Introductionmentioning

confidence: 99%

Manganese–cobalt hydroxide nanosheets anchored on a hollow sulfur-doped bimetallic MOF for high-performance supercapacitors and the hydrogen evolution reaction in alkaline media

Zhang,

Sun,

et al. 2024

Dalton Trans.

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Section: Introductionmentioning

confidence: 99%

Manganese–cobalt hydroxide nanosheets anchored on a hollow sulfur-doped bimetallic MOF for high-performance supercapacitors and the hydrogen evolution reaction in alkaline media

Zhang,

Sun,

et al. 2024

Dalton Trans.

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“…With the rapid development of human society, excessive consumption of fossil fuels has caused serious energy crises and environmental concerns. It is particularly vital to seek sustainable, clean, and efficient technologies to resolve energy and environmental problems. − Electrochemical water splitting has attracted wide attention as the most potent way to produce hydrogen energy instead of traditional hydrogen production. , Typically, electrochemical water splitting comprises two half-reactions including the anodic oxygen evolution reaction (OER) with a four-electron transfer and the cathodic hydrogen evolution reaction (HER) with a two-electron transfer. − Because of the intricate reaction pathways and complex oxygen-involving intermediates, the reaction kinetics of OER is sluggish and requires a high overpotential to overcome the reaction energy barrier. Hence, developing highly efficient OER catalysts is essential for the further application of OER and water splitting. , Among various candidates, catalysts based on noble metals, such as Ru and Ir, exhibit the ideal performance toward OER. − However, their scarcity and high price hinder their widespread generalization.…”

Section: Introductionmentioning

confidence: 99%

Realizing a Lattice Se Atom-Modified Co Hydroxide Catalyst via Electrochemical Reconstruction for Enhanced Oxygen Evolution Performance

et al. 2023

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Realizing a highly efficient oxygen evolution reaction (OER) process is of great significance for hydrogen energy development. The main challenge still lies in fabricating superior electrocatalysts with favorable performance. Constructing electrocatalysts with ingenious lattice modifications is a considerable way for the rational design of highly active catalytic centers. Here, theoretical calculations predict that the lattice incorporation of Se atoms can effectively enhance the reaction activity of OER with a decreased energy barrier for the rate-determining step. To obtain the corresponding desired electrocatalyst, the optimized lattice Se-modified CoOOH, with the ideal OER performance of low overpotential and stability, was delicately designed and fabricated by the electrochemical activation of the Co 0.85 Se precatalyst. Xray absorption spectroscopy (XAS) demonstrates that lattice incorporation is more likely to be generated in Co 0.85 Se compared to CoSe 2 and CoO precatalysts, which promoted the subsequent OER process. This work clarified the correlation between the precatalyst and the lattice-modified final catalyst in connection with electrochemical reconstruction.

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“…Developing new technologies to obtain renewable energy and exploiting alternatives to fossil fuels have drawn global interest with ever-growing global energy demand and environmental degradation. − Electrocatalytic oxygen evolution reaction (OER) plays a crucial part in renewable-energy conversion and storage technologies, like metal–air batteries, water electrolysis, and fuel cells. − Nevertheless, the OER has sluggish kinetics as a result of the four-electron proton coupling process in alkaline media, which usually causes high overpotentials, greatly reducing the energy conversion efficiency of the equipment. − As a result, effective electrocatalysts for OER (2H 2 O → O 2 + 4H + +4e – ) have been thoroughly investigated to overcome the sluggish OER process. To date, Ir- and Ru-based catalysts are still recognized as state-of-the-art OER electrocatalysts, but their disadvantages of inherent scarcity, low stability, and high expense badly hindered their industrialization. − Consequently, a key target for researchers is to design and develop a nonprecious metal-based OER electrocatalyst with low expenses, high catalytic activity, and robust durability, as well as understand the underlying mechanism. − The corresponding design will be developed based on several considerations, including suitable dimensionality and morphology, favorable conductivity, and numerous exposed active sites, among others. , …”

Section: Introductionmentioning

confidence: 99%

Self-Reconstruction of Fe-Doped Co-Metal–Organic Frameworks Boosted Electrocatalytic Performance for Oxygen Evolution Reaction

Wang

et al. 2022

Inorg. Chem.

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Rational design of facile and low-cost efficient electrocatalysts for oxygen evolution reaction (OER) is crucial to solve the energy crisis. Benefiting from in situ self-reconstruction from metal–organic frameworks (MOFs) to (oxy)hydroxides in alkaline electrolytes, MOFs have become alternative OER catalysts. Thus, Fe-doped Co-MOF nanosheets (Co-MOF/Fe) were prepared and utilized straightforwardly as OER electrocatalysts. CoFe-layered bimetallic hydroxides (CoFe-LDHs) with abundant active sites are obtained from in situ conversion of Co-MOF/Fe after etching by the KOH electrolyte, which are generally actual active species. Meanwhile, the introduction of Fe ions will also produce a synergistic effect that greatly improves the electrocatalytic OER performance. The optimized catalyst (Co-MOF/Fe10) shows exceptional OER activity (η10 = 260 mV) and excellent durability over 50 h. The outstanding OER performance of Co-MOF/Fe10 can also be reflected in the two-electrode hydrolyzer (1.57 V at 10 mA cm–2). This study offers a pathway to probe the catalytic mechanism of MOFs and the rational construction of efficient MOF-derived catalysts.

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Highly Effective OER Electrocatalysts Generated from a Two-Dimensional Metal–Organic Framework Including a Sulfur-Containing Linker without Doping

Cited by 10 publications

References 63 publications

Manganese–cobalt hydroxide nanosheets anchored on a hollow sulfur-doped bimetallic MOF for high-performance supercapacitors and the hydrogen evolution reaction in alkaline media

Manganese–cobalt hydroxide nanosheets anchored on a hollow sulfur-doped bimetallic MOF for high-performance supercapacitors and the hydrogen evolution reaction in alkaline media

Realizing a Lattice Se Atom-Modified Co Hydroxide Catalyst via Electrochemical Reconstruction for Enhanced Oxygen Evolution Performance

Self-Reconstruction of Fe-Doped Co-Metal–Organic Frameworks Boosted Electrocatalytic Performance for Oxygen Evolution Reaction

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