An Efficient and Earth‐Abundant Oxygen‐Evolving Electrocatalyst Based on Amorphous Metal Borides

Nsanzimana, Jean Marie Vianney; Peng, Yuecheng; Xu, Yang; Thia, Larissa; Wang, Cheng; Xia, Bao Yu; Wang, Xin

doi:10.1002/aenm.201701475

Cited by 306 publications

(225 citation statements)

References 45 publications

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“…could also be explored by reasonably selecting the reaction precursors and layered materials. In particular, if 2D nanomaterials with unusual crystal phases144–148 or amorphous structures,149–151 and crystal‐phase heterostructures152–155 or amorphous/crystalline hetero‐phase nanostructures156,157 can be prepared via confined synthesis, their promising properties and applications can be explored, which is an important research direction in the near future. Moreover, other host matrices, such as black phosphorus,158,159 hexagonal boron nitride,160,161 graphitic carbon nitride,162,163 silicene,164,165 antimonene,166,167 2D perovskites,168,169 as well as 2D MOFs and COFs, could be developed as new nanoreactors.…”

Section: Discussionmentioning

confidence: 99%

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Zhang

Cheng

et al. 2019

Advanced Energy Materials

139

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2D nanostructured materials have shown great application prospects in energy conversion, owing to their unique structural features and fascinating physicochemical properties. Developing efficient approaches for the synthesis of well‐defined 2D nanostructured materials with controllable composition and morphology is critical. The emerging concept, confined synthesis, has been regarded as a promising strategy to design and synthesize novel 2D nanostructured materials. This review mainly summarizes the recent advances in confined synthesis of 2D nanostructured materials by using layered materials as host matrices (also denoted as “nanoreactors”). By virtue of the space‐ and surface‐confinement effects of these layered hosts, various well‐organized 2D nanostructured materials, including 2D metals, 2D metal compounds, 2D carbon materials, 2D polymers, 2D metal‐organic frameworks (MOFs) and covalent‐organic frameworks (COFs), as well as 2D carbon nitrides are successfully synthesized. The wide employment of these 2D materials in electrocatalytic applications (e.g., electrochemical oxygen/hydrogen evolution reactions, small molecule oxidation, and oxygen reduction reaction) is presented and discussed. In the final section, challenges and prospects in 2D confined synthesis from the viewpoint of designing new materials and exploring practical applications are commented, which would push this fast‐evolving field a step further toward greater success in both fundamental studies and ultimate industrialization.

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Section: Discussionmentioning

confidence: 99%

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Zhang

Cheng

et al. 2019

Advanced Energy Materials

139

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“…Compared with NPs with well‐defined crystalline structures, some amorphous NPs have demonstrated fascinating properties in catalytic reactions due to the abundance of defective sites and the presence of “dangling bonds.” In 2017, Li et al fabricated CeO x ‐induced amorphous Au NPs anchored on reduced graphite oxide (a‐Au/CeO x ‐RGO) with an outstanding performance in electrocatalytic NRR (NH 3 yield rate:8.3 µg mg −1 cat h −1 and FE: 10.10% at −0.2 V versus RHE) . In the control experiment, α‐Au/CeO x ‐RGO significantly outperformed its crystalline counterpart (c‐Au/RGO, NH 3 yield: 3.5 µg mg −1 cat h −1 , FE: 3.67%).…”

Section: Advanced Catalysts For Nitrogen Conversion To Ammoniamentioning

confidence: 99%

Recent Advanced Materials for Electrochemical and Photoelectrochemical Synthesis of Ammonia from Dinitrogen: One Step Closer to a Sustainable Energy Future

Yan

Xia

et al. 2019

Advanced Energy Materials

122

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Ammonia (NH3), an important raw material for chemical industry and agriculture, is also considered to be an intriguing energy storage and transportation media for chemical conversion schemes. The world's primary NH3 supply is based on the natural nitrogen fixation by diazotrophs through an enzymatic nitrogenase process and the industrial nitrogen fixation through a traditional Haber–Bosch process. The natural synthesis of NH3 can hardly meet the rapidly growing global demand. Meanwhile, the industrial NH3 production is still dominated by the high‐temperature and high‐pressure reaction between nitrogen and hydrogen (N2 + 3H2 → 2NH3), requiring intensive energy input and generating massive CO2. Therefore, seeking a breakthrough in the development of catalysts toward efficient ammonia synthesis has become the frontier of energy and chemical conversion schemes. This review summarizes and discusses the recent progress on developing new strategies to optimize the efficiency of NH3 production coupled with renewable energy sources, with a specific focus on electrocatalytic and photoelectrocatalytic conversion of N2 to NH3. The most recent advances in the development of catalytic materials, the design of the reaction systems, and the computational insights for electrochemical and photoelectrochemical ammonia synthesis are covered.

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“…Harsh conditions, such as high temperature, high pressure, or highly negative electrical potentials, are generally required to convert CO 2 into other carbon compounds . On the other hand, the catalytic reduction of CO 2 via multiproton–multielectron‐coupled transfer in aqueous solutions into value‐added chemical/fuels has been regarded as a promising approach, due to its mild reaction conditions and potential product selectivity …”

Section: Introductionmentioning

confidence: 99%

Nanostructured Copper‐Based Electrocatalysts for CO₂ Reduction

et al. 2018

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The continuous increase of CO2 concentration in the atmosphere has been imposing an imminent threat for global climate change and environmental hazards. In recent years, the electrochemical or photochemical conversion of CO2 into value‐added chemicals or fuels has received significant attention, as it may enable an attractive means to mitigate the atmospheric CO2 concentration and complete the imbalanced carbon‐neutral energy cycle, as well as create renewable energy resources for human use. Among the different electrocatalysts being studied, Cu‐based materials have been demonstrated as the only category of candidates that allows the conversion of CO2 into a variety of reducing products, including carbon monoxide, hydrocarbons, and alcohols. Herein, the reaction pathways for different Cu‐based catalysts for C1 and C2+ products are introduced. Then, different parameters in tuning Cu‐based electrocatalysts are summarized and discussed, including the morphologies, compositions, crystal facets, and oxide derivation. In addition, various types of parameters for CO2 electroreduction are also described, particularly the option of electrolytes such as aqueous, ionic liquids, and organic solutions. Finally, the current challenges are discussed and the potential strategies to facilitate the future development of CO2 electroreduction are summarized.

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An Efficient and Earth‐Abundant Oxygen‐Evolving Electrocatalyst Based on Amorphous Metal Borides

Cited by 306 publications

References 45 publications

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Recent Advanced Materials for Electrochemical and Photoelectrochemical Synthesis of Ammonia from Dinitrogen: One Step Closer to a Sustainable Energy Future

Nanostructured Copper‐Based Electrocatalysts for CO₂ Reduction

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An Efficient and Earth‐Abundant Oxygen‐Evolving Electrocatalyst Based on Amorphous Metal Borides

Cited by 306 publications

References 45 publications

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Confined Synthesis of 2D Nanostructured Materials toward Electrocatalysis

Recent Advanced Materials for Electrochemical and Photoelectrochemical Synthesis of Ammonia from Dinitrogen: One Step Closer to a Sustainable Energy Future

Nanostructured Copper‐Based Electrocatalysts for CO2 Reduction

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Product

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Nanostructured Copper‐Based Electrocatalysts for CO₂ Reduction