Edge‐Rich Fe−N<sub>4</sub> Active Sites in Defective Carbon for Oxygen Reduction Catalysis

Wang, Xing; Jia, Yi; Mao, Xin; Liu, Daobin; He, Wenxiang; Li, Jia; Liu, Jianguo; Yan, Xuecheng; Chen, Jun; Li, Song; Du, Aijun; Yao, Xiangdong

doi:10.1002/adma.202000966

Cited by 227 publications

(178 citation statements)

References 40 publications

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“…[ 114–120 ] Despite the above‐mentioned pyrrole‐type FeN 4 , most researchers still believe that the pyridinic‐N coordinated metal center is the active site. [ 1,86,121–126 ] In addition to the experimental evidences, general principles were also applied to guide the catalyst design. Cheng and co‐workers established a universal activity descriptor, [ 127 ] expressed as follows

φ = θ_{normald} \times \frac{E_{M} + α \times n_{normalN} \times E_{normalN}}{E_{normalO / normalH}}

where θ d is the number of valence electrons in the metal d‐orbital, E M , E N , and E O/H are the electronegativity of the metal atom, nitrogen atom, and oxygen atom or hydrogen atom, respectively, n N is the number of nearest nitrogen atom around the metal atom, and α is the correction coefficient.…”

Section: Strategies To Tune the Surrounding Environment Of Atomic Metmentioning

confidence: 99%

“…[114][115][116][117][118][119][120] Despite the above-mentioned pyrrole-type FeN 4 , most researchers still believe that the pyridinic-N coordinated metal center is the active site. [1,86,[121][122][123][124][125][126] In addition to the experimental evidences, general principles were also applied to guide the catalyst design. Cheng and co-workers established a universal activity descriptor, [127] expressed as follows…”

Section: Coordinated Nitrogen Atomsmentioning

confidence: 99%

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Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Zhang

Yang

Liu

2020

Advanced Energy Materials

251

185

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Future renewable energy supplies and a sustainable environment rely on many important catalytic processes. Single‐atom catalysts (SACs) are attractive because of their maximum atom utilization efficiency, tunable electronic structures, and outstanding catalytic performance. Of particular note, transition‐metal SACs exhibit excellent catalytic activity and selectivity for the oxygen reduction reaction (ORR)—an important half reaction in fuel cells and metal–air batteries as well as for portable hydrogen peroxide (H2O2) production. Although considerable efforts have been made on the synthesis of SACs for ORR, the regulation of the coordination environments of SACs and thus the electronic structures still pose a big challenge. In this review, strategies for manipulating the coordination environments of SACs are classified into three categories, including regulation of the center metal atoms, manipulation of the surrounding environment connecting to the center metal atom, and modification of the geometric configuration of the support. Finally, some issues regarding the future development of SACs for ORR are raised and possible solutions are proposed.

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φ = θ_{normald} \times \frac{E_{M} + α \times n_{normalN} \times E_{normalN}}{E_{normalO / normalH}}

Section: Strategies To Tune the Surrounding Environment Of Atomic Metmentioning

confidence: 99%

Section: Coordinated Nitrogen Atomsmentioning

confidence: 99%

Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Zhang

Yang

Liu

2020

Advanced Energy Materials

251

185

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“…Meanwhile, the controllable synthesis of defects is also beneficial for probing the structure–performance relationships, thus facilitating the rational design and fabrication of more efficient electrocatalysts for the target reactions. [ 47–49 ]…”

Section: Anion Defects In Transition Metal Compounds For Electrocatalmentioning

confidence: 99%

Defective Structures in Metal Compounds for Energy‐Related Electrocatalysis

2020

Self Cite

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Catalysts play a critical role in accelerating the electrochemical reactions. Engineering the electronic structures and surface properties of electrocatalysts is a feasible approach to improve their catalytic performance. Introducing defects such as anion and cation vacancies into transition metal‐based materials to enhance their activity for various energy‐related electrocatalytic reactions has been receiving increasingly attention in recent years. In this review, a systematic summary of the anion and cation defects on different electrochemical reactions will be presented. In particular, the commonly used methods to produce anion vacancies (such as oxygen, sulfur, and phosphorus defects) and cation vacancies (such as Fe, Co, and Ni defects) will be discussed. The control of the defect density and refilling heteroatoms to stabilize the anion defects and simultaneously to further enhance their catalytic performance are also summarized. In addition, recent work on creating multivacancies in transition metal‐based electrocatalysts for maximizing their catalytic activities is reviewed as well. Finally, future research on defect engineering in metal compounds for electrocatalysis is proposed. This review will guide the further development of various energy‐related electrocatalytic reactions promoted by defective structures in metal composites.

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“…In the nitrogen‐containing modified defect catalysts, defects easily capture metal atoms to form a stable catalyst. [ 49‐52 ] The catalyst has a high density of active sites and a defective environment around the metal center and therefore exhibits excellent catalytic performance. [ 53 ] The defects can accurately determine the electronic structure and surface/interface properties of the catalyst, thereby adjusting the adsorption energy of intermediate substances by destroying the tiny original distribution and generating a new quantum equilibrium, thereby accelerating the kinetics of the electrocatalytic reaction.…”

Section: Synthetic Methods For Atomic Level Dispersed Metal–nitrogen–mentioning

confidence: 99%

Atomic Level Dispersed Metal–Nitrogen–Carbon Catalyst toward Oxygen Reduction Reaction: Synthesis Strategies and Chemical Environmental Regulation

Yin

Xia

Zhao

et al. 2020

Energy & Environ Materials

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For development and application of proton exchange membrane fuel cell (PEMFC) energy transformation technology, the cost performance must be elevated for the catalyst. At present, compared with noble metal‐based catalysts, such as Pt‐based catalysts, atomically dispersed metal–nitrogen–carbon (M–N–C) catalysts are popularity and show great potential in maximizing active site density, high atom utilization and high activity, making them the first choice to replace Pt‐based catalysts. In the preparation of atomically dispersed metal–nitrogen–carbon catalyst, it is difficult to ensure that all active sites are uniformly dispersed, and the structure system of the active sites is not optimal. Based on this, we focus on various approaches for preparing M–N–C catalysts that are conducive to atomic dispersion, and the influence of the chemical environmental regulation of atoms on the catalytic sites in different catalysts. Therefore, we discuss the chemical environmental regulation of the catalytic sites by bimetals, atom clusters, and heteroatoms (B, S, and P). The active sites of M–N–C catalysts are explored in depth from the synthesis and characterization, reaction mechanisms, and density functional theory (DFT) calculations. Finally, the existing problems and development prospects of the current atomic dispersion M–N–C catalyst are proposed in detail.

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Edge‐Rich Fe−N₄ Active Sites in Defective Carbon for Oxygen Reduction Catalysis

Cited by 227 publications

References 40 publications

Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Defective Structures in Metal Compounds for Energy‐Related Electrocatalysis

Atomic Level Dispersed Metal–Nitrogen–Carbon Catalyst toward Oxygen Reduction Reaction: Synthesis Strategies and Chemical Environmental Regulation

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Edge‐Rich Fe−N4 Active Sites in Defective Carbon for Oxygen Reduction Catalysis

Cited by 227 publications

References 40 publications

Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Coordination Engineering of Single‐Atom Catalysts for the Oxygen Reduction Reaction: A Review

Defective Structures in Metal Compounds for Energy‐Related Electrocatalysis

Atomic Level Dispersed Metal–Nitrogen–Carbon Catalyst toward Oxygen Reduction Reaction: Synthesis Strategies and Chemical Environmental Regulation

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Product

Resources

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Edge‐Rich Fe−N₄ Active Sites in Defective Carbon for Oxygen Reduction Catalysis