Enabling Direct H2O2 Production in Acidic Media through Rational Design of Transition Metal Single Atom Catalyst

Gao, Jiajian; Yang, Hong Bin; Huang, Xiang; Hung, Sung‐Fu; Cai, Weizheng; Jia, Chunmiao; Miao, Shu; Chen, Hao Ming; Yang, Xiaofeng; Huang, Yanqiang; Zhang, Tao; Liu, Bin

doi:10.1016/j.chempr.2019.12.008

Cited by 456 publications

(476 citation statements)

References 57 publications

(82 reference statements)

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“…Gao et al found that the Co SAC has the optimum close to zero ΔG OOH* among Mn, Fe, Co, Ni, and Cu, suggesting it has the highest catalytic activity toward the two-electron ORR pathway ( Figure 5C). 31 The subsequent electrochemical tests were consistent with the theoretical prediction, showing that the Co-NC SAC even slightly outperformed the best previously reported catalysts in acidic media, the Pd-Hg alloy. 114 Jiang et al conducted a study on the two-electron ORR SACs with CNTs as the support.…”

Section: Oxygen Reduction Reaction (Orr)supporting

confidence: 85%

“…For instance, the two-electron pathway ORR is more favorable on SACs since the adsorption of O 2 preferably takes the end-on configuration, which favors the formation of OOH* instead of O-O bond cleavage. 31 The strong metal-support interaction not only stabilizes the isolated atoms and prevents the agglomerations, but also substantially modulates the atom electronic state via charge-transfer. This is frequently discussed and demonstrated via characterization techniques and density funcitonal theory (DFT) calculations.…”

Section: Introductionmentioning

confidence: 99%

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Designing the future atomic electrocatalyst for efficient energy systems

Sun

Huang

2020

Engineering Reports

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Following the fast development of electrocatalysts, atomic catalysts have surely become the most frontier research topic in energy supply systems. In varied electrochemical reactions, they have displayed untapped potential for practical applications due to the exceptional performances in both electroactivity and selectivity, ultra‐high metal utilization, and flexible substrates. Besides the conventional experimental synthesis strategies and characterization techniques, advanced theoretical calculations and even machine learning algorithms have been introduced to understand and predict the electrocatalysis performances of novel atomic catalysts, supplying the insightful knowledge for the future rational design and synthesis of the atomic catalyst with the desired properties. Therefore, this review will highlight the recent advance achievements in atomic catalysts regarding the atomic catalyst synthesis and applications, covering the mainstream electrochemical process in energy applications. Meanwhile, we also summarize the application of advanced theoretical explorations as valuable references for future electrocatalyst design. Moreover, we will summarize the existing challenges for the practical applications and the prospects of present atomic catalysts.

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Section: Oxygen Reduction Reaction (Orr)supporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Designing the future atomic electrocatalyst for efficient energy systems

Sun

Huang

2020

Engineering Reports

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“…More recently, Liu and co-workers carried out a detailed kinetic analysis on Co-NC single atom catalyst for 2e − ORR in acidic media. [98] By tuning electrolyte pH and O 2 partial pressure, they observed a H + reaction order of −0.05-−0.07 and a O 2 reaction order of 0.53-0.9 within an overpotential of 0 to 250 mV, suggesting the first electron transfer step (O 2 + * + e − → *O 2 − ) to be the rate-limiting step for H 2 O 2 synthesis at this onset region (Figure 5c).…”

Section: Defects and Heteroatoms Engineering On Carbon-based Catalystsmentioning

confidence: 99%

“…Reproduced with permission. [98] Copyright 2020, Elsevier. d) Atomic distribution and coordination environmental analysis of Fe−CNT catalyst by atom probe topography, together with the determined H 2 O 2 selectivity on different motifs.…”

Section: Defects and Heteroatoms Engineering On Carbon-based Catalystsmentioning

confidence: 99%

Catalyst Design for Electrochemical Oxygen Reduction toward Hydrogen Peroxide

Jiang

Zhao

Wang

2020

Adv Funct Materials

183

101

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Precise electrochemical synthesis under ambient conditions has provided emerging opportunities for renewable energy utilization. Among many promising systems, the production of hydrogen peroxide (H2O2) from the cathodic oxygen reduction reaction (ORR) has attracted considerable interest in past decades due to the increasing market demands and the vital role of ORR in the electrocatalysis field. This work describes recent advances in cathodic materials for H2O2 synthesis from 2e- ORR. By using Pt as a stereotype, the tuning knobs are overviewed, including the intrinsic binding strength of oxygenated species, the intermediate diffusion path and the isolation of Pt–Pt ensembles that enable 2e- ORR pathway from 4e- total reduction. This knowledge is successfully applied to other transition metal systems and leads to the discovery of more efficient alloy catalysts with balanced improvement on both activity and selectivity. In addition, mesostructure engineering and heteroatoms doping strategies on carbon‐based materials, which significantly boost the H2O2 production efficiency as compared to intact carbon sites, are also reviewed. Finally, future directions and challenges of transferring developed catalysts from lab scale tests to pilot plant operations are briefly outlooked.

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“…97 Thirdly, the enzyme-like catalysis on SAzymes in essence is the heterocatalysis process, the selectivity arises from the differences of interaction force between single-sites and reactants, which includes the adsorption, desorption, and electron and proton transfer processes. Based on the well-established singleatom electrocatalyst and electrochemical research systems, the reaction kinetics and electrocatalytic properties of SACs could be extended to the analogous enzyme-like catalysis to ltrate highly selective SAzymes, 98 for instance, the SACs with highly selectivity in four-electron or two-electron oxygen reduction reaction electrocatalysis respectively corresponding to the halfreaction of oxidase-like or glucose oxidase-like SAzyme catalysis. 99,100 Shen et al reported the catalyst of single-atom Pt with a CuS x support (h-Pt 1 -CuS x ), which can consistently reduce O 2 to H 2 O 2 with high selectivity.…”

Section: Enzyme-like Selectivitiesmentioning

confidence: 99%