Your search keyword '"Miao, Zhengpei"' showing total 22 results

1. Bimetallic niobium-iron oxynitride as a highly active catalyst towards the oxygen reduction reaction in acidic media

Author

Luo, Junming, Lu, Zhe, Zhang, Yating, Wu, Daoxiong, Dang, Dai, Yu, Neng, Xu, Yueshan, Feng, Suyang, Wang, Shaolei, Zhang, Zhiyin, Zhao, Yihan, Deng, Peilin, Li, Jing, Miao, Zhengpei, and Tian, Xinlong

Published

2024

2. Self-assembled heterojunction CoSe2@CoO catalysts for efficient seawater electrolysis

Author

Feng, Suyang, Rao, Peng, Yu, Yanhui, Li, Jing, Deng, Peilin, Kang, Zhenye, Wang, Shaolei, Miao, Zhengpei, Shen, Yijun, Tian, Xinlong, and Wu, Zhifu

Published

2023

3. Ternary single atom catalysts for effective oxygen reduction and evolution reactions

Author

Li, Ruisong, Gu, Chengshan, Rao, Peng, Deng, Peilin, Wu, Daoxiong, Luo, Junming, Li, Jing, Miao, Zhengpei, Zheng, Chong-wei, Shen, Chong, and Tian, Xinlong

Published

2023

4. Regeneration of spent cathodes of Li-ion batteries into multifunctional electrodes for overall water splitting and rechargeable Zn-air batteries by ultrafast carbothermal shock

Author

Zheng, Xuerong, Zhao, Xin, Lu, Junda, Li, Jihong, Miao, Zhengpei, Xu, Wei, Deng, Yida, and Rogach, Andrey L.

Published

2022

5. Protection of Fe Single‐Atoms by Fe Clusters for Chlorine‐Resistant Oxygen Reduction Reaction.

Author

Rao, Peng, Liu, Yurong, Shi, Xiaodong, Yu, Yanhui, Zhou, Yu, Li, Ruisong, Liang, Ying, Wu, Daoxiong, Li, Jing, Tian, Xinlong, and Miao, Zhengpei

Subjects

CHEMICAL kinetics, ATOMIC clusters, TRANSMISSION electron microscopes, OXYGEN reduction, DENSITY functional theory

Abstract

Direct seawater zinc‐air batteries (S‐ZABs), with their inherent properties of high energy density, intrinsic safety, and low cost, present a compelling avenue for the development of energy storage technology. However, the presence of chloride ions in seawater poses challenges to their air electrode, resulting in sluggish reaction kinetics and poor stability for the oxygen reduction reaction (ORR). Herein, Fe atomic clusters (ACs) decorated Fe single‐metal atoms (SAs) catalyst (FeSA‐FeAC/NC) is prepared using a plasma treatment strategy. The aberration‐corrected transmission electron microscope images confirm the successful construction of Fe SAs surrounding Fe ACs, which delivers robust ORR activity with a half‐wave potential of 0.886 V in alkaline seawater electrolyte. When utilized as the cathode catalyst in assembled S‐ZABs, the battery demonstrates excellent discharge performance, achieving a peak power density of 222 mW cm−2, which is 2.3 times higher than Pt/C based S‐ZABs. Moreover, density functional theory calculations unveil that the synergy effect between the Fe ACs and SAs not only reduces the spin‐down d‐band center in the Fe SAs, but also efficiently suppresses Cl−1 adsorption on Fe SAs due to their strong Cl−1 absorption ability of the Fe ACs, thereby enhancing both the activity and stability of the catalyst. [ABSTRACT FROM AUTHOR]

Published

2024

6. Carbon nanosheet-supported CrN nanoparticles as efficient and robust oxygen reduction electrocatalysts in acidic media and seawater Zn–air batteries.

Author

Zhang, Yating, Wu, Haoming, Ma, Jun, Luo, Junming, Lu, Zhe, Feng, Suyang, Deng, Yijie, Chen, Hui, Wang, Qi, Miao, Zhengpei, Rao, Peng, Yu, Neng, Yuan, Yuliang, Li, Jing, and Tian, Xinlong

Abstract

Exploring non-precious oxygen reduction reaction (ORR) catalysts is essential to fuel cells and seawater metal–air batteries. Transition metal nitrides are promising ORR catalysts with high corrosion resistance but fail to render satisfactory ORR performance. Herein, we introduce a novel method for the synthesis of carbon nanosheet-supported transition metal nitrides. Using dicyandiamine (DCDA) as the nitrogen and carbon source, we prepared carbon nanosheet-supported CrN nanoparticles (CrN/CNS) via a two-step pyrolysis method. The optimal CrN/CNS material has an ORR half-wave potential (E1/2) of 0.76 V vs. reversible hydrogen electrode (RHE) in acidic media and 0.50 V vs. RHE in simulated seawater, which is one of the best among those reported for transition metal nitrides. Furthermore, the optimal material has remarkable ORR stability in both acidic media and simulated seawater. Its ORR E1/2 shows 27 mV decay in acidic media and 20 mV increase in simulated seawater after stability tests, outperforming a commercial Pt/C catalyst and many transition metal nitrides. More importantly, the optimal CrN/CNS material-based seawater Zn–air batteries (ZABs) exhibit good stability within 200 h constant discharging. It is found that both the proportion of the Cr–N valence state and the Cr content in surfaces played a key role in the ORR activity of CrN/CNS materials. [ABSTRACT FROM AUTHOR]

Published

2024

7. Inside Back Cover: Understanding the improvement mechanism of plasma etching treatment on oxygen reduction reaction catalysts (EXP2 1/2024)

Author

Rao, Peng, primary, Yu, Yanhui, additional, Wang, Shaolei, additional, Zhou, Yu, additional, Wu, Xiao, additional, Li, Ke, additional, Qi, Anyuan, additional, Deng, Peilin, additional, Cheng, Yonggang, additional, Li, Jing, additional, Miao, Zhengpei, additional, and Tian, Xinlong, additional

Published

2024

8. Bimetallic niobium-iron oxynitride as a highly active catalyst towards the oxygen reduction reaction in acidic media

Author

Luo, Junming, primary, Lu, Zhe, additional, Zhang, Yating, additional, Wu, Daoxiong, additional, Dang, Dai, additional, Yu, Neng, additional, Xu, Yueshan, additional, Feng, Suyang, additional, Wang, Shaolei, additional, Zhang, Zhiyin, additional, Zhao, Yihan, additional, Deng, Peilin, additional, Li, Jing, additional, Miao, Zhengpei, additional, and Tian, Xinlong, additional

Published

2023

9. Understanding the improvement mechanism of plasma etching treatment on oxygen reduction reaction catalysts

Author

Rao, Peng, primary, Yu, Yanhui, additional, Wang, Shaolei, additional, Zhou, Yu, additional, Wu, Xiao, additional, Li, Ke, additional, Qi, Anyuan, additional, Deng, Peilin, additional, Cheng, Yonggang, additional, Li, Jing, additional, Miao, Zhengpei, additional, and Tian, Xinlong, additional

Published

2023

10. Understanding the Bifunctional Trends of Fe‐Based Binary Single‐Atom Catalysts

Author

Li, Ruisong, primary, Rao, Peng, additional, Wu, Daoxiong, additional, Li, Jing, additional, Deng, Peilin, additional, Miao, Zhengpei, additional, and Tian, Xinlong, additional

Published

2023

11. Understanding the improvement mechanism of plasma etching treatment on oxygen reduction reaction catalysts.

Author

Rao, Peng, Yu, Yanhui, Wang, Shaolei, Zhou, Yu, Wu, Xiao, Li, Ke, Qi, Anyuan, Deng, Peilin, Cheng, Yonggang, Li, Jing, Miao, Zhengpei, and Tian, Xinlong

Subjects

PLASMA etching, OXYGEN reduction, NITROGEN plasmas, CATALYSTS, IRON

Abstract

Plasma etching treatment is an effective strategy to improve the electrocatalytic activity, but the improvement mechanism is still unclear. In this work, a nitrogen‐doped carbon nanotube‐encased iron nanoparticles (Fe@NCNT) catalyst is synthesized as the model catalyst, followed by plasma etching treatment with different parameters. The electrocatalytic activity improvement mechanism of the plasma etching treatment is revealed by combining the physicochemical characterizations and electrochemical results. As a result, highly active metal–nitrogen species introduced by nitrogen plasma etching treatment are recognized as the main contribution to the improved electrocatalytic activity, and the defects induced by plasma etching treatment also contribute to the improvement of the electrocatalytic activity. In addition, the prepared catalyst also demonstrates superior ORR activity and stability than the commercial Pt/C catalyst. [ABSTRACT FROM AUTHOR]

Published

2024

12. Multimetallic Single-Atom Catalysts for Bifunctional Oxygen Electrocatalysis.

Author

Li, Ruisong, Fan, Wenjun, Rao, Peng, Luo, Junming, Li, Jing, Deng, Peilin, Wu, Daoxiong, Huang, Wei, Jia, Chunman, Liu, Zhongxin, Miao, Zhengpei, and Tian, Xinlong

Published

2023

13. Si Doping Enables Activity and Stability Enhancement on Atomically Dispersed Fe−Nx/C Electrocatalysts for Oxygen Reduction in Acid

Author

Li, Shenzhou, primary, Li, Zhiqiang, additional, Huang, Tianping, additional, Xie, Huan, additional, Miao, Zhengpei, additional, Liang, Jiashun, additional, Pan, Ran, additional, Wang, Tanyuan, additional, Han, Jiantao, additional, and Li, Qing, additional

Published

2022

14. Nanostructure Engineering of Sn‐Based Catalysts for Efficient Electrochemical CO 2 Reduction

Author

Ren, Tiyao, primary, Miao, Zhengpei, additional, Ren, Lu, additional, Xie, Huan, additional, Li, Qing, additional, and Xia, Changlei, additional

Published

2022

15. Effective Approaches for Designing Stable M–Nx/C Oxygen‐Reduction Catalysts for Proton‐Exchange‐Membrane Fuel Cells

Author

Miao, Zhengpei, primary, Li, Shenzhou, additional, Priest, Cameron, additional, Wang, Tanyuan, additional, Wu, Gang, additional, and Li, Qing, additional

Published

2022

16. Nanostructure Engineering of Sn‐Based Catalysts for Efficient Electrochemical CO2 Reduction.

Author

Ren, Tiyao, Miao, Zhengpei, Ren, Lu, Xie, Huan, Li, Qing, and Xia, Changlei

Published

2023

17. Si Doping Enables Activity and Stability Enhancement on Atomically Dispersed Fe−Nx/C Electrocatalysts for Oxygen Reduction in Acid.

Author

Li, Shenzhou, Li, Zhiqiang, Huang, Tianping, Xie, Huan, Miao, Zhengpei, Liang, Jiashun, Pan, Ran, Wang, Tanyuan, Han, Jiantao, and Li, Qing

Subjects

OXYGEN reduction, ELECTROCATALYSTS, METAL catalysts, STANDARD hydrogen electrode, GRAPHITIZATION, HETEROGENEOUS catalysis, FUEL cells

Abstract

Fe−N−C represents the most promising non‐precious metal catalysts (NPMCs) for the oxygen reduction reaction (ORR) in fuel cells, but often suffers from poor stability in acid due to the dissolution of metal sites and the poor oxidation resistance of carbon substrates. In this work, silicon‐doped iron‐nitrogen‐carbon (Si/Fe−N−C) catalysts were developed by in situ silicon doping and metal–polymer coordination. It was found that Si doping could not only promote the density of Fe−Nx/C active sites but also elevated the content of graphitic carbon through catalytic graphitization. The best‐performing Si/Fe−N−C exhibited a half‐wave potential of 0.817 V vs. reversible hydrogen electrode in 0.5 m H2SO4, outperforming that of undoped Fe−N−C and most of the reported Fe−N−C catalysts. It also exhibited significantly enhanced stability at elevated temperature (≥60 °C). This work provides a new way to develop non‐precious metal ORR catalysts with improved activity and stability in acidic media. [ABSTRACT FROM AUTHOR]

Published

2023

18. Precise Synthesis of Dual‐Single‐Atom Electrocatalysts through Pre‐Coordination‐Directed in Situ Confinement for CO2 Reduction.

Author

Rao, Peng, Han, Xingqi, Sun, Haochen, Wang, Fangyuan, Liang, Ying, Li, Jing, Wu, Daoxiong, Shi, Xiaodong, Kang, Zhenye, Miao, Zhengpei, Deng, Peilin, and Tian, Xinlong

Subjects

*BIMETALLIC catalysts, *METAL phthalocyanines, *ELECTROCATALYSTS, *CATALYSTS, *CARBON dioxide

Abstract

Dual‐single‐atom catalysts (DSACs) are the next paradigm shift in single‐atom catalysts because of the enhanced performance brought about by the synergistic effects between adjacent bimetallic pairs. However, there are few methods for synthesizing DSACs with precise bimetallic structures. Herein, a pre‐coordination strategy is proposed to precisely synthesize a library of DSACs. This strategy ensures the selective and effective coordination of two metals via phthalocyanines with specific coordination sites, such as −F− and −OH−. Subsequently, in situ confinement inhibits the migration of metal pairs during high‐temperature pyrolysis, and obtains the DSACs with precisely constructed metal pairs. Despite changing synthetic parameters, including transition metal centers, metal pairs, and spatial geometry, the products exhibit similar atomic metal pairs dispersion properties, demonstrating the universality of the strategy. The pre‐coordination strategy synthesized DSACs shows significant CO2 reduction reaction performance in both flow‐cell and practical rechargeable Zn‐CO2 batteries. This work not only provides new insights into the precise synthesis of DSACs, but also offers guidelines for the accelerated discovery of efficient catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

19. Cobalt Incorporation Promotes CO 2 Desorption from Nickel Active Sites Encapsulated by Nitrogen-Doped Carbon Nanotubes in Urea-Assisted Water Electrolysis.

Author

Zhang Q, Ma S, Xie Y, Pan S, Miao Z, Wang J, and Yang Z

Abstract

The potential application prospects of urea-assisted water electrolysis toward hydrogen production in renewable energy infrastructure can effectively alleviate energy shortages and environmental pollution caused by rich urea wastewater. It is of prominent significance that adjusting the CO 2 desorption of nickel-based electrocatalysts can overcome the slow reaction kinetics for urea oxidation reaction (UOR) to achieve exceptional catalytic activity. In this work, cobalt (Co) metal doping is employed to boost the UOR performance of nitrogen-doped carbon nanotubes encapsulating nickel nanoparticle electrocatalysts (Ni@N-CNT). The influence of diverse Co doping concentrations on the performance of UOR and hydrogen evolution reaction (HER) catalytic activities associated with stability are systematically investigated. The Co dopant can effectively promote the dynamical conversion of Ni to Ni 3+ species; as a result, the UOR catalytic activity is improved by 1.8-fold at 1.6 V vs RHE. The DFT calculation results show that the CoNi bimetallic structure possesses a comparably lower binding energy for CO 2 adsorption accelerating the rate-limiting step. Meanwhile, the Co dopant also boosts the HER performance, achieving a 57 mV reduction in overpotential at 100 mA cm -2 due to the creation of more active sites. In addition, the assembled urea-assisted water electrolysis attains 10 mA cm -2 at merely 1.51 V as well as excellent stability.

Published

2024

20. Si Doping Enables Activity and Stability Enhancement on Atomically Dispersed Fe-N x /C Electrocatalysts for Oxygen Reduction in Acid.

Author

Li S, Li Z, Huang T, Xie H, Miao Z, Liang J, Pan R, Wang T, Han J, and Li Q

Abstract

Fe-N-C represents the most promising non-precious metal catalysts (NPMCs) for the oxygen reduction reaction (ORR) in fuel cells, but often suffers from poor stability in acid due to the dissolution of metal sites and the poor oxidation resistance of carbon substrates. In this work, silicon-doped iron-nitrogen-carbon (Si/Fe-N-C) catalysts were developed by in situ silicon doping and metal-polymer coordination. It was found that Si doping could not only promote the density of Fe-N x /C active sites but also elevated the content of graphitic carbon through catalytic graphitization. The best-performing Si/Fe-N-C exhibited a half-wave potential of 0.817 V vs. reversible hydrogen electrode in 0.5 m H 2 SO 4 , outperforming that of undoped Fe-N-C and most of the reported Fe-N-C catalysts. It also exhibited significantly enhanced stability at elevated temperature (≥60 °C). This work provides a new way to develop non-precious metal ORR catalysts with improved activity and stability in acidic media., (© 2022 Wiley-VCH GmbH.)

Published

2023

21. Nanostructure Engineering of Sn-Based Catalysts for Efficient Electrochemical CO 2 Reduction.

Author

Ren T, Miao Z, Ren L, Xie H, Li Q, and Xia C

Subjects

Adsorption, Electronics, Engineering, Carbon Dioxide, Nanostructures

Abstract

Excessive anthropogenic CO 2 emission has caused a series of ecological and environmental issues, which threatens mankind's sustainable development. Mimicking the natural photosynthesis process (i.e., artificial photosynthesis) by electrochemically converting CO 2 into value-added products is a promising way to alleviate CO 2 emission and relieve the dependence on fossil fuels. Recently, Sn-based catalysts have attracted increasing research attentions due to the merits of low price, abundance, non-toxicity, and environmental benignancy. In this review, the paradigm of nanostructure engineering for efficient electrochemical CO 2 reduction (ECO 2 R) on Sn-based catalysts is systematically summarized. First, the nanostructure engineering of size, composition, atomic structure, morphology, defect, surficial modification, catalyst/substrate interface, and single-atom structure, are systematically discussed. The influence of nanostructure engineering on the electronic structure and adsorption property of intermediates, as well as the performance of Sn-based catalysts for ECO 2 R are highlighted. Second, the potential chemical state changes and the role of surface hydroxides on Sn-based catalysts during ECO 2 R are introduced. Third, the challenges and opportunities of Sn-based catalysts for ECO 2 R are proposed. It is expected that this review inspires the further development of highly efficient Sn-based catalysts, meanwhile offer protocols for the investigation of Sn-based catalysts., (© 2022 Wiley-VCH GmbH.)

Published

2023

22. Effective Approaches for Designing Stable M-N x /C Oxygen-Reduction Catalysts for Proton-Exchange-Membrane Fuel Cells.

Author

Miao Z, Li S, Priest C, Wang T, Wu G, and Li Q

Abstract

The large-scale commercialization of proton-exchange-membrane fuel cells (PEMFCs) is extremely limited by their costly platinum-group metals (PGMs) catalysts, which are used for catalyzing the sluggish oxygen reduction reaction (ORR) kinetics at the cathode. Among the reported PGM-free catalysts so far, metal-nitrogen-carbon (M-N x /C) catalysts hold a great potential to replace PGMs catalysts for the ORR due to their excellent initial activity and low cost. However, despite tremendous progress in this field in the past decade, their further applications are restricted by fast degradation under practical conditions. Herein, the theoretical fundamentals of the stability of the M-N x /C catalysts are first introduced in terms of thermodynamics and kinetics. The primary degradation mechanisms of M-N x /C catalysts and the corresponding mitigating strategies are discussed in detail. Finally, the current challenges and the prospects for designing highly stable M-N x /C catalysts are outlined., (© 2022 Wiley-VCH GmbH.)

Published

2022