Unravelling the Tip Effect of Oxygen Catalysis in Integrated Cathode for High-Performance Flexible/Wearable Zn–Air Batteries

IF 17.2 1区 工程技术 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Yirun Shen, Haoning Mao, Chen Li, Keer Li, Yi Liu, Jihai Liao, Shengsen Zhang, Yueping Fang, Xin Cai
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Abstract

The exploration of high-efficiency transition metal–nitrogen–carbon (M–N–C) catalysts is crucial for accelerating the kinetics of oxygen reduction/oxygen evolution reactions (ORR/OER). Fine-tuning the distribution of accessible metal sites and the correlated triphase interfaces within the M–N–C catalysts holds significant promise. In this study, we present an integrated electrocatalyst comprised of tip-enriched NiFe nanoalloys encapsulated within N-doped carbon nanotubes (NiFe@CNTs), synthesized using an in-situ wet-electrochemistry mediated approach. The well-defined NiFe@CNTs catalyst possesses a porous heterostructure, synergistic M–Nx–C active sites, and intimate micro interfaces, facilitating accelerated redox kinetics. This leads to exceptional OER/ORR activities with a low overall ΔE of 630 mV. Experimental results and density functional theory calculations unveil the predominant electronic interplay between the apical bimetallic sites and neighboring N-doped CNTs, thereby enhancing the binding of intermediates on NiFe@CNTs. Molecular dynamics simulations reveal that the local gas–liquid environment surrounding NiFe@CNTs favors the diffusion/adsorption of the OH/O2 reactants. Consequently, NiFe@CNTs contribute to high-performance aqueous Zn–Air batteries (ZABs), exhibiting a high gravimetric energy density (936 Wh kgZn–1) and superb cycling stability (> 425 h) at 20 mA cm–2. Furthermore, solid-state ZABs based on NiFe@CNTs demonstrate impressive electrochemical performance (e.g., peak power density of 108 mW cm−2, specific energy of 1003 Wh kgZn–1) and prominent flexibility. This work illuminates a viable strategy for constructing metal site-specific, cobalt-free, and integrated M–N–C electrocatalysts for multifunctional catalysis and advanced/flexible energy storage applications.

Graphical Abstract

Abstract Image

揭示高性能柔性/耐磨锌-空气电池集成阴极中氧催化的尖端效应
探索高效过渡金属-氮-碳(M-N-C)催化剂对于加速氧还原/氧进化反应(ORR/OER)的动力学至关重要。微调 M-N-C 催化剂中可访问金属位点的分布和相关的三相界面具有重大意义。在本研究中,我们介绍了一种集成电催化剂,它由封装在掺杂 N 的碳纳米管(NiFe@CNTs)中的尖端富集 NiFe 纳米合金组成,采用原位湿电化学介导法合成。定义明确的 NiFe@CNTs 催化剂具有多孔异质结构、协同的 M-Nx-C 活性位点和亲密的微界面,从而促进了氧化还原动力学的加速发展。这使得该催化剂具有卓越的 OER/ORR 活性和 630 mV 的低总 ΔE。实验结果和密度泛函理论计算揭示了顶端双金属位点与邻近掺杂 N 的 CNT 之间的主要电子相互作用,从而增强了 NiFe@CNT 上中间产物的结合。分子动力学模拟显示,NiFe@CNT 周围的局部气液环境有利于 OH-/O2 反应物的扩散/吸附。因此,NiFe@CNT 为高性能水性锌-空气电池(ZABs)做出了贡献,在 20 mA cm-2 的条件下表现出较高的重力能量密度(936 Wh kgZn-1)和超强的循环稳定性(425 h)。此外,基于 NiFe@CNTs 的固态 ZAB 还表现出令人印象深刻的电化学性能(例如,峰值功率密度为 108 mW cm-2,比能量为 1003 Wh kgZn-1)和突出的灵活性。这项工作为构建金属位点特异性、无钴和集成的 M-N-C 电催化剂提供了一种可行的策略,可用于多功能催化和先进/柔性储能应用。
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来源期刊
CiteScore
18.70
自引率
11.20%
发文量
109
期刊介绍: Advanced Fiber Materials is a hybrid, peer-reviewed, international and interdisciplinary research journal which aims to publish the most important papers in fibers and fiber-related devices as well as their applications.Indexed by SCIE, EI, Scopus et al. Publishing on fiber or fiber-related materials, technology, engineering and application.
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