Aluminum vacancy-rich MOF-derived carbon nanosheets for high-capacity and long-life aqueous aluminum-ion battery

EcoEnergy Pub Date : 2024-06-24 DOI:10.1002/ece2.49
Jiuzeng Jin, Ruiying Zhang, Xiaodong Zhi, Dongxin Liu, Yun Wang, Zhongmin Feng, Ting Sun
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Abstract

Eco-friendly and safe aqueous aluminum-ion batteries as energy storage devices with low economic burden, high stability and fast ion transport have been lucubrated deeply in response to the call for sustainable development. However, the poor cycle performance caused by difficult (de-)intercalation hinders the development prospect. In this work, the aluminum vacancy-rich MOF-derived carbon is constructed to achieve reversible aluminum storage during the charge-discharge cycles. The MOF-derived carbon with anti-stacking waxberry-like structure exhibits high capacity (282.1 mAh g−1 at 50 mA g−1) and long cycle performance (84.4% capacity retention rate at 1 A g−1 after 5000 cycles). Further investigations demonstrate that (de-)intercalation occurs among the vacancies of carbon nanosheets in the form of hydrated aluminum ions. Meanwhile, the introduced nitrogen as energy storage sites contributes part of the capacity. The proposed aluminum vacancy engineering improves the current situation of the capacitive energy storage mode for 2D carbon materials, which may exploit an advanced theoretical model for the design of aqueous batteries.

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富含铝空位的 MOF 衍生碳纳米片用于高容量和长寿命水性铝离子电池
铝离子水电池作为一种经济负担低、稳定性高、离子传输速度快的储能装置,其生态友好性和安全性已得到深入研究,以响应可持续发展的号召。然而,由于难以(去)插层而导致的循环性能不佳阻碍了其发展前景。本研究构建了富含铝空位的 MOF 衍生碳,以实现充放电循环过程中铝的可逆存储。这种具有反堆叠蜡梅状结构的 MOF 衍生碳具有高容量(50 mA g-1 时为 282.1 mAh g-1)和长循环性能(5000 次循环后,1 A g-1 时的容量保持率为 84.4%)。进一步的研究表明,碳纳米片的空位以水合铝离子的形式发生了(去)插层。同时,引入的氮作为储能位点也贡献了部分容量。所提出的铝空位工程改善了二维碳材料电容储能模式的现状,为水性电池的设计提供了先进的理论模型。
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