Rechargeable Lithium-Hydrogen Gas Batteries

Zaichun Liu; Yirui Ma; Nawab Ali Khan; Taoli Jiang; Zhengxin Zhu; Ke Li; Kai Zhang; Shuang Liu; Zehui Xie; Yuan Yuan; Mingming Wang; Xinhua Zheng; Jifei Sun; Weiping Wang; Yahan Meng; Yan Xu; Mingyan Chuai; Jinlong Yang; Wei Chen

doi:10.1002/anie.202419663

Rechargeable Lithium-Hydrogen Gas Batteries

Zaichun Liu, Yirui Ma, Nawab Ali Khan, Taoli Jiang, Zhengxin Zhu, Ke Li, Kai Zhang, Shuang Liu, Zehui Xie, Yuan Yuan, Mingming Wang, Xinhua Zheng, Jifei Sun, Weiping Wang, Yahan Meng, Yan Xu, Mingyan Chuai, Jinlong Yang, Wei Chen

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2 引用（Scopus）

摘要

The global clean energy transition and carbon neutrality call for developing high-performance batteries. Here we report a rechargeable lithium metal - catalytic hydrogen gas (Li−H) battery utilizing two of the lightest elements, Li and H. The Li−H battery operates through redox of H₂/H⁺ on the cathode and Li/Li⁺ on the anode. The universal properties of the H₂ cathode enable the battery to demonstrate attractive electrochemical performance, including high theoretical specific energy up to 2825 Wh kg⁻¹, discharge voltage of 3 V, round-trip efficiency of 99.7 %, reversible areal capacity of 5–20 mAh cm⁻², all-climate characteristics with a wide operational temperature range of −20–80 °C, and high utilization of active materials. A rechargeable anode-free Li−H battery is further constructed by plating Li metal from cost-effective lithium salts under a low catalyst loading of <0.1 mg cm⁻². This work presents a route to design batteries based on catalytic hydrogen gas cathode for high-performance energy storage applications.

源语言	英语
文章编号	e202419663
期刊	Angewandte Chemie - International Edition
卷	64
期	7
DOI	https://doi.org/10.1002/anie.202419663
出版状态	已出版 - 10 2月 2025
已对外发布	是

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title = "Rechargeable Lithium-Hydrogen Gas Batteries",

abstract = "The global clean energy transition and carbon neutrality call for developing high-performance batteries. Here we report a rechargeable lithium metal - catalytic hydrogen gas (Li−H) battery utilizing two of the lightest elements, Li and H. The Li−H battery operates through redox of H2/H+ on the cathode and Li/Li+ on the anode. The universal properties of the H2 cathode enable the battery to demonstrate attractive electrochemical performance, including high theoretical specific energy up to 2825 Wh kg−1, discharge voltage of 3 V, round-trip efficiency of 99.7 %, reversible areal capacity of 5–20 mAh cm−2, all-climate characteristics with a wide operational temperature range of −20–80 °C, and high utilization of active materials. A rechargeable anode-free Li−H battery is further constructed by plating Li metal from cost-effective lithium salts under a low catalyst loading of <0.1 mg cm−2. This work presents a route to design batteries based on catalytic hydrogen gas cathode for high-performance energy storage applications.",

keywords = "Anode-free, High energy, Hydrogen gas electrochemistry, Lithium metal, Low cost, Rechargeable batteries",

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T1 - Rechargeable Lithium-Hydrogen Gas Batteries

AU - Liu, Zaichun

AU - Ma, Yirui

AU - Ali Khan, Nawab

AU - Jiang, Taoli

AU - Zhu, Zhengxin

AU - Li, Ke

AU - Zhang, Kai

AU - Liu, Shuang

AU - Xie, Zehui

AU - Yuan, Yuan

AU - Wang, Mingming

AU - Zheng, Xinhua

AU - Sun, Jifei

AU - Wang, Weiping

AU - Meng, Yahan

AU - Xu, Yan

AU - Chuai, Mingyan

AU - Yang, Jinlong

AU - Chen, Wei

PY - 2025/2/10

Y1 - 2025/2/10

N2 - The global clean energy transition and carbon neutrality call for developing high-performance batteries. Here we report a rechargeable lithium metal - catalytic hydrogen gas (Li−H) battery utilizing two of the lightest elements, Li and H. The Li−H battery operates through redox of H2/H+ on the cathode and Li/Li+ on the anode. The universal properties of the H2 cathode enable the battery to demonstrate attractive electrochemical performance, including high theoretical specific energy up to 2825 Wh kg−1, discharge voltage of 3 V, round-trip efficiency of 99.7 %, reversible areal capacity of 5–20 mAh cm−2, all-climate characteristics with a wide operational temperature range of −20–80 °C, and high utilization of active materials. A rechargeable anode-free Li−H battery is further constructed by plating Li metal from cost-effective lithium salts under a low catalyst loading of <0.1 mg cm−2. This work presents a route to design batteries based on catalytic hydrogen gas cathode for high-performance energy storage applications.

AB - The global clean energy transition and carbon neutrality call for developing high-performance batteries. Here we report a rechargeable lithium metal - catalytic hydrogen gas (Li−H) battery utilizing two of the lightest elements, Li and H. The Li−H battery operates through redox of H2/H+ on the cathode and Li/Li+ on the anode. The universal properties of the H2 cathode enable the battery to demonstrate attractive electrochemical performance, including high theoretical specific energy up to 2825 Wh kg−1, discharge voltage of 3 V, round-trip efficiency of 99.7 %, reversible areal capacity of 5–20 mAh cm−2, all-climate characteristics with a wide operational temperature range of −20–80 °C, and high utilization of active materials. A rechargeable anode-free Li−H battery is further constructed by plating Li metal from cost-effective lithium salts under a low catalyst loading of <0.1 mg cm−2. This work presents a route to design batteries based on catalytic hydrogen gas cathode for high-performance energy storage applications.

KW - Anode-free

KW - High energy

KW - Hydrogen gas electrochemistry

KW - Lithium metal

KW - Low cost

KW - Rechargeable batteries

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DO - 10.1002/anie.202419663

M3 - 文章

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VL - 64

JO - Angewandte Chemie - International Edition

JF - Angewandte Chemie - International Edition

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ER -

Rechargeable Lithium-Hydrogen Gas Batteries

摘要

联合国可持续发展目标

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