Threading the MOF-derived mesoporous carbon host with CNT network: An effective modification layer for high-areal-capacity Li metal anodes

Mustehsin Ali; Ting Zhao; Sundas Iqbal; Wenyu Zhao; Helin Wang; Siyuan Liu; Shaowen Li; Zhaohui Wang; Yue Ma

doi:10.1016/j.cej.2021.134194

Threading the MOF-derived mesoporous carbon host with CNT network: An effective modification layer for high-areal-capacity Li metal anodes

Mustehsin Ali, Ting Zhao, Sundas Iqbal, Wenyu Zhao, Helin Wang, Siyuan Liu, Shaowen Li, Zhaohui Wang, Yue Ma

材料学院

科研成果: 期刊稿件 › 文章 › 同行评审

16 引用（Scopus）

摘要

The ramified lithium dendrite growth and severe volume expansion upon the metallic plating process impede the practical deployment of the lithium metal anode in the energy-dense battery system. In this article, a thin modification layer of the Al-based metal–organic framework (MOF) is carbonized into the mesoporous carbon nanorods (PCRs) with atomically dispersed lithiophilic sites; meanwhile these storage units are structurally reinforced by the in-situ grown carbon nanotubes. The interfacial engineered substrate (Al-PCRs/CNTs-Cu) exhibits an enhanced Li affinity with mitigated nucleation barrier, and thus realizes the long-lifespan up to 1000 h at high-capacity-loading of 8 mAh cm⁻². When integrating the modified substrate with LiN_0.8Co_0.1Mn_0.1O₂ (NCM-811) (∼10.5 mg cm⁻²) the cathode in a prelithiated full cell model (2*Li excess), the prototype exhibits a high energy density of 414.38 Wh kg⁻¹ at the highest power density of 1243.14 W kg⁻¹. This dual-functionalized, carbonaceous interfacial layer provides a facile and effective approach to construct the energy/power-dense metallic batteries.

源语言	英语
文章编号	134194
期刊	Chemical Engineering Journal
卷	431
DOI	https://doi.org/10.1016/j.cej.2021.134194
出版状态	已出版 - 1 3月 2022

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title = "Threading the MOF-derived mesoporous carbon host with CNT network: An effective modification layer for high-areal-capacity Li metal anodes",

abstract = "The ramified lithium dendrite growth and severe volume expansion upon the metallic plating process impede the practical deployment of the lithium metal anode in the energy-dense battery system. In this article, a thin modification layer of the Al-based metal–organic framework (MOF) is carbonized into the mesoporous carbon nanorods (PCRs) with atomically dispersed lithiophilic sites; meanwhile these storage units are structurally reinforced by the in-situ grown carbon nanotubes. The interfacial engineered substrate (Al-PCRs/CNTs-Cu) exhibits an enhanced Li affinity with mitigated nucleation barrier, and thus realizes the long-lifespan up to 1000 h at high-capacity-loading of 8 mAh cm−2. When integrating the modified substrate with LiN0.8Co0.1Mn0.1O2 (NCM-811) (∼10.5 mg cm−2) the cathode in a prelithiated full cell model (2*Li excess), the prototype exhibits a high energy density of 414.38 Wh kg−1 at the highest power density of 1243.14 W kg−1. This dual-functionalized, carbonaceous interfacial layer provides a facile and effective approach to construct the energy/power-dense metallic batteries.",

keywords = "Dendrite-free deposition, Dual-functionalized carbon, High-areal-capacity, Lithiophilic sites, Lithium metal anode, MOF derived storage unit",

author = "Mustehsin Ali and Ting Zhao and Sundas Iqbal and Wenyu Zhao and Helin Wang and Siyuan Liu and Shaowen Li and Zhaohui Wang and Yue Ma",

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doi = "10.1016/j.cej.2021.134194",

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T2 - An effective modification layer for high-areal-capacity Li metal anodes

AU - Ali, Mustehsin

AU - Zhao, Ting

AU - Iqbal, Sundas

AU - Zhao, Wenyu

AU - Wang, Helin

AU - Liu, Siyuan

AU - Li, Shaowen

AU - Wang, Zhaohui

AU - Ma, Yue

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N2 - The ramified lithium dendrite growth and severe volume expansion upon the metallic plating process impede the practical deployment of the lithium metal anode in the energy-dense battery system. In this article, a thin modification layer of the Al-based metal–organic framework (MOF) is carbonized into the mesoporous carbon nanorods (PCRs) with atomically dispersed lithiophilic sites; meanwhile these storage units are structurally reinforced by the in-situ grown carbon nanotubes. The interfacial engineered substrate (Al-PCRs/CNTs-Cu) exhibits an enhanced Li affinity with mitigated nucleation barrier, and thus realizes the long-lifespan up to 1000 h at high-capacity-loading of 8 mAh cm−2. When integrating the modified substrate with LiN0.8Co0.1Mn0.1O2 (NCM-811) (∼10.5 mg cm−2) the cathode in a prelithiated full cell model (2*Li excess), the prototype exhibits a high energy density of 414.38 Wh kg−1 at the highest power density of 1243.14 W kg−1. This dual-functionalized, carbonaceous interfacial layer provides a facile and effective approach to construct the energy/power-dense metallic batteries.

AB - The ramified lithium dendrite growth and severe volume expansion upon the metallic plating process impede the practical deployment of the lithium metal anode in the energy-dense battery system. In this article, a thin modification layer of the Al-based metal–organic framework (MOF) is carbonized into the mesoporous carbon nanorods (PCRs) with atomically dispersed lithiophilic sites; meanwhile these storage units are structurally reinforced by the in-situ grown carbon nanotubes. The interfacial engineered substrate (Al-PCRs/CNTs-Cu) exhibits an enhanced Li affinity with mitigated nucleation barrier, and thus realizes the long-lifespan up to 1000 h at high-capacity-loading of 8 mAh cm−2. When integrating the modified substrate with LiN0.8Co0.1Mn0.1O2 (NCM-811) (∼10.5 mg cm−2) the cathode in a prelithiated full cell model (2*Li excess), the prototype exhibits a high energy density of 414.38 Wh kg−1 at the highest power density of 1243.14 W kg−1. This dual-functionalized, carbonaceous interfacial layer provides a facile and effective approach to construct the energy/power-dense metallic batteries.

KW - Dendrite-free deposition

KW - Dual-functionalized carbon

KW - High-areal-capacity

KW - Lithiophilic sites

KW - Lithium metal anode

KW - MOF derived storage unit

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Threading the MOF-derived mesoporous carbon host with CNT network: An effective modification layer for high-areal-capacity Li metal anodes

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