Contact
    Start Publications Piperazine-based two-dimensional covalent organic framework for ...
    ←  Publication Finder
    KSV NIMA

    Piperazine-based two-dimensional covalent organic framework for high performance anodic lithium storage

    Year: 2021

    Journal: Energy Storage Mater., Volume 40, SEP, page 124–138

    Authors: Zhou, Rui; Huang, Yang; Li, Zhenhu; Kang, Shuai; Wang, Xiaomin; Liu, Shuangyi

    Organizations: National Natural Science Foundation of China [21875245]; Key Project of Technological Innovation Application Development Plan of Chongqing City [cstc2019jscx-fxydX0007]; Chinese Academy of Sciences Science and Technology Service Network Initiative [KFJ-STS-SCYD-308, KFJ-STS-ZDTP-068]

    Keywords: Covalent organic frameworks (COFs); Few-layered and microporous structure; Lithium-ion batteries (LIBs); Anode; High specific capacity

    The controllably spatial and chemical structures and abundantly elemental reserves of covalent organic frameworks (COFs) endow them the potential of being applied in next generation of electrochemical lithium-ions storage with high performances. Here, a piperazine-based two-dimensional covalent organic framework (PTDCOF) is designed and synthesized. PTDCOF is constructed by triphenylene units through irreversible piperazine linkages to afford the regular in-plane pores sized similar to 11 angstrom. PTDCOF is charactered with few-layered features, which is crystalized through eclipsed (AA) and staggered (AB) stacking modes together. And the synthesized framework exhibits excellent stability upon harsh chemical environments. As the active material of anodic lithium storage, the guest-eliminated product derived by PTDCOF demonstrates remarkable lithiation (1644.3 mAh g(-1) capacity contribution at 0.1 A g(-1) ), rate and cycling performances. The abundant active sites lead to a high and reversible lithium loading of at least 14 lithium atoms per triphenylene unit (Li-14(C18N3H9)). Such product presents superior anodic lithiation capability comparing with previously reported carbonaceous materials. This study provides a possible and attractive path for hunting the high performances of lithium or other metal ions storage systems.
    View publication