Integrated Covalent Organic Framework/Carbon Nanotube Composite as Li‐Ion Positive Electrode with Ultra‐High Rate Performance

Covalent organic frameworks (COFs) are promising electrode materials for Li‐ion batteries. However, the utilization of redox‐active sites embedded within COFs is often limited by the low intrinsic conductivities of bulk‐grown material, resulting in poor electrochemical performance. Here, a general strategy is developed to improve the energy storage capability of COF‐based electrodes by integrating COFs with carbon nanotubes (CNT). These COF composites feature an abundance of redox‐active 2,7‐diamino‐9,10‐phenanthrenequinone (DAPQ) based motifs, robust β‑ketoenamine linkages, and well‐defined mesopores. The composite materials (DAPQ‐COFX—where X = wt% of CNT) are prepared by in situ polycondensation and have tube‐type core‐shell structures with intimately grown COF layers on the CNT surface. This synergistic structural design enables superior electrochemical performance: DAPQ‐COF50 shows 95% utilization of redox‐active sites, long cycling stability (76% retention after 3000 cycles at 2000 mA g−1), and ultra‐high rate capability, with 58% capacity retention at 50 A g−1. This rate translates to charging times of ≈11 s (320 C), implying that DAPQ‐COF50 holds excellent promise for high‐power cells. Furthermore, the rate capability outperformed all previous reports for carbonyl‐containing organic electrodes by an order of magnitude; indeed, this power density and the rapid (dis)charge time are competitive with electrochemical capacitors.

[1]  Jiaxing Jiang,et al.  Toward High‐Performance Dihydrophenazine‐Based Conjugated Microporous Polymer Cathodes for Dual‐Ion Batteries through Donor–Acceptor Structural Design , 2021, Advanced Functional Materials.

[2]  Xiaofei Yang,et al.  Dual‐Active‐Center of Polyimide and Triazine Modified Atomic‐Layer Covalent Organic Frameworks for High‐Performance Li Storage , 2021, Advanced Functional Materials.

[3]  V. Kale,et al.  2D Covalent‐Organic Framework Electrodes for Supercapacitors and Rechargeable Metal‐Ion Batteries , 2021, Advanced Energy Materials.

[4]  E. Kymakis,et al.  Quinone-Enriched Conjugated Microporous Polymer as an Organic Cathode for Li-Ion Batteries. , 2021, ACS applied materials & interfaces.

[5]  Xiaoyi Li,et al.  Side‐Chain Engineering for High‐Performance Conjugated Polymer Batteries , 2021, Advanced Functional Materials.

[6]  D. Jiang Covalent Organic Frameworks: A Molecular Platform for Designer Polymeric Architectures and Functional Materials , 2021, Bulletin of the Chemical Society of Japan.

[7]  Reiner Sebastian Sprick,et al.  Crosslinked Polyimide and Reduced Graphene Oxide Composites as Long Cycle Life Positive Electrode for Lithium‐Ion Cells , 2020, ChemSusChem.

[8]  J. W. Ward,et al.  Synthesis of Stable Thiazole-Linked Covalent Organic Frameworks via a Multicomponent Reaction. , 2020, Journal of the American Chemical Society.

[9]  Yongsheng Chen,et al.  A 3D cross-linked graphene-based honeycomb carbon composite with excellent confinement effect of organic cathode material for lithium-ion batteries , 2020 .

[10]  Tao Huang,et al.  Benzoquinone-based Polyimide Derivatives as High-Capacity and Stable Organic Cathodes for Lithium-Ion Batteries. , 2019, ACS applied materials & interfaces.

[11]  Zhichuan J. Xu,et al.  Two-Dimensional (2D) Covalent Organic Framework as Efficient Cathodes for Binder-free Lithium-Ion Battery. , 2019, ChemSusChem.

[12]  William R. Dichtel,et al.  Phenazine-Based Covalent Organic Framework Cathode Materials with High Energy and Power Densities. , 2019, Journal of the American Chemical Society.

[13]  Gang Wang,et al.  A Crystalline, 2D Polyarylimide Cathode for Ultrastable and Ultrafast Li Storage , 2019, Advanced materials.

[14]  Pengpeng Shao,et al.  Fast Ion Transport Pathway Provided by Polyethylene Glycol Confined in Covalent Organic Frameworks. , 2019, Journal of the American Chemical Society.

[15]  G. Wang,et al.  A Nitrogen-Rich 2D sp2 -Carbon-Linked Conjugated Polymer Framework as a High-Performance Cathode for Lithium-Ion Batteries. , 2018, Angewandte Chemie.

[16]  Yaobing Wang,et al.  Direct Solar-to-Electrochemical Energy Storage in a Functionalized Covalent Organic Framework. , 2018, Angewandte Chemie.

[17]  Yong Lu,et al.  A Microporous Covalent-Organic Framework with Abundant Accessible Carbonyl Groups for Lithium-Ion Batteries. , 2018, Angewandte Chemie.

[18]  Yong Wang,et al.  Boosting lithium storage in covalent organic framework via activation of 14-electron redox chemistry , 2018, Nature Communications.

[19]  Katsuhiko Ariga,et al.  Redox-Active Polymers for Energy Storage Nanoarchitectonics , 2017 .

[20]  Xiao Feng,et al.  Three-Dimensional Anionic Cyclodextrin-Based Covalent Organic Frameworks. , 2017, Angewandte Chemie.

[21]  Pengpeng Shao,et al.  Exfoliation of Covalent Organic Frameworks into Few-Layer Redox-Active Nanosheets as Cathode Materials for Lithium-Ion Batteries. , 2017, Journal of the American Chemical Society.

[22]  U. Schubert,et al.  Polymer-Based Organic Batteries. , 2016, Chemical reviews.

[23]  Haoshen Zhou,et al.  Polyanthraquinone as a Reliable Organic Electrode for Stable and Fast Lithium Storage. , 2015, Angewandte Chemie.

[24]  H. Karunadasa,et al.  Quinone-Functionalized Carbon Black Cathodes for Lithium Batteries with High Power Densities , 2015 .

[25]  Dingcai Wu,et al.  Electrochemically active, crystalline, mesoporous covalent organic frameworks on carbon nanotubes for synergistic lithium-ion battery energy storage , 2015, Scientific Reports.

[26]  V. Presser,et al.  Carbons and Electrolytes for Advanced Supercapacitors , 2014, Advanced materials.

[27]  William R. Dichtel,et al.  β-Ketoenamine-linked covalent organic frameworks capable of pseudocapacitive energy storage. , 2013, Journal of the American Chemical Society.

[28]  Haoshen Zhou,et al.  Towards sustainable and versatile energy storage devices: an overview of organic electrode materials , 2013 .

[29]  Jun Chen,et al.  Function-oriented design of conjugated carbonyl compound electrodes for high energy lithium batteries , 2013 .

[30]  R. Banerjee,et al.  Construction of crystalline 2D covalent organic frameworks with remarkable chemical (acid/base) stability via a combined reversible and irreversible route. , 2012, Journal of the American Chemical Society.

[31]  A. Costero,et al.  A new phenanthrene-based bis-oxime chemosensor for Fe(III) and Cr(III) discrimination , 2012 .

[32]  Jun Liu,et al.  Polymer-graphene nanocomposites as ultrafast-charge and -discharge cathodes for rechargeable lithium batteries. , 2012, Nano letters.

[33]  Stephan Irle,et al.  High-rate charge-carrier transport in porphyrin covalent organic frameworks: switching from hole to electron to ambipolar conduction. , 2012, Angewandte Chemie.

[34]  Phillip K. Koech,et al.  Factors Affecting the Battery Performance of Anthraquinone-based Organic Cathode Materials , 2012 .

[35]  Jean-Marie Tarascon,et al.  Lithium salt of tetrahydroxybenzoquinone: toward the development of a sustainable Li-ion battery. , 2009, Journal of the American Chemical Society.

[36]  M. Armand,et al.  Building better batteries , 2008, Nature.

[37]  John Wang,et al.  Pseudocapacitive Contributions to Electrochemical Energy Storage in TiO2 (Anatase) Nanoparticles , 2007 .

[38]  Michael O'Keeffe,et al.  Porous, Crystalline, Covalent Organic Frameworks , 2005, Science.

[39]  G. Yushin,et al.  A Naphthalene Diimide Covalent Organic Framework: Comparison of Cathode Performance in Lithium-Ion Batteries with Amorphous Cross-linked and Linear Analogues, and Its Use in Aqueous Lithium-Ion Batteries , 2021 .

[40]  Jun Chen,et al.  Review—Advanced Carbon-Supported Organic Electrode Materials for Lithium (Sodium)-Ion Batteries , 2015 .