Redox of Dual-Radical Intermediates in a Methylene-Linked Covalent Triazine Framework for High-Performance Lithium-Ion Batteries

Wang, Zhiqiang; Gu, Shuai; Cao, Lujie; Kong, Long; Wang, Zhenyu; Qin, Ning; Li, Mu-Qing; Luo, Wen; Chen, Jingjing; Wu, Sisi; Liu, Guiyu; Yuan, Huan; Bai, Ya Mei; Zhang, Kaili; Lu, Zhouguang

doi:10.1021/acsami.0c17692

Cited by 41 publications

(36 citation statements)

References 57 publications

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“…118 The capability of the α-C˙radicals in COF to accommodate alkali metal ions was also confirmed recently through DFT computations of MESP. 166 Therefore, harnessing the reactivity and availability of these radical intermediates is crucial to the stability and performance of the COF electrodes. For instance, Gu et al 118 demonstrated that increasing the stacking thickness of DAAQ-COF results in a higher degree of extinction and deactivation of the α-C˙radical intermediates due to increased self-discharge of the radicals during the redox process.…”

Section: Cof Geometry-energy Storage Relationshipsmentioning

confidence: 99%

Covalent organic frameworks: Design and applications in electrochemical energy storage devices

Jin

Allam

Jang

et al. 2022

InfoMat

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As an emerging class of crystalline organic material, covalent organic frameworks (COFs) possess uniform porosity, versatile functionality, and precise control over designated structures. Aside from the favorable charge and mass transport pathways offered by the porous framework, COFs can also exhibit designed reversible redox activity. In the past few years, their potential has attracted a great deal of attention for charge storage and transport applications in various electrochemical energy storage devices, and numerous design strategies have been proposed to enhance the corresponding electrochemical properties. This review summarizes the working principle and synthesis methods of COFs and discusses significant findings for supercapacitors and various rechargeable battery systems, emphasizing the representative design strategies and their underlying relationship with electrochemical performances. In addition, key advances achieved by computations are highlighted along with the challenges and prospects in this field.

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Section: Cof Geometry-energy Storage Relationshipsmentioning

confidence: 99%

Covalent organic frameworks: Design and applications in electrochemical energy storage devices

Jin

Allam

Jang

et al. 2022

InfoMat

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“…[253] Methylene group functionalized CTFs derived from ZnCl 2 -catalyzed trimerization of p-xylylene dicyanide (Figure 3) was exploited as cathode material in LIBs, displaying a specific capacity of 247 mAh g −1 at 20 mA g −1 . [254] A series of materials derived from fluorinated CQNs was prepared via the polymerization of 2,5-diamino-3,6-difluoroterephthalonitrile (DADFTN) promoted by ZnCl 2 at reaction temperatures of 400-700 °C (denoted as F-CQN-1-T, T = reaction temperature) (Figure 13A). The as-afforded materials were amorphous but possessed abundant porosity and codoped with nitrogen and fluorine moieties.…”

Section: As Cathode Materialsmentioning

confidence: 99%

“…[ 253 ] Methylene group functionalized CTFs derived from ZnCl 2 ‐catalyzed trimerization of p ‐xylylene dicyanide (Figure 3) was exploited as cathode material in LIBs, displaying a specific capacity of 247 mAh g −1 at 20 mA g −1 . [ 254 ]…”

Section: Task‐specific Applications Of Graphitic Aza‐fused π‐Conjugat...mentioning

confidence: 99%

Graphitic Aza‐Fused π‐Conjugated Networks: Construction, Engineering, and Task‐Specific Applications

et al. 2022

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.202107947.2D π-conjugated networks linked by aza-fused units represent a pivotal category of graphitic materials with stacked nanosheet architectures. Extensive efforts have been directed at their fabrication and application since the discovery of covalent triazine frameworks (CTFs). Besides the triazine cores, tricycloquinazoline and hexaazatriphenylene linkages are further introduced to tailor the structures and properties. Diverse related materials have been developed rapidly, and a thorough outlook is necessitated to unveil the structure-property-application relationships across multiple subcategories, which is pivotal to guide the design and fabrication toward enhanced taskspecific performance. Herein, the structure types and development of related materials including CTFs, covalent quinazoline networks, and hexaazatriphenylene networks, are introduced. Advanced synthetic strategies coupled with characterization techniques provide powerful tools to engineer the properties and tune the associated behaviors in corresponding applications. Case studies in the areas of gas adsorption, membrane-based separation, thermo-/ electro-/photocatalysis, and energy storage are then addressed, focusing on the correlation between structure/property engineering and optimization of the corresponding performance, particularly the preferred features and strategies in each specific field. In the last section, the underlying challenges and opportunities in construction and application of this emerging and promising material category are discussed.

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“…[ 47–51 ] In addition, the variety of COF structures and their superior electrochemical stability has led COFs to become versatile platforms for an array of engineering applications. This is aided by the functionalizability of COF backbones, which can afford COF platforms for energy devices [ 52–58 ] and a diversity of other applications, such as molecular sorption and separation, [ 59–65 ] molecular sensing, [ 66,67 ] catalysis, [ 68–73 ] optoelectronics, [ 74–78 ] piezoelectrics, [ 79 ] and low‐ k dielectric materials [ 80,81 ]…”

Section: Introductionmentioning

confidence: 99%

“…However, these membranes suffer from severe capacity fade under extreme platforms for an array of engineering applications. This is aided by the functionalizability of COF backbones, which can afford COF platforms for energy devices [52][53][54][55][56][57][58] and a diversity of other applications, such as molecular sorption and separation, [59][60][61][62][63][64][65] molecular sensing, [66,67] catalysis, [68][69][70][71][72][73] optoelectronics, [74][75][76][77][78] piezoelectrics, [79] and low-k dielectric materials [80,81] A distinct type of COFs are ionic COFs (iCOFs), [82,83] which are COFs that contain a repeating unit bearing ionic groups. In a sense, iCOFs are analogous to polyelectrolytes, as a substantial proportion of the groups on their polymer backbones are ionic or ionizable.…”

Section: Introductionmentioning

confidence: 99%

Ionic Covalent Organic Frameworks for Energy Devices

et al. 2021

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Covalent organic frameworks (COFs) are a class of porous crystalline materials whose facile preparation, functionality, and modularity have led to their becoming powerful platforms for the development of molecular devices in many fields of (bio)engineering, such as energy storage, environmental remediation, drug delivery, and catalysis. In particular, ionic COFs (iCOFs) are highly useful for constructing energy devices, as their ionic functional groups can transport ions efficiently, and the nonlabile and highly ordered all‐covalent pore structures of their backbones provide ideal pathways for long‐term ionic transport under harsh electrochemical conditions. Here, current research progress on the use of iCOFs for energy devices, specifically lithium‐based batteries and fuel cells, is reviewed in terms of iCOF backbone‐design strategies, synthetic approaches, properties, engineering techniques, and applications. iCOFs are categorized as anionic COFs or cationic COFs, and how each of these types of iCOFs transport lithium ions, protons, or hydroxides is illustrated. Finally, the current challenges to and future opportunities for the utilization of iCOFs in energy devices are described. This review will therefore serve as a useful reference on state‐of‐the‐art iCOF design and application strategies focusing on energy devices.

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Redox of Dual-Radical Intermediates in a Methylene-Linked Covalent Triazine Framework for High-Performance Lithium-Ion Batteries

Cited by 41 publications

References 57 publications

Covalent organic frameworks: Design and applications in electrochemical energy storage devices

Covalent organic frameworks: Design and applications in electrochemical energy storage devices

Graphitic Aza‐Fused π‐Conjugated Networks: Construction, Engineering, and Task‐Specific Applications

Ionic Covalent Organic Frameworks for Energy Devices

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