Multiple Active Sites: Lithium Storage Mechanism of Cu‐TCNQ as an Anode Material for Lithium‐Ion Batteries

Meng, Chao; Chen, Tianhui; Fang, Chun; Huang, Yunhui; Hu, Pinfei; Tong, Yongli; Bian, Ting; Zhang, Jiaojiao; Wang, Zhaoxuan; Yuan, Aihua

doi:10.1002/asia.201901190

Cited by 34 publications

(22 citation statements)

References 47 publications

(100 reference statements)

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“…The concentric rings revealed the polycrystalline structure of the shell layer of CuTCNQ@CuBTC, and the inside ring corresponding to the interplanar spacing of 3.1 Å was indexed to the (120) plane of CuTCNQ (phase I), with a 2θ angle of 28.8° in the powder X‐ray diffraction pattern [25] . The second ring of the SAED pattern should be designated to a plane with a 2θ higher than 46°, which exceeded the reported PXRD angle range of CuTCNQ (phase I) [12,25] …”

Section: Resultsmentioning

confidence: 90%

“…[25] The second ring of the SAED pattern should be designated to a plane with a 2θ higher than 46°, which exceeded the reported PXRD angle range of CuTCNQ (phase I). [12,25] The effect of reaction time on CuTCNQ@CuBTC…”

Section: Resultsmentioning

confidence: 99%

“…For example, CuBTC and CuBTC-derived composite materials are widely applied in the adsorption and removal of poluttant, [7][8] and Cu-based organic reaction catalysts. [9][10][11] Recently, MOFs and their derivatives are investigated as active materials for electrochemical applications such as batteries, [12] supercapacitors, [13] and electrocatalysts. [14] The large specific surface area of MOFs is conducive to electrochemical reactions, and transition metal ions with multiple valence and organic ligands can provide abundant active sites for the chemical reaction.…”

Section: Introductionmentioning

confidence: 99%

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Improve the Conductivity of CuBTC by in‐situ Reduction to Core‐Shell CuTCNQ@CuBTC

Meng

Chen

et al. 2020

ChemistrySelect

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In recent years, metal‐organic frameworks (MOFs) have been widely used in the fields of hydrogen storage, gas separation, catalysts, and so on. It is inspiring to apply MOFs in the field of electrochemistry, whereas the intrinsic low electric conductivity of MOFs limits their promising future. Herein, a new approach to improve the electronic conductivity of Cu‐MOF (CuBTC) is developed, by adopting LiTCNQ solution as the reductant to generate CuTCNQ@CuBTC (BTC=1,3,5‐benzenetricarboxylic acid; TCNQ=7,7,8,8‐tetracyanoquinodimethane) core‐shell nanoparticles with conductive CuTCNQ as the shell and non‐conductive CuBTC as the core, and the reaction conditions are optimized. Mutually validated data indicate that conductive CuTCNQ shell grows thicker with a higher temperature (60 °C) and prolonged time (24 h). With this method, the conductivity of the CuBTC material is effectively improved from 3.84×10−9 to 2.94×10−7 S cm−1.

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Section: Resultsmentioning

confidence: 90%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Improve the Conductivity of CuBTC by in‐situ Reduction to Core‐Shell CuTCNQ@CuBTC

Meng

Chen

et al. 2020

ChemistrySelect

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“…It was well proved that the organic moiety (including the carboxylate groups and the benzene ring) of MOFs played important roles in the lithium storage capability. [46][47][48] However, whether the coordinated transition metal ions participated in the lithiation process of MOF was elusive. [24,47] To further determine the role of Cu 2 + , the high-resolution XPS measurement was carried out to investigate the fresh Cu-BTC powder and fully-discharged Cu-BTC (Figure 5d).…”

Section: The LI + Insertion/desertion Mechanism Of Cu-btcmentioning

confidence: 99%

“…Above all, both copper species and organic ligands of Cu-BTC took part in the redox chemistry contributing to the lithium storage capability, like other conventional MOFs. [24,46]…”

Section: The LI + Insertion/desertion Mechanism Of Cu-btcmentioning

confidence: 99%

Strategies to Optimize the Lithium Storage Capability of the Metal‐Organic Framework Copper‐1,3,5‐Trimesic Acid (Cu‐BTC)

Yuan

Meng

et al. 2020

ChemElectroChem

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Metal-organic frameworks (MOFs) have recently been considered as potential electrodes for lithium-ion batteries. However, there are only a few reports of pristine MOFs as high-performance electrode materials; whereas, in other cases, their overall specific capacities and cycle stabilities are insufficient. In this work, Cu-BTC (BTC = 1,3,5-trimesic acid) is taken as an example to systematically explore the effects of polymer binder, activation temperature, and synthesis method on the electrochemical properties of MOFs. Through the optimization of these conditions, the electrochemical properties of Cu-BTC can be significantly improved. With carboxymethyl cellulose (CMC) as the binder, the activated Cu-BTC (synthesized with the precooling method) displays a stable specific capacity of 626.4 mAh g À 1 after 100 cycles of charge and discharge at a current density of 100 mA g À 1. Besides, the mechanism study shows that both the copper species and organic ligands of Cu-BTC take part in the redox chemistry contributing to the lithium storage capability.

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Cobalt(II)‐Hexaazatriphenylene Hexacarbonitrile Coordination Compounds Based Cathode Materials with High Capacity and Long Cycle Stability

Poldorn

Wongnongwa

Jungsuttiwong

et al. 2022

Adv Funct Materials

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Organic cathode materials are plagued by their low cycle stability and poor electronic conductivity, even though they have attracted increasing attention in the context of lithium‐ion batteries (LIBs). Herein, a coordination polymer cobalt‐hexaazatriphenylene hexacarbonitrile (Co(HAT‐CN)) is prepared via a facile solvothermal method, which is composed of the redox‐active HAT‐CN linker and the Co(II) ion center. The fabricated material shows excellent structural stability and high conductivity. Moreover, graphene oxide (GO) is introduced as a substrate, and in‐situ loading of Co(HAT‐CN) on its surface shows enhanced cycling stability. For Co(HAT‐CN)/GO, a high specific capacity of 204 mAh g–1 can be retained even after 200 cycles at a current density of 40 mA g–1 in a voltage window of 1.2–3.9 V. Ex situ and in situ analyses are applied to probe the reversibility of the pyrazine redox‐active center during the cycling process and the lithium storage process. Density functional theory calculations reveal that the high conductivity of Co(HAT‐CN) should be ascribed to the narrow LUMO‐HOMO gap (0.61 eV), and strong binding of lithiated molecules.

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Multiple Active Sites: Lithium Storage Mechanism of Cu‐TCNQ as an Anode Material for Lithium‐Ion Batteries

Cited by 34 publications

References 47 publications

Improve the Conductivity of CuBTC by in‐situ Reduction to Core‐Shell CuTCNQ@CuBTC

Improve the Conductivity of CuBTC by in‐situ Reduction to Core‐Shell CuTCNQ@CuBTC

Strategies to Optimize the Lithium Storage Capability of the Metal‐Organic Framework Copper‐1,3,5‐Trimesic Acid (Cu‐BTC)

Cobalt(II)‐Hexaazatriphenylene Hexacarbonitrile Coordination Compounds Based Cathode Materials with High Capacity and Long Cycle Stability

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