TCNQ Confined in Porous Organic Structure as Cathode for Aqueous Zinc Battery

Chola, Noufal Merukan; Nagarale, Rajaram K.

doi:10.1149/1945-7111/ab9cc9

Cited by 28 publications

(19 citation statements)

References 39 publications

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“…The introduction of multifunctional CCP additive effectively improved the electrochemical performance, leading to a boosted capacity of up to 171 mAh g −1 with longer cycling stability versus pure TCNQ cathode. [ 97 ] Grzybowski et al reported a systematic work of 2D COF‐protected zinc anodes using a series of 1,3,5‐triphloroglucinol (TFP)‐based COFs (labeled as a DIP series). The authors designed a dip‐coating method to fabricate large self‐assembling COF films (30 × 12 cm 2 ) on zinc and other substrates (Figure 9c) with a controllable thickness varying from 5 to over 100 nm.…”

Section: D Carbon‐rich Polymersmentioning

confidence: 99%

Constructing Advanced Aqueous Zinc‐Ion Batteries with 2D Carbon‐Rich Materials

Xiong

Jin

Liu

2022

Adv Energy and Sustain Res

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As a promising electrochemical energy storage system (EESS), aqueous zinc‐ion batteries (AZIBs) hold the potential to achieve energy storage with low‐cost and nonpollution merits. However, the intrinsic defects of these systems block their further development severely, including dendrite growth, structural deterioration, parasitic reactions, and sluggish charge/discharge kinetics. Herein, the application of 2D carbon‐rich materials against the drawbacks of AZIBs is introduced. Advantages of each representative 2D carbon‐rich material (i.e., graphdiyne, graphene, 2D covalent organic frameworks, 2D metal organic frameworks, and 2D conductive polymers) are thoroughly discussed, along with recent progress of AZIB cathodes, anodes, separators, and electrolytes utilizing 2D carbon‐rich materials. Finally, the features of various 2D carbon‐rich materials are summarized and several perspectives on optimization of 2D carbon‐rich materials, development of characterization techniques, and the practical use of AZIBs in the future are given.

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Section: D Carbon‐rich Polymersmentioning

confidence: 99%

Constructing Advanced Aqueous Zinc‐Ion Batteries with 2D Carbon‐Rich Materials

Xiong

Jin

Liu

2022

Adv Energy and Sustain Res

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“…Figure S9 shows that at pristine state (Supporting Information: Figure S9a,d), XPS peak for -C≡N is the main functional group, while at 0.5 V (Supporting Information: Figure S9b two new diffraction peaks are generated near 2θ = 9.2°and 21.8°and the peak intensity continuously enhances along discharging, indicating that a new substance is formed, which is preliminarily determined to be Zn-TCNQ. 20 When charging is completed, the diffraction peaks are recovered to that of the initial state, indicating a highly reversible process of p-TCNQ during charging/discharging.…”

Section: Av = Bmentioning

confidence: 94%

“…When discharged to 0.77 V, rod morphology is observed on the surface of the electrode; when fully discharged to 0.5 V, more rods appeared, exhibiting the formation of Zn-TCNQ, since it was reported to be onedimensional rods. 20 When charged to 1.16 V, the TCNQ particles gradually recover. At a fully charged state (1.35 V vs. Zn 2+ /Zn), the TCNQ electrode returns to its original morphology, which also illustrates the reversibility of TCNQ along charging and discharging.…”

Section: Av = Bmentioning

confidence: 99%

“…[15][16][17][18][19] Recently, TCNQ was employed as a cathode for AZIBs at room temperature. 20 Unfortunately, it only delivered half of its theoretic capacity at a current density of 100 mA g −1 in 1 M ZnSO 4 electrolyte and the capacity dropped fast with cycles (only 50% capacity retention after 30 cycles) due to the partial dissolution of Zn-TCNQ. Later, Shen et al 21 improved the capacity and cyclability of Zn//TCNQ battery by using 2 M Na 2 SO 4 , 1 M ZnSO 4 , and 1 M Al 2 (SO 4 ) 3 as electrolytes.…”

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Significantly raising tetracyanoquinodimethane electrode performance in zinc‐ion battery at low temperatures by eliminating impurities

et al. 2023

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Applications of organic compounds‐based electrodes in aqueous zinc‐ion batteries (AZIBs) at low temperatures are severely restricted by the freezing of aqueous electrolytes and the inferior dynamic behavior of organic electrodes below zero. Herein, tetracyanoquinodimethane (TCNQ) was purified by the sublimation method and used as a cathode in AZIBs to investigate electrochemical Zn storage performance in comparison with nonpurified TCNQ at a temperature range of 25°C to −40°C. Nuclear magnetic resonance and elemental analysis prove increased purity in purified TCNQ (p‐TCNQ), whereas scanning electron microscope and Brunner−Emmet−Teller data verify reduced particle size and increased surface area of p‐TCNQ. Kinetic analysis demonstrates that p‐TCNQ is a more surface‐controlled electrode process than TCNQ and offers much higher ionic diffusivity than the latter at various temperatures. Molecular dynamics simulation validates that the existence of impurity increases the absorption energy of TCNQ in a TCNQ//Zn system that is unfavorable to Zn migration. Comprehensive analysis, including ex situ X‐ray diffraction, Fourier transform infrared, Raman, and electron spin‐resonance spectroscopy characterization confirm the high reversibility of transformation between C≡N and −C═N groups in p‐TCNQ. This work provides a simple, environmentally friendly strategy to fabricate a high‐performance AZIB at low temperatures while offering fundamental chemistry insight into organic electrode performance, thus possessing universal significance.

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“…The high carrier mobility in Zn(TCNQ) 2 could induce low interfacial impedance and high current-carrying capacity, resulting in uniform surface current distributions of Zn anode. 30 Furthermore, the oxidation potential of Zn(TCNQ) 2 can be confirmed to be 1.125 V (vs Zn/Zn 2+ ), 23 suggesting that Zn(TCNQ) 2 will not undergo redox reactions during the Zn plating/stripping process. Importantly, the cyano groups (−CN) in Zn(TCNQ) 2 can capture and immobilize the highly active H 2 O molecules from [Zn(H 2 O) 6 ] 2+ via hydrogen bonding, which could accelerate the desolvation process of Zn 2+ .…”

Section: Metrics and Morementioning

confidence: 99%

Charge-Transfer Complex-Based Artificial Layers for Stable and Efficient Zn Metal Anodes

et al. 2023

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Herein, we report a charge-transfer complex electrolyte additive, 7,7,8,8-tetracyanoquinodimethane (TCNQ), with high Zn affinity, which was tightly adsorbed on the surface of a Zn anode to form a dense and robust interfacial complex layer and suppress the activity of H2O. As verified by comprehensive experimental and computational analyses, this complex layer could construct a Zn–Zn(TCNQ)2 Ohmic contact interface, guide rapid ion/electron transport, ameliorate electric field distribution, and inhibit the direct contact between the active H2O and Zn anode, demonstrating a dendrite-free Zn anode and facile Zn plating/stripping kinetics. Consequently, the Zn||Zn symmetrical cell exhibits a high Zn plating/stripping reversibility of over 1000 h at 20 mA cm–2 and 5 mA h cm–2 and a high depth of discharge (43%). Moreover, the Zn||MnO2 full cell delivers a high capacity of 143.3 mA h g–1 at 2000 mA g–1 even after 4000 cycles and a capacity retention of 94.7% after returning to 100 mA g–1.

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TCNQ Confined in Porous Organic Structure as Cathode for Aqueous Zinc Battery

Cited by 28 publications

References 39 publications

Constructing Advanced Aqueous Zinc‐Ion Batteries with 2D Carbon‐Rich Materials

Constructing Advanced Aqueous Zinc‐Ion Batteries with 2D Carbon‐Rich Materials

Significantly raising tetracyanoquinodimethane electrode performance in zinc‐ion battery at low temperatures by eliminating impurities

Charge-Transfer Complex-Based Artificial Layers for Stable and Efficient Zn Metal Anodes

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