Lithium Charge Storage Mechanisms of Cross-Linked Triazine Networks and Their Porous Carbon Derivatives

See, Kimberly A.; Hug, Stephan J.; Schwinghammer, Katharina; Lumley, Margaret A.; Zheng, Yonghao; Nolt, Jaya M.; Stucky, Galen D.; Wudl, Fred; Lotsch, Bettina V.; Seshadri, Ram

doi:10.1021/acs.chemmater.5b00772

Cited by 57 publications

(71 citation statements)

References 30 publications

(77 reference statements)

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“…Reaction (i) should result in drastic drop in capacity due to the irreversible conversion to Li‐C=N ,. Reaction (ii) is more appropriate for the usage of g‐C 3 N 4 as an anode material due to it's higher degree of reversibility as compared to the former.…”

Section: Resultsmentioning

confidence: 99%

“…Upon calculating the specific capacity with respect to carbon mass only on the electrode, the values are obtained to be 640 and 960 mAh g −1 , which are practically impossible for carbon black. The initial high capacity loss between the 1st and 2nd discharge cycles is due to the SEI formation involving irreversible reaction of Li + ‐ion with quaternary nitrogen groups ,. Subsequently, the charge capacities decrease reaching a minimum in the 6th cycle to 20 mAh g −1 and 65 mAh g −1 for T‐gCN and T‐gCNP respectively.…”

Section: Resultsmentioning

confidence: 99%

“…synthesized and studied redox‐activity of bare triazine moieties. Their studies reveal triazine to be redox inactive . In spite of these two contradictory reports, the appealing inherent structure coupled with interesting physical properties, encouraged us to undertake an intensive study on its electrochemical activity.…”

Section: Introductionmentioning

confidence: 99%

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Li–Ion‐Conducting Pillar‐Like Graphitic Carbon Nitrides as Novel Anodes for Li–Ion Batteries

2018

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There is still a sustained effort to explore and develop new electrode materials for Li‐ion rechargeable batteries. Presently, materials exploration not only focuses on the enhancement of Li‐ion battery performance, but also targets to make them cheaper and safer. This expectedly will make them market competitive against established battery chemistries. Graphitic carbon nitride (g‐C3N4), which has emerged as an important photon harvesting material, is demonstrated here as a potential efficient and cost effective alternative anode for Li‐ion cells. The g‐C3N4, synthesized here from pyrolysis of thiourea, possesses both graphitic and amorphous phases (T‐gCN). The intercalation of Li+ ions in the densely packed layered structure of T‐gCN (lithiated T‐gCN) results in an ionic conductivity ≈ 10−7 S/cm compared to the non‐lithiated T‐gCN which shows no ionic conductivity. The ionic transport takes place via both the amorphous and graphitic phases in T‐gCN. The T‐gCN when treated with an acidified dichromate solution disintegrates in to filaments, which on prolonged stirring self‐assemble into pillar‐like g‐C3N4 structures (T‐gCNP). The T‐gCNP exhibited higher crystallinity and an even higher ionic conductivity compared to the T‐gCN. The T‐gCN and T‐gCNP deliver modest specific capacities compared to battery grade graphite and other reported carbonaceous/non‐carbonaceous materials in the half‐cell operation. However, when coupled with cathodes such as LiFePO4 and LiMn2O4 in a full Li‐ion cell, the specific capacity obtained in the 1st discharge cycle for both LiFePO4 and LiMn2O4 are very close to their theoretical capacities. The cells display stable cycling and good current rate capability over widely varying current values. This is remarkable in spite of the fact that the samples are not completely crystalline with an average carbon content of approximately 31%. It is envisaged that a continuous network persists for electron transport for their participation in the reversible redox process.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Li–Ion‐Conducting Pillar‐Like Graphitic Carbon Nitrides as Novel Anodes for Li–Ion Batteries

2018

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“…近年来，在材料科学领域中，新型有机/无机杂化材料正引起人们的广泛关注。该类材料由于有机和无机组分的协同效应，使其具有突出的性能，在光、电、磁等领域具有广泛的应用前景 [1][2][3]。有机共轭聚合物(COPs)是一类非常特殊的聚合物功能材料，由于其独特的共轭结构，导电性，电化学活性，使它们成为功能聚合物功能材料研究的热点 [4][5][6][7][8][9]。比如，芳胺聚合物中的聚苯胺在常温下经过化学和电化学掺杂过程使其具有优异的导电性能，并且由于其易于合成、原料易得、结构多样化、掺杂原理独特、导电性和稳定性好等优势，是目前最具应用前景的导电聚合物。而聚苯二胺作为一种重要的芳香二胺类聚合物，因为其大分子结构中含有比聚苯胺较多的活性自由氨基和亚胺基，并且还拥有多功能性，近年来已被广泛关注 [10][11][12][13][14][15]。普鲁士蓝(prussian blue， PB)及其衍生物是一种混合价态的化合物。其具有优良的电化学可逆性，高度的稳定性，容易制备等优点，因此在化学修饰电极、电显示、电催化、二次储能电池等方面有很大的应用前景 [15][16][17][18][19][20][21][22][23][24][25][26][27][28][29]…”

Section: ．引言unclassified

Preparation of Ferricyanic Acid Doped Aryl Amine Copolymer and Its Electrochemical Properties

Xu¹

2018

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In this paper, five hybrid copolymers of HCF/PANI, HCF/P(ANI:pPD=5:1), HCF/P(ANI:pPD=3:1), HCF/P(ANI:pPD=1:1), HCF/PpPD were prepared by in-situ synthesis using the prepared ferricyanic acid (HCF) as doping acid with electrochemical activity. The prepared hybrid material was further applied as cathode electrode to prepare lithium battery. And the structure, morphology, electrochemistry and battery performance of the prepared material were studied in detail. FTIR spectra show that hybrid materials have been successfully prepared. SEM results showed that with the increase of p-phenylenediamine monomer in aromatic amine copolymer, the morphology of hybrid materials gradually decreased from the granular morphology of HCF/PANI to a relatively flat stacking state. Cyclic voltammetric (CV) test showed that the redox reaction for arylamine polymer and HCF presented two obvious characteristic peaks. And the introduction of a small amount of p-phenylenediamine monomer caused the oxidation/reduction potential of hybrid material (HCF/P(ANI:pPD=5:1)) to be significantly close each other and the peak space to decrease. With further increasing the proportion of p-phenylenediamine monomer in aromatic amine copolymer, the oxidation peak and reduction peak of hybrid material move reversely to high potential and low potential respectively. Battery performance studies showed that the initial charge-discharge specific capacities

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“…They pointed out that synthesis temperatures above 500°C are crucial to induce electrical conductivity in the CTF material. [41] Thereby, the well-defined polymers are partially decomposed, creating N-containing amorphous carbon rather than a defined CTF material. In addition, these materials were found to perform similar to super-capacitor materials but showed redox activity in contrast to a pure carbon material.…”

Section: Introductionmentioning

confidence: 99%

Mechanistic Insights into the Role of Covalent Triazine Frameworks as Cathodes in Lithium‐Sulfur Batteries

Troschke

Kensy

Haase

et al. 2020

Batteries & Supercaps

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This study illuminates the applicability of covalent triazine frameworks (CTFs) as a potential cathode material in lithiumsulfur (LiÀ S) batteries. A systematic synthesis protocol is applied to generate a set of model CTFs containing covalently bound sulfur with varying porosities and conductivities. An in-depth structural characterization reconsiders the bonding motif of sulfur within the pore system. The model materials are electrochemically evaluated in coin cells. The CTF cathodes exhibit practically no cycling performance as a result of active material loss in carbonate-based electrolyte (� 200 mAh g sulfur À 1 after 200 cycles). Moreover, in ether-based electrolytes the differentiation between sulfur transformation on the surface of the conductive additive and the (semi-)conducting CTF matrix is hardly feasible. Based on these results, the influence of the CTF material and the conductive additive with respect to sulfur utilization are discussed, demonstrating the critical role of this class of materials for application in LiÀ S batteries.

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Lithium Charge Storage Mechanisms of Cross-Linked Triazine Networks and Their Porous Carbon Derivatives

Cited by 57 publications

References 30 publications

Li–Ion‐Conducting Pillar‐Like Graphitic Carbon Nitrides as Novel Anodes for Li–Ion Batteries

Li–Ion‐Conducting Pillar‐Like Graphitic Carbon Nitrides as Novel Anodes for Li–Ion Batteries

Preparation of Ferricyanic Acid Doped Aryl Amine Copolymer and Its Electrochemical Properties

Mechanistic Insights into the Role of Covalent Triazine Frameworks as Cathodes in Lithium‐Sulfur Batteries

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