Facile Synthesis of Non-Graphitizable Polypyrrole-Derived Carbon/Carbon Nanotubes for Lithium-ion Batteries

Jin, Bo; Gao, Fan; Zhu, Yongfu; Lang, Xing‐You; Han, Gao‐Feng; Wang, Gao; Wen, Zi; Zhao, Ming; Li, Jian-Chen; Jiang, Qing

doi:10.1038/srep19317

Cited by 54 publications

(32 citation statements)

References 53 publications

(69 reference statements)

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“…The chemically obtained polypyrrole depends on the conditions and the chemistry of the reaction mixture formed [16]. Various additives (such as carbon nanotubes) can be added to the electrolyte to form a polypyrrole-based composite [17]. The most practical method for obtaining polypyrrole is the electrochemical oxidation because its application is easy and the polypyrrole base properties (film morphology, thickness and electrical properties) can be tailored by the deposition conditions (by changing the electrolyte conditions and the applied potential) [18].…”

Section: Introductionmentioning

confidence: 99%

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Yavuz

Aktas

Durdu

2019

Sakarya University Journal of Science

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Graphite electrode was modified by polypyrrole (PPy) thin film. PPy was electrodeposited potentiostatically by applying-1.5 V from acidic aqueous solution having pyrrole monomers. The waiting time of deposition solution effect the surface coverage of resulted films. PPy modified electrodes fabricated by old solution have lower surface coverage than PPy obtained from freshly prepared solution. PPy films were transferred to aqueous (acidic, neutral, alkaline) and a non-aqueous (Deep Eutectic Solvent) solutions for cycling. Capacitance performance of PPy film in a choline chloride based ionic liquid (Ethaline) was compared with that of PPy films in aqueous solutions. As PPy film in salt solution (LiClO4 and NaCl) was evolved because deposition electrolyte was different (H2SO4) than deposition electrolyte and salt ions are exchanged at the beginning of cycling. Film obtained in acidic media was transferred into alkaline solution or ionic liquid is electroinactive. PPy film is strongly electroactive in an acidic media for hundreds of cycles as acidic media can cause the highest charge which is directly related to capacitive performance. Upon increasing pH value of cycling electrolyte, current and charge value decreases. PPy film in a salt solution (NaCl or LiClO4 in water) and acidic solution (H2SO4) is electroactive and can be used for supercapacitor application. As PPy film in ionic liquids and alkaline solution cannot be electroactive, they cannot be used for supercapacitor applications. Capacity retention of PPy in KOH and Ethaline is low (around 5%). However, PPy thin film in H2SO4 has 77% of capacitance retention after 500 scans.

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Section: Introductionmentioning

confidence: 99%

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Yavuz

Aktas

Durdu

2019

Sakarya University Journal of Science

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“…As alternative materials to graphite, a variety of nano-structured carbonaceous materials have been proposed, such as carbon nanotubes, [9,10] graphene, [11,12] hollow carbon spheres, [13,14] porous carbons [15][16][17][18] or hybrids between all these systems [19,20]. Doping by heteroatoms such as nitrogen [21,22] or boron [23] has also been investigated.…”

Section: Introductionmentioning

confidence: 99%

Alginic acid-derived mesoporous carbonaceous materials (Starbon®) as negative electrodes for lithium ion batteries: Importance of porosity and electronic conductivity

Kim

bruyn

Alauzun

et al. 2018

Journal of Power Sources

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Alginic acid-derived mesoporous carbonaceous materials (Starbon¨ A800 series) were investigated as negative electrodes for lithium ion batteries. To this extent, a set of mesoporous carbons with different pore volume and electronic conductivity was tested. The best electrochemical performance was obtained for A800 with High Pore Volume (A800HPV), which displays both the highest pore volume (0.9 cm 3 g-1) and the highest electronic conductivity (84 S m-1) of the tested materials. When compared to a commercial mesoporous carbon, A800HPV was found to exhibit both a better long-term stability, and a markedly improved rate capability. The presence of a hierarchical interconnected pore network in A800HPV, accounting for a high electrolyte accessibility, could lay at the origin of the good electrochemical performance. Overall, the electronic conductivity and the mesopore size appear to be the most important parameters, much more than the specific surface area. Finally, A800HPV electrodes display similar electrochemical performance when formulated with or without added conductive additive, which could make for a simpler and more eco-friendly electrode processing.

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“…However, before LIBs can be applied on a large scale in the abovementioned fields, their cycle life, rate capability, and safety performance must be further improved . So far, graphite‐based materials are still the most commonly used anode materials in commercial LIBs, because of their high reversibility, high capacity of 372 mAh g −1 , and low cost . Unfortunately, graphite‐based materials have low potential, close to that of lithium metal, which leads to the formation of a solid–electrolyte interphase (SEI) film and lithium dendrites during the charging process.…”

Section: Introductionmentioning

confidence: 99%

High Lithium Insertion Voltage Single‐Crystal H₂Ti₁₂O₂₅ Nanorods as a High‐Capacity and High‐Rate Lithium‐Ion Battery Anode Material

Guo

Chen

Shan³

et al. 2017

ChemSusChem

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H2Ti12O25 holds great promise as a high‐voltage anode material for advanced lithium‐ion battery applications. To enhance its electrochemical performance, control of the crystal orientation and morphology is an effective way to cope with slow Li+‐ion diffusion inside H2Ti12O25 with severe anisotropy. In this report, Na2Ti6O13 nanorods, prepared from Na2CO3 and anatase TiO2 in molten NaCl medium, were used as a precursor in the synthesis of long single‐crystal H2Ti12O25 nanorods with reactive facets. The as‐prepared H2Ti12O25 nanorods with a diameter of 100–200 nm showed higher charge (extraction) specific capacity and better rate performance than previously reported systems. The reversible capacity of H2Ti12O25 was 219.8 mAh g−1 at 1C after 100 cycles, 172.1 mAh g−1 at 10C, and 144.4 mAh g−1 at 20C after 200 cycles; these values are higher than those of H2Ti12O25 prepared by the conventional soft‐chemical method. Moreover, the as‐prepared H2Ti12O25 nanorods exhibited superior cycle stability with more than 94 % retention of capacity with nearly 100 % coulombic efficiency after 100 cycles at 1C. On the basis of the above results, long single‐crystal H2Ti12O25 nanorods synthesized in molten NaCl with outstanding electrochemical characteristics hold a significant amount of promise for hybrid electric vehicles and energy‐storage systems.

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Facile Synthesis of Non-Graphitizable Polypyrrole-Derived Carbon/Carbon Nanotubes for Lithium-ion Batteries

Cited by 54 publications

References 53 publications

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Alginic acid-derived mesoporous carbonaceous materials (Starbon®) as negative electrodes for lithium ion batteries: Importance of porosity and electronic conductivity

High Lithium Insertion Voltage Single‐Crystal H₂Ti₁₂O₂₅ Nanorods as a High‐Capacity and High‐Rate Lithium‐Ion Battery Anode Material

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Facile Synthesis of Non-Graphitizable Polypyrrole-Derived Carbon/Carbon Nanotubes for Lithium-ion Batteries

Cited by 54 publications

References 53 publications

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Polypyrrole Modified Graphite Electrode for Supercapacitor Application: The Effect of Cycling Electrolytes

Alginic acid-derived mesoporous carbonaceous materials (Starbon®) as negative electrodes for lithium ion batteries: Importance of porosity and electronic conductivity

High Lithium Insertion Voltage Single‐Crystal H2Ti12O25 Nanorods as a High‐Capacity and High‐Rate Lithium‐Ion Battery Anode Material

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High Lithium Insertion Voltage Single‐Crystal H₂Ti₁₂O₂₅ Nanorods as a High‐Capacity and High‐Rate Lithium‐Ion Battery Anode Material