Synthesis of graphene-like porous carbon from biomass for electrochemical energy storage applications

Yeleuov, Mukhtar; Daulbayev, Chingis; Taurbekov, Azamat; Abdisattar, Alisher; Ebrahim, Rabi; Kumekov, S. E.; Приходько, Н. Г.; Lesbayev, B. T.; Batyrzhan, Karakozov

doi:10.1016/j.diamond.2021.108560

Cited by 35 publications

(11 citation statements)

References 65 publications

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“…These experimental observations support the capability of the recycled MDF-based graphene derivative as a low-cost, scalable carbon electrode material for energy storage devices. Yeleuov et al 132 obtained a high specific capacitance of 263 F g −1 and 96.8% Coulombic efficiency (at I D = 1 A g −1 ) for a walnut shell-based few-layered graphene supercapacitors. The symmetric supercapacitor showed excellent capacitive stability at higher current densities (only a 23% decrease in C sp per 10-fold increase in I D ) with a high rate performance, demonstrating the high efficiency of the graphene derivative for EDLC applications.…”

Section: Energy Storage Applicationsmentioning

confidence: 99%

Graphene/Graphene Derivatives from Coal, Biomass, and Wastes: Synthesis, Energy Applications, and Perspectives

2022

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In the last decade, there has been a phenomenal development in the commercially viable, large-scale synthesis of graphene, a multifunctional advanced carbon nanomaterial, which is gaining popularity for its diverse range of applications, especially in energy storage, composites, sensors, and membranes. With the increasing demand, a large number of worldwide research efforts have been employed, resulting in a series of enormous breakthroughs both in its fundamental science and innovative applications. The earlier reviews on graphene show that the increase in the production yield is often accompanied by the generation of substandard graphene quality, making the process unsuited for commercialization. However, recent studies on graphene synthesis have shown the use of naturally available carbonaceous sources for the production of low-cost graphene derivatives is becoming an emerging trend in graphene research. In this present review, the most recent advances in the synthesis of high-quality graphene from solid carbon precursors, particularly abundant coal, biomass, and waste materials, have been extensively discussed along with their potential scalability for commercial production. The quality and yield of these graphene derivatives synthesized through different methods like chemical vapor deposition, exfoliation, laser-induced, microwave irradiation, and chemical methods are also examined to determine the best-suited synthetic methodology from the available literature. The utilization of graphene derivatives in the energy sector was further discussed, particularly in the emerging field of energy storage. Finally, the challenges and future prospects of this study are highlighted to have a better understanding of the current graphene production scenario, with an insight into the most efficient method for synthesizing high-purity low-cost graphene and their potential for scaleup and energy applications in the distant future.

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Section: Energy Storage Applicationsmentioning

confidence: 99%

Graphene/Graphene Derivatives from Coal, Biomass, and Wastes: Synthesis, Energy Applications, and Perspectives

2022

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“…Katchala et al prepared graphite porous carbon sheets (GPCS) with an interlayer spacing of 0.36 nm from jute stick waste using KOH activation method (figure 3(a)) [86]. Likewise, Yeleuov et al have prepared graphite-like ACs using walnut shells that have on average number of 5-7 graphene layers and exhibited high specific capacitance value of 263 F g −1 at 1 A g −1 [97]. The ordered structure of graphite-like carbon can effectively reduce the concentration of internal defects and the irreversible capacity loss in the first cycle, which obviously improves the ICE of materials.…”

Section: Graphite-like Carbonmentioning

confidence: 99%

Renewable waste biomass-derived carbon materials for energy storage

Huang¹,

Tang²,

Zhou³

et al. 2022

J. Phys. D: Appl. Phys.

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It is crucial to develop high-performance electrode materials for the increasing energy demands of various energy storage systems. Biomass-derived carbons demonstrate great potential due to their rich structure, low cost, abundance in reserves, and excellent electrochemical performance. So far, various carbon structures ranging from highly disordered non-graphitic carbon to locally ordered graphite-like carbon have been achieved from different biomass. And they are employed as electrodes for different energy storage systems. However, to our best knowledge, there is no systematic review to show the latest progress in this area. Herein, we have systematically classified the waste biomass and discussed the microstructures of their derived carbons. In particular, as electrode materials, the effects of biomass-derived carbons’ structure, porosity, interlayer spacing, and heteroatomic doping on different energy storage devices are analyzed in detail. Furthermore, the challenges, as well as the corresponding solutions and developing trends to biomass-derived carbons, have been summarized.

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“…In addition, in this work, these parameters are confirmed experimentally and demonstrate the wide applicability of AC as electrode material for energy storage systems. Composites are based on activated carbon obtained from biological waste such as rice husks [10] and walnut shells [11] etc.…”

Section: Nio/с Composites For Energy Storage Systemsmentioning

confidence: 99%

Carbon/NiO Compositional Fibers

Мансуров

Смагулова

Imash³

et al. 2022

Eurasian Chem. Tech. J.

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This article presents the results of the synthesis of carbon-NiO composite fibers. Fibers doped with NiO particles are of practical interest for applications in sensors, energy storage systems, photocatalysts, etc. Four-component initial fibers based on polyacrylonitrile (PAN), activated carbon (AC), coal tar pitch (CTP), and NiO particles were obtained. CTP was obtained by thermal treatment of coal tar, AC by carbonization of apricot kernels, NiO by solution combustion synthesis. PAN, CTP, and AC are a source of carbon, but each of them plays a specific role. PAN is the basis of carbon fibers and a fiber-forming material, CTP is a technogenic waste added to replace polymer particles, AC is an additive that could increase the carbon content and the porosity of the final fibers. The fibers were obtained using the electrospinning method, which makes it possible to use complex suspensions and obtain fibers of various diameters. PAN:CTP:AC:NiO fibers were obtained. Next, the processes of stabilization and carbonization of the fibers were carried out. The fibers at each stage were examined by scanning electron microscopy and EDAX. The result of the synthesis was carbon/NiO fibers with a diameter of 100‒300 nm. The resulting fibers are promising for practical applications due to the one-dimensional structure of the fibers and better adhesion between the fiber and NiO particles.

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Synthesis of graphene-like porous carbon from biomass for electrochemical energy storage applications

Cited by 35 publications

References 65 publications

Graphene/Graphene Derivatives from Coal, Biomass, and Wastes: Synthesis, Energy Applications, and Perspectives

Graphene/Graphene Derivatives from Coal, Biomass, and Wastes: Synthesis, Energy Applications, and Perspectives

Renewable waste biomass-derived carbon materials for energy storage

Carbon/NiO Compositional Fibers

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