Graphene from waste and bioprecursors synthesis method and its application: A review

Arifin, Nur Fatihah Tajul; Yusof, Norazah; Jaafar, Juhana; Aziz, Farhana; Salleh, Wan Norharyati Wan

doi:10.11113/mjfas.v16n3.1491

Cited by 18 publications

(4 citation statements)

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“…140 Afterward, various natural carbonaceous sources, such as plants, wood parts, biomass waste, fruits, vegetables, biopolymers and insect parts, have been explored in research literature for graphene derivatives production by biomass carbonization. 124,141 Figure 11 demonstrates examples of the exploited biomass for 2D GDs synthesis through pyrolysis in inert atmosphere. 124 The principal of graphene synthesis from biomass carbonization is based on the pyrolysis of biomass upon thermal treatment at high temperature ∼ 1000°C under an inert atmosphere.…”

Section: Bottom-up Synthesis Techniquesmentioning

confidence: 99%

“…19 Thus, a recent study on the mechanical properties of ceramic composites based on alumina and zirconia with carbon allotropes, reported that graphene derivatives significantly enhance the fracture toughness, low-temperature wear resistance, creep behavior and superplasticity at high temperatures of ceramic materials. 141 Also, graphene largely modifies the electronic behavior of ceramic materials. For example, Pernia et al 161 have developed 3 mol% yttria tetragonal zirconia polycrystalline (3YTZP) ceramic composites with graphene nanoplatelets (GNPs), via Ex-situ solution mixing using ultrasound agitation.…”

Section: D Graphene Derivatives/inorganic Materials Compositesmentioning

confidence: 99%

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Recent trends in two-dimensional graphene derivatives-based composites: Review on synthesis, properties and applications

Mohamed

Adel

El-Aziz

2023

Journal of Composite Materials

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Owing to the unique properties of 2D graphene derivatives (2D GDs), their composites with other materials possess superior characteristics over other existing materials in the universe. Accordingly, 2D GDs-based composites have emerged as leading materials for substantial advancements of various technological industries such as energy, electronics, sensors, catalysis, environmental remediation, biomedical and structural sectors. Recently, numerous research innovations, have been developed for reliable production of 2D GDs-based composites with high quality, plentiful availability and competitive costs. The overall performance of 2D GDs-based composites is controlled by three main issues. First, the synthesis strategy of GD sheets, which determines the characteristic properties, quantity and cost of the 2D GD product. Second, the surface functionalization of GD sheets, which enhances the compatibility and chemical affinity between GD sheets and other materials within the composites. Finally, the processing method of the composite that strongly affects its microstructure, properties, productivity and cost. This makes such three processes, matters of great concern when designing 2D GDs-based composites for specific application. In this article, the structure, properties, synthesis and surface functionalization of 2D GDs are reviewed. Then, the review article discusses the research developments of 2D GDs-based composites with inorganic materials and polymers, in terms of preparation, properties and applications. Particular focus is placed on Green and/or clean production technologies. The recent research interest in the 2D GDs/multicomponent hybrid composites, with their distinctive multifunctional properties, is highlighted. Also, the new implemented applications of 2D GDs-based composites from 2021, are pointed out, as well as the currently running practical projects, which are proposing innovative futural applications prospects.

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Section: Bottom-up Synthesis Techniquesmentioning

confidence: 99%

Section: D Graphene Derivatives/inorganic Materials Compositesmentioning

confidence: 99%

Recent trends in two-dimensional graphene derivatives-based composites: Review on synthesis, properties and applications

Mohamed

Adel

El-Aziz

2023

Journal of Composite Materials

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“…In some variations, microwaveassisted hydrothermal method is also adopted, where microwave heating facilitates faster reaction to form GCDs with uniform size distribution [102][103][104][105][106]. Apart from GCD, graphene sheets are obtained from glucose via carbonization and calcination in the presence of some activating agents (like FeCl 3 etc) [107,108]. In another interesting process, chemical blowing techniques are utilized to blow molten sugar (or glucose) to prepare graphene.…”

Section: Green-chemical Reduction Of Graphene Oxidementioning

confidence: 99%

Green syntheses of graphene and its applications in internet of things (IoT)—a status review

Banerjee¹

2022

Nanotechnology

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Internet of Things (IoT) is a trending technological field that converts any physical object into a communicable smarter one by converging the physical world with the digital world. This innovative technology connects the device to the internet and provides a platform to collect real-time data, cloud storage, and analyze the collected data to trigger smart actions from a remote location via remote notifications etc. Because of its wide-ranging applications, this technology can be integrated into almost all the industries. Another trending field with tremendous opportunities is Nanotechnology, which provides many benefits in several areas of life, and helps to improve many technological and industrial sectors. So, integration of IoT and Nanotechnology can bring about the very important field of Internet of Nanothings (IoNT), which can re-shape the communication industry. For that, data (collected from trillions of nanosensors, connected to billions of devices) would be the ‘ultimate truth’, which could be generated from highly efficient nanosensors, fabricated from various novel nanomaterials, one of which is graphene, the so-called ‘wonder material’ of the 21st century. Therefore, graphene-assisted IoT/IoNT platforms may revolutionize the communication technologies around the globe. In this article, a status review of the smart applications of graphene in the IoT sector is presented. Firstly, various green synthesis of graphene for sustainable development is elucidated, followed by its applications in various nanosensors, detectors, actuators, and memory and nano-communication devices. Also, the future market prospects are discussed to converge various emerging concepts like machine learning, fog/edge computing, artificial intelligence, big data, blockchain, with the graphene-assisted IoT field to bring about the concept of ‘all-round connectivity in every sphere possible.

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“…This not only conserves energy but also preserves material integrity, facilitating the rapid metamorphosis of soft carbon into graphite endowed with comparable properties to conventional graphite . Following this, both chemical exfoliation and thermal reduction stand out as preferred approaches, given their extensive exploration as feasible avenues for producing graphene-based materials. , The methodology combining Hummer’s method with thermal annealing has garnered substantial attention due to its scalability, operational simplicity, moderate reaction conditions, and cost-effectiveness …”

Section: Introductionmentioning

confidence: 99%

Structural Metamorphosis of Graphitic Derivatives Produced from Fractionated Bamboo Lignin

Ahmad Farid,

Lease,

Zheng

et al. 2023

ACS Sustainable Resour. Manage.

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The demand for sustainable and renewable materials has prompted extensive research on lignocellulosic biomass as a potential feedstock for advanced nanomaterials. This article describes the sequential processes of iron-catalyzed graphitization, improved Hummer's method, and low-temperature thermal annealing designed to transform ethanosolv lignin into bio-based graphene products. The lignin undergoes a metamorphosis during graphitization, transforming into turbostratic crystallite with a unique flake-like configuration at high temperatures in a tightly sealed muffle furnace. Following oxidation, the structure of the resultant graphite undergoes dynamic changes, leading to exfoliation-induced distancing of the sheets of graphene layers. Notwithstanding the reduction process, the geometrical morphology of its oxidized state remains unaltered, preserving the lamellar configuration. Notably, the resulting graphitized lignin showcases a substantial carbon content exceeding 75 wt % and a relatively low oxygen content below 16 wt %. In contrast, graphene oxides (GOs) exhibit elevated oxygen levels resulting from the introduction of oxygen moieties during the oxidation step, which subsequently diminishes following thermal annealing. Diffraction patterns confirm the presence of ( 001), (002), and (100) planes in all graphene-based materials, indicating an aromatic ring orientation. Oxidation affects interlayer spacing with GOs exhibiting larger distances than graphitized lignin and reduced graphene oxides (rGOs). Graphitization increases the sp 2 carbon composition by removing volatiles and mineral matter. Oxidation increases the sp 3 carbon composition, but it decreases after thermal annealing due to the partial removal of oxygen species, leading to a reorientation of the sp 2 carbon configuration.

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Graphene from waste and bioprecursors synthesis method and its application: A review

Cited by 18 publications

References 0 publications

Recent trends in two-dimensional graphene derivatives-based composites: Review on synthesis, properties and applications

Recent trends in two-dimensional graphene derivatives-based composites: Review on synthesis, properties and applications

Green syntheses of graphene and its applications in internet of things (IoT)—a status review

Structural Metamorphosis of Graphitic Derivatives Produced from Fractionated Bamboo Lignin

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