Graphene synthesis: a Review

Shams, Shabana; Zhang, Ruoyu; Zhu, Jin

doi:10.1515/msp-2015-0079

Cited by 132 publications

(77 citation statements)

References 117 publications

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“…As a special type of advanced carbon material, graphene is regarded as one of the most promising materials in the 21st century for various applications, including electrochemical energy storage and conversion, due to its extraordinary electronic and mechanical properties of having an ultrathin structure, quantum electronic transport, bandgap opening, high mechanical strength, and excellent thermal and electrical conductivity . There are several different approaches for graphene synthesis, involving mechanical peeling, liquid exfoliation, chemical exfoliation, and epitaxial growth like chemical vapor deposition (CVD) . However, the original mechanical peeling and liquid exfoliation method just only yields small amounts of high‐quality graphene, and many strong oxidizers and reducing agents, which are toxic and hazardous to the environment and human health, are necessary in the chemical oxidation–reduction process .…”

Section: Preparation and Characterization Of Lignin‐derived Electrochmentioning

confidence: 99%

Lignin‐derived electrochemical energy materials and systems

Jiang

Wang

et al. 2020

Biofuels Bioprod Bioref

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Electrode and electrolyte materials with higher performance, longer life, and lower cost need to be developed, given the substantial growing demand for advanced electrochemical energy systems. Lignin, the second most abundant natural polymer, has been successfully demonstrated to be a viable precursor or feedstock for the preparation of high-performance electrochemical energy materials and components such as electrodes, electrolyte additives, membrane separators, and binders. Moreover, techno-economic analyses indicate that it is possible to prepare cost-effective carbon structures from lignin at engineering scale, in contrast with current carbon products. These facts suggest that the scalable conversion of lignin into high-value energy materials will offer a promising pathway to not only promote the utilization and valorization of lignin but also boost the development of advanced electrochemical energy systems. This review examines cutting-edge renewable energy materials derived from various lignin compounds and Review: Lignin to energy materials X Wu et al.their applications in electrochemical energy systems with an emphasis on supercapacitors, rechargeable batteries, and fuel cells. Meanwhile, this review also aims to carve out the critical barriers for lignin-derived high-performance materials for energy applications, and to identify viable approaches for the synthesis of sustainable new energy materials.

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Section: Preparation and Characterization Of Lignin‐derived Electrochmentioning

confidence: 99%

Lignin‐derived electrochemical energy materials and systems

Jiang

Wang

et al. 2020

Biofuels Bioprod Bioref

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“…Titanium Oxides (TiO2), Zirconium oxide, Tantalum Oxide (Ta2O5), Alumina thin films (Al2O3). Ceramic oxide coatings are better over metallic or organic oxides in terms of their higher hardness and strength [57]. These are used in industrial applications on account of excellent resistant to oxidation, corrosion, and wear than metals in high-temperature applications [58].…”

Section: Ceramic Nano Coatingsmentioning

confidence: 99%

“…Polymer and metallic matrices nanocomposite coatings are receiving a great attention in industry as protective coatings on account of extraordinary hydrophobic properties. In polymer bases nano coatings, polymers are as host matrices & nanomaterials are inducted as filler or pigment resulting in hybrid organic-inorganic material [57]. Popularly used nano fillers are CNT [69], Graphene oxide [67,69], ZrO [69], SiO2 [70]etc with polymer matrix of epoxy, vinyl, epoxy resins and fluoropolymer.…”

Section: Nano Composite Coatingsmentioning

confidence: 99%

“…Research conducted in last 10 years implies that the high quality graphene and its composite membranes could be impermeable and exhibit excellent barrier properties to many reactive and gases (e.g. hydrogen, helium) and liquids, salts and acids [56][57][58][59][60][61][62][63][64][65][66][67][68][69][70][71][72][73] along with high chemical and thermal stability. These features position graphene ahead over other barrier materials available for industrial application.…”

Section: Application Of Graphene Based Coatings For Mitigation Of Hydmentioning

confidence: 99%

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Combating Hydrogen Embrittlement With Graphene Based Coatings

Khare¹,

Vishwakarma²,

Ahmed³

2019

IJARET

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Hydrogen embrittlement (HE) is an epidemic problem for high strength medium carbon low alloy steel causing reduction in mechanical strength and useful service lifetime. Hydrogen embrittlement of high strength steel is concern for various industrial components used in critical applications. Unpredictable & sudden failure of mechanical equipment/components made of high strength steel (HSS) below designed allowable stress and without appreciable deformation resulted in many catastrophic accidents. HSS being used in various engineering applications such as Aerospace, Nuclear, Marine and Transportation etc. Components typically affected by hydrogen embrittlement are pressure vessels, boilers, automobile frame, fasteners & hardware, shafts, axles, rotors, pipelines etc. Extensive research has been done by scientists & engineers to explore various ways to prevent hydrogen embrittlement. Some of them are i) addition of alloying elements ii) selection of material with less susceptibility to hydrogen iii) use of barrier layers to prevent hydrogen diffusion iv) change in manufacturing process and application environment v) use of advance Nano coatings to minimize hydrogen penetration etc. Out of all these methods of controlling hydrogen embrittlement, use of advance coatings appears to be more practical, less intricate and economical. In current decade Graphene has achieved a great attention from engineering world because of its excellent chemical, physical, mechanical & thermal properties. Graphene can act as a protective barrier against many environmental induced degradation of alloy steels because of its extraordinary impermeability. This review article summaries the current state of research & available commercial solutions for mitigations of hydrogen embrittlement using graphene based Nanocoatings. Authors have conducted experiments on several available coatings including graphene to investigate the behavior in an environment promoting hydrogen embrittlement and compared the effect on mechanical properties and ductility of high strength steel (EN24/AISI4340/34CrNiMo6)

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“…Manifestation of properties of this two-dimensional carbon structure in the form of high mobility of charge carriers [1], thermal conductivity [2], strength [3], and low gas permeability [4] allows its use in various scientific and technical fields. Graphene can be synthesized in many ways [5], but the most widely spread method is chemical vapor deposition (CVD). In this method, copper (Cu) is most often used as a catalytic surface, where graphene grows [6 -8].…”

Section: Introductionmentioning

confidence: 99%

Method for determining the adhesion force between graphene and copper

et al. 2019

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The paper presents the technique of qualitative assessment of the strength of graphene layers adhesion to the surface of a copper substrate, where they are formed. The technique uses a complex of approved analytical methods: electron backscatter diffraction (EBSD), Raman spectroscopy and optical microscopy. The technique was tested on multilayer graphene grown on a copper grain with crystal orientation (111). The presented method can be used to assess the effectiveness of the methods of graphene transfer from grains with different crystal orientation.

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Graphene synthesis: a Review

Cited by 132 publications

References 117 publications

Lignin‐derived electrochemical energy materials and systems

Lignin‐derived electrochemical energy materials and systems

Combating Hydrogen Embrittlement With Graphene Based Coatings

Method for determining the adhesion force between graphene and copper

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