Raman spectroscopy study of graphene formed by “in situ” chemical interaction of an organic precursor with a molten aluminium matrix

Yolshina, L.A.; Вовкотруб, Э. Г.; Shatunova, A.A.; Pryakhina, V. I.

doi:10.1002/jrs.5771

Cited by 7 publications

(4 citation statements)

References 42 publications

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“…According to the data reported in [16][17][18][19][20], there exist various techniques of introducing carbon nanomaterials into a metal matrix: infiltration of liquid metal into the fibers [16], ball milling [17], implantation of carbon ions into the Al target [18], selective laser melting [19], SPD [20], etc. Among new experimental methods of obtaining graphenereinforced composites, one should mention the in sit synthesis of graphene nanoparticles from carbon-containing precursors directly in the metal matrix in molten salt media [21][22][23][24][25]. Among the key advantages of such a technique is the elimination of porosity, which is characteristic of composites produced ex situ, when previously obtained ultrafine nanoparticles are introduced into the metal matrix.…”

Section: Introductionmentioning

confidence: 99%

Effect of Grain Size on the Properties of Aluminum Matrix Composites with Graphene

Бродова

Yolshina²,

Разоренов³

et al. 2022

Metals

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The structure and mechanical properties of composites consisting of a metal matrix based on aluminum and its alloys of different compositions (AA-3003 and AA-5154) and graphene synthes sized in situ under a layer of molten salts were investigated depending on the chemical composition and grain size of the matrix. Aluminum matrix composites of three compositions were studied in as-cast coarse-grained, deformed fine-grained (grain size < 1 mm), and deformed sub microcrystalline (grain size < 1 μm) states in order to compare the structural characteristics of composites with different grain sizes. The composites were subjected to deformation with a split Hopkinson (Kolsky) bar and to dynamic-channel angular pressing. The hardness and dynamic mechanical properties of the composites were measured at strain rates ε˙ from 1.8 − 4.7 × 103 to 1.6 − 2.4 × 105 s−1. It was found that grain refinement induced a sharp increase in the hardness of composites with various compositions (by a factor of 1.6–2.6). A correlation of the elastic-plastic properties of the aluminum matrix composites with the grain sizes and chemical compositions of the matrices was established. A transition from coarse-grained to sub microcrystalline structure was shown to improve the elastic-plastic properties on average by a factor of 1.5. It was proved that the reinforcing effect of graphene increased with the decreasing grain size of the matrix. Mechanisms of reinforcement of the aluminum matrix composites using graphene were proposed.

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Section: Introductionmentioning

confidence: 99%

Effect of Grain Size on the Properties of Aluminum Matrix Composites with Graphene

Бродова

Yolshina²,

Разоренов³

et al. 2022

Metals

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“…1 A schematic representation and a photo of the electrochemical cell 1-working electrodes; 2-Teflon cell; 3liners for holding the electrodes and the separator; 4-electrolyte; 5-porous separator with electrolyte 1586 cm −1 ; 2D-2704 cm −1 . The intensity ratio I 2D /I G is 0.47, which implies the formation of three-layered graphene [32]. The D peak is considered to indicate the defects in the graphene layer; therefore, its low intensity confirms the formation of perfect quality graphene in the aluminum matrix.…”

Section: Negative Electrode Materialsmentioning

confidence: 99%

Fast-charged aluminum-ion battery with aluminum-graphene nanocomposite anode

Yolshina

Shevelin

Druzhinin

et al. 2020

Ionics

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Currently, aluminum-ion batteries are considered attractive energy storage devices because aluminum is an inexpensive, widely available, environmentally friendly, low-flammable, and high recyclable electrode material. Electrochemical cell simulating the work of an aluminum-ion battery with aluminum-graphene nanocomposite-negative electrode, positive graphene electrode, and chloroaluminate ionic liquid 1-ethyl-3-methylimidazolium chloride has been designed and tested. The cell exhibits excellent performance and long shelf life. The aluminum-graphene composite is not prone to oxidation over a long period of time. Consequently, the negative electrode surface does not undergo passivation by trace amounts of water and oxygen in the electrolyte during storage, which considerably prolongs the battery shelf life. The analyzed cell delivered stable performance across a wide range of charge/discharge rates for several thousands of cycles without any noticeable loss in capacity and Coulombic efficiency. It has almost 100% Coulombic efficiency at high charge/discharge current densities and retains its characteristics after a 7-day current-free period.

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“…With these two effective ways, all the information on 2D materials structure, including the electronic properties and lattice-vibrations can be extracted and exploited to survey the thickness in the case of monolayer and number of layers in the case of vdW heterostructures, biaxial and uni-axial strain, structural stability of the materials, and more especially the defects chemistry as well as a stacking orders of 2D materials. [81][82][83][84][85][86][87] Indeed, it has been recognized that Raman-spectroscopy constitutes a potential and effective way to characterize defects chemistry in 2D materials with graphene or graphene like-structure, owing to the existence of D-and D'peaks relative to defects in the spectrum of samples. [88][89][90][91] In the case of other 2D materials, namly, TMDs, there also appear some additional Raman-peaks immediately after introducing the defects chemistry with an intensity correlated to the density of the defects.…”

Section: (2d)mentioning

confidence: 99%

“…In contrast, the optical spectroscopic techniques, especially Raman and photoluminescence spectroscopies, provide an efficient and nondestructive way to characterize defect on 2D materials. With these two effective ways, all the information on 2D materials structure, including the electronic properties and lattice‐vibrations can be extracted and exploited to survey the thickness in the case of monolayer and number of layers in the case of vdW heterostructures, bi‐axial and uni‐axial strain, structural stability of the materials, and more especially the defects chemistry as well as a stacking orders of 2D materials [81–87] . Indeed, it has been recognized that Raman‐spectroscopy constitutes a potential and effective way to characterize defects chemistry in 2D materials with graphene or graphene like‐structure, owing to the existence of D‐ and D’‐peaks relative to defects in the spectrum of samples [88–91] .…”

Section: Defect Chemistry In 2d Materialsmentioning

confidence: 99%

Recent progress of defect chemistry on 2D materials for advanced battery anodes

Khossossi

Singh

Ainane

et al. 2020

Chemistry An Asian Journal

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The rational design of anode materials plays a significant factor in harnessing energy storage. With an indepth insight into the relationships and mechanisms that underlie the charge and discharge process of two-dimensional (2D) anode materials. The efficiency of rechargeable batteries has significantly been improved through the implementation of defect chemistry on anode materials. This mini review highlights the recent progress achieved in defect chemistry on 2D materials for advanced rechargeable battery electrodes, including vacancies, chemical functionalization, grain boundary, Stone Wales defects, holes and cracks, folding and wrinkling, layered von der Waals (vdW) heterostructure in 2D materials. The defect chemistry on 2D materials provides numerous features such as a more active adsorption sites, great adsorption energy, better ionsdiffusion and therefore higher ion storage, which enhances the efficiency of the battery electrode.

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Raman spectroscopy study of graphene formed by “in situ” chemical interaction of an organic precursor with a molten aluminium matrix

Cited by 7 publications

References 42 publications

Effect of Grain Size on the Properties of Aluminum Matrix Composites with Graphene

Effect of Grain Size on the Properties of Aluminum Matrix Composites with Graphene

Fast-charged aluminum-ion battery with aluminum-graphene nanocomposite anode

Recent progress of defect chemistry on 2D materials for advanced battery anodes

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