Microstructure of natural graphite flakes revealed by oxidation: Limitations of XRD and Raman techniques for crystallinity estimates

Badenhorst, Heinrich

doi:10.1016/j.carbon.2013.09.065

Cited by 93 publications

(60 citation statements)

References 65 publications

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“…A recent extensive investigation on natural flake graphite, very similar to the materials under consideration in this study, concluded that the flakes are comprised of polygonized stacks of interlinked crystals as seen from an angle in Figure 1A. [36]. The morphology is the result of complex crystal growth phenomena during flake formation.…”

Section: Discussionmentioning

confidence: 96%

Characterization of commercial expandable graphite fire retardants

et al. 2014

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Thermal analysis and other techniques were employed to characterize two expandable graphite samples. The expansion onset temperatures of the expandable graphite's were ca.220°C and 300°C respectively. The key finding is that the commercial products are not just pure graphite intercalation compounds with sulfuric acid species intercalated as guest ions and molecules in between intact graphene layers. A more realistic model is proposed where graphite oxide-like layers are also randomly interstratified in the graphite flakes. These graphite oxide-like layers comprise highly oxidized graphene sheets which contain many different oxygen-containing functional groups. This model explains the high oxygen to sulfur atomic ratios found in both elemental analysis of the neat materials and in the gas generated during the main exfoliation event.

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Section: Discussionmentioning

confidence: 96%

Characterization of commercial expandable graphite fire retardants

et al. 2014

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“…Although in the last decade NG production has grown, at current rates it is estimated that production could be maintained for over 200 years. Currently, to prepare graphene, only high-purity graphite (more than 99.9% fixed carbon) is used [15,16]. To achieve this level of purity, silicate mineral impurities in the starting graphite must be removed by vaporization at ultra-high temperature or leaching in hydrofluoric acid [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Untreated Natural Graphite as a Graphene Source for High-Performance Li-Ion Batteries

et al. 2018

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Graphene nanosheets (GNS) are synthesized from untreated natural graphite (NG) for use as electroactive materials in Li-ion batteries (LIBs), which avoids the pollution-generating steps of purifying graphite. Through a modified Hummer method and subsequent thermal exfoliation, graphitic oxide and graphene were synthesized and characterized structurally, morphologically and chemically. Untreated natural graphite samples contain 45-50% carbon by weight; the rest is composed of different elements such as aluminium, calcium, iron, silicon and oxygen, which are present as calcium carbonate and silicates of aluminium and iron. Our results confirm that in the GO and GNS synthesized, calcium is removed due to oxidation, though other impurities are maintained because they are not affected by the synthesis. Despite the remaining mineral phases, the energy storage capacity of GNS electrodes is very promising. In addition, an electrochemical comparison between GNS and NG demonstrated that the specific capacity in GNS is higher during the whole cycling process, 770 mA·g −1 at 100th cycle, which is twice that of graphite.

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“…The Hummers method tends to create large puffed regions during exfoliation, resembling a concertina. The reason for this may be the segmented stacking structure found in this type of graphite [31]. The gas phase material on the other hand shows a more evenly distributed expansion, due the 1 st stage intercalation, rather resulting in a lattice work structure as exemplified in Figure 10 (B).…”

Section: Modified Hummers Methodsmentioning

confidence: 95%

“…In all cases the so-called disorder or D-peak was practically absent, indicating that the residual damage present in the material cannot be detected by this method. This is not surprising given the fairly large size of the GNPs compared to the small spot size of the Raman laser [31].…”

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confidence: 97%

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The influence of three different intercalation techniques on the microstructure of exfoliated graphite

Heerden

Badenhorst

2015

Carbon

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The characteristics of exfoliated graphite derived from three intercalation methods: gas phase intercalation of iron (III) chloride, modified Hummers method and an electrochemical technique, were compared.Despite the absence of strong oxidizers the electrochemical method produced a material which is very similar to that of the modified Hummers method in virtually every respect. These both produced a graphite oxide based material whilst the gas phase method resulted in a stage 1 intercalation compound. The different materials demonstrated very distinctive exfoliation behaviour.The gas phase material exhibits 3% mass loss during expansion but has a large amount of residual intercalant. The graphite oxide based methods result in mass loss of up to 25% in the expansion zone. For all three samples the residual impurities lead to a reduction in oxidative resistance. Once removed all samples exhibit nearly identical oxidation behaviour.All three methods delivered graphite nanoplatelets with a very high aspect ratio through considerable expansion. Surprisingly the gas phase method caused persistent residual damage. All three methods yielded a product with varying levels of basal and edge damage, but the purified Hummers material exhibited marginally more "ideal" characteristics. The simplest but still effective technique was found to be the electrochemical approach.

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Microstructure of natural graphite flakes revealed by oxidation: Limitations of XRD and Raman techniques for crystallinity estimates

Cited by 93 publications

References 65 publications

Characterization of commercial expandable graphite fire retardants

Characterization of commercial expandable graphite fire retardants

Untreated Natural Graphite as a Graphene Source for High-Performance Li-Ion Batteries

The influence of three different intercalation techniques on the microstructure of exfoliated graphite

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