Characterization of Graphene-Nanoplatelets Structure via Thermogravimetry

Shtein, Michael; Pri‐Bar, Ilan; Varenik, Maxim; Regev, Oren

doi:10.1021/acs.analchem.5b00228

Cited by 63 publications

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“…The thermal stability of GNP, and hence a further qualitative evaluation of its defectiveness, was evaluated by TGA in air ( Figure 2d); in fact, it was reported that size and defectiveness, of graphenerelated materials, affect the onset of decomposition temperature [54]. The thermogram of the GNP used in this study exhibits two degradation steps: in the first, weight loss of about 6 wt.% occurred between ~ 450°C and 600°C, which could be related to smaller and highly defective nanoparticles; whereas in the second step a further 80 wt.% loss is verified between ~ 600°C and 850°C, with the maximum of mass loss rate centered at ~ 762 °C and about 11 wt.% residue at 850°C, thus indicating an high content of large and low defective nanoflakes, according to the work of Shtein et al [54]. This is crucial for the obtainment of highly thermally conductive polymer nanocomposites.…”

Section: Nanoflakes Characterizationmentioning

confidence: 99%

Effect of processing conditions on the thermal and electrical conductivity of poly (butylene terephthalate) nanocomposites prepared via ring-opening polymerization

et al. 2017

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Successful preparation of polymer nanocomposites, exploiting graphene-related materials, via melt mixing technology requires precise design, optimization and control of processing. In the present work, the effect of different processing parameters during the preparation of poly (butylene terephthalate) nanocomposites, through ring-opening polymerization of cyclic butylene terephthalate in presence of graphite nanoplatelets (GNP), was thoroughly addressed. Processing temperature (240°C or 260°C), extrusion time (5 or 10 minutes) and shear rate (50 or 100 rpm) were varied by means of a full factorial design of experiment approach, leading to the preparation of polybutylene terephthalate/GNP nanocomposite in 8 different processing conditions. Morphology and quality of GNP were investigated by means of electron microscopy, X-ray photoelectron spectroscopy, thermogravimetry and Raman spectroscopy. Molecular weight of the polymer matrix in nanocomposites and nanoflake dispersion were experimentally determined as a function of the different processing conditions. The effect of transformation parameters on electrical and thermal properties was studied by means of electrical and thermal conductivity measurement. Heat and charge transport performance evidenced a clear correlation with the dispersion and fragmentation of the GNP nanoflakes; in particular, gentle processing conditions (low shear rate, short mixing time) turned out to be the most favourable condition to obtain high conductivity values. . This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ ©2017. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ higher thermal conductivity [28,29]. In a recent paper, we demonstrated that the addition of hightemperature-annealed rGO in a polymer matrix leads to a thermal conductivity which is about 2-fold those of poly (butylene terephthalate) containing pristine rGO (higher defectiveness) or GNP [30], further confirming the need of high quality nanoflakes for the preparation of highly thermally conductive polymer nanocomposites. On the other hand, the control of GRM organization into a polymer matrix remains crucial in terms of nanoparticle distribution and quality of contacts between particles. Attempts in precisely controlling orientation and contacts between nanoparticles indeed resulted in an improvement of thermal transfer [31-33] but the methods adopted for the preparation of these nanocomposites are hardly up-scalable or requires very high filler concentrations. Finally, the reduction of interfacial thermal resistance was also pursued by nanoparticle functionalization [34][35][36], despite the effectiveness of this strategy may be also related to the lateral size of the nanoflakes [37]. Recently, the preparation of polymer nanocomposites was obtained by in-situ ring-opening polymerization of cyclic butylene terephthalate (CBT) oligomers into poly (butylene terephthalate), ...

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Section: Nanoflakes Characterizationmentioning

confidence: 99%

Effect of processing conditions on the thermal and electrical conductivity of poly (butylene terephthalate) nanocomposites prepared via ring-opening polymerization

et al. 2017

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“…Furthermore, the second-order spectrum for both rGO shows a narrower and more intense G' peak at ~2705 cm -1 . temperature plot, Figure S2), to indirectly investigate their structural features, knowing that the onset decomposition temperature can be qualitatively related to the size and the defectiveness of graphenerelated materials [35]. T onset (Table 1) for GNP was measured at 632°C, whereas significantly lower values were obtained for RGO (558°C) and RGO-2 (471°C).…”

Section: Nanoflakes Characterizationmentioning

confidence: 99%

Effect of morphology and defectiveness of graphene-related materials on the electrical and thermal conductivity of their polymer nanocomposites

Colonna

Monticelli

Gómez

et al. 2016

Polymer

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In this work, electrically and thermally conductive poly (butylene terephthalate) nanocomposites were prepared by in-situ ring-opening polymerization of cyclic butylene terephthalate (CBT) in presence of a tin-based catalyst. One type of graphite nanoplatelets (GNP) and two different grades of reduced graphene oxide (rGO) were used. Furthermore, high temperature annealing treatment under vacuum at 1700°C was carried out on both RGO to reduce their defectiveness and study the correlation between the electrical/thermal properties of the nanocomposites and the nanoflakes structure/defectiveness. The morphology and quality of the nanomaterials were investigated by means of electron microscopy, x-ray photoelectron spectroscopy, thermogravimetry and Raman spectroscopy. Thermal, mechanical and electrical properties of the nanocomposites were investigated by means of rheology, dynamic mechanical thermal analysis, volumetric resistivity and thermal conductivity measurements. Physical properties of nanocomposites were correlated with the structure and defectiveness of nanoflakes, evidencing a strong dependence of properties on nanoflakes structure and defectiveness. In particular, a significant enhancement of both thermal and electrical conductivities was demonstrated upon the reduction of nanoflakes defectiveness.

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“…We started from non‐aromatic compounds (e.g., NaCl) and non‐conjugated aromatics (e.g., polystyrene), and proceeded through semi‐conjugated aromatics (e.g., dibenzo crown ether and diphenylbutadiyne) to fully conjugated aromatics (e.g., naphthalene, anthracene, and pyrene) ( Figure ). The more conjugated (and planar) the diluent, the stronger its adsorption to and protection of the graphitic surface from converting to amorphous carbon, as analyzed by thermogravimetric analysis (TGA) (Figure b, and Section S3.1, Supporting Information). TGA parameters, such as T 1/2 , the temperature of the combustion step at which half of the total weight loss is reached (Section S3.1, Supporting Information), is correlated with both the graphene sheet dimensions (thickness and mean lateral dimension (MLD), Section S4, Supporting Information) and the defect density .…”

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confidence: 99%

“…The more conjugated (and planar) the diluent, the stronger its adsorption to and protection of the graphitic surface from converting to amorphous carbon, as analyzed by thermogravimetric analysis (TGA) (Figure b, and Section S3.1, Supporting Information). TGA parameters, such as T 1/2 , the temperature of the combustion step at which half of the total weight loss is reached (Section S3.1, Supporting Information), is correlated with both the graphene sheet dimensions (thickness and mean lateral dimension (MLD), Section S4, Supporting Information) and the defect density . Additional TGA parameter is Δ T , the temperature range in which the graphene sheets burn (Sections S3.1 and S4, Supporting Information) is related to the polydispersity of the graphene products …”

mentioning

confidence: 99%

“…TGA parameters, such as T 1/2 , the temperature of the combustion step at which half of the total weight loss is reached (Section S3.1, Supporting Information), is correlated with both the graphene sheet dimensions (thickness and mean lateral dimension (MLD), Section S4, Supporting Information) and the defect density . Additional TGA parameter is Δ T , the temperature range in which the graphene sheets burn (Sections S3.1 and S4, Supporting Information) is related to the polydispersity of the graphene products …”

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Graphite‐to‐Graphene: Total Conversion

et al. 2016

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The rush to develop graphene applications mandates mass production of graphene sheets. However, the currently available complex and expensive production technologies are limiting the graphene commercialization. The addition of a protective diluent to graphite during ball-milling is demonstrated to result in a game-changer yield (>90%) of defect-free graphene, whose size is controlled by the milling energy and the diluent type.

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Characterization of Graphene-Nanoplatelets Structure via Thermogravimetry

Cited by 63 publications

References 33 publications

Effect of processing conditions on the thermal and electrical conductivity of poly (butylene terephthalate) nanocomposites prepared via ring-opening polymerization

Effect of processing conditions on the thermal and electrical conductivity of poly (butylene terephthalate) nanocomposites prepared via ring-opening polymerization

Effect of morphology and defectiveness of graphene-related materials on the electrical and thermal conductivity of their polymer nanocomposites

Graphite‐to‐Graphene: Total Conversion

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