Chemically Reduced Graphite Oxide with Improved Shape Anisotropy

Abstract. Interactive effects of carbon allotropes on the mechanical reinforcement of polymer nanocomposites were investigated. Carbon nanotubes (CNT) and nano-graphite with high shape anisotropy (nanoG) were melt blended with poly(1,4-cis-isoprene), as the only fillers or in combination with carbon black (CB), measuring the shear modulus at low strain amplitudes for peroxide crosslinked composites. The nanofiller was found to increase the low amplitude storage modulus of the matrix, with or without CB, by a factor depending on nanofiller type and content. This factor, fingerprint of the nanofiller, was higher for CNT than for nanoG. The filler-polymer interfacial area was able to correlate modulus data of composites with CNT, CB and with the hybrid filler system, leading to the construction of a common master curve.

Section: Mechanical Characterization and Data Elaborationmentioning

confidence: 74%

mentioning

confidence: 99%

Interactive effects between carbon allotrope fillers on the mechanical reinforcement of polyisoprene based nanocomposites

Agnelli¹,

Cipolletti²,

Musto³

et al. 2014

“…Correlation between surface area and oil absorption appears for CNT, CB N110 and for the CB grade with lower surface area, CB N326, whereas the oil absorption for HSAG appears relatively low. The number of graphene layers stacked in crystalline domains was calculated by applying the Scherrer equation (see experimental section) to the (002) reflection in the XRD pattern, as already reported [23]. For HSAG, such number is about 35 in its pristine state and increases to about 70 in the crosslinked composite.…”

Section: Determination Of Bound Rubbermentioning

confidence: 99%

“…Carbon black and carbon nanofillers have been separately investigated for quite a long time. Recently, features such as crystallinity, shape anisotropy, density, surface area and oil absorption of CNT, a nanosized graphite and CB have been comparatively investigated [23,24]. Moreover, studies on synergistic effects have been performed, both in thermoplastic [15] and elastomeric matrices [24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Master curves for the sulphur assisted crosslinking reaction of natural rubber in the presence of nano- and nano-structured sp2 carbon allotropes

Musto¹,

Barbera²,

Cipolletti³

et al. 2017

Abstract. In this paper, master curves are reported for the crosslinking of a diene rubber with a sulphur based system in the presence of either nano-or nano-structured carbon allotropes, such as carbon nanotubes (CNT), a nanosized graphite with high surface area (HSAG) and carbon black (CB). Poly(1,4-cis-isoprene) from Hevea Brasiliensis was the diene rubber and crosslinking was performed in temperatures ranging from 151 to 180°C, with carbon allotropes below and above their percolation threshold. Such carbon allotropes were characterized by different aspect ratio, surface area and pH. However, in the crosslinking reaction, they revealed common behaviour. In fact, the specific interfacial area could be used to correlate crosslinking parameters, such as induction time (t s1 ) and activation energy (E a ) calculated by applying the autocatalytic model. Monotonous decrease of t s1 and increase of E a were observed, with points lying on master curves, regardless of the nature of the carbon allotropes. Remarkable differences were however observed in the structure of the crosslinking network: when the carbon allotrope was above the percolation threshold much larger crosslinking density was obtained in the presence of CNT whereas composites based on HSAG became soluble in hydrocarbon solvent, after the reaction with a thiol. Proposed explanation of these results is based on the reactivity of carbon allotropes with sulphur and sulphur based compounds, demonstrated through the reaction of 1-dodecanethiol and sulphur with CNT and HSAG and with a model substrate such as anthracene.

“…Indeed, increasing interest is on hybrid systems based on CB-CNT and CB-GRM [24], developed by partially substituting CB with nanometric carbon allotropes. In most studies, CB and carbon nanofillers have been separately investigated and only recently [25,26] crystallinity, shape anisotropy, density, surface area and oil absorption of CNT, a nanosized graphite and CB have been compared. Interestingly, synergistic effects on mechanical reinforcement, between CB and nanofillers, have been shown in both elastomeric [17,24,25,[27][28][29][30] and thermoplastic [31] matrices.…”

Section: Introductionmentioning

confidence: 99%

sp2 carbon allotropes in elastomer matrix: From master curves for the mechanical reinforcement to lightweight materials

Galimberti¹,

Infortuna²,

Guerra³

et al. 2018

Abstract. This work presents high surface area sp 2 carbon allotropes as important tools to design and prepare lightweight materials. Composites were prepared based on either carbon black (CB) or carbon nanotubes (CNT) or hybrid CB/CNT filler systems, with either poly(1,4-cis-isoprene) or poly(styrene-co-butadiene) as the polymer matrix. A correlation was established between the specific interfacial area (i.a.), i.e. the surface made available by the filler per unit volume of composite, and the initial modulus of the composite (G′ γmin ), determined through dynamic mechanical shear tests. Experimental points could be fitted with a common line, a sort of master curve, up to about 30.2 and 9.8 mass% as CB and CNT content, respectively. The equation of such master curve allowed to correlate modulus and density of the composite. Thanks to the master curve, composites with the same modulus and lower density could be designed by substituting part of CB with lower amount of the carbon allotrope with larger surface area, CNT. This work establishes a quantitative correlation as a tool to design lightweight materials and paves the way for large scale application in polymer matrices of innovative sp 2 carbon allotropes.