Thermally Activable Bistetrazoles for Elastomers Crosslinking

Monti, Mauro; Giannini, Luca; Tadiello, Luciano; Guerra, Silvia; Papagni, Antonio; Vaghi, Luca

doi:10.3390/polym14142919

Cited by 2 publications

(2 citation statements)

References 23 publications

(26 reference statements)

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“…A standard cross-linking system (with sulfur) is, however, not completely satisfactory as it is difficult to control the degree and homogeneity of cross-linking as well as the activation temperature. These latter aspects can lead to the undesirable scorching of the rubber composition due to early vulcanization and suboptimal sulfur dispersion, ending up with materials with poor hysteretic properties [ 14 , 15 ]. In addition, the use of a conventional curing system has disadvantages such as worse thermal resistance, low compression set, the migration of the curing agent or accelerators, the emission of toxic products of the accelerator decomposition (e.g., N-nitrosamines) and varied susceptibility of the elastomer to the pre-vulcanization and reversion [ 5 , 16 ].…”

Section: Introductionmentioning

confidence: 99%

The Morphology, Mechanical and Dynamic Properties, Fire Hazard and Toxicity of Chloroprene and Butadiene Rubber Composites Cross-Linked with Zinc

et al. 2023

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This paper presents the influence of zinc on the cross-linking process, mechanical and dynamic properties, morphologies and balance of thermal degradation of blends containing chloroprene rubber (CR) and butadiene rubber (BR). The novel aspect of this research is a comprehensive approach presenting a new curing agent for the CR/BR blends to increase their cross-linking density and final properties, including non-flammability and low fire hazard. This is due to the need to find an alternative to zinc oxide, which is the standard curing agent for chloroprene rubber. The regulations of the European Union enforce a significant limitation on the use of this compound in elastomer technology, due to its harmful effect on aquatic organisms. In this paper, the CR/BR composites were cured with zinc and filled with natural silica fillers (sillitin or chalcedonite) or synthetic silica filler (aerosil). The investigation focused on the morphology characterization of the obtained compounds, their cross-linking degree, swelling, mechanical and dynamic properties, fire hazard and toxicity. The structure of cured CR/BR blends was characterized via scanning electron microscopy (SEM). The fire resistance studies were performed using cone calorimetry or oxygen index methods, whereas toxicity tests were performed with the use of the FB-FTIR (fluidized bed reactor coupled with FTIR analyzer) method. The results showed that obtained CR/BR products were characterized by satisfactory final properties. The properties determined by the oxygen index and cone calorimetry methods, including the behaviors of the tested CR/BR vulcanizates in fire conditions, showed that the produced compounds were characterized by a low fire hazard and can be classified as non-combustible rubber products. However, the toxicity of the decomposition products, determined at 450, 550 and 750 °C, was very high.

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Section: Introductionmentioning

confidence: 99%

The Morphology, Mechanical and Dynamic Properties, Fire Hazard and Toxicity of Chloroprene and Butadiene Rubber Composites Cross-Linked with Zinc

et al. 2023

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“…One major challenge arises in the competitive trade-off between the strength and extensibility of the commercial elastomers. Despite the development of specific chemical agents − or reinforcing filler particles − to impart elastomers with desirable strength, the extensibility is always severely damaged. Furthermore, the long-term impacts of petroleum-based elastomers on the ecological environment are also acknowledged as a significant concern.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous Physical Cross-Linking and Mechanical Strengthening of Elastomers by Enantiomeric Interactions through Reactive Processing

Chen,

Ling,

et al. 2023

ACS Appl. Polym. Mater.

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Exploiting robust elastomers without sacrificing thermoplasticity has been extremely desired for decades, yet it is challenging. Noncovalent interactions are a versatile platform for the development of networks with reversible cross-linking joints. Herein, an alternative strategy is proposed to straightforwardly construct a mechanical strengthening elastomer with a dynamic cross-linking network via multiple H-bonding between enantiomeric polymer pairs. First, poly-L-lactic acid (PLLA)/poly-D-lactic acid (PDLA) were pregrafted onto polyolefin elastomer (POE) to obtain POE-g-PLLA and POE-g-PDLA, respectively. Due to the specific intermolecular interactions, stereocomplex crystals (SC) were formed and preserved during the subsequent melt-compounding. SC enabled the immobilization of the cross-linking point within the POE matrix, facilitating the construction of the SC noncovalent network (SC-N). As such, SC-N endowed the elastomer with synergistically enhanced modulus, strength, and heat resistance, as compared with traditional chemical cross-linked counterparts. More importantly, SC-N displayed desirable reprocessability upon the temporary dissociation of physical cross-linking linkages above T m,SC . These findings may open a feasible avenue of designing advanced elastomers with dynamic behaviors and provide deeper insights into the underlying mechanism of covalent adaptable cross-linking.

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Thermally Activable Bistetrazoles for Elastomers Crosslinking

Cited by 2 publications

References 23 publications

The Morphology, Mechanical and Dynamic Properties, Fire Hazard and Toxicity of Chloroprene and Butadiene Rubber Composites Cross-Linked with Zinc

The Morphology, Mechanical and Dynamic Properties, Fire Hazard and Toxicity of Chloroprene and Butadiene Rubber Composites Cross-Linked with Zinc

Simultaneous Physical Cross-Linking and Mechanical Strengthening of Elastomers by Enantiomeric Interactions through Reactive Processing

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