A Self-Healable High Glass Transition Temperature Bioepoxy Material Based on Vitrimer Chemistry

Liu, Tuan; Hao, Cheng; Zhang, Shuai; Yang, Xiaoning; Wang, Liwei; Han, Jiarui; Li, Yuzhan; Xin, Junna; Zhang, Jinwen

doi:10.1021/acs.macromol.8b01010

Cited by 255 publications

(194 citation statements)

References 38 publications

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“…118 To increase the circularity of these thermosets bio-based monomers can be used. Partial 126 and full 100,[127][128][129][130][131] bio-based vitrimers are already reported in recent literature.…”

Section: Thermally Reversible Covalent Bondsmentioning

confidence: 99%

A Review on the Potential and Limitations of Recyclable Thermosets for Structural Applications

et al. 2019

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The outstanding performance of conventional thermosets arising from their covalently cross-linked networks directly results in a limited recyclability. The available commercial or close-to-commercial techniques facing this challenge can be divided into mechanical, thermal, and chemical processing. However, these methods typically require a high energy input and do not take the recycling of the thermoset matrix itself into account. Rather, they focus on retrieving the more valuable fibers, fillers, or substrates. To increase the circularity of thermoset products, many academic studies report potential solutions which require a reduced energy input by using degradable linkages or dynamic covalent bonds. However, the majority of these studies have limited potential for industrial implementation. This review aims to bridge the gap between the industrial and academic developments by focusing on those which are most relevant from a technological, sustainable and economic point of view. An overview is given of currently used approaches for the recycling of thermoset materials, the development of novel inherently recyclable thermosets and examples of possible applications that could reach the market in the near future.

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Section: Thermally Reversible Covalent Bondsmentioning

confidence: 99%

A Review on the Potential and Limitations of Recyclable Thermosets for Structural Applications

et al. 2019

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“…The lower reactivity of internal epoxies compared to terminal ones are well‐known in the literature, however, anhydrides are known to easily open these epoxy moieties . This is the reason why the epoxies were cured with 4‐methylcyclohexane‐1,2‐dicarboxylic anhydride (MHHPA), which is a common anhydride used in epoxy‐anhydride thermosets (Scheme ) . MHHPA was also chosen for its liquid state at room temperature, as it allows for a homogeneous system, whereas most anhydrides are solids at room temperature and thus the mixing process is highly complicated.…”

Section: Resultsmentioning

confidence: 99%

Cardanol‐Based Epoxy Monomers for High Thermal Properties Thermosets

Mora

Decostanzi

David

et al. 2019

Euro J Lipid Sci & Tech

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In this paper, epoxy‐anhydride networks are synthesized from a new product of Cardolite Corporation: the Cardolite GX‐2551 epoxy monomer. Due to the complexity of the GX‐2551 structure, an NMR study is performed first to characterize this new commercial product. This epoxy monomer is then reacted with an anhydride (MHHPA) to form polyepoxide thermosets. After curing, dynamic mechanical and thermal analyses are performed for the different thermosets, and then the results are compared to each other. Practical Applications: The cardanol‐derived epoxy monomer described in this contribution, i.e., fully epoxidized molecular cardanol, is a new fully biobased monomer for further epoxy thermoset synthesis. The resulting polyepoxide networks exhibit much higher thermo‐mechanical properties than previous cardanol‐derived epoxy thermosets. Two cardanol‐based epoxy monomers are fully characterized. The GX2551 is reported for the first time and exhibits a higher renewable carbon content. Both monomers are reacted with hexahydro‐4‐methylphtalic anhydride to yield bio‐based aromatic polyepoxide networks with interesting mechanical and thermal properties.

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“…Further strengthening the applicability of TE-epoxies, many attempts to implement them in advanced materials have been made. Just to mention some: silica-epoxy nanocomposites [52]; high T g self-healing bio-epoxies from vanillin-guaiacol [22] or eugenol [5]; industrial rubbers and composites thereof [56]. The major strength of transesterification is that it is targeted to commercially-relevant and straight-forward chemicals, connoting a simple implementation.…”

Section: Transesterificationmentioning

confidence: 99%

“…In fact, for most systems, it seems natural to assume that high temperatures and pressures up to hundreds or thousands of kPa are necessary [38]. However, when the network is extremely rigid, even 220°C for 1 h may not be enough to produce nicely welded surfaces in a hot press [22].…”

Section: Weldabilitymentioning

confidence: 99%

The Impact of Vitrimers on the Industry of the Future: Chemistry, Properties and Sustainable Forward-Looking Applications

2020

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Thermosets are known to be very reliable polymeric materials for high-performance and light-weight applications, due to their retained dimensional stability, chemical inertia and rigidity over a broad range of temperatures. However, once fully cured, they cannot be easily reshaped or reprocessed, thus leaving still unsolved the issues of recycling and the lack of technological flexibility. Vitrimers, introduced by Leibler et al. in 2011, are a valiant step in the direction of bridging the chasm between thermoplastics and thermosets. Owing to their dynamic covalent networks, they can retain mechanical stability and solvent resistance, but can also flow on demand upon heating. More generally, the family of Covalent Adaptable Networks (CANs) is gleaming with astounding potential, thanks to the huge variety of chemistries that may enable bond exchange. Arising from this signature feature, intriguing properties such as self-healing, recyclability and weldability may expand the horizons for thermosets in terms of improved life-span, sustainability and overall enhanced functionality and versatility. In this review, we present a comprehensive overview of the most promising studies featuring CANs and vitrimers specifically, with particular regard for their industrial applications. Investigations into composites and sustainable vitrimers from epoxy-based and elastomeric networks are covered in detail.

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A Self-Healable High Glass Transition Temperature Bioepoxy Material Based on Vitrimer Chemistry

Cited by 255 publications

References 38 publications

A Review on the Potential and Limitations of Recyclable Thermosets for Structural Applications

A Review on the Potential and Limitations of Recyclable Thermosets for Structural Applications

Cardanol‐Based Epoxy Monomers for High Thermal Properties Thermosets

The Impact of Vitrimers on the Industry of the Future: Chemistry, Properties and Sustainable Forward-Looking Applications

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