Dynamic Enamine-one Bond Based Vitrimer via Amino-yne Click Reaction

Guo, Xinru; Gao, Fei; Chen, Fengbiao; Zhong, Jiang; Shen, Liang; Lin, Cong; Lin, Yangju

doi:10.1021/acsmacrolett.1c00550

Cited by 38 publications

(36 citation statements)

References 37 publications

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“…Developed over the past decade, vitrimers have been designed from many different chemistries and for many different applications. Vitrimers can provide an ideal platform for designing the viscoelastic properties of a polymer via changes in the chemistry of the polymer backbone − or the type of dynamic bond. ,− These materials have been investigated in applications including shockwave dissipation, three-dimensional (3D) printing, creep resistant plastics, thermally conductive materials, solid battery electrolytes, and ultrathin coatings, where the viscosity and modulus contribute substantially to the resultant performance. In most cases, vitrimers show an Arrhenius temperature dependence of viscosity and a storage modulus, which increases with the cross-link density. ,,, The modulus of vitrimers has also been shown to increase upon heating in contrast to most dissociative dynamic networks. ,, Through a combination of multiple dynamic bonds, the goal of precise control over the temperature-dependent viscoelasticity of a polymer may be possible.…”

Section: Introductionmentioning

confidence: 99%

Relaxation of Vitrimers with Kinetically Distinct Mixed Dynamic Bonds

et al. 2022

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Designing materials with tunable modulus and viscosity is key for applications such as three-dimensional (3D) printing, sound damping, and wearable devices. Vitrimers provide an ideal platform for viscoelastic design because their dynamic, conserved bond exchange allows for control of both cross-link density and exchange kinetics. Here, multiple boronic acid cross-linkers with different functionalities and kinetics were reacted with silicone diols to form poly(dimethylsiloxane) (PDMS) vitrimers. Networks cross-linked with boric acid or two phenyl-substituted boric acids exhibited relaxation times and viscosities within one order of magnitude of each other. Conversely, a cross-linker with nitrogen neighboring groups led to a four order of magnitude acceleration in network relaxation time while still exhibiting a similar modulus to the slower systems. All of these samples demonstrate an increase in moduli with temperature due to entropic elasticity. To understand the effect of more than one dynamic bond on the viscoelastic response, multiple cross-linkers were then combined into a single network and the relaxation spectrum was characterized. The mixed vitrimers exhibit a single relaxation peak, which more closely follows the dynamics of their faster component. These rheological observations are essential for designing complex viscoelastic materials.

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Section: Introductionmentioning

confidence: 99%

Relaxation of Vitrimers with Kinetically Distinct Mixed Dynamic Bonds

et al. 2022

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“…In other words, the dicarboxamide motif served as a dynamic protecting group, facilitating the thermal release of the exchange enabling primary amines. 31 While fast transamination exchange within VU-based vitrimers is widely reported to critically rely on the presence of free primary amines, 7,25,32,33 stable adducts when reacted with acetoacetates, due to a lack of internal hydrogen bond stabilization in the resulting VU. 32 However, this general lack of nucleophilic reactivity might be drastically enhanced when a secondary amine group is present in close proximity to a normal VU cross-link.…”

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confidence: 99%

Masked Primary Amines for a Controlled Plastic Flow of Vitrimers

et al. 2022

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We present a simple method for increasing the reprocessability of vinylogous urethane (VU) vitrimers while decreasing the possibility of creep deformation at lower temperatures. In particular, varying amounts of triethylenetetramine were added as a comonomer to the curing VU formulation to ensure that all of the primary amines reacted to form enaminone cross-links, resulting in a network without reactive primary amine chain-ends. As a result, transamination was significantly slowed down because secondary amines are much less reactive to VU exchange. On the other hand, at higher temperatures, pendent primary amines can be released via a dynamic, endothermic exchange with a nearby less-reactive secondary amine, thereby (re)activating material flow. As a result, ambivalent viscoelastic behavior could be achieved without depolymerization by dynamically releasing pendent primary amines from vinylogous urethane polymer chains. Through careful comonomer selection, VU vitrimers with low viscosity at processing temperatures and at the same time high viscosity at service temperatures could be prepared without the use of catalysts or additives, leveraging the synergistic effects of mildly reactive functionalities through neighboring group participation.

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“…The remarkable similarities found above when comparing INTRA and INTER materials could be partially attributed to the dynamic character of the enamine cross-linking bonds, as demonstrated by the variety of vitrimers that have been prepared based on this “forgotten” dynamic covalent bond. Nevertheless, the clear differences in the broadness of the distribution characterizing the dynamic heterogeneities produced by cross-linking evidence that those materials prepared starting from the dilute solution of SCNP preserve a majority of intramolecular cross-links.…”

Section: Discussionmentioning

confidence: 81%

Intra- vs Intermolecular Cross-Links in Poly(methyl methacrylate) Networks Containing Enamine Bonds

et al. 2022

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The molecular dynamics of a copolymer composed of methyl methacrylate (MMA) and (2-acetoacetoxy)ethyl methacrylate (AEMA) monomers and the influence on it of intra- to intermolecular cross-links of AEMA units with ethylenediamine (EDA) was studied by combining dielectric relaxation experiments and thermal investigations. The dielectric spectra of the non-cross-linked copolymer show three dynamical processes: a slow relaxation (α) and a faster (β), both dominated by the MMA dynamics, and an even faster secondary relaxation (γ) reflecting the AEMA dynamics. Already for low cross-linking densities, the γ process is very much affected and eventually disappears, increasing the cross-linking density. The secondary β relaxation however was nearly unaffected by cross-linking. The effect of cross-linking on the α relaxation was very pronounced with an important increasing of the glass transition temperature T g. There was also an increase of the dynamic heterogeneity and the relaxation intensity when increasing the cross-linking density (up to the maximum explored, 9 mol % EDA). The quality of the average time scale and T g value have similarities in behavior for intra- and intermolecular cross-linking, but clear differences in the dynamic heterogeneities where observed. These differences can be interpreted in connection with the sparse internal structure of the collapsed single chains obtained by intramolecular cross-linking.

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Dynamic Enamine-one Bond Based Vitrimer via Amino-yne Click Reaction

Cited by 38 publications

References 37 publications

Relaxation of Vitrimers with Kinetically Distinct Mixed Dynamic Bonds

Relaxation of Vitrimers with Kinetically Distinct Mixed Dynamic Bonds

Masked Primary Amines for a Controlled Plastic Flow of Vitrimers

Intra- vs Intermolecular Cross-Links in Poly(methyl methacrylate) Networks Containing Enamine Bonds

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