Reversible Reactions, Mesh Size, and Segmental Dynamics Control Penetrant Diffusion in Ethylene Vitrimers

Huang, Junrou; Sheridan, Grant S.; Chen, Chen; Ramlawi, Nabil; Ewoldt, Randy H.; Evans, Christopher M.

doi:10.1021/acsmacrolett.3c00244

Cited by 5 publications

(3 citation statements)

References 59 publications

(98 reference statements)

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“…Significant progress in this direction was recently made in the ECNLE theory framework for homopolymers melts . Vitrimers are also potentially new separation membrane materials with novel functionality, as suggested by the recent experimental study of one of us. , This motivates our ongoing efforts to extend the presented approach to create a predictive theory for penetrant transport in dynamic bonding materials. Of critical importance for understanding penetrant mobility is how bond exchange affects the matrix segmental relaxation time, and hence the penetrant hopping rate and diffusivity.…”

Section: Summary and Discussionmentioning

confidence: 95%

“…Vitrimers also have other varied proposed applications such as solid polymer electrolytes, superhydrophobic coatings, shape-memory materials, , and adhesives . Although a large body of experimental work has been directed toward investigating the self-healing, recyclability, and stress relaxation behavior of vitrimers, ,, quantitative studies of the effects of bond exchange in dense melts and on phenomena such as crystallization, phase separation, self-assembly, , and ion and molecular transport , are relatively rare. From a broad perspective, a more comprehensive understanding of dynamics across length and time scales is required for materials design and optimization, in addition to creating a mechanistic understanding of dynamic cross-linking on monomer scale relaxation in vitrimers.…”

Section: Introductionmentioning

confidence: 99%

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Self-Consistent Theory for Structural Relaxation, Dynamic Bond Exchange Times, and the Glass Transition in Polymeric Vitrimers

Mei,

Evans,

Schweizer

2024

Macromolecules

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We formulate a statistical mechanical theory for how dynamic bond exchange influences the activated hopping-driven relaxation of Kuhn segments in dynamically cross-linked networks or vitrimers over a wide range of temperatures and cross-link densities. The key new methodological aspect is to address in a self-consistent manner the dynamic consequences of bond exchange on the Kuhn segmental alpha relaxation, and vice versa. The predicted temperature dependence of the segmental alpha time of vitrimers at high temperatures remains the same as that of permanent networks, but at lower temperatures, a significant acceleration of relaxation occurs due to bond exchanges. From a mechanistic perspective, the vitrimer local cage barrier is very weakly affected by bond exchange, while the collective elastic barrier contribution decreases significantly in the deeply supercooled regime. The vitrimer glass transition temperature is predicted to grow linearly with the square root of the cross-link density, as previously found for permanent networks. Material-specific chemical effects such as cross-linker size relative to that of the normal Kuhn segment or special attraction of a cross-linker with polymers are crudely considered based on model calculations. The theory is quantitatively applied to recent experiments on dry ethylene vitrimers. Good agreements are found including that the bond exchange time follows an Arrhenius law at high enough temperatures but upward non-Arrhenius deviations emerge in the deeply supercooled regime, and a collapsed master curve of the segment alpha time exists over a wide range of cross-link densities and temperatures. Possible extensions to treat dynamic heterogeneity effects and penetrant transport in vitrimers are briefly discussed.

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Section: Summary and Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Self-Consistent Theory for Structural Relaxation, Dynamic Bond Exchange Times, and the Glass Transition in Polymeric Vitrimers

Mei,

Evans,

Schweizer

2024

Macromolecules

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“…The slow dynamic bonds do not seem to influence the diffusion of the dye through the material because the rate at which bond exchange occurs is not high enough to differentiate the material from a permanent network. However, in the case of fast dynamic bonds, the bond exchange reactions (BERs) occur on timescales where penetrant hopping is possible, enhancing the diffusion of the penetrant as a consequence [39,40].…”

Section: Introductionmentioning

confidence: 99%

Molecular Simulation of Covalent Adaptable Networks and Vitrimers: A Review

Karatrantos,

Couture,

Hesse

et al. 2024

Polymers

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Covalent adaptable networks and vitrimers are novel polymers with dynamic reversible bond exchange reactions for crosslinks, enabling them to modulate their properties between those of thermoplastics and thermosets. They have been gathering interest as materials for their recycling and self-healing properties. In this review, we discuss different molecular simulation efforts that have been used over the last decade to investigate and understand the nanoscale and molecular behaviors of covalent adaptable networks and vitrimers. In particular, molecular dynamics, Monte Carlo, and a hybrid of molecular dynamics and Monte Carlo approaches have been used to model the dynamic bond exchange reaction, which is the main mechanism of interest since it controls both the mechanical and rheological behaviors. The molecular simulation techniques presented yield sufficient results to investigate the structure and dynamics as well as the mechanical and rheological responses of such dynamic networks. The benefits of each method have been highlighted. The use of other tools such as theoretical models and machine learning has been included. We noticed, amongst the most prominent results, that stress relaxes as the bond exchange reaction happens, and that at temperatures higher than the glass transition temperature, the self-healing properties are better since more bond BERs are observed. The lifetime of dynamic covalent crosslinks follows, at moderate to high temperatures, an Arrhenius-like temperature dependence. We note the modeling of certain properties like the melt viscosity with glass transition temperature and the topology freezing transition temperature according to a behavior ruled by either the Williams–Landel–Ferry equation or the Arrhenius equation. Discrepancies between the behavior in dissociative and associative covalent adaptable networks are discussed. We conclude by stating which material parameters and atomistic factors, at the nanoscale, have not yet been taken into account and are lacking in the current literature.

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Stress‐induced dynamics of glassy vitrimers with fast bond exchange rate

Pandya,

Perego,

Khabaz

2023

J of Applied Polymer Sci

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Vitrimers are dynamic covalent networks, showing considerable promise in self‐healing and reprocessability applications. In this work, molecular simulations are used to study the shear stress‐induced dynamics of vitrimers in the glassy regime and compare their response with that of permanent networks, providing valuable insights into the macroscopic properties of these networks. Results show that vitrimers undergo bond exchange reactions induced by the application of the shear stress, and these events result in accelerated dynamics and subsequently, higher shear compliance of vitrimer compared to the thermoset. When the applied shear stress is high and deformation enters the nonlinear regime, the vitrimer network shows large shear creep compliance and enhanced non‐affine dynamics. Furthermore, the analysis of the self‐particle dynamics demonstrates that the dynamical behavior of vitrimers is highly heterogeneous at short observation times under low and intermediate stress values, while they become homogeneous in the regime of the shear compliance where it shows significantly higher compliance than the permanent network. The significance of the rate of deformation on the dynamics of glassy vitrimers is successfully demonstrated.

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Reversible Reactions, Mesh Size, and Segmental Dynamics Control Penetrant Diffusion in Ethylene Vitrimers

Cited by 5 publications

References 59 publications

Self-Consistent Theory for Structural Relaxation, Dynamic Bond Exchange Times, and the Glass Transition in Polymeric Vitrimers

Self-Consistent Theory for Structural Relaxation, Dynamic Bond Exchange Times, and the Glass Transition in Polymeric Vitrimers

Molecular Simulation of Covalent Adaptable Networks and Vitrimers: A Review

Stress‐induced dynamics of glassy vitrimers with fast bond exchange rate

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