Linear and Nonlinear Viscoelasticities of Dissociative and Associative Covalent Adaptable Networks: Discrepancies and Limits

Chen, Xiang; Jiang, Nuofei; Shao, Jingyu; Zhang, Hongdong; Yang, Yuliang; Tang, Ping

doi:10.1021/acs.macromol.2c02122

Cited by 18 publications

(52 citation statements)

References 67 publications

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“…Consequently, PET vitrimers show more obvious nonlinear characteristics as shown in Figure 9. It is worth noting that the effect of orientation is negligible in vitrimers without dissociation, and all PET vitrimers show rigid network under extensional flow 35 . In summary, the ductility of PET vitrimers would decrease with increase in crosslinking degree, resulting in smaller maximum strain.…”

Section: Resultsmentioning

confidence: 90%

“…A predicted overshoot in viscosity growth which is similar to ionomers was not observed at higher extensional rate of 0.3 s À1 due to edge rupture. 35 It is obvious that 811-1.5 underwent melt fracture at edge as shown in the inserted pictures in Figure 10A. In dissociated ionomers, η þ at long time slightly hardens above the LVE curve at higher extensional rates, exhibits an overshoot, and then approaches the zero-shear viscosity η 0 .…”

Section: Start-up Shear Flowmentioning

confidence: 90%

“…The creep resistance and crosslinking degree were investigated by Qiu's work, confirming excellent processability of PET vitrimers 20 . The theory and simulation study with regard to dynamic network structures have been investigated in detail by our group 32–35 . However, rheology behavior of PET vitrimers in experiments such as different mechanisms in the whole relaxation process, especially nonlinear rheology of vitrimers, has not been explored rigorously so far.…”

Section: Introductionmentioning

confidence: 91%

“…It is worth noting that the effect of orientation is negligible in vitrimers without dissociation, and all PET vitrimers show rigid network under extensional flow. 35 In summary, the ductility of PET vitrimers would decrease with increase in crosslinking degree, resulting in smaller maximum strain. Obviously, the extensional behavior of materials can be tuned by the load of crosslinking agent (network density).…”

Section: Extensional Rheologymentioning

confidence: 97%

“…20 The theory and simulation study with regard to dynamic network structures have been investigated in detail by our group. [32][33][34][35] However, rheology behavior of PET vitrimers in experiments such as different mechanisms in the whole relaxation process, especially nonlinear rheology of vitrimers, has not been explored rigorously so far. Though this PET system is not perfect for research of vitrimer dynamics due to difficulty in characterization of detailed chemical structure, high-performance PET with excellent processability has an enormous potential in industry.…”

Section: Introductionmentioning

confidence: 99%

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Linear viscoelasticity, nonlinear rheology and applications of polyethylene terephthalate vitrimers

Zhang,

Cui,

Zhang

et al. 2023

Journal of Polymer Science

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To enhance mechanical properties and processing performance of poly(ethylene terephthalate) (PET), it was upcycled to processable PET vitrimers with different crosslinking degrees by introducing dynamic network. The thermodynamics and linear viscoelasticity of PET vitrimers were explored by non‐isothermal crystallization, isothermal sweep, frequency sweep and stress relaxation after incorporation of network. In particular, rheology experiments are sensitive to network structure and bond exchange mechanism in vitrimers. The pseudo‐master curves show that relaxation processes are composed of three characteristic regions: Rouse‐type relaxation of network strands, rubbery plateau and terminal relaxation of network, which is consistent with reversible gelation (RG) model. Two distinct (flow and chemical reaction) activation energies, are obtained by time–temperature superposition principle due to different temperature dependences of two relaxation behaviors. In addition, nonlinear rheology of PET vitrimers was investigated by extensional flow and start‐up shear at the same Weissenberg number, and obvious strain hardening behavior were observed in all vitrimers. However, vitrimers with different crosslinking density exhibited distinct strain hardening trends as increase of extensional rate, corresponding to the ductility of material. On the basis of kinetics study, self‐repairing and welding properties are further quantitatively explored for industrial applications.

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Section: Resultsmentioning

confidence: 90%

Section: Start-up Shear Flowmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 91%

Section: Extensional Rheologymentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Linear viscoelasticity, nonlinear rheology and applications of polyethylene terephthalate vitrimers

Zhang,

Cui,

Zhang

et al. 2023

Journal of Polymer Science

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Synthesis, Recycling and High‐Throughput Reprocessing of Phase‐Separated Vitrimer‐Thermoplastic Blends

Joosten,

Cassagnau,

Drockenmuller

et al. 2023

Adv Funct Materials

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Phase‐separated polymer blends including a transesterification vitrimer and polypropylene are synthesized from widely available precursors through reactive processing. It is shown that proper formulation during the process including a viscosity modifier of the vitrimer precursors and a reactive interface compatibilizer yields well‐dispersed vitrimer phases with fractions up to 75 wt.% in the polypropylene phase. These vitrimer blends can be easily reprocessed by multiple shredding‐injection cycles and processed in high‐shear conditions through capillary rheometry. Rheological analyses reveal that a percolating dynamic network is formed across the vitrimer domains. It breaks apart during high shear reprocessing of the material and dynamically reforms after thermal annealing of the blends. It therefore ideally combines the mechanical and high‐throughput (re)processing properties of the thermoplastic matrix minor phase with the chemical, thermomechanical, and dynamic properties of the vitrimer major phase. This work illustrates the decoupling of processing at high shear rates enabled by the polypropylene processing aid from the kinetics of dynamic exchanges of the vitrimer phase and thermomechanical properties at the service temperature of the blends.

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Next‐Generation Vitrimers Design through Theoretical Understanding and Computational Simulations

Li,

Tran,

Pan

et al. 2023

Advanced Science

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Vitrimers are an innovative class of polymers that boast a remarkable fusion of mechanical and dynamic features, complemented by the added benefit of end‐of‐life recyclability. This extraordinary blend of properties makes them highly attractive for a variety of applications, such as the automotive sector, soft robotics, and the aerospace industry. At their core, vitrimer materials consist of crosslinked covalent networks that have the ability to dynamically reorganize in response to external factors, including temperature changes, pressure variations, or shifts in pH levels. In this review, the aim is to delve into the latest advancements in the theoretical understanding and computational design of vitrimers. The review begins by offering an overview of the fundamental principles that underlie the behavior of these materials, encompassing their structures, dynamic behavior, and reaction mechanisms. Subsequently, recent progress in the computational design of vitrimers is explored, with a focus on the employment of molecular dynamics (MD)/Monte Carlo (MC) simulations and density functional theory (DFT) calculations. Last, the existing challenges and prospective directions for this field are critically analyzed, emphasizing the necessity for additional theoretical and computational advancements, coupled with experimental validation.

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Linear and Nonlinear Viscoelasticities of Dissociative and Associative Covalent Adaptable Networks: Discrepancies and Limits

Cited by 18 publications

References 67 publications

Linear viscoelasticity, nonlinear rheology and applications of polyethylene terephthalate vitrimers

Linear viscoelasticity, nonlinear rheology and applications of polyethylene terephthalate vitrimers

Synthesis, Recycling and High‐Throughput Reprocessing of Phase‐Separated Vitrimer‐Thermoplastic Blends

Next‐Generation Vitrimers Design through Theoretical Understanding and Computational Simulations

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