Relationship between Reaction Kinetics and Chain Dynamics of Vitrimers Based on Dioxaborolane Metathesis
Processability of vitrimers strongly relies on the temperature dependence of viscosity. In this study, we analyzed temperature-dependent viscoelasticity of vitrimers based on the dioxaborolane metathesis reaction. A sol-to-gel transition process and a reverse gel-to-sol process are observed in the l...
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| Published in | Macromolecules Vol. 53; no. 4; pp. 1180 - 1190 |
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| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
American Chemical Society
25.02.2020
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| Abstract | Processability of vitrimers strongly relies on the temperature dependence of viscosity. In this study, we analyzed temperature-dependent viscoelasticity of vitrimers based on the dioxaborolane metathesis reaction. A sol-to-gel transition process and a reverse gel-to-sol process are observed in the linear viscoelasticity with increasing content of the cross-linker. The latter gel-to-sol process is owing to a reverse reaction between a two-site interchain cross-linking point with an excess cross-linker, forming two noncross-linking sites. For samples above the gel point, the increasing temperature leads to a weaker acceleration of the decross-linking process than the Rouse-type relaxation, and accordingly, broadening of the plateau region. This trend is easily visualized in samples slightly above the gel point for which the stress relaxation arising from the Rouse-type relaxation and the decross-linking process are not well separated over time. This temperature-dependent behavior reflects a case that the lifetime of the dynamic covalent bond is significantly larger than the Rouse time of the network strands. As a result, the stress borne by a strand relaxes immediately upon decrosslinking, and thus, the low activation energy of the dioxaborolane metathesis reaction governs the strand relaxation. |
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| AbstractList | Processability of vitrimers strongly relies on the temperature dependence of viscosity. In this study, we analyzed temperature-dependent viscoelasticity of vitrimers based on the dioxaborolane metathesis reaction. A sol-to-gel transition process and a reverse gel-to-sol process are observed in the linear viscoelasticity with increasing content of the cross-linker. The latter gel-to-sol process is owing to a reverse reaction between a two-site interchain cross-linking point with an excess cross-linker, forming two noncross-linking sites. For samples above the gel point, the increasing temperature leads to a weaker acceleration of the decross-linking process than the Rouse-type relaxation, and accordingly, broadening of the plateau region. This trend is easily visualized in samples slightly above the gel point for which the stress relaxation arising from the Rouse-type relaxation and the decross-linking process are not well separated over time. This temperature-dependent behavior reflects a case that the lifetime of the dynamic covalent bond is significantly larger than the Rouse time of the network strands. As a result, the stress borne by a strand relaxes immediately upon decrosslinking, and thus, the low activation energy of the dioxaborolane metathesis reaction governs the strand relaxation. |
| Author | Yang, Huanhuan Huang, Shaoyong Chen, Quan Wu, Shilong |
| AuthorAffiliation | Changchun Institute of Applied Chemistry Chinese Academy of Sciences, Changchun Institute of Applied Chemistry, State Key Lab of Polymer Physics and Chemistry |
| AuthorAffiliation_xml | – name: Changchun Institute of Applied Chemistry – name: Chinese Academy of Sciences, Changchun Institute of Applied Chemistry, State Key Lab of Polymer Physics and Chemistry |
| Author_xml | – sequence: 1 givenname: Shilong surname: Wu fullname: Wu, Shilong – sequence: 2 givenname: Huanhuan surname: Yang fullname: Yang, Huanhuan – sequence: 3 givenname: Shaoyong orcidid: 0000-0001-8210-8928 surname: Huang fullname: Huang, Shaoyong – sequence: 4 givenname: Quan orcidid: 0000-0002-7771-5050 surname: Chen fullname: Chen, Quan email: qchen@ciac.ac.cn |
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| SubjectTerms | activation energy chemical bonding crosslinking gels reaction kinetics stress relaxation temperature viscoelasticity viscosity |
| Title | Relationship between Reaction Kinetics and Chain Dynamics of Vitrimers Based on Dioxaborolane Metathesis |
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