<scp>Composition‐dependent</scp>glass transition temperature in mixtures: Evaluation of configurational entropy models*

Lopez, Evelyn; Koh, Yung P.; Zapata‐Hincapie, John A.; Simon, Sindee L.

doi:10.1002/pen.26018

Cited by 4 publications

(5 citation statements)

References 69 publications

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“…It is just this competing effect between cross-link density and cohesive interaction “strength” on fragility that complicates the prediction of the segmental relaxation of thermoset materials and, thus, their material design . In addition, the fragility is also found to be modified by the compositions without changing the cohesive energy or cross-link density of polymers, where the addition of oligomers, , plasticizers, and anti-plasticizers ,, would decrease the fragility compared to the pure polymer melts. For example, the work of Dalle-Ferrier et al found that the addition of an oligomer could modify the fragility of polystyrene/oligomer blends.…”

Section: Resultsmentioning

confidence: 99%

Competing Effects of Cohesive Energy and Cross-Link Density on the Segmental Dynamics and Mechanical Properties of Cross-Linked Polymers

et al. 2022

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To develop structure–property relationships for cross-linked thermosetting polymers, it is crucial to better understand key factors that control their segmental dynamics and macroscopic properties. Here, we employ a coarse-grained (CG) polymer model to systematically explore the combined effect of varying the cohesive energy (ε) and cross-link density (c) on the segmental relaxation time and mechanical properties for a model cross-linked glass-forming thermoset material. We find that increasing c increases both the glass transition temperature T g and fragility of glass formation, while the fragility decreases with an increase in ε. These competing effects of ε and c on fragility are practically important since fragility determines the overall temperature width of the glass formation over which the non-Arrhenius temperature dependence is observed. Our simulation results show that the basic mechanical properties (i.e., bulk and shear moduli) of cross-linked thermosets are mainly influenced by ε. More interestingly, the macroscopic mechanical properties are found to be strongly correlated with the Debye–Waller parameter ⟨u 2⟩, a measure of material “stiffness” at a molecular level. In particular, the distribution of local molecular stiffness, 1/⟨u 2⟩, exhibits a nearly universal Gaussian distribution at a fixed reduced temperature T/T g. Our work reveals the key and competitive roles of cohesive energy and cross-link density in controlling the segmental dynamics, large scale, and local mechanical properties of cross-linked thermosets, providing an understanding that should be useful in the molecular design of these materials.

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Section: Resultsmentioning

confidence: 99%

Competing Effects of Cohesive Energy and Cross-Link Density on the Segmental Dynamics and Mechanical Properties of Cross-Linked Polymers

et al. 2022

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“…While there is evidence of a clear answer for the first question and there is significant progress concerning the second, for the last topic, many unanswered questions remain. In another article by Lopez et al, [ 2 ] mixing rules for the glass transition temperatures are scrutinized. As well as having an immediate relevance for the estimation of T g of blends, this study allows an insight on the origin of T g from the theoretical concept of configurational entropy.…”

Section: Figurementioning

confidence: 99%

Editorial: In honor of Gregory B. McKenna's contributions to the field of polymer science

Zorn

2022

Polymer Engineering & Sci

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“…Studies have used the Kwei equation to fit and explain the T g -composition relation of hydrogen bonding polymer mixtures. 55 − 57 In addition, the Kwei equation can also provide a good fit to the measured T g of binary mixtures of molecular liquids. 57 − 59 For example, the quadratic term of the Kwei equation used to fit the T g of binary blends of trehalose and choline dihydrogen phosphate was attributed to hydrogen bonding.…”

Section: Introductionmentioning

confidence: 96%

“… 55 − 57 In addition, the Kwei equation can also provide a good fit to the measured T g of binary mixtures of molecular liquids. 57 − 59 For example, the quadratic term of the Kwei equation used to fit the T g of binary blends of trehalose and choline dihydrogen phosphate was attributed to hydrogen bonding. 58 The Kwei equation has the potential to predict the T g of SOA mixtures when the Gordon–Taylor equation fails, particularly in the cases of substantial intermolecular interactions.…”

Section: Introductionmentioning

confidence: 96%

“…Kwei attributed the quadratic term q normalK normalw normale normali x normala ( 1 − x a ) to the effect of hydrogen bonding forming cross linkages in the polymer mixtures. Studies have used the Kwei equation to fit and explain the T g -composition relation of hydrogen bonding polymer mixtures. − In addition, the Kwei equation can also provide a good fit to the measured T g of binary mixtures of molecular liquids. − For example, the quadratic term of the Kwei equation used to fit the T g of binary blends of trehalose and choline dihydrogen phosphate was attributed to hydrogen bonding . The Kwei equation has the potential to predict the T g of SOA mixtures when the Gordon–Taylor equation fails, particularly in the cases of substantial intermolecular interactions.…”

Section: Introductionmentioning

confidence: 99%

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Glass Transition Temperatures of Organic Mixtures from Isoprene Epoxydiol-Derived Secondary Organic Aerosol

et al. 2023

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The phase states and glass transition temperatures (T g ) of secondary organic aerosol (SOA) particles are important to resolve for understanding the formation, growth, and fate of SOA as well as their cloud formation properties. Currently, there is a limited understanding of how T g changes with the composition of organic and inorganic components of atmospheric aerosol. Using broadband dielectric spectroscopy, we measured the T g of organic mixtures containing isoprene epoxydiol (IEPOX)-derived SOA components, including 2-methyltetrols (2-MT), 2-methyltetrolsulfate (2-MTS), and 3-methyltetrol-sulfate (3-MTS). The results demonstrate that the T g of mixtures depends on their composition. The Kwei equation, a modified Gordon−Taylor equation with an added quadratic term and a fitting parameter representing strong intermolecular interactions, provides a good fit for the T g -composition relationship of complex mixtures. By combining Raman spectroscopy with geometry optimization simulations obtained using density functional theory, we demonstrate that the non-linear deviation of T g as a function of composition may be caused by changes in the extent of hydrogen bonding in the mixture.

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Composition‐dependentglass transition temperature in mixtures: Evaluation of configurational entropy models*

Cited by 4 publications

References 69 publications

Competing Effects of Cohesive Energy and Cross-Link Density on the Segmental Dynamics and Mechanical Properties of Cross-Linked Polymers

Competing Effects of Cohesive Energy and Cross-Link Density on the Segmental Dynamics and Mechanical Properties of Cross-Linked Polymers

Editorial: In honor of Gregory B. McKenna's contributions to the field of polymer science

Glass Transition Temperatures of Organic Mixtures from Isoprene Epoxydiol-Derived Secondary Organic Aerosol

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