Theoretically predicting the solubility of polydisperse polymers using Flory-Huggins theory

Stijn H.M. van Leuken; Rolf A.T.M. van Benthem; Remco Tuinier; Mark Vis

doi:10.1088/2515-7639/ad08d1

Theoretically predicting the solubility of polydisperse polymers using Flory-Huggins theory

Stijn H.M. van Leuken, Rolf A.T.M. van Benthem, Remco Tuinier, Mark Vis (Corresponding author)

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Abstract

Polydispersity affects physical properties of polymeric materials, such as solubility in solvents. Most biobased, synthetic, recycled, mixed, copolymerized, and self-assembled polymers vary in size and chemical structure. Using solvent fractionation, this variety in molecular features can be reduced and a selection of the sizes and molecular features of the polymers can be made. The significant chemical and physical dispersity of these polymers, however, complicates theoretical solubility predictions. A theoretical description of the fractionation process can guide experiments and material design. During solvent fractioning of polymers, a part of the polydisperse distribution of the polymers dissolves. To describe this process, this paper presents a theoretical tool using Flory-Huggins theory combined with molecular mass distributions and distributions in the number of functional groups. This paper quantifies how chemical and physical polydispersity of polymers affects their solubility. Comparison of theoretical predictions with experimental measurements of lignin in a mixture of solvents shows that multiple molecular features can be described well using a single set of parameters, giving a tool to theoretically predict the selective solubility of polymers.

Original language	English
Article number	015005
Number of pages	14
Journal	JPhys Materials
Volume	7
Issue number	1
DOIs	https://doi.org/10.1088/2515-7639/ad08d1
Publication status	Published - 1 Jan 2024

Funding

This work was performed within the framework of the public-private knowledge institute of Chemelot InSciTe, which we gratefully acknowledge for their financial support. The authors thank the members of the Laboratory of Inorganic Materials & Catalysis at Eindhoven University and Vertoro for the fruitful collaboration and their contributions to the experimental work referenced in this research. Furthermore, the authors thank the members of the Chemelot InSciTe HiperBioPol team and the members of the Laboratory of Physical Chemistry and Laboratory at Eindhoven University for the discussions, inspiration, and feedback.

Keywords

analytical approximations
chemical variation
Flory-Huggins theory
lignin
polydispersity
solution theory

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title = "Theoretically predicting the solubility of polydisperse polymers using Flory-Huggins theory",

abstract = "Polydispersity affects physical properties of polymeric materials, such as solubility in solvents. Most biobased, synthetic, recycled, mixed, copolymerized, and self-assembled polymers vary in size and chemical structure. Using solvent fractionation, this variety in molecular features can be reduced and a selection of the sizes and molecular features of the polymers can be made. The significant chemical and physical dispersity of these polymers, however, complicates theoretical solubility predictions. A theoretical description of the fractionation process can guide experiments and material design. During solvent fractioning of polymers, a part of the polydisperse distribution of the polymers dissolves. To describe this process, this paper presents a theoretical tool using Flory-Huggins theory combined with molecular mass distributions and distributions in the number of functional groups. This paper quantifies how chemical and physical polydispersity of polymers affects their solubility. Comparison of theoretical predictions with experimental measurements of lignin in a mixture of solvents shows that multiple molecular features can be described well using a single set of parameters, giving a tool to theoretically predict the selective solubility of polymers.",

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Theoretically predicting the solubility of polydisperse polymers using Flory-Huggins theory

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