A Molecular Dynamics Study on the Miscibility and Morphology of Polyester Blends used in Coil Coatings

Computational simulations can be used to save on both time and costs, complementing experimental work and providing further guidance. Immiscible polymer blends induce phase segregation, and in some cases can produce useful multicoat systems. This works uses a range of Molecular Dynamics Simulations methods, including an extended Flory Huggins Interaction Parameter χ to initially probe the interactions and miscibility between ester monomers commonly used in coil coatings. This work indicates that blends with similar backbone structures or “like with like” show increased miscibility and those with different structures lead to a large χ value and immiscibility. Further to this, polyester blends with different backbone structures have then been coarse grained with MARTINI beads and simulations of 10 µs have been run to identify the morphology of the blends at the mesoscopic level. Finally, the melamine crosslinker commonly used in polyester formulations has previously been shown to form agglomerates at higher melamine content, these agglomerates have been shown in atomistic simulations.

A Molecular Dynamics Study on the Miscibility and Morphology of Polyester Blends used in Coil Coatings

Computational simulations can be used to save on both time and costs, complementing experimental work and providing further guidance. Immiscible polymer blends induce phase segregation, and in some cases can produce useful multicoat systems. This works uses a range of Molecular Dynamics Simulations methods, including an extended Flory Huggins Interaction Parameter χ to initially probe the interactions and miscibility between ester monomers commonly used in coil coatings. This work indicates that blends with similar backbone structures or “like with like” show increased miscibility and those with different structures lead to a large χ value and immiscibility. Further to this, polyester blends with different backbone structures have then been coarse grained with MARTINI beads and simulations of 10 µs have been run to identify the morphology of the blends at the mesoscopic level. Finally, the melamine crosslinker commonly used in polyester formulations has previously been shown to form agglomerates at higher melamine content, these agglomerates have been shown in atomistic simulations.

A Molecular Dynamics Study on the Miscibility and Morphology of Polyester Blends used in Coil CoatingsA Molecular Dynamics Study on the Miscibility and Morphology of Polyester Blends used in Coil Coatings

Computational simulations can be used to save on both time and costs, complementing experimental work and providing further guidance. Immiscible polymer blends induce phase segregation, and in some cases can produce useful multicoat systems. This works uses a range of Molecular Dynamics Simulations methods, including an extended Flory Huggins Interaction Parameter χ to initially probe the interactions and miscibility between ester monomers commonly used in coil coatings. This work indicates that blends with similar backbone structures or “like with like” show increased miscibility and those with different structures lead to a large χ value and immiscibility. Further to this, polyester blends with different backbone structures have then been coarse grained with MARTINI beads and simulations of 10 µs have been run to identify the morphology of the blends at the mesoscopic level. Finally, the melamine crosslinker commonly used in polyester formulations has previously been shown to form agglomerates at higher melamine content, these agglomerates have been shown in atomistic simulations.

Helical mesoscopic crystals based on an achiral charge-transfer complex with controllable untwisting/breaking

The donor and acceptor molecules self-assemble into a helical morphology under the effect of polar solvent. By controlling the temperature to induce phase transition, the co-crystal undergoes predictable crystal breaking or untwisting.

Nuclear body phase separation drives telomere clustering in ALT cancer cells

A chemical dimerization approach is developed to induce phase separation of APB nuclear bodies involved in telomere elongation in alternative lengthening of telomeres (ALT) cancer cells. It reveals that ALT telomere-associated promyelocytic leukemia nuclear body (APB) fusion leads to telomere clustering to provide templates for homology-directed telomere synthesis, an ability that is decoupled from APB function in enriching DNA repair factors.

First principles study on 2H–1T′ transition in MoS2 with copper

Adsorption of Cu can induce phase transition of MoS2 from 2H to metallic 1T′.