Effect of sequence dispersity on morphology of tapered diblock copolymers from molecular dynamics simulations

Levine, W. Garrett; Seo, Yongsok; Brown, Jonathan R.; Hall, Lisa M.

doi:10.1063/1.4972141

Cited by 24 publications

(24 citation statements)

References 47 publications

(82 reference statements)

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“…The exploration of sequence space has, for the most part, been approached from its limiting cases; variations on block copolymers (the large-limit) and alternating or random copolymers (the small-limit) have long been considered in the pursuit of new material properties. For the former, gradient and tapered copolymers represent sequence definition at the large-limit, [52][53][54][55][56][57][58][59][60][61][62] and are synthesized by statistical copolymer-ization of two or more monomers at a proportion that varies at a defined extent over a defined portion of the chain. 58,63 These perturbations from standard block copolymers have been extensively studied as a way to modify phase diagram boundaries in a controlled fashion, as the large-sequence resolution becomes commensurate with the associated microphaseseparated length scales.…”

Section: Does Sequence Matter?mentioning

confidence: 99%

100th Anniversary of Macromolecular Science Viewpoint: Opportunities in the Physics of Sequence-Defined Polymers

2020

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Polymer science has been driven by ever-increasing molecular complexity, as polymer synthesis expands an alreadyvast palette of chemical and architectural parameter space. Copolymers represent a key example, where simple homopolymers have given rise to random, alternating, gradient, and block copolymers. Polymer physics has provided the insight needed to explore this monomer sequence parameter space. The future of polymer science, however, must contend with further increases in monomer precision, as this class of macromolecules moves ever closer to the sequence-monodisperse polymers that are the workhorses of biology. The advent of sequence-defined polymers gives rise to opportunities for material design, with increasing levels of chemical information being incorporated into long-chain molecules; however, this also raises questions that polymer physics must address. What properties uniquely emerge from sequence-definition? Is this circumstance dependent? How do we define and think about sequence dispersity? How do we think about a hierarchy of sequence effects? Are more sophisticated characterization methods, as well as theoretical and computational tools needed to understand this class of macromolecules? The answers to these questions touch on many difficult scientific challenges, setting the stage for a rich future for sequence-defined polymers in polymer physics.

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Section: Does Sequence Matter?mentioning

confidence: 99%

100th Anniversary of Macromolecular Science Viewpoint: Opportunities in the Physics of Sequence-Defined Polymers

2020

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“…In particular, the continuum of behaviors between block and random co-polymers has been probed in terms of equilibrium properties (e.g., phase behavior 18 , 19 , compatibilization 20 ) using coarse-grained modeling and theory. These works consider portions of a vast sequence parameter space, using monomer sequence correlations (i.e., blockiness) 18 , 19 , sophisticated machine learning methods 20 , or sequence gradients 21 . These situations focus on short-range dispersive interactions, where monomers interact primarily with their immediate neighbors.…”

Section: Introductionmentioning

confidence: 99%

Sequence and entropy-based control of complex coacervates

et al. 2017

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Biomacromolecules rely on the precise placement of monomers to encode information for structure, function, and physiology. Efforts to emulate this complexity via the synthetic control of chemical sequence in polymers are finding success; however, there is little understanding of how to translate monomer sequence to physical material properties. Here we establish design rules for implementing this sequence-control in materials known as complex coacervates. These materials are formed by the associative phase separation of oppositely charged polyelectrolytes into polyelectrolyte dense (coacervate) and polyelectrolyte dilute (supernatant) phases. We demonstrate that patterns of charges can profoundly affect the charge–charge associations that drive this process. Furthermore, we establish the physical origin of this pattern-dependent interaction: there is a nuanced combination of structural changes in the dense coacervate phase and a 1D confinement of counterions due to patterns along polymers in the supernatant phase.

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“…These encouraging results suggest that developing architectural complexity beyond a simple diblock could have significant impact on blend performance and is still an active area of investigation. 32 , 33 …”

Section: Introductionmentioning

confidence: 99%

Linear, Graft, and Beyond: Multiblock Copolymers as Next-Generation Compatibilizers

Self

Zervoudakis

Peng

et al. 2022

JACS Au

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Properly addressing the global issue of unsustainable plastic waste generation and accumulation will require a confluence of technological breakthroughs on various fronts. Mechanical recycling of plastic waste into polymer blends is one method expected to contribute to a solution. Due to phase separation of individual components, mechanical recycling of mixed polymer waste streams generally results in an unsuitable material with substantially reduced performance. However, when an appropriately designed compatibilizer is used, the recycled blend can have competitive properties to virgin materials. In its current state, polymer blend compatibilization is usually not cost-effective compared to traditional waste management, but further technical development and optimization will be essential for driving future cost competitiveness. Historically, effective compatibilizers have been diblock copolymers or in situ generated graft copolymers, but recent progress shows there is great potential for multiblock copolymer compatibilizers. In this perspective, we lay out recent advances in synthesis and understanding for two types of multiblock copolymers currently being developed as blend compatibilizers: linear and graft. Importantly, studies of appropriately designed copolymers have shown them to efficiently compatibilize model binary blends at concentrations as low as ∼0.2 wt %. These investigations pave the way for studies on more complex (ternary or higher) mixed waste streams that will require novel compatibilizer architectures. Given the progress outlined here, we believe that multiblock copolymers offer a practical and promising solution to help close the loop on plastic waste. While a complete discussion of the implementation of this technology would entail infrastructural, policy, and social developments, they are outside the scope of this perspective which instead focuses on material design considerations and the technical advancements of block copolymer compatibilizers.

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Effect of sequence dispersity on morphology of tapered diblock copolymers from molecular dynamics simulations

Cited by 24 publications

References 47 publications

100th Anniversary of Macromolecular Science Viewpoint: Opportunities in the Physics of Sequence-Defined Polymers

100th Anniversary of Macromolecular Science Viewpoint: Opportunities in the Physics of Sequence-Defined Polymers

Sequence and entropy-based control of complex coacervates

Linear, Graft, and Beyond: Multiblock Copolymers as Next-Generation Compatibilizers

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