Strain-Induced Nanocavitation in Block Copolymer Thin Films for High Performance Filtration Membranes

Weller, Daniel W.; Ma, Guorong; Galuska, Luke; Song, Zhanqian; Stringer, Michael; Aracri, Sophia; Wang, Weiyu; Hong, Kunlun; Gu, Xiaodan

doi:10.1021/acsapm.1c00963

Cited by 4 publications

(2 citation statements)

References 56 publications

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“…[2][3][4][5][6] Several approaches were developed and used to create nano and/or micro-patterned porous surfaces such as non-solventinduced phase separation (NIPS), vapor-induced phase separation, stretching, 3D printing, and cold zone annealing. [7][8][9][10] However, one of the simple approaches is driven by the interaction between water vapor and a highly volatile solvent on the polymer surfaces. This method is called breath figure (BF) imprinting.…”

Section: Introductionmentioning

confidence: 99%

A versatile route for the fabrication of micro-patterned polylactic-acid (PLA)-based membranes with tailored morphology via breath figure imprinting

Akoumeh,

Noun,

Ponnamma

et al. 2024

Soft Matter

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Section: Introductionmentioning

confidence: 99%

A versatile route for the fabrication of micro-patterned polylactic-acid (PLA)-based membranes with tailored morphology via breath figure imprinting

Akoumeh,

Noun,

Ponnamma

et al. 2024

Soft Matter

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“…The phase behavior of block copolymers underlies many technological applications that rely on the morphology of block copolymers, such as lithography, water purification, gas permeation, and ion transport in batteries. − Predicting the phase behavior of block copolymers has been celebrated as a triumph of polymer field theory. − Much of the parameter space, including the molecular weight, block composition, enthalpic interaction strength, and polymer architecture, has been extensively explored. One promising direction to expand the parameter space is to replace the conventional linear chains with nonconcatenated rings. − Such an expansion is intriguing due to the distinctive conformations, − dynamics, ,− and material properties − revealed for homopolymer rings in the past two decades and also timely because of the advances in synthesizing and characterizing high-molecular-weight ring polymers. , …”

Section: Introductionmentioning

confidence: 99%

Molecular Simulations Revealing Effects of Non-concatenated Ring Topology on Phase Behavior of Symmetric Diblock Copolymers

Wijesekera,

Vigil,

2024

Macromolecules

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The distinctiveness of nonconcatenated ring polymers, as manifested in their fractal globular conformations and selfsimilar dynamics with no long-lived entanglement network, propels the idea of using ring topology to transform the phase behavior of block copolymers. With limited experimental studies of high-molecular-weight diblock ring polymers, large-scale molecular simulations of symmetric diblock copolymers are used to investigate the effects of nonconcatenated ring topology on their phase behavior. The absence of an entanglement network facilitates the phase-separation kinetics, suggesting relative ease in processing diblock ring polymers. The more compact globular conformations of ring polymers with respect to the Gaussian random-walk conformations require a higher enthalpic repulsion to drive the lamellar phase separation. Compared with the mean-field theory for the order−disorder transition in Gaussian diblock ring polymers, the simulations demonstrate the necessity for a new theory incorporating both the effects of fluctuations and the topological invariance of nonconcatenation. In the strong segregation regime, diblock ring polymers are stretched near the lamellar interface but with the globular conformational statistics preserved at larger length scales. The lamellar spacing d increases with enthalpic repulsion between the two blocks as well as the molecular weight of the diblock ring. The scaling argument for d of diblock linear polymers is modified by accounting for the globular conformations and predicts well the dependencies of d on the enthalpic repulsion and molecular weight. The lamellar interface becomes sharper as the enthalpic repulsion increases. While the theory predicts that the intrinsic interfacial width does not depend on the polymer molecular weight or topology, the apparent interfacial width w, which is broadened by the capillary wave, exhibits slight variation with the molecular weight and topology.

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Degradable block copolymer-derived nanoporous membranes and their applications

Zhai

Gao

2023

Giant

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Strain-Induced Nanocavitation in Block Copolymer Thin Films for High Performance Filtration Membranes

Cited by 4 publications

References 56 publications

A versatile route for the fabrication of micro-patterned polylactic-acid (PLA)-based membranes with tailored morphology via breath figure imprinting

A versatile route for the fabrication of micro-patterned polylactic-acid (PLA)-based membranes with tailored morphology via breath figure imprinting

Molecular Simulations Revealing Effects of Non-concatenated Ring Topology on Phase Behavior of Symmetric Diblock Copolymers

Degradable block copolymer-derived nanoporous membranes and their applications

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