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Main Authors: Chen, Jing, Zhu, Aiping, Wei, Dan, Shi, An-Chang, Jiang, Kai
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.26927
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author Chen, Jing
Zhu, Aiping
Wei, Dan
Shi, An-Chang
Jiang, Kai
author_facet Chen, Jing
Zhu, Aiping
Wei, Dan
Shi, An-Chang
Jiang, Kai
contents Grain boundaries (GBs) are ubiquitous defects in crystalline materials. However, they remain less explored in block copolymer ordered phases. Here, we develop a self-consistent field theory framework to investigate GB structure and energetics in double-gyroid (DG) diblock copolymer networks. The GB energy landscape is obtained as a function of GB orientation, which reveals multiple local minima representing distinct network-switching GBs. Remarkably, the global minimum is a previously unidentified asymmetric-tilt network-switching GB (ATNS), exhibiting a lower energy than the experimentally observed $(422)$ twin boundary (TB). Comparative analyses of representative low- (ATNS, $(422)$ TB) and high-energy twist ($(0\bar{1}\bar{1})$, $(100)$ TNSs) GBs reveal that, unlike enthalpy-dominated hard matter, GB stability in DG networks is predominantly entropy-driven. Twist-type GBs generate new nodes and disrupt nodal coplanarity, causing chain packing frustration and large entropy penalties. Conversely, the ATNS preserves favorable network connectivity and minimizes conformational constraints on polymer chains, making it the energetically preferred GB.
format Preprint
id arxiv_https___arxiv_org_abs_2605_26927
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Structure and energetics of grain boundaries in self-assembled double-gyroid block copolymer networks
Chen, Jing
Zhu, Aiping
Wei, Dan
Shi, An-Chang
Jiang, Kai
Soft Condensed Matter
Grain boundaries (GBs) are ubiquitous defects in crystalline materials. However, they remain less explored in block copolymer ordered phases. Here, we develop a self-consistent field theory framework to investigate GB structure and energetics in double-gyroid (DG) diblock copolymer networks. The GB energy landscape is obtained as a function of GB orientation, which reveals multiple local minima representing distinct network-switching GBs. Remarkably, the global minimum is a previously unidentified asymmetric-tilt network-switching GB (ATNS), exhibiting a lower energy than the experimentally observed $(422)$ twin boundary (TB). Comparative analyses of representative low- (ATNS, $(422)$ TB) and high-energy twist ($(0\bar{1}\bar{1})$, $(100)$ TNSs) GBs reveal that, unlike enthalpy-dominated hard matter, GB stability in DG networks is predominantly entropy-driven. Twist-type GBs generate new nodes and disrupt nodal coplanarity, causing chain packing frustration and large entropy penalties. Conversely, the ATNS preserves favorable network connectivity and minimizes conformational constraints on polymer chains, making it the energetically preferred GB.
title Structure and energetics of grain boundaries in self-assembled double-gyroid block copolymer networks
topic Soft Condensed Matter
url https://arxiv.org/abs/2605.26927