Tetragonal gyroid structure from symmetry manipulation: A brand-new member of the gyroid surface family

Gyroid (G) surfaces, the most famous naturally occurring triply periodic hyperbolic surfaces, are well known for their amazing properties closely associated with their intriguing symmetries. Although mathematicians and physicists are devoted to exploring new G surface family members, it remains a my...

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Published inChem Vol. 10; no. 5; pp. 1406 - 1424
Main Authors Wang, Shuqi, Chen, Hao, Zhong, Tianyu, Deng, Quanzheng, Yang, Shaobo, Cao, Yuanyuan, Li, Yongsheng, Han, Lu
Format Journal Article
LanguageEnglish
Published Elsevier Inc 09.05.2024
Subjects
3D reconstruction
block copolymer
electron crystallography
electron microscopy
gyroid
mesostructure
self-assembly
surfactant
symmetry breaking
triply periodic minimal surface
block copolymer
self-assembly
symmetry breaking
3D reconstruction
triply periodic minimal surface
electron microscopy
gyroid
mesostructure
surfactant
electron crystallography
SDG9: Industry, innovation, and infrastructure
Online AccessGet full text
ISSN2451-9294
DOI10.1016/j.chempr.2023.12.017

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Abstract Gyroid (G) surfaces, the most famous naturally occurring triply periodic hyperbolic surfaces, are well known for their amazing properties closely associated with their intriguing symmetries. Although mathematicians and physicists are devoted to exploring new G surface family members, it remains a mystery whether any novel symmetrical G substructure can be experimentally validated beyond its well-known cubic-symmetrical systems. Herein, we report a tetragonal G substructure (shifted tG) obtained from a cooperative binary self-assembly system consisting of polystyrene-b-poly(acrylic acid) and cetyltrimethylammonium bromide. Shifted tG features periodic distributions of uneven matrix thicknesses with local concave free energies, exhibits an extraordinarily shifted double-gyroidal network with a low-symmetry space group of I41/a (no. 88), and possesses shifting-degree-dependent photonic band gaps that are never present in its unshifted cubic-symmetrical counterparts. The emergence of new G structures demonstrates a new frontier in the minimal surface subject, crucial for its exploration and innovation. [Display omitted] •Symmetry manipulation of gyroid surfaces is realized through binary assembly system•The shifted double-gyroidal networks possess a brand-new tetragonal structure•The structure features periodic wall thickness due to local concave free energy•The tetragonal gyroid exhibits intriguing optical properties due to symmetry breaking Triply periodic minimal surfaces (TPMSs), the unique three-dimensional geometry characterized by infinite and non-self-intersecting periodic networks with complex symmetries, are diamonds shining in mathematics, physics, and soft matter science. Gyroid surfaces, the most appealing and complicated TPMSs, possess extraordinary properties highly associated with their symmetrical features and have inspired various terrific man-made artifacts. Manipulating the symmetry of gyroid surfaces is crucial to exploring the beauty of their geometry, but all of their known stable structures are restricted to cubic space groups. In this study, by manipulating symmetry in a designed binary self-assembly system to break the principles of thermodynamic restriction of the polymer phase separation, we obtained a brand-new tetragonal gyroid with intriguing optical properties, which opens up new avenues for generating novel materials with exceptional structures and understanding the minimal surface families. A new gyroid family member, the tetragonal gyroid surface (shifted tG), was designed on the basis of a binary self-assembly system containing diblock copolymer PS-b-PAA as the main building block and the small surfactant cetrimonium bromide (CTAB) as the structure manipulator. Featuring shifted double-gyroidal networks, shifted tG belongs to a tetragonal symmetry with the low-symmetry space group I41/a and shows a widened photonic band gap along with shifting degrees, initiating a new gyroid symmetric system.
AbstractList Gyroid (G) surfaces, the most famous naturally occurring triply periodic hyperbolic surfaces, are well known for their amazing properties closely associated with their intriguing symmetries. Although mathematicians and physicists are devoted to exploring new G surface family members, it remains a mystery whether any novel symmetrical G substructure can be experimentally validated beyond its well-known cubic-symmetrical systems. Herein, we report a tetragonal G substructure (shifted tG) obtained from a cooperative binary self-assembly system consisting of polystyrene-b-poly(acrylic acid) and cetyltrimethylammonium bromide. Shifted tG features periodic distributions of uneven matrix thicknesses with local concave free energies, exhibits an extraordinarily shifted double-gyroidal network with a low-symmetry space group of I41/a (no. 88), and possesses shifting-degree-dependent photonic band gaps that are never present in its unshifted cubic-symmetrical counterparts. The emergence of new G structures demonstrates a new frontier in the minimal surface subject, crucial for its exploration and innovation. [Display omitted] •Symmetry manipulation of gyroid surfaces is realized through binary assembly system•The shifted double-gyroidal networks possess a brand-new tetragonal structure•The structure features periodic wall thickness due to local concave free energy•The tetragonal gyroid exhibits intriguing optical properties due to symmetry breaking Triply periodic minimal surfaces (TPMSs), the unique three-dimensional geometry characterized by infinite and non-self-intersecting periodic networks with complex symmetries, are diamonds shining in mathematics, physics, and soft matter science. Gyroid surfaces, the most appealing and complicated TPMSs, possess extraordinary properties highly associated with their symmetrical features and have inspired various terrific man-made artifacts. Manipulating the symmetry of gyroid surfaces is crucial to exploring the beauty of their geometry, but all of their known stable structures are restricted to cubic space groups. In this study, by manipulating symmetry in a designed binary self-assembly system to break the principles of thermodynamic restriction of the polymer phase separation, we obtained a brand-new tetragonal gyroid with intriguing optical properties, which opens up new avenues for generating novel materials with exceptional structures and understanding the minimal surface families. A new gyroid family member, the tetragonal gyroid surface (shifted tG), was designed on the basis of a binary self-assembly system containing diblock copolymer PS-b-PAA as the main building block and the small surfactant cetrimonium bromide (CTAB) as the structure manipulator. Featuring shifted double-gyroidal networks, shifted tG belongs to a tetragonal symmetry with the low-symmetry space group I41/a and shows a widened photonic band gap along with shifting degrees, initiating a new gyroid symmetric system.
Author Yang, Shaobo
Deng, Quanzheng
Cao, Yuanyuan
Li, Yongsheng
Han, Lu
Wang, Shuqi
Chen, Hao
Zhong, Tianyu
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  email: luhan@tongji.edu.cn
  organization: School of Chemical Science and Engineering, Tongji University, Shanghai 200092, China
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Keywords block copolymer
self-assembly
symmetry breaking
3D reconstruction
triply periodic minimal surface
electron microscopy
gyroid
mesostructure
surfactant
electron crystallography
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SSID ssj0001821750
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Snippet Gyroid (G) surfaces, the most famous naturally occurring triply periodic hyperbolic surfaces, are well known for their amazing properties closely associated...
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elsevier
SourceType Enrichment Source
Index Database
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StartPage 1406
SubjectTerms 3D reconstruction
block copolymer
electron crystallography
electron microscopy
gyroid
mesostructure
self-assembly
surfactant
symmetry breaking
triply periodic minimal surface
Title Tetragonal gyroid structure from symmetry manipulation: A brand-new member of the gyroid surface family
URI https://dx.doi.org/10.1016/j.chempr.2023.12.017
Volume 10
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