Construction Archimedean tiling patterns based on soft materials from block copolymers and covalent organic frameworks

Kuo, Shiao‐Wei

doi:10.1016/j.giant.2023.100170

Cited by 11 publications

(3 citation statements)

References 138 publications

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“…11–15 The various POPs are produced by synthetic approaches that incorporate conjugated microporous polymers (CMP), covalent organic frameworks (COF), covalent triazine frameworks, and hyper-crosslinked polymers (HCP), and they are constructed using imine, azine, imide and triazine linkages. 16–20…”

Section: Introductionmentioning

confidence: 99%

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors

Chen,

Kuo

2024

Polym. Chem.

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Section: Introductionmentioning

confidence: 99%

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors

Chen,

Kuo

2024

Polym. Chem.

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“…Self-assembled structures such as typical lamella (LAM), hexagonal packing cylinder (HPC), sphere, double gyroid (DG), and even special Frank–Kasper phases of immiscible diblock copolymers (BCP) have been widely investigated during recent years because of their potential applications including soft lithography, photonic crystals, nanocomposites, and mesoporous materials. − The synthetic strategies of BCP with composition and structural variety are mainly from sequential addition of monomer through controlled living polymerization techniques or coupling reactions from the active chain ends with two different polymer chains. − It is well-known that the self-assembled structures are primarily dependent on the volume fraction, interaction parameter (χ), and degree of polymerization ( N ); however, mediating the volume fraction is complicated and time-consuming through the controlled living polymerization . As a result, blending homopolymer (A or B) into an A- b -B diblock copolymer is a relatively simpler method to mediate different self-assembled structures for varying volume fractions …”

Section: Introductionmentioning

confidence: 99%

Controllable Wet-Brush Blending of Linear Diblock Copolymers with Phenolic/DDSQ Hybrids toward Mesoporous Structure Phase Diagram

Chou,

Kuo

2024

Macromolecules

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In recent decades, the microphase separation behavior of diblock copolymers has been extensively discussed, whereby their inherent thermodynamic tendencies enable the bottom-up establishment of various self-assembled nanostructures. In this study, we employed ring-opening polymerization (ROP) to synthesize three linear poly(ethylene oxide-b-caprolactone) (PEO-b-PCL) diblock copolymers with different degrees of polymerization but similar volume fractions and utilized phenolic resin modified with double-decker silsesquioxane (PDDSQ) for controllable wet-brush blending. FTIR analyses revealed a competitive hydrogen bonding phenomenon and confirmed that increasing the chain length led to self-coiling of the segments, weakening the extent of hydrogen bonding. Through the evaporation-induced phase separation (EISA) mechanism, the crosslinking of PDDSQ, we obtained the mesoporous hybrid materials after template removal. Remarkably, through temperaturedependent SAXS, we were able to reproduce the changes in surface energy and d-spacing during the curing process of PDDSQ, demonstrating the mechanism of reaction-induced microphase separation leading to order−order phase transition. The presence of DDSQ resulted in a relatively higher χ value for the system, allowing for the formation of mesoporous structures such as lamella, hexagonal-packing cylinder, double gyroid, sphere, and even the less common hexagonal-perforated layer (HPL) structure. Additionally, the degree of polymerizations of the three diblock copolymers resulted in different α values (α = M n,h-A /M n,b-A) for the blending system, whereby increasing the polymerization degree led to a decrease in the α value under the same blending weight fraction, prompting the system to form structures with higher interfacial curvature. TEM images and SAXS patterns served as evidence of this order−order phase transition. In summary, this study manipulated the polymerization degree of diblock copolymers to control the level of wet-brush blending in the system, presenting a mesoporous structure phase diagram for different weight fractions and template chain lengths, providing new insights and the opportunity to form desired self-assembled mesoporous structures at fixed volume fractions.

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“…Various POP structures incorporating covalently linked linkages, such as boroxine, triazine, hydrazine, imide, and imine units, have been synthesized using chemical reactions like Suzuki, Sonogashira, Schiff base formation, Heck, Yamamoto, and Friedel couplings [38][39][40][41][42][43][44]. POPs can be categorized into several materials, including COFs, CMPs, PIMs, HCPs, and CTFs [45][46][47][48]. These diverse categories demonstrate the versatility and potential of POPs for various applications, highlighting their importance in the development of advanced materials for addressing environmental concerns and energy-related challenges.…”

Section: Introductionmentioning

confidence: 99%

Strategic Design and Synthesis of Ferrocene Linked Porous Organic Frameworks toward Tunable CO2 Capture and Energy Storage

Mousa

Chuang

Kuo

et al. 2023

IJMS

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This work focuses on porous organic polymers (POPs), which have gained significant global attention for their potential in energy storage and carbon dioxide (CO2) capture. The study introduces the development of two novel porous organic polymers, namely FEC-Mel and FEC-PBDT POPs, constructed using a simple method based on the ferrocene unit (FEC) combined with melamine (Mel) and 6,6′-(1,4-phenylene)bis(1,3,5-triazine-2,4-diamine) (PBDT). The synthesis involved the condensation reaction between ferrocenecarboxaldehyde monomer (FEC-CHO) and the respective aryl amines. Several analytical methods were employed to investigate the physical characteristics, chemical structure, morphology, and potential applications of these porous materials. Through thermogravimetric analysis (TGA), it was observed that both FEC-Mel and FEC-PBDT POPs exhibited exceptional thermal stability. FEC-Mel POP displayed a higher surface area and porosity, measuring 556 m2 g−1 and 1.26 cm3 g−1, respectively. These FEC-POPs possess large surface areas, making them promising materials for applications such as supercapacitor (SC) electrodes and gas adsorption. With 82 F g−1 of specific capacitance at 0.5 A g−1, the FEC-PBDT POP electrode has exceptional electrochemical characteristics. In addition, the FEC-Mel POP showed remarkable CO2 absorption capabilities, with 1.34 and 1.75 mmol g−1 (determined at 298 and 273 K; respectively). The potential of the FEC-POPs created in this work for CO2 capacity and electrical testing are highlighted by these results.

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Construction Archimedean tiling patterns based on soft materials from block copolymers and covalent organic frameworks

Cited by 11 publications

References 138 publications

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors

Controllable Wet-Brush Blending of Linear Diblock Copolymers with Phenolic/DDSQ Hybrids toward Mesoporous Structure Phase Diagram

Strategic Design and Synthesis of Ferrocene Linked Porous Organic Frameworks toward Tunable CO2 Capture and Energy Storage

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Construction Archimedean tiling patterns based on soft materials from block copolymers and covalent organic frameworks

Cited by 11 publications

References 138 publications

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO2 storage and supercapacitors

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO2 storage and supercapacitors

Controllable Wet-Brush Blending of Linear Diblock Copolymers with Phenolic/DDSQ Hybrids toward Mesoporous Structure Phase Diagram

Strategic Design and Synthesis of Ferrocene Linked Porous Organic Frameworks toward Tunable CO2 Capture and Energy Storage

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Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors

Enhanced thermal and porous properties of double-decker-shaped polyhedral silsesquioxane-bismaleimide (DDSQ-BMI) nanocomposites for high-performance CO₂ storage and supercapacitors