Construction of Covalent Organic Frameworks Bearing Three Different Kinds of Pores through the Heterostructural Mixed Linker Strategy

Pang, Zhong-Fu; Xu, Shunqi; Zhou, Tian; Liang, Rong‐Ran; Zhan, Tian‐Guang; Zhao, Xin

doi:10.1021/jacs.6b01244

Cited by 267 publications

(154 citation statements)

References 34 publications

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“…The validity of this approach has recentlyb een demonstrated by the successful construction of severalh eteropore COFs by combination of linearl inkersw ith D 2h -symmetric tetraphenylethenebased monomers (Scheme 1b) [34][35][36][37] or C 2v -symmetric building blocks (Scheme 1c). The validity of this approach has recentlyb een demonstrated by the successful construction of severalh eteropore COFs by combination of linearl inkersw ith D 2h -symmetric tetraphenylethenebased monomers (Scheme 1b) [34][35][36][37] or C 2v -symmetric building blocks (Scheme 1c).…”

Section: Introductionmentioning

confidence: 99%

“…The validity of this approach has recentlyb een demonstrated by the successful construction of severalh eteropore COFs by combination of linearl inkersw ith D 2h -symmetric tetraphenylethenebased monomers (Scheme 1b) [34][35][36][37] or C 2v -symmetric building blocks (Scheme 1c). The previous studies have indeed revealed that, although the combination of tetraphenylethene-based D 2h -symmetrical monomers and linear linkers resulted in dual-pore COFs, [34][35][36][37] the formation of single-pore COFs was also observed when building blocks having the same symmetry but different structures were used. However,e ach of these two strategies theoretically can lead to two types of COFs with different topological structures.…”

Section: Introductionmentioning

confidence: 99%

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Precision Construction of 2D Heteropore Covalent Organic Frameworks by a Multiple‐Linking‐Site Strategy

Qian

Jiang

et al. 2016

Chemistry A European J

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Integrating different kinds of pores into one covalent organic framework (COF) endows it with hierarchical porosity and thus generates a member of a new class of COFs, namely, heteropore COFs. Whereas the construction of COFs with homoporosity has already been well developed, the fabrication of heteropore COFs still faces great challenges. Although two strategies have recently been developed to successfully construct heteropore COFs from noncyclic building blocks, they suffer from the generation of COF isomers, which decreases the predictability and controllability of construction of this type of reticular materials. In this work, this drawback was overcome by a multiple-linking-site strategy that offers precision construction of heteropore COFs containing two kinds of hexagonal pores with different shapes and sizes. This strategy was developed by designing a building block in which double linking sites are introduced at each branch of a C -symmetric skeleton, the most widely used scaffold to construct COFs with homogeneous porosity. This design provides a general way to precisely construct heteropore COFs without formation of isomers. Furthermore, the as-prepared heteropore COFs have hollow-spherical morphology, which has rarely been observed for COFs, and an uncommon staggered AB stacking was observed for the layers of the 2D heteropore COFs.

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Section: Introductionmentioning

confidence: 99%

“…The validity of this approach has recentlyb een demonstrated by the successful construction of severalh eteropore COFs by combination of linearl inkersw ith D 2h -symmetric tetraphenylethenebased monomers (Scheme 1b) [34][35][36][37] or C 2v -symmetric building blocks (Scheme 1c). The previous studies have indeed revealed that, although the combination of tetraphenylethene-based D 2h -symmetrical monomers and linear linkers resulted in dual-pore COFs, [34][35][36][37] the formation of single-pore COFs was also observed when building blocks having the same symmetry but different structures were used. However,e ach of these two strategies theoretically can lead to two types of COFs with different topological structures.…”

Section: Introductionmentioning

confidence: 99%

Precision Construction of 2D Heteropore Covalent Organic Frameworks by a Multiple‐Linking‐Site Strategy

Qian

Jiang

et al. 2016

Chemistry A European J

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“…Der Einbau von symmetriereduzierten Eckbausteinen [164,165] oder Vorstufen mit unterschiedlichen Bisswinkeln [166][167][168] kann zu geordneten Stukturen mit zwei oder drei unterschiedlichen Poren führen. Auch soziale Selbstsortierung von Mehr-Komponenten-Mischungen führte zu 2D-COFs mit einem dreifachen Porensystem [167] oder anisotropen Strukturen mit ungewçhnlichen Poren von niedriger Symmetrie. [169] Mehrere unterschiedliche Porenkanäle konnten auch durch den Einbau von formgetreuen Makrozyklen als Bausteine erreicht werden, [170,171] wobei die erste Pore intrinsisch durch den Makrozyklus und die zweite durch die Polymerisation erzeugt wird.…”

Section: Selbstsortierung Von Mehr-komponenten-mischungenunclassified

“…[163] Derartige 2D-COFs kçnnten beispiellose Eigenschaften fürG asspeicherung und Gasteinschluss aufweisen. Der Einbau von symmetriereduzierten Eckbausteinen [164,165] oder Vorstufen mit unterschiedlichen Bisswinkeln [166][167][168] kann zu geordneten Stukturen mit zwei oder drei unterschiedlichen Poren führen. Die Einführung von sterisch anspruchsvollen Substitutenten kann jedoch zu einem Vermeiden von kleineren Poren und damit zu einem Wechsel der COF-Topologie führen.…”

Section: Selbstsortierung Von Mehr-komponenten-mischungenunclassified

Kovalente organische Netzwerke und Käfigverbindungen: Design und Anwendungen von polymeren und diskreten organischen Gerüsten

Beuerle

Gole

2018

Angewandte Chemie

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Poröse organische Materialien sind eine aufstrebende Klasse funktionaler Nanostrukturen mit beispiellosen Eigenschaften. Die dynamisch‐kovalente Organisation kleiner organischer Bausteine unter thermodynamischer Kontrolle wird dabei für die verblüffend einfache Bildung komplexer Architekturen in Eintopfreaktionen genutzt. In diesem Aufsatz werden die grundlegenden Designprinzipien analysiert, die zur Bildung von entweder kovalenten organischen Netzwerken als kristalline poröse Polymere oder kovalenten organischen Käfigverbindungen als formgetreue molekulare Objekte führen. Konventionelle Synthesevorschriften und Analysemethoden werden neben ausgefeilteren Strategien, wie postsynthetische Modifizierungen oder Selbstsortierung, diskutiert. Gegebenenfalls werden die entsprechenden Eigenschaften und Besonderheiten von polymeren Netzwerken und diskreten organischen Käfigen verglichen. Darüber hinaus wird das Potenzial dieser Materialien für Anwendungen, von der Gasspeicherung über die Katalyse bis hin zur organischen Elektronik, erörtert.

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“…These results indicated multiple‐component strategy is also useful for the preparation of luminescent materials. COFs with tetraphenylethene (TPE) building blocks have been recently developed to show high crystallinity and porosity; however, their luminescence properties have not been demonstrated …”

Section: Porous Luminescent Systems Based On Covalent Organic Frameworkmentioning

confidence: 99%

Luminescent Porous Polymers Based on Aggregation‐Induced Mechanism: Design, Synthesis and Functions

Dalapati

Jiang

2016

Small

101

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Enormous research efforts are focusing on the design and synthesis of advanced luminescent systems, owing to their diverse capability in scientific studies and technological developments. In particular, fluorescence systems based on aggregation-induced emission (AIE) have emerged to show great potential for sensing, bio-imaging, and optoelectronic applications. Among them, integrating AIE mechanisms to design porous polymers is unique because it enables the combination of porosity and luminescence activity in one molecular skeleton for functional design. In recent years rapid progress in exploring AIE-based porous polymers has developed a new class of luminescent materials that exhibit broad structural diversity, outstanding properties and functions and promising applications. By classifying the structural nature of the skeleton, herein the design principle, synthetic development and structural features of different porous luminescent materials are elucidated, including crystalline covalent organic frameworks (COFs), metal-organic frameworks (MOFs), and amorphous porous organic polymers (POPs). The functional exploration of these luminescent porous polymers are highlighted by emphasizing electronic interplay within the confined nanospace, fundamental issues to be addressed are disclosed, and future directions from chemistry, physics and materials science perspectives are proposed.

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Construction of Covalent Organic Frameworks Bearing Three Different Kinds of Pores through the Heterostructural Mixed Linker Strategy

Cited by 267 publications

References 34 publications

Precision Construction of 2D Heteropore Covalent Organic Frameworks by a Multiple‐Linking‐Site Strategy

Precision Construction of 2D Heteropore Covalent Organic Frameworks by a Multiple‐Linking‐Site Strategy

Kovalente organische Netzwerke und Käfigverbindungen: Design und Anwendungen von polymeren und diskreten organischen Gerüsten

Luminescent Porous Polymers Based on Aggregation‐Induced Mechanism: Design, Synthesis and Functions

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