Halogen Bonding versus Hydrogen Bonding in Driving Self‐Assembly and Performance of Light‐Responsive Supramolecular Polymers

Priimägi, Arri; Cavallo, Gabriella; Forni, Alessandra; Gorynsztejn–Leben, Mikael; Kaivola, Matti; Metrangolo, Pierangelo; Milani, Roberto; Shishido, Atsushi; Pilati, Tullio; Resnati, Giuseppe; Terraneo, Giancarlo

doi:10.1002/adfm.201200135

Cited by 182 publications

(183 citation statements)

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“…14a, allows for tuning the halogen bonding interaction strength with pyridine. 144,145 As Fig. 14b and c show, there is a direct correlation with the halogen bond strength and SRG formation efficiency, the iodine-capped (resulting in relatively strong halogen bonding) azobenzene complexed with P4VP resulting in the highest and fluorinecapped (no specific interaction with P4VP) resulting in the lowest SRGs.…”

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confidence: 94%

“…Moreover, it was shown that in the concentration range studied (10-20 mol%), the halogen-bonded polymerazobenzene complexes outperform the corresponding hydrogenbonded analogues in SRG formation efficiency, even though the hydrogen bond interaction is significantly stronger. 144,145 This was attributed to the higher directionality of the halogen bond compared to hydrogen bond. Thus, both the nature and strength of the supramolecular bond make a significant difference in the SRG formation efficiency.…”

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confidence: 99%

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Supramolecular design principles for efficient photoresponsive polymer–azobenzene complexes

2018

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a Noncovalent binding of azobenzenes to polymers allows harnessing light-induced molecular-level motions (photoisomerization) for inducing macroscopic effects, including photocontrol over molecular alignment and self-assembly of block copolymer nanostructures, and photoinduced surface patterning of polymeric thin films. In the last 10 years, a growing body of literature has proven the utility of supramolecular materials design for establishing structure-property-function guidelines for photoresponsive azobenzene-based polymeric materials. In general, the bond type and strength, engineered by the choice of the polymer and the azobenzene, influence the photophysical properties and the optical response of the material system. Herein, we review this progress, and critically assess the advantages and disadvantages of the three most commonly used supramolecular design strategies:hydrogen, halogen and ionic bonding. The ease and versatility of the design of these photoresponsive materials makes a compelling case for a paradigm shift from covalently-functionalized side-chain polymers to supramolecular polymer-azobenzene complexes.

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Supramolecular design principles for efficient photoresponsive polymer–azobenzene complexes

2018

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“…As their microstructures can be deliberately and easily modified, the ICPs have gained growing attention in potential applications such as gas storage [3] and separation [4], drug delivery [5], and catalysis [6]. The formation of various ICPs morphologies mainly depends on the intra-molecules non-covalent interactions such as metal-ligand interactions [7]，hydrogen bonding [8] and π-π stacking [9]. In comparison with metal organic frameworks (MOFs), these ICPs exhibit a higher level of structural tailorability, including size and morphology-dependent properties.…”

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confidence: 99%

Facile synthesis and characterizations of copper–zinc-10,15,20-tetra(4-pyridyl) porphyrin (Cu–ZnTPyP) coordination polymer with hexagonal micro-lump and micro-prism morphologies

Zhang

Zhao

et al. 2014

Journal of Colloid and Interface Science

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“…This contact is quite short especially if compared to the only other XB found in the CSD involving an iodine atom and an azo group (Refcode: TEGFUI; 3.240 Å (N c = 0.95), 152.5°). 29 This short contact is rather unexpected as nitrogen atoms of the azo moiety are only mildly basic and thus poor XB-acceptors. 30 Probably, the tight proximity imposed by the network conveniently preorganizes the interacting units and favors the occurrence of a relatively short XB.…”

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Coordination networks incorporating halogen-bond donor sites and azobenzene groups

et al. 2016

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a Two Zn coordination networks, {[ZnĲ1)ĲPy) 2 ] 2 Ĳ2-propanol)} n (3) and {[ZnĲ1) 2 ĲBipy) 2 ]ĲDMF) 2 } n (4), incorporating halogen-bond (XB) donor sites and azobenzene groups have been synthesized and fully characterized.Obtaining 3 and 4 confirms that it is possible to use a ligand wherein its coordination bond acceptor sites and XB donor sites are on the same molecular scaffold (i.e., an aromatic ring) without interfering with each other. We demonstrate that XBs play a fundamental role in the architectures and properties of the obtained coordination networks. In 3, XBs promote the formation of 2D supramolecular layers, which, by overlapping each other, allow the incorporation of 2-propanol as a guest molecule. In 4, XBs support the connection of the layers and are essential to firmly pin DMF solvent molecules through I⋯O contacts, thus increasing the stability of the solvated systems.

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Halogen Bonding versus Hydrogen Bonding in Driving Self‐Assembly and Performance of Light‐Responsive Supramolecular Polymers

Cited by 182 publications

References 60 publications

Supramolecular design principles for efficient photoresponsive polymer–azobenzene complexes

Supramolecular design principles for efficient photoresponsive polymer–azobenzene complexes

Facile synthesis and characterizations of copper–zinc-10,15,20-tetra(4-pyridyl) porphyrin (Cu–ZnTPyP) coordination polymer with hexagonal micro-lump and micro-prism morphologies

Coordination networks incorporating halogen-bond donor sites and azobenzene groups

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