Supramolecular hierarchy among halogen and hydrogen bond donors in light-induced surface patterning

Saccone, Marco; Dichiarante, Valentina; Forni, Alessandra; Goulet‐Hanssens, Alexis; Cavallo, Gabriella; Vapaavuori, Jaana; Terraneo, Giancarlo; Barrett, Christopher J.; Resnati, Giuseppe; Metrangolo, Pierangelo; Priimägi, Arri

doi:10.1039/c4tc02315c

Cited by 88 publications

(118 citation statements)

References 79 publications

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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.…”

Section: 141mentioning

confidence: 95%

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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Section: 141mentioning

confidence: 95%

Supramolecular design principles for efficient photoresponsive polymer–azobenzene complexes

2018

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“…Surprisingly, they reported that for their hydrogen bonded polymer (P4VP-OH(DMA)), only 1 mol % of chromophore loading was sufficient to obtain efficient gratings ( Figure 5a); hence, the inscription rate is lowered by decreasing chromophore concentration. In addition to the use of hydrogen bonds to create supramolecular azobenzene-containing polymers, Priimagi and co-workers reported on the creation of supramolecular polymers by use of halogen bonds [78][79][80][81]. They determined the superiority of halogen-bonded polymer-azobenzene complexes over the analogous hydrogen-bonded complexes.…”

Section: Light-induced Permanent Surface Relief Gratings In Linear Azmentioning

confidence: 99%

“…Recently, a more comparative study of different halogen bond donor chromophores showed that the efficiency of the SRG formation is increased with interaction strength (Figure 6). Moreover, the most effective halogen bond donor was found to be a iodoacetylene azo dye [81]. Seki et al reported on liquid crystalline linear polymer systems that can create SRGs with light [38,82,83].…”

Section: Light-induced Permanent Surface Relief Gratings In Linear Azmentioning

confidence: 99%

“…In turn, this leads to the partial or complete erasure of the SRGs. This light-initiated erasure of the gratings is more appealing than thermal erasure due to its capability of generating "on" and "off" states that can be controlled remotely, affect the film [81]. The label X can be either H, OH, or any halogen.…”

Section: Light-induced Reversible Surface Relief Gratings In Linear Amentioning

confidence: 99%

“…(f) Diffraction efficiency of the different fluorinated and (g) AFM surface profiles of the gratings for azobenzene modules P4VP(n) 0.1 (a) with n = 1 (X = F), n = 2 (X = Br) and n = 3 (X = I). Reproduced from [81].…”

Section: Light-induced Reversible Surface Relief Gratings In Linear Amentioning

confidence: 99%

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Light-Triggered Formation of Surface Topographies in Azo Polymers

et al. 2017

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Properties such as friction, wettability and visual impact of polymer coatings are influenced by the surface topography. Therefore, control of the surface structure is of eminent importance to tuning its function. Photochromic azobenzene-containing polymers are an appealing class of coatings of which the surface topography is controllable by light. The topographies form without the use of a solvent, and can be designed to remain static or have dynamic properties, that is, be capable of reversibly switching between different states. The topographical changes can be induced by using linear azo polymers to produce surface-relief gratings. With the ability to address specific regions, interference patterns can imprint a variety of structures. These topographies can be used for nanopatterning, lithography or diffractive optics. For cross-linked polymer networks containing azobenzene moieties, the coatings can form topographies that disappear as soon as the light trigger is switched off. This allows the use of topography-forming coatings in a wide range of applications, ranging from optics to self-cleaning, robotics or haptics.

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