Effect of hydrogen-bond strength on photoresponsive properties of polymer-azobenzene complexes
Supramolecular complexation between photoresponsive azobenzene chromophores and a photopassive polymer host offers synthetic and design advantages compared with conventional covalent azo-containing polymers. In this context, it is important to understand the impact of the strength of the supramolecu...
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| Published in: | Canadian journal of chemistry Vol. 98; no. 9; pp. 531 - 538 |
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| Format: | Journal Article |
| Language: | English |
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01-09-2020
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| Abstract | Supramolecular complexation between photoresponsive azobenzene chromophores and a photopassive polymer host offers synthetic and design advantages compared with conventional covalent azo-containing polymers. In this context, it is important to understand the impact of the strength of the supramolecular interaction on the optical response. Herein, we study the effect of hydrogen-bonding strength between a photopassive polymer host [poly(4-vinylpyridine), or P4VP] and three azobenzene analogues capable of forming weaker (hydroxyl), stronger (carboxylic acid), or no H-bonding with P4VP. The hydroxyl-functionalized azo forms complete H-bonding complexation up to equimolar ratio with VP, whereas the COOH-functionalized azo reaches only up to 30% H-bond complexation due to competing acid dimerization that leads to partial phase separation and azo crystallization. We show that the stronger azo-polymer H-bonding nevertheless provides higher photoinduced orientation and better performance during optical surface patterning, in terms of grating depth and diffraction efficiency, when phase separation is either avoided altogether or is limited by using relatively low azo contents. These results demonstrate the importance of the H-bonding strength on the photoresponse of azopolymer complexes, as well as the need to consider the interplay between different intermolecular interactions that can affect complexation. |
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| AbstractList | Supramolecular complexation between photoresponsive azobenzene chromophores andaphotopassive polymer host offers synthetic and design advantages compared with conventional covalent azo-containing polymers. In this context, it is important to understand the impact of the strength of the supramolecular interaction on the optical response. Herein, we study the effect of hydrogen-bonding strength between a photopassive polymer host [poly(4-vinylpyridine), or P4VP] and three azobenzene analogues capable of forming weaker (hydroxyl), stronger (carboxylic acid), or no H-bonding with P4VP. The hydroxyl-functionalized azo forms complete H-bonding complexation up to equimolar ratio with VP, whereas the COOH-functionalized azo reaches only up to 30% H-bond complexation due to competing acid dimerization that leads to partial phase separation and azo crystallization. We show that the stronger azo-polymer H-bonding nevertheless provides higher photoin-duced orientation and better performance during optical surface patterning, in terms of grating depth and diffraction efficiency, when phase separation is either avoided altogether or is limited by using relatively low azo contents. These results demonstrate the importance of the H-bonding strength on the photoresponse of azopolymer complexes, as well as the need to consider the interplay between different intermolecular interactions that can affect complexation. Supramolecular complexation between photoresponsive azobenzene chromophores and a photopassive polymer host offers synthetic and design advantages compared with conventional covalent azo-containing polymers. In this context, it is important to understand the impact of the strength of the supramolecular interaction on the optical response. Herein, we study the effect of hydrogen-bonding strength between a photopassive polymer host [poly(4-vinylpyridine), or P4VP] and three azobenzene analogues capable of forming weaker (hydroxyl), stronger (carboxylic acid), or no H-bonding with P4VP. The hydroxyl-functionalized azo forms complete H-bonding complexation up to equimolar ratio with VP, whereas the COOH-functionalized azo reaches only up to 30% H-bond complexation due to competing acid dimerization that leads to partial phase separation and azo crystallization. We show that the stronger azo-polymer H-bonding nevertheless provides higher photoinduced orientation and better performance during optical surface patterning, in terms of grating depth and diffraction efficiency, when phase separation is either avoided altogether or is limited by using relatively low azo contents. These results demonstrate the importance of the H-bonding strength on the photoresponse of azopolymer complexes, as well as the need to consider the interplay between different intermolecular interactions that can affect complexation. Supramolecular complexation between photoresponsive azobenzene chromophores andaphotopassive polymer host offers synthetic and design advantages compared with conventional covalent azo-containing polymers. In this context, it is important to understand the impact of the strength of the supramolecular interaction on the optical response. Herein, we study the effect of hydrogen-bonding strength between a photopassive polymer host [poly(4-vinylpyridine), or P4VP] and three azobenzene analogues capable of forming weaker (hydroxyl), stronger (carboxylic acid), or no H-bonding with P4VP. The hydroxyl-functionalized azo forms complete H-bonding complexation up to equimolar ratio with VP, whereas the COOH-functionalized azo reaches only up to 30% H-bond complexation due to competing acid dimerization that leads to partial phase separation and azo crystallization. We show that the stronger azo-polymer H-bonding nevertheless provides higher photoin-duced orientation and better performance during optical surface patterning, in terms of grating depth and diffraction efficiency, when phase separation is either avoided altogether or is limited by using relatively low azo contents. These results demonstrate the importance of the H-bonding strength on the photoresponse of azopolymer complexes, as well as the need to consider the interplay between different intermolecular interactions that can affect complexation. Key words: supramolecular complexes, azo-containing materials, photo-orientation, surface relief gratings. La complexation supramoleculaire entre des chromophores azobenzeniques photosensibles et un hote polymerique photopassif offre des avantages sur le plan de la synthese et de la conception par rapport aux polymeres azoiques covalents classiques. Dans ce contexte, il importe de comprendre les effets de la force des interactions supramoleculaires sur la reponse optique. Dans le cadre des presents travaux, nous avons etudie l'effet de la force des liaisons hydrogene entre un hote polymerique photopassif--la poly(4-vinylpyridine), ou P4VP - et trois analogues azobenzeniques capables de former des liaisons hydrogene faibles (hydroxyle) ou fortes (acide carboxylique) avec la P4VP, ou de ne former aucune liaison hydrogene. Les composes azoiques hydroxyles se complexent entierement par liaisons hydrogene avec la VP, la complexation atteignant un rapport equimolaire, tandis que les composes azoiques carboxyles n'atteignent qu'un taux de complexation par liaisons hy-drogene de 30%. Ce dernier resultat est attribuable a la dimerisation de l'acide, qui entre en competition, entrainant une separation de phases partielle et la cristallisation du compose azoique. Nous demontrons que les liaisons hydrogene plus fortes avec le polymere azoique permettent neanmoins une orientation photo-induite plus importante et une meilleure performance durant le modelage optique de la surface, notamment en ce qui concerne la profondeur du reseau et l'efficacite de diffraction, lorsque la separation de phases est evitee completement ou limitee par l'utilisation de quantites relativement faibles de compose azoique. Ces resultats demontrent l'influence de la force des liaisons hydrogene sur la photosensibilite des complexes de polymeres azoiques de meme que la necessite de prendre en compte l'interrelation entre les differentes interactions inter-moleculaires qui peuvent intervenir dans la complexation. [Traduit par la Redaction] Mots-cles : complexes supramoleculaires, composes azoiques, photo-orientation, reseaux de surface. |
| Abstract_FL | La complexation supramoléculaire entre des chromophores azobenzéniques photosensibles et un hôte polymérique photopassif offre des avantages sur le plan de la synthèse et de la conception par rapport aux polymères azoïques covalents classiques. Dans ce contexte, il importe de comprendre les effets de la force des interactions supramoléculaires sur la réponse optique. Dans le cadre des présents travaux, nous avons étudié l’effet de la force des liaisons hydrogène entre un hôte polymérique photopassif — la poly(4-vinylpyridine), ou P4VP – et trois analogues azobenzéniques capables de former des liaisons hydrogène faibles (hydroxyle) ou fortes (acide carboxylique) avec la P4VP, ou de ne former aucune liaison hydrogène. Les composés azoïques hydroxylés se complexent entièrement par liaisons hydrogène avec la VP, la complexation atteignant un rapport équimolaire, tandis que les composés azoïques carboxylés n’atteignent qu’un taux de complexation par liaisons hydrogène de 30%. Ce dernier résultat est attribuable à la dimérisation de l’acide, qui entre en compétition, entraînant une séparation de phases partielle et la cristallisation du composé azoïque. Nous démontrons que les liaisons hydrogène plus fortes avec le polymère azoïque permettent néanmoins une orientation photo-induite plus importante et une meilleure performance durant le modelage optique de la surface, notamment en ce qui concerne la profondeur du réseau et l’efficacité de diffraction, lorsque la séparation de phases est évitée complètement ou limitée par l’utilisation de quantités relativement faibles de composé azoïque. Ces résultats démontrent l’influence de la force des liaisons hydrogène sur la photosensibilité des complexes de polymères azoïques de même que la nécessité de prendre en compte l’interrelation entre les différentes interactions intermoléculaires qui peuvent intervenir dans la complexation. [Traduit par la Rédaction] |
| Audience | Academic |
| Author | Priimagi, Arri Vapaavuori, Jaana Bazuin, C. Geraldine Ras, Robin H.A Koskela, Jenni E Pellerin, Christian Wang, Xiaoxiao |
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| CitedBy_id | crossref_primary_10_1016_j_optmat_2023_113755 crossref_primary_10_1016_j_commatsci_2021_110909 crossref_primary_10_1021_acs_jpcb_1c01988 |
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| Snippet | Supramolecular complexation between photoresponsive azobenzene chromophores and a photopassive polymer host offers synthetic and design advantages compared... Supramolecular complexation between photoresponsive azobenzene chromophores andaphotopassive polymer host offers synthetic and design advantages compared with... |
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| SubjectTerms | Analysis Azo compounds Azo polymers azo-containing materials Bonding strength Carboxylic acids Chromophores Complexation complexes supramoléculaires composés azoïques Crystallization Diffraction efficiency Diffraction patterns Dimerization Hydrogen Hydrogen bonding Hydroxides Phase separation photo-orientation Polymers Polyvinyl pyridine réseaux de surface supramolecular complexes surface relief gratings |
| Title | Effect of hydrogen-bond strength on photoresponsive properties of polymer-azobenzene complexes |
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