Synthesis and Optoelectronic Characterization of Perylene Diimide-Quinoline Based Small Molecules

Aivali, Stefania; Tsimpouki, Loukia; Anastasopoulos, Charalampos; Kallitsis, Joannis K.

doi:10.3390/molecules24234406

Cited by 19 publications

(22 citation statements)

References 49 publications

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“…The versatility of this original SMC reaction was demonstrated by replacing the phenyl boronic acid substituted with the electron-withdrawing formyl group by the (4-diphenylamino)phenyl electron-donating group. In 2019, J. K. Kallistsis and co-workers applied the same conditions to functionalize the PDI with a protected phenoxy and a styryl moiety [67]. Those anchoring groups were subsequently used to attach withdrawing quinoline derivatives through Heck coupling or nucleophilic substitution after the alcohol deprotection.…”

Section: Palladium-catalyzed Cross-coupling Reactionsmentioning

confidence: 99%

Nitro-Perylenediimide: An Emerging Building Block for the Synthesis of Functional Organic Materials

2020

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Perylenediimide (PDI) is one of the most important classes of dyes and is intensively explored in the field of functional organic materials. The functionalization of this electron-deficient aromatic core is well-known to tune the outstanding optoelectronic properties of PDI derivatives. In this respect, the functionalization has been mostly addressed in bay-positions to halogenated derivatives through nucleophilic substitutions or metal-catalyzed coupling reactions. Being aware of the synthetic difficulties of obtaining the key intermediate 1-bromoPDI, we will present as an alternative in this review the potential of 1-nitroPDI: a powerful building block to access a large variety of PDI-based materials.

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Section: Palladium-catalyzed Cross-coupling Reactionsmentioning

confidence: 99%

Nitro-Perylenediimide: An Emerging Building Block for the Synthesis of Functional Organic Materials

2020

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“…Even if we mentioned conjugated polymers, the discussion should be extended to a wide collection of chromophores, which have been successfully tested; in particular, chromophores with small aromatic cores (naphthalenes [65], pyrenes [66], and perylenes [67]) are typical examples of discrete molecules that are easy to handle and precisely modify (unlike polymers), and they are able to create ordered nanostructures that resemble polymer chains (columns, stacks of lamellae), due to π-π stacking interactions. Some relevant efforts have focused on the engineering of π-conjugated macromolecules by direct arylation strategies for BHJs [68], fluoro-functionalized quinoxaline-based polymers to be used as low-band gap acceptors [69], and finally perylene diimides as n-type organic molecules usable as non-fullerene acceptors in organic photovoltaics [70]. Generally speaking, strong π-π interactions are desirable, since they allow for the propagation of excitons and/or charge carriers through relatively long distance (like in a polymer chain), although there is not a physical network of bonded atoms.…”

Section: The Photoactive Materials Of Choice-structural Parameters Anmentioning

confidence: 99%

Tackling Performance Challenges in Organic Photovoltaics: An Overview about Compatibilizers

et al. 2020

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Organic Photovoltaics (OPVs) based on Bulk Heterojunction (BHJ) blends are a mature technology. Having started their intensive development two decades ago, their low cost, processability and flexibility rapidly funneled the interest of the scientific community, searching for new solutions to expand solar photovoltaics market and promote sustainable development. However, their robust implementation is hampered by some issues, concerning the choice of the donor/acceptor materials, the device thermal/photo-stability, and, last but not least, their morphology. Indeed, the morphological profile of BHJs has a strong impact over charge generation, collection, and recombination processes; control over nano/microstructural morphology would be desirable, aiming at finely tuning the device performance and overcoming those previously mentioned critical issues. The employ of compatibilizers has emerged as a promising, economically sustainable, and widely applicable approach for the donor/acceptor interface (D/A-I) optimization. Thus, improvements in the global performance of the devices can be achieved without making use of more complex architectures. Even though several materials have been deeply documented and reported as effective compatibilizing agents, scientific reports are quite fragmentary. Here we would like to offer a panoramic overview of the literature on compatibilizers, focusing on the progression documented in the last decade.

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“…PDIs find application as laser dyes due to their high luminescence efficiency [ 34 ]. According to the literature [ 35 ], PDIs can be considered as very useful materials due to the versatility of their chemical structure. Solubility, tunability, electronic, optical, and morphological features for PDIs may vary depending on the substituents in the ortho, bay, or imide positions.…”

Section: Introductionmentioning

confidence: 99%

Perylene-Based Chromophore as a Versatile Dye for Light Amplification

et al. 2022

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One of the challenges for modern optoelectronics is to find versatile, easily adaptable components for novel laser-based technologies. A very attractive perylene-derivative chromophore in different organic matrices for high-performance light amplification is discussed and outlined. Our approach demonstrates the outstandingly compatible laser dye and a viable strategy to provide an effective optical gain for stimulated emission enhancement. Through structural control, we produce simple optical devices embedded in organic matrices, such as poly(methyl methacrylate), nematic liquid crystalline (NLC) mixture, and a hybrid emulsion system (poly(vinyl alcohol) PVA + NLC mesophase). Importantly, we investigate and compare the spectroscopy of differently constructed organic systems in terms of stimulated-emission thresholds and light amplification process efficiency. Moreover, we report the effects of tunability for LC cells by an applied external electric field stimulus. Future directions of laser systems are outlined with an emphasis on the role of the perylene derivative. The studies meet current challenges in the field of modern organic technologies dedicated to various optoelectronic systems, including touch screens, displays, and Li-Fi networks.

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Synthesis and Optoelectronic Characterization of Perylene Diimide-Quinoline Based Small Molecules

Cited by 19 publications

References 49 publications

Nitro-Perylenediimide: An Emerging Building Block for the Synthesis of Functional Organic Materials

Nitro-Perylenediimide: An Emerging Building Block for the Synthesis of Functional Organic Materials

Tackling Performance Challenges in Organic Photovoltaics: An Overview about Compatibilizers

Perylene-Based Chromophore as a Versatile Dye for Light Amplification

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