Active discovery of organic semiconductors

We dedicate this contribution to Klaus Müllen on the occasion of his 75th birthday. He advanced the synthesis and application of organic electronic compounds in an internationally leading position for many years and always challenged theory to provide a better understanding.The field of organic semiconductors is multifaceted and the potentially suitable molecular compounds are very diverse. Representative examples include discotic liquid crystals, dye-sensitized solar cells, conjugated polymers, and graphene-based low-dimensional materials. This huge variety not only represents enormous challenges for synthesis but also for theory, which aims at a comprehensive understanding and structuring of the plethora of possible compounds. Eventually computational methods should point to new, better materials, which have not yet been synthesized. In this perspective, it is shown that the answer to this question rests upon the delicate balance between computational efficiency and accuracy of the methods used in the virtual screening. To illustrate the fundamentals of virtual screening, chemical design of non-fullerene acceptors, thermally activated delayed fluorescence emitters, and nanographenes are discussed.

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“…[ 131 ] This process can be further optimized by using active machine learning [ 132 , 133 ] or generative models. [ 134 ]…”

Section: Discussionmentioning

confidence: 99%

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

et al. 2022

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“… 441,442 Other recent studies have focused on how improving the ML-guided exploration of materials space, and for example active machine learning has proven able to identify OSCs with larger charge conduction properties than competing exploration strategies. 443 …”

Section: Discussionmentioning

confidence: 99%

High-throughput virtual screening for organic electronics: a comparative study of alternative strategies

et al. 2021

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“…As a matter of fact, the ideal COF-based photocatalyst, tailored for a specific reaction, might be already described in the literature, in terms of its molecular composition and framework arrangement. In this context, the emerging power of active machine learning (AML) approaches − will probably be of great help in assisting and accelerating the discovery of the best suitable COF-based photocatalyst, for instance by analyzing charge transport, optical absorption range, and linkage bond strength, among other specific descriptors. Indeed, fundamental photophysical studies can provide important guidelines for photocatalytic COF design.…”

Section: Discussionmentioning

confidence: 99%

Light-Induced Organic Transformations by Covalent Organic Frameworks as Reticular Platforms for Selective Photosynthesis

Costa

Vega‐Peñaloza

Cognigni

et al. 2021

ACS Sustainable Chem. Eng.

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Photoassisted synthesis of value-added organic products has developed greatly in the last decades in response to the pressing need for a transition toward sustainable processes and renewable energy. One of the formidable challenges of the light-induced chemical steps is provided by the control of the catalytic efficiency and selectivity under photocatalytic conditions. An attractive perspective is foreseen by triggering the photoreaction events in confined spaces, wherein light harvesting and photocatalytic units are framed into functional architectures. Division of tasks among specialized compartments responds to a bioinspired strategy with the final aim to orchestrate the rate of concurrent and sequential events, to maximize performance while directing the reaction selectivity. Covalent organic frameworks (COFs) are a class of emerging materials that can meet these requirements, with the potential to bridge the existing gap between molecular and heterogeneous photocatalysis. Here, a rich pool of molecular building blocks and chemical linkages is available to afford crystalline porous solids with tailored photophysical properties emerging from the interconnected COF structure walls, while catalytic cofactors can be provided by engineering of the pore surface. In this Perspective, we highlight recent developments where COFs have been successfully employed as photocatalysts for selective organic transformations. The relationship between the COF reticular structure and its photocatalytic behavior is discussed, in terms of the light-conversion pathways and photoredox events, including electron and/or energy transfer mechanisms. The possible role of confinement effects, intrinsic in long-range order porous COF materials, remains largely unexplored in photocatalytic applications. New progress is expected to arise from close interdisciplinary cooperation involving synthetic chemistry and materials science communities.

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Active discovery of organic semiconductors

Cited by 72 publications

References 81 publications

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

Virtual Screening for Organic Solar Cells and Light Emitting Diodes

High-throughput virtual screening for organic electronics: a comparative study of alternative strategies

Light-Induced Organic Transformations by Covalent Organic Frameworks as Reticular Platforms for Selective Photosynthesis

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