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Improving the Robustness of Organic Semiconductors through Hydrogen Bonding

Paula Gómez, Stamatis Georgakopoulos, Miriam Más‐Montoya, Jesús Cerdá, José Pérez, Enrique Ortı́, Juan Aragó, David Curiel

2021ACS Applied Materials & Interfaces32 citationsDOIOpen Access PDF

Abstract

Molecular organization plays an essential role in organic semiconductors since it determines the extent of intermolecular interactions that govern the charge transport present in all electronic applications. The benefits of hydrogen bond-directed self-assembly on charge transport properties are demonstrated by comparing two analogous pyrrole-based, fused heptacyclic molecules. The rationally designed synthesis of these materials allows for inducing or preventing hydrogen bonding. Strategically located hydrogen bond donor and acceptor sites control the solid-state arrangement, favoring the supramolecular expansion of the π-conjugated surface and the subsequent π-stacking as proved by X-ray diffraction and computational calculations. The consistency observed for the performance of organic field-effect transistors and the morphology of the organic thin films corroborate that higher stability and thermal robustness are achieved in the hydrogen-bonded material.

Topics & Concepts

Materials scienceStackingOrganic semiconductorHydrogen bondIntermolecular forceSupramolecular chemistryChemical physicsAcceptorSemiconductorMoleculeConjugated systemNanotechnologyRobustness (evolution)PolymerOptoelectronicsOrganic chemistryCondensed matter physicsChemistryPhysicsGeneComposite materialBiochemistryOrganic Electronics and PhotovoltaicsConducting polymers and applicationsMolecular Junctions and Nanostructures
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