H. Méndez scite author profile

Ground-state integer charge transfer is commonly regarded as the basic mechanism of molecular electrical doping in both, conjugated polymers and oligomers. Here, we demonstrate that fundamentally different processes can occur in the two types of organic semiconductors instead. Using complementary experimental techniques supported by theory, we contrast a polythiophene, where molecular p-doping leads to integer charge transfer reportedly localized to one quaterthiophene backbone segment, to the quaterthiophene oligomer itself. Despite a comparable relative increase in conductivity, we observe only partial charge transfer for the latter. In contrast to the parent polymer, pronounced intermolecular frontier-orbital hybridization of oligomer and dopant in 1:1 mixed-stack co-crystallites leads to the emergence of empty electronic states within the energy gap of the surrounding quaterthiophene matrix. It is their Fermi–Dirac occupation that yields mobile charge carriers and, therefore, the co-crystallites—rather than individual acceptor molecules—should be regarded as the dopants in such systems.

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Doping of Organic Semiconductors: Impact of Dopant Strength and Electronic Coupling

Méndez¹,

Heimel²,

Opitz³

et al. 2013

Angew Chem Int Ed

201

227

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Molecular doping: The standard model for molecular p-doping of organic semiconductors (OSCs) assumes integer charge transfer between OSC and dopant. This is in contrast to an alternative model based on intermolecular complex formation instead. By systematically varying the acceptor strength it was possible to discriminate the two models. The latter is clearly favored, suggesting strategies for the chemical design of more efficient molecular dopants.

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Doping of Organic Semiconductors: Impact of Dopant Strength and Electronic Coupling

et al. 2013

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Gedopte Moleküle: Das Standardmodell für die molekulare Dotierung organischer Halbleiter (OSCs) basiert auf ganzzahligem Ladungstransfer zwischen OSC und Dotand. Ein alternatives Modell geht von der Bildung eines Komplexes aus OSC und Dotand aus. Experimente unter systematischer Variation der Akzeptorstärke sprechen klar für letzteres Modell, was zum gezielten chemischen Design effizienterer molekularer Dotanden beitragen könnte.

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H. Méndez

Charge-transfer crystallites as molecular electrical dopants

Doping of Organic Semiconductors: Impact of Dopant Strength and Electronic Coupling

Doping of Organic Semiconductors: Impact of Dopant Strength and Electronic Coupling

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