Perpendicular crossing chains enable high mobility in a noncrystalline conjugated polymer

Perpendicular crossing chains enable high mobility in a noncrystalline conjugated polymer

The nature of interchain π-system contacts, and their relationship to hole transport, are elucidated for the high-mobility, noncrystalline conjugated polymer C16-IDTBT by the application of scanning tunneling microscopy, molecular dynamics, and quantum chemical calculations. The microstructure is sh...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2024-09, Vol.121 (37), p.e2403879121
Hauptverfasser: Coker, Jack F, Moro, Stefania, Gertsen, Anders S, Shi, Xingyuan, Pearce, Drew, van der Schelling, Martin P, Xu, Yucheng, Zhang, Weimin, Andreasen, Jens W, Snyder, Chad R, Richter, Lee J, Bird, Matthew J, McCulloch, Iain, Costantini, Giovanni, Frost, Jarvist M, Nelson, Jenny
Format: Artikel
Sprache:eng
Schlagworte:
Charge transport
conjugated polymers
Contact angle
INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY
Microstructure
Mobility
Molecular chains
Molecular dynamics
organic electronics
Physical Sciences
Polymers
Quantum chemistry
Scanning tunneling microscopy
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Zusammenfassung:The nature of interchain π-system contacts, and their relationship to hole transport, are elucidated for the high-mobility, noncrystalline conjugated polymer C16-IDTBT by the application of scanning tunneling microscopy, molecular dynamics, and quantum chemical calculations. The microstructure is shown to favor an unusual packing motif in which paired chains cross-over one another at near-perpendicular angles. By linking to mesoscale microstructural features, revealed by coarse-grained molecular dynamics and previous studies, and performing simulations of charge transport, it is demonstrated that the high mobility of C16-IDTBT can be explained by the promotion of a highly interconnected transport network, stemming from the adoption of perpendicular contacts at the nanoscale, in combination with fast intrachain transport.
ISSN:0027-8424
1091-6490
1091-6490
DOI:10.1073/pnas.2403879121