In Situ Generation of n‐Type Dopants by Thermal Decarboxylation

Molecular doping is a powerful and increasingly popular approach toward enhancing electronic properties of organic semiconductors (OSCs) past their intrinsic limits. The development of n‐type dopants has been hampered, however, by their poor stability and high air‐reactivity, a consequence of their...

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Published in:Advanced functional materials 2023-03, Vol.33 (12), p.n/a
Main Authors: Aniés, Filip, Nugraha, Mohamad I., Fall, Arona, Panidi, Julianna, Zhao, Yuxi, Vanelle, Patrice, Tsetseris, Leonidas, Broggi, Julie, Anthopoulos, Thomas D., Heeney, Martin
Format: Article
Language:English
Subjects:
Carbon dioxide
Chemical Sciences
Decarboxylation
Dimerization
Dopants
Electron mobility
Electron transfer
electron transport enhancement
Field effect transistors
Materials science
molecular doping
n‐type dopants
organic field‐effect transistors
Organic semiconductors
Precursors
Semiconductor devices
Semiconductors
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Summary:Molecular doping is a powerful and increasingly popular approach toward enhancing electronic properties of organic semiconductors (OSCs) past their intrinsic limits. The development of n‐type dopants has been hampered, however, by their poor stability and high air‐reactivity, a consequence of their generally electron rich nature. Here, the use of air‐stable carboxylated dopant precursors is reported to overcome this challenge. Active dopants are readily generated in solution by thermal decarboxylation and applied in n‐type organic field‐effect transistors (OFETs). Both 1,3‐dimethylimidazolium‐2‐carboxylate (CO2‐DMI) and novel dopant 1,3‐dimethylbenzimidazolium‐2‐carboxylate (CO2‐DMBI) are applied to n‐type OFETs employing well‐known organic semiconductors (OSCs) P(NDI2OD‐T2), PCBM, and O‐IDTBR. Successful improvement of performance in all devices demonstrates the versatility of the dopants across a variety of OSCs. Experimental and computational studies indicate that electron transfer from the dopant to the host OSC is preceded by decarboxylation of the precursor, followed by dimerization to form the active dopant species. Transistor studies highlight CO2‐DMBI as the most effective dopant, improving electron mobility by up to one order of magnitude, while CO2‐DMI holds the advantage of commercial availability. The doping capabilities of two air‐stable imidazolium carboxylate dopant precursors are demonstrated. Through in situ thermal decarboxylation in the presence of n‐type organic semiconductors, electron mobilities of fabricated organic field‐effect transistors are improved by up to one order of magnitude. Successful doping of small molecules, polymers, and fullerene species demonstrates the versatility of the dopants.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202212305