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Abstract
The mechanistic study of molecular doping of organic semiconductors (OSC) requires
an improved understanding of the role and formation of integer charge transfer complexes
(ICTC) on a microscopic level. In the present work we go one crucial step beyond
the simplest scenario of an isolated bi-molecular ICTC and study ICTCs formed of
up to two (poly[2,6-(4,4-bis(2-ethylhexyl)-4H-cyclopenta[2,1-b,3,4-b”]dithiophene)-alt-4,7-(2,1,3-
benzothiadiazole)](PCPDT-BT) oligomers and up to two CN6-CP molecules. We find that depending
on geometric arrangement, complexes containing two conjugated oligomers and two
dopant molecules can show p-type doping with double integer charge transfer, resulting in either
two singly doped oligomers or one doubly doped oligomer. Interestingly, compared to an individual
oligomer-dopant complex, the resulting in-gap states on the doped oligomers are significantly
lowered in energy. Indicating that, already in the relatively small systems studied here, Coulomb
binding of the doping-induced positive charge to the counter-ion is reduced which is an elemental
step towards generating mobile charge carriers through molecular doping.
