Organic materials have proven to be efficient active materials in electronics, being possible
alternatives to inorganic semiconductors in electronic devices, such as organic field effects transistors
(OFETs) or organic solar cells. The versatility of organic synthesis allows us to endow small molecules
or polymers with the desired optoelectronic properties. However, the final efficiency of a given device
is not only based on the molecular design but also on the way the molecules assemble. In this sense,
non-covalent interactions play a crucial role as they are able to control the supramolecular assembly.
Hydrogen-bonding has been proven a promising strategy to improve the film morphology in organic
electronic devices with semiconductors able to efficiently transport charges. In this project, two
compounds have been studied, based on a straightforward diketopyrrolopyrrole (DPP) with a
thiophene-capped as the electroactive component and amide groups serving as the hydrogen-bonding
units1. Theamide groups are positioned with two different topologies, C-centered (C-1) or N-centered
(N-1) which are five carbons apart from the lactam rings of the DPP. We have compared these materials
with the control derivative, 1, whose structure lack amide groups (Figure 1). Finally, the potential of
these semicondcutors as active components in organic electronics have been tested in organic field
effects transistors (OFETs).