Graphene exhibits exceptional mechanical, optical and electrical properties that are unfortunately accompanied by a) poor processability and b)  poor tunability of its properties. The controlled interaction of graphene with tailor-made organic semiconductors (OS) can offer a solution to solve simultaneously these two problems. The use of well-chosen organic semiconducting molecules interacting with graphene, such as small polyaromatic dyes (fig. 1a,b) or polymers (fig.1 c,d) enables an optimal control over the molecular self-assembly process forming low-dimensional graphene-organic architectures. Moreover, OS allow to modulate numerous physical and chemical properties of graphene, including controlled electrical doping, ultimately making it possible to boost the performance of conventional organic electronic devices. Significantly, the interaction of organic molecules with graphene is strong not only at short distance but it is relevant also on longer distances, up to 30 nm. In this talk, we will review some of the most enlightening results in the field, giving an overview of the interaction between graphene and organic molecules, starting from the simplest systems at molecular scale, single molecules on single layer graphene in UHV, up to mesoscopic, more complex systems i.e., thick interpenetrated layers of graphene-organic composites embedded in working electronic or photovoltaic devices.

Graphene exhibits exceptional mechanical, optical and electrical properties that are unfortunately accompanied by a) poor processability and b)  poor tunability of its properties. The controlled interaction of graphene with tailor-made organic semiconductors (OS) can offer a solution to solve simultaneously these two problems. The use of well-chosen organic semiconducting molecules interacting with graphene, such as small polyaromatic dyes (fig. 1a,b) or polymers (fig.1 c,d) enables an optimal control over the molecular self-assembly process forming low-dimensional graphene-organic architectures. Moreover, OS allow to modulate numerous physical and chemical properties of graphene, including controlled electrical doping, ultimately making it possible to boost the performance of conventional organic electronic devices. Significantly, the interaction of organic molecules with graphene is strong not only at short distance but it is relevant also on longer distances, up to 30 nm. In this talk, we will review some of the most enlightening results in the field, giving an overview of the interaction between graphene and organic molecules, starting from the simplest systems at molecular scale, single molecules on single layer graphene in UHV, up to mesoscopic, more complex systems i.e., thick interpenetrated layers of graphene-organic composites embedded in working electronic or photovoltaic devices.