Advances in organic synthetic chemistry combined with the exceptional electronic properties of carbon allotropes, particularly graphene, is the basis to design and fabricate novel electron donor-‐acceptor ensembles with desired properties for technological applications. Thiophene-‐based materials, mainly thiophene-‐containing polymers, are known for their notable electronic properties. In this frame moving from polymer to oligomer forms, new fundamental information would help to the better understanding of their electrochemical and photophysical properties. Furthermore, a successful combination of their electronic properties with those of graphene is a challenging goal. In this work two oligothiophene compounds consists of three and nine thiophene-‐rings, abbreviated as 3T and 9T, respectively, were synthesized and noncovalently associated with liquid phase exfoliated few-‐layered graphene sheets (abbreviated as eG), forming donor-‐acceptor 3T/eG and 9T/eG nanoensembes. Markedly, intra-‐ensemble electronic interactions between the two components in the ground and excited states were evaluated with the aid of UV-‐Vis and photoluminescence spectroscopy. Furthermore, redox assays revealed an one-‐electron oxidation of 3T accompanied by one-‐electron reduction due to eG in 3T/eG, while two reversible one-‐electron oxidations of 9T accompanied by one-‐electron reduction of eG 9T/eG. The electrochemical band gap for 3T/eG and 9T/eG ensembles were calculated and verified that the negative free-‐energy change for the charge-‐separated state of 3T/eG and 9T/eG via the singlet excited state of 3T and 9T respectively, were thermodynamically favorable. Finally, results of transient pump-‐probe spectroscopic studies at the femtosecond time scale were supportive of charge transfer type interactions in the 3T/eG and 9T/eG ensembles. The estimated rates for intra-‐ensemble charge separation were found to be 9.52 x 109 s-‐1 and 2.2 x 1011 s-‐1, respectively, for 3T/eG and 9T/eG in THF, revealing moderate to ultrafast photoinduced events in the oligothiophene/graphene supramolecular ensembles
