Charge transfer in molecular wires over varying distances is a subject of great interest in
the field of molecular electronics. By increasing the distance between the electroactive
centers, transport mechanisms generally accounted for on the basis of tunneling or
superexchange operating over small distances, progressively gives way to hopping
assisted transport. However, the underlying molecular sequential steps that likely take
place during hopping and the operative mechanism occurring at intermediate distances
have received much less attention given the difficulty in assessing detailed molecular-level
information. We describe here the operating mechanisms for unimolecular electron
transfer in the ground state of radical-anion mixed-valence derivatives occurring between
their terminal perchlorotriphenylmethyl/ide groups through thiophene-vinylene oligomers
that act as conjugated wires of increasing length up to 30 Å. In this sense, while in the
shorter radical-anions a flickering resonance mechanism is the operative one, in the larger
molecular wires, as a unique finding, the net transport of the electron is assisted by an
electron-hole delocalization.