The impact of intramolecular π-coupling and steric flexibility on the ordering of organic films at solid/liquid-interfaces

In the present work the effect of the intramolecular steric flexibility on the structural self-assembly of organic cations and their redox activity at a chloride precovered Cu(100) electrode is investigated. In particular the adsorption of 1,1′-dibenzyl-4,4′-(propane-1,3-diyl)dipyridinium (C3-DBDP) is studied by means of cyclic voltametry (CV), in situ scanning tunneling microscopy (EC-STM) and ex situ X-ray photoelectron spectroscopy (XPS) and the experimental results are compared to previously published findings on related bipyridinium (“viologen”) molecules. The CV measurements reveal a loss of the redox activity of the more flexible C3-DBDP2 + compared to dibenzylviologen (DBV2 +), as the first electron reduction step of C3-DBDP2 + does not appear within the potential window of the Cu(100), but is shifted below the hydrogen evolution regime. This reduced redox activity is the result of the lifting of the extended π-system of the bipyridinium core by introducing the propyl chain between the two pyridinium rings. In agreement with this result, XP spectra prove that the C3-DBDP2 + cations retain their initial dicationic charge within the entire potential window in solution but also upon adsorption on the Cl-c(2x2)/Cu(100) substrate, where they are found to form an inter-linked stripe phase. The building blocks of each stripe are attributed to one pyridinium-benzyl moiety, which represents half of one C3-DBDP2 + molecule. The resulting consecutive arrangement of half C3-DBDP2 + molecules along one stripe is stabilized by electrostatic attraction between the positively charged pyridinium rings and the negatively charged π-system of the benzyl rings.