Dependence of Field Switched Ordered Arrays of Dinuclear Mixed-Valence Complexes on the Distance between the Redox Centers and the Size of the Counterions.

trans-[(H2NCH2CH2C=N)(dppe)2Ru(C≡C)6Ru(dppe)2(N≡CCH2CH2NH2)][PF6]2, 2[PF6]2, a derivative of trans-[Cl(dppe)2Ru(C≡C)6Ru(dppe)2Cl] functionalized for binding to a silicon substrate, has been prepared and characterized spectroscopically, electrochemically, and with a solid state, single-crystal structure determination. Covalent binding via reaction of one amine group to a boron-doped, smooth Si-Cl substrate is verified by XPS measurements and surface electrochemistry. Vertical orientation is demonstrated by film thickness measurements. Synthesis of the 2[PF6]3 mixed-valence complex on the surface is established by electrochemical techniques. Measurement of the ac capacitance of the film at 1 MHz as a function of voltage across the film with a pulse-counter pulse technique demonstrates controlled electric field generation of the two stable mixed-valence forms differing in the spatial location of one electron, that is, switching. As compared to [trans-Ru(dppm)2(C≡CFc)(NCCH2CH2NH2)][PF6][Cl], 1 [PF6][Cl], the magnitude of the capacitance signal per complex observed on switching is shown to increase with increasing distance between the metal centers. Additional experiments on 1 [X][Cl] show that the potential for switching 1 [X][Cl] increases in the order [X]- = [SO3CF3]-<[PF6] <[Cl]. A simple electrostatic model suggests that the smaller is the counterion, the greater is the perturbation of the metal sites and the larger is the barrier for switching. [ABSTRACT FROM AUTHOR]