Redox Processes in Mesoporous Oxide Membranes: Layered TiO2 Phytate and TiO2 Flavin Adenine Dinucleotide Films

Abstract

Thin films of TiO₂ (anatase) nanoparticles are assembled at an electrode surface via a layer-by-layer deposition process employing phytic acid, pyromellitic acid, or flavin adenine dinucleotide (FAD) as molecular binders. With all three types of binders, layers of typically 30 nm thickness are formed each deposition cycle. FAD as an electrochemically active component immobilized at the surface of the TiO₂ particles is reduced to FADH₂ and reoxidized in a chemically reversible two electron−two proton redox process. Two distinct voltammetric signals are observed for the immobilized FAD redox system associated with (i) hopping of electrons at the TiO₂ surface (reversible) and (ii) conduction of electrons through the TiO₂ assembly (irreversible). The conduction of electrons through the TiO₂ assembly is possible by diffusion over considerable distances as well as through a “spacer” layer of TiO₂ phytate. An order of magnitude (upper limit) estimate for the diffusion coefficient of electrons through TiO₂ phytate, D_electron ≈ 10^-6 m² s^-1, is obtained from voltammetric data. Finally, it is demonstrated that the calcination of TiO₂ assemblies causes dramatic changes in the electron transfer kinetics for the immobilized FAD/FADH₂ redox system.