Self-Inhibitory Electron Transfer of the Co(III)/Co(II)-Complex Redox Couple at Pristine Carbon Electrode

Applications of conducting carbon materials for highly efficient electrochemical energy devices require a greater fundamental understanding of heterogeneous electron-transfer (ET) mechanisms. This task, however, is highly challenging experimentally, because an adsorbing carbon surface may easily conceal its intrinsic reactivity through adventitious contamination. Herein, we employ nanoscale scanning electrochemical microscopy (SECM) and cyclic voltammetry to gain new insights into the interplay between heterogeneous ET and adsorption of a Co(III)/Co(II)-complex redox couple at the contamination-free surface of electron-beam-deposited carbon (eC). Specifically, we investigate the redox couple of tris(1,10-phenanthroline)cobalt(II), Co(phen)(3)(2+), as a promising mediator for dye-sensitized solar cells and redox flow batteries. A pristine eC surface overlaid with KC1 is prepared in vacuum, protected from contamination in air, and exposed to an ultrapure aqueous solution of Co(phen)(3)(2+) by the dissolution of the protective KC1 layer. We employ SECM-based nanogap voltammetry to quantitatively demonstrate that Co(phen)(3)(2+) is adsorbed on the pristine eC surface to electrostatically self-inhibit outer-sphere ET of nonadsorbed Co(phen)(3)(3+) and Co(phen)(3)(2+). Strong electrostatic repulsion among Co(phen)(3)(2+) adsorbates is also demonstrated by SECM-based nanogap voltammetry and cyclic voltammetry. Quantitatively, self-inhibitory ET is characterized by a linear decrease in the standard rate constant of Co(phen)(3)(2+) oxidation with a higher surface concentration of Co(phen)(3)(2+) at the formal potential. This unique relationship is consistent not with the Frumkin model of double layer effects, but with the Amatore model of partially blocked electrodes as extended for self-inhibitory ET. Significantly, the complicated coupling of electron transfer and surface adsorption is resolved by combining nanoscale and macroscale voltammetric methods.