The distance and orientation dependence of the heterogeneous electron-transfer reaction between ferrocytochrome c (Fe 2+ Cc) and a silver film over nanosphere (AgFON) electrode is examined in detail using electrochemical surface-enhanced resonance Raman spectroscopy (SERRS) as a molecularly specific and structurally sensitive probe. The distance between the Fe 2+ redox center and the electrode surface is controlled by varying the chain length x of an intervening carboxylic acid terminated alkanethiol, HS(CH 2 ) x COOH, self-assembled monolayer (SAM). The orientation of the heme in Fe 2+ Cc with respect to the AgFON/S(CH 2 ) x -COOH electrode surface is controlled by its binding motif. Electrostatic binding of Fe 2+ Cc to AgFON/S(CH 2 ) x -COOH yields a highly oriented redox system with the heme edge directed toward the electrode surface. The binding constants were determined to be K ) 5.0 × 10 6 M -1 and 1.1 × 10 6 M -1 , respectively, for the x ) 5 and x ) 10 SAMs. In contrast, covalent binding of Fe 2+ Cc yields a randomly oriented redox system with no preferred direction between the heme edge and the electrode surface. SERRS detected electrochemistry demonstrates that Fe 2+ Cc electrostatically bound to the x ) 5 AgFON/S(CH 2 ) x COOH surface exhibits reversible oxidation to ferricytochrome c, whereas Fe 2+ Cc electrostatically bound to the x ) 10 surface exhibits irreversible oxidation. In comparison, Fe 2+ Cc covalently bound to the x ) 5 and x ) 10 surfaces both exhibit oxidation with an intermediate degree of reversibility. In addition to these primary results, the work presented here shows that AgFON/S(CH 2 ) x COOH surfaces (1) are biocompatible -Fe 2+ Cc is observed in its native state and (2) are stable to supporting electrolyte changes spanning a wide range of ionic strength and pH thus enabling, for the first time, SERRS studies of these variables in a manner not accessible with either the widely used colloid or electrochemically roughened SERS-active surfaces.
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