Electrochemical properties of phenols and quinones in organic solvents are strongly influenced by hydrogen-bonding with water

The electrochemical behavior of several phenols, quinones and hydroquinone in acetonitrile (CH₃CN) with varying amounts of water were investigated to understand the effect of hydrogen-bonding on their voltammetric responses. Karl Fischer coulometric titrations were performed to obtain an accurate reading of the water concentrations. The solvent/electrolyte mixture was carefully dried using 3 Å molecular sieves to obtain an initial water content that was close to the substrate concentration (∼1 × 10 ^-3 M), and higher water contents were then achieved via the addition from microliter syringes. It was found that small changes in what is often considered "trace" amounts of water were sufficient to substantially change the potential and in some cases the appearance of the voltammetric waves observed during the oxidation of the phenols/hydroquinones and reduction of the quinones. Density functional theory calculations were performed on the reduced/oxidized species in the presence of varying numbers of water molecules to better understand the hydrogen-bonding interactions at the molecular level. The results highlight the importance of accurately knowing the trace water content of organic solvents when used for voltammetric experiments.