Evolution from Hydrogen Bond to Proton Transfer Pathways in the Electroreduction of α-NH-Quinones in Acetonitrile

Abstract

On the basis of voltammetric behaviors obtained for the electrochemical reduction of a series of α-NH-quinones (Q) of increasing basicity (5H-benzo[b]carbazole-6,11-dione (BCD), 2-{[4^′-(trifluoromethyl)phenyl]amine}-1,4-naphthalenedione (p­CF3PAN),(p­CF3PAN), 2-(phenylamine)-1,4-naphthalenedione (PAN), 2-[(4^′-methoxyphenyl)amine]-1,4-naphthalenedione (p-MeOPAN), and 2,5-di(α-methylbenzylamine)-1,4-benzoquinone (DMeBABQ)), in the presence of additives with increasing acidity [ethanol (EtOH), phenol(PhOH), benzoic acid (HBz), perchloric acid (HClO4)],(HClO4)], it was possible to identify some of the species present in the diffusion kinetic layer, allowing to control the protonation steps and/or hydrogen bond formation prior to and/or following the electron transfer processes. EtOH and PhOH act as hydrogen bonding donors with the corresponding semiquinone radical anion, (Q•−),(Q•−), and dianion hydroquinone, (Q2−),(Q2−), electrogenerated species. Due to the low acidity level of EtOH, the hydrogen bonding association process was detected only for [EtOH]/[Q]ratio>100;[EtOH]/[Q]ratio>100; meanwhile, with PhOH a strong hydrogen bonding process was detected, even at 0.3 equivalents of PhOH. The diagrams of average number of “ligands” (nav)(nav) vs. log [EtOH]/[Q] for Q•−(EtOH)nQ•−(EtOH)n and Q2−(EtOH)mQ2−(EtOH)m complexes were constructed using the successive association constants obtained from the experimental half-wave potential displacements. These diagrams show that the maximum number of molecules of EtOH hydrogen bonded to Q•−Q•− and Q2−Q2− directly depends on the basicity of the corresponding quinone. With HBz, the voltamperometric behavior shows the direct protonation of the electrogenerated Q•−Q•− provoking a typical electrochemical-chemical-electrochemical mechanism, with “the chemical step” being a proton transfer. Finally, the use of a completely dissociated acid HClO4HClO4 in acetonitrile solution, allowed to observe the successive interaction of protons with each of the different species appearing in the quinone/hydroquinone systems, including mono- and di-protonation of the neutral quinones. © 2004 The Electrochemical Society. All rights reserved.