Ab-Initio MO Study of the Peracid Oxidation of Dimethyl Thiosulfinate

The mechanism of oxidation of dimethyl thiosulfinate with performic acid was investigated theoretically at MO ab-initio level. Equilibrium geometries and transition states were optimized with two different basis sets (3-21G* and 6-31G*) and the inclusion of dynamic correlation correction at MP2 level. Along the possible reactions paths three different transition states were characterized, namely, those leading to the formation of the diastereomeric forms (RR/SS or RS/SR) of α-disulfoxide and that leading to the thiosulfonate. The calculated values of activation energies and free energies of activation, in the gas phase, fail to reproduce the observed chemoselectivity of oxidation reactions. However, when the formation of reaction clusters, or better, the inclusion of solvent effects (evaluated via SCFR method) is taken into account, one obtains a correct behavior that fits the experimental trend. The reaction path was also analyzed by employing the intrinsic reaction coordinate methodology in order to examine the transitory character of α-disulfoxide. The effect of acids in depressing the reactivity was also demonstrated

Theoretical and Electrochemical Analysis of Dissociative Electron Transfers Proceeding through Formation of Loose Radical Anion Species: Reduction of Symmetrical and Unsymmetrical Disulfides

The dissociative reduction of a series of symmetrical (RSSR, R = H, Me, t-Bu, Ph) and unsymmetrical disulfides (RSSR‘, R = H, R‘ = Me and R = Ph, R‘ = Me, t-Bu) was studied theoretically, by MO ab initio calculations and, for five of them, also experimentally, by convolution voltammetry in N,N-dimethylformamide. The reduction is dissociative but proceeds by a stepwise mechanism entailing the formation of the radical anion species. The electrochemical data led to estimated large intrinsic barriers, in agreement with an unusually large structural modification undergone by the disulfide molecules upon electron transfer. The theoretical results refer to MP2/3-21G*//MP2/3-21G*, MP2/3-21*G*//MP2/3-21G*, CBS-4M, and G2(MP2), the latter approach being used only for the molecules of small molecular complexity. A loose radical-anion intermediate was localized and the dissociation pattern for the relevant bonds analyzed. For all compounds, the best fragmentation pathway in solution is cleavage of the S−S bond. In addition, S−S bond elongation is the major structural modification undergone by the disulfide molecule on its way to the radical anion and eventually to the fragmentation products. The calculated energy of activation for the initial electron transfer was estimated from the crossing of the energy profiles of the neutral molecule and its radical anion (in the form of Morse-like potentials) as a function of the S−S bond length coordinate. The inner intrinsic barrier obtained in this way is in good agreement with that determined by convolution voltammetry, once the solvent effect is taken into account

One-Pot Synthesis of Symmetric Octithiophenes from Asymmetric β-Alkylsulfanyl Bithiophenes

Starting from 4-(octylsulfanyl)-2,2‘-bithiophene, 4-bromo-4‘-(octylsulfanyl)-2,2‘-bithiophene, 4-iodo-4‘-(octylsulfanyl)-2,2‘-bithiophene, 4-bromo-4‘-[(S)-2-methylbutylsulfanyl]-2,2‘-bithiophene, and 4-iodo-4‘-[(S)-2-methylbutylsulfanyl]-2,2‘-bithiophene, a new series of symmetrically β-substituted octithiophenes were synthesized by one-pot oxidative coupling with FeCl3. The octithiophenes obtained are soluble in common organic solvents and show different solvatochromic properties depending on the substitution type. In particular, the bromine atom exerts a positive influence on the supramolecular organization:  the brominated octithiophenes display high filmability, solvatochromism, and CD induced by aggregation (when the chiral 2-methylbutylsulfanyl group is present), properties usually observed for polythiophenes. Density functional theory (DFT) calculations were carried out an a model bithiophene (4-substituted with a methylsulfanyl group) in order to understand the possible mechanism of the growth, the regiochemistry, and the reason for the polymerization leads to an octithiophene

Evidence for Large Inner Reorganization Energies in the Reduction of Diaryl Disulfides: Toward a Mechanistic Link between Concerted and Stepwise Dissociative Electron Transfers?

Evidence for Large Inner Reorganization Energies in the Reduction of Diaryl Disulfides:  Toward a Mechanistic Link between Concerted and Stepwise Dissociative Electron Transfers

Electrochemical and Theoretical Investigation of Corannulene Reduction Processes

The voltammetric generation of corannulene anions was investigated over a large range of experimental conditions comprising either “traditional” electrochemical solvents, such as dimethylformamide, acetonitrile, and tetrahydrofuran, or “unconventional” solvents, such as liquid ammonia, liquid methylamine, or liquid dimethylamine, and several different supporting electrolytes. Strong ion pairing effects were found to dominate the electrochemical generation of corannulene higher anions, and through the suitable choice of the solvent/electrolyte system, we observed, for the first time, the reversible electrochemical generation of up to the triply reduced corannulene. The standard potentials obtained experimentally compared rather well with the theoretical values calculated by ab initio and density functional methods, in which solvation and ion pairing effect were explicitly taken into account. In particular, the calculations considered the effect of the electrolyte cation size on ion pairing in order to rationalize the occurrence of the third reduction within the experimental potential window

Experimental and Theoretical Study of the p- and n-Doped States of Alkylsulfanyl Octithiophenes

The charge-transfer and spectral properties of two octithiophenes, namely 4′,4′′′,3′v,3v′-tetra(octylsulfanyl)-2,2′:5′,2′′:5′′,2′′′:5′′′,2′v:5′v,2v:5v,2v′:5v′,2v′′-octithiophene and 4,3′′,4v,4v′′-tetrabromo-4′,4′′′,3′v,3v′-tetra[(R)-2-methylbutylsulfanyl]-2,2′:5′,2′′:5′′,2′′′:5′′′,2′v:5′v,2v:5v,2v′:5v′,2v′′-octithiophene, OT1 and OT2, respectively, are characterized by cyclic voltammetry and spectroelectrochemistry under ultradry conditions. The analysis of the voltammetric results shows the formation of up to the dication for both OT1 and OT2 and up to the tetraanion (OT1) and trianion (OT2) anions. The optical properties of the OT1 (2+, 1+, neutral, 1−, 2−) species were probed by in situ UV−vis-NIR spectroelectrochemistry. The calculated standard potentials at the B3LYP/cc-pVTZ level of the theory allowed the rationalization of the experimental electrochemical results. The UV−vis-NIR spectra were successfully compared with the theoretical electronic transitions and oscillator strength data obtained by time-dependent B3LYP/6-31G* calculations. Theoretical redox potentials and optical transitions properties are calculated including “the solvent effect” within the CPCM model. The consistency obtained between experimental and theoretical results indicates the existence of the hypothesized high-spin/high-charge p- and n-doped electronic states for the OT1 and OT2 octithiophenes here studied