Quantum mechanical investigation of the inner sphere reduction of the [(NSSSN)Co(III)Cl+2] cation and its analogs

William Smith

Quantum mechanical investigation of the inner sphere reduction of the [(NSSSN)Co(III)Cl+2] cation and its analogs

Files

Smith_AS_2017_A.pdf (606.63 KB)

Date

2017

Authors

William Smith

Publisher

College of Natural and Health Sciences, The University of Tampa

Abstract

The inner sphere pathway is an electron transfer (ET) mechanism that utilizes a bridging ligand to covalently link oxidant and reductant centers. The reductions of chloro-N-methyl-bis(5-amino- 3-thiapentyl)amine cobalt(III) [(NSNSN)Co(III)Cl+3] and chloro(1,11- diamino-3,6,9-trithiaundecane)cobalt(III) cation [(NSSSN)Co(III)Cl+2] by iron(II) via inner sphere ET have been shown experimentally to occur with rate constants more than 107 times faster than the nitrogen analog [(NNNNN)Co(III)Cl+2]. It has been hypothesized that this is due to non-bridging ligand effects. To test this hypothesis, the role of ground state electronic effects by the sulfur-containing ligands on the ET is investigated through the use of quantum chemistry methods. The non-bridging ligand effects were explored through the structural parameters of the cobalt complexes and by examining the LUMOs using both wavefunction theory (WFT) and density functional theory (DFT) methods. We show that the complexes containing sulfur atoms (NSSSN and NSNSN) display similar geometries. These are in contrast to the nitrogen analog (NNNNN) geometry, pointing towards a possible structural driving force in the rate constant difference.

Description

Recommended Citation: Smith, William . “Quantum Mechanical Investigation of the Inner Sphere Reduction of the [(NSSSN)Co(III)Cl+2] Cation and Its Analogs.” Acta Spartae, 2017. https://doi.org/10.48497/JZSB-EB70.

Keywords

inner sphere pathway, Department of Chemistry, Biochemistry and Physics, Research Subject Categories::NATURAL SCIENCES, Research Subject Categories::NATURAL SCIENCES::Chemistry

Citation

Smith, William . “Quantum Mechanical Investigation of the Inner Sphere Reduction of the [(NSSSN)Co(III)Cl+2] Cation and Its Analogs.” Acta Spartae, 2017. https://doi.org/10.48497/JZSB-EB70.