Characterization of a Ferryl Flip in Electronically Tuned Nonheme Complexes. Consequences in Hydrogen Atom Transfer Reactivity

Two oxoiron(IV) isomers (^R 2a and ^R 2b) of general formula [Fe^IV (O)(^R PyNMe₃ )(CH₃ CN)]²⁺ are obtained by reaction of their iron(II) precursor with NBu₄ IO₄ . The two isomers differ in the position of the oxo ligand, cis and trans to the pyridine donor. The mechanism of isomerization between ^R 2a and ^R 2b has been determined by kinetic and computational analyses uncovering an unprecedented path for interconversion of geometrical oxoiron(IV) isomers. The activity of the two oxoiron(IV) isomers in hydrogen atom transfer (HAT) reactions shows that ^R 2a reacts one order of magnitude faster than ^R 2b, which is explained by a repulsive noncovalent interaction between the ligand and the substrate in ^R 2b. Interestingly, the electronic properties of the R substituent in the ligand pyridine ring do not have a significant effect on reaction rates. Overall, the intrinsic structural aspects of each isomer define their relative HAT reactivity, overcoming changes in electronic properties of the ligand.

Syntheses and investigation of metal complexes with macrocyclic polythioether ligands

Copper(I) complexes with the macrocyclic thioether ligands 1,4,8,11-tetrathiacyclotetradecane (tetrathiacyclam, 14-S₄) and 1,8-dithia-4,11-diazacyclotetradecane (dithiacyclam, 14-N₂S₂) were synthesised and structurally characterised. While the copper(I) complexes showed no reactivity towards dioxygen, the formation of "dioxygen adduct complexes" could be spectroscopically detected with ozone using low temperature stopped-flow techniques. Furthermore, it was possible to synthesise and characterise iron(II) and cobalt(II) complexes with the tetrathiacyclam ligand. No "dioxygen adduct" intermediates were observed when these complexes were reacted with dioxygen or ozone. Depending on the reaction conditions, the coordination of the metal ions could be controlled (endo- vs. exo-coordination and cis- vs. trans-coordination) and in addition to mononuclear complexes, also coordination polymers were obtained.

Spin State Tunes Oxygen Atom Transfer towards FeIV O Formation in FeII Complexes

Oxoiron(IV) complexes bearing tetradentate ligands have been extensively studied as models for the active oxidants in non-heme iron-dependent enzymes. These species are commonly generated by oxidation of their ferrous precursors. The mechanisms of these reactions have seldom been investigated. In this work, the reaction kinetics of complexes [Fe^II (CH₃ CN)₂ L](SbF₆ )₂ ([1](SbF₆ )₂ and [2](SbF₆ )₂ ) and [Fe^II (CF₃ SO₃ )₂ L] ([1](OTf)₂ and [2](OTf)₂ (1, L=^Me,H Pytacn; 2, L=^nP,H Pytacn; ^R,R' Pytacn=1-[(6-R'-2-pyridyl)methyl]-4,7- di-R-1,4,7-triazacyclononane) with Bu₄ NIO₄ to form the corresponding [Fe^IV (O)(CH₃ CN)L]²⁺ (3, L=^Me,H Pytacn; 4, L=^nP,H Pytacn) species was studied in acetonitrile/acetone at low temperatures. The reactions occur in a single kinetic step with activation parameters independent of the nature of the anion and similar to those obtained for the substitution reaction with Cl^- as entering ligand, which indicates that formation of [Fe^IV (O)(CH₃ CN)L]²⁺ is kinetically controlled by substitution in the starting complex to form [Fe^II (IO₄ )(CH₃ CN)L]⁺ intermediates that are converted rapidly to oxo complexes 3 and 4. The kinetics of the reaction is strongly dependent on the spin state of the starting complex. A detailed analysis of the magnetic susceptibility and kinetic data for the triflate complexes reveals that the experimental values of the activation parameters for both complexes are the result of partial compensation of the contributions from the thermodynamic parameters for the spin-crossover equilibrium and the activation parameters for substitution. The observation of these opposite and compensating effects by modifying the steric hindrance at the ligand illustrates so far unconsidered factors governing the mechanism of oxygen atom transfer leading to high-valent iron oxo species.

Facile Conversion of syn-[FeIV (O)(TMC)]2+ into the anti Isomer via Meunier's Oxo-Hydroxo Tautomerism Mechanism

The syn and anti isomers of [FeIV (O)(TMC)]2+ (TMC=tetramethylcyclam) represent the first isolated pair of synthetic non-heme oxoiron(IV) complexes with identical ligand topology, differing only in the position of the oxo unit bound to the iron center. Both isomers have previously been characterized. Reported here is that the syn isomer [FeIV (Osyn )(TMC)(NCMe)]2+ (2) converts into its anti form [FeIV (Oanti )(TMC)(NCMe)]2+ (1) in MeCN, an isomerization facilitated by water and monitored most readily by 1 H NMR and Raman spectroscopy. Indeed, when H218 O is introduced to 2, the nascent 1 becomes 18 O-labeled. These results provide compelling evidence for a mechanism involving direct binding of a water molecule trans to the oxo atom in 2 with subsequent oxo-hydroxo tautomerism for its incorporation as the oxo atom of 1. The nonplanar nature of the TMC supporting ligand makes this isomerization an irreversible transformation, unlike for their planar heme counterparts.