Quantum Chemical Investigation of the Transition States and Intermediates for the Reaction of the Nitrosonium Ion with the Pentaammineazidocobalt(III) Ion

François Rotzinger
American Chemical Society, 2016
Journal paper

Abstract

The water exchange reaction on Co(NH3)(5)OH23+ was investigated with various density functionals and basis sets. A Gibbs activation energy (Delta G(double dagger)) agreeing with experiment was obtained with the long-range-corrected functionals omega B97X-D3 and LC-BOP-LRD, SMD hydration, and modified Karlsruhe def2-TZVP basis sets. This computational technique was then applied to the reaction of NO+ with Co(NH3)(5)N-3(2+). All of the possible pathways were investigated, NO+ attack at the terminal N of Co(NH3)(5)N-3(2+) via the E and the Z isomers of the transition states, and NO+ attack at the bound N of azide, also via both isomers. The most favorable pathway proceeds via the attack at the bound N via the Z isomer. This leads to the intermediate with an oxatetrazole ligand bound to Co (III) at the N in the 3-position, Co(NH3)(5)(cycl-N4O)(3+), which undergoes N-2 elimination to yield the Co(NH3)(5)NN2O3+ intermediate. The subsequent substitution of N2O by water follows the Id mechanism with retention of the configuration. No evidence for the existence of the square-pyramidal pentacoordinated intermediate Co(NH3)(5)(3+) was found. All of the investigated intermediates, Co(NH3)(5)N-2(3+), Co(NH3)(5)E-N(N-2) (NO), CO (NH3)(5)(E-ON4)(3+), CO(NH3)(5)ON23+, CO(NH3)(5)(cycl-N4O)(3+), and Co(NH3)(5)N2O3+, exhibit short lifetimes of less than similar to 60 mu s and react via the I-d mechanism.

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https://infoscience.epfl.ch/record/224919?ln=en

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François Rotzinger

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2008

The Cause for Tremendous Acceleration of Chloride Substitution via Base Catalysis in the Chloro Pentaammine Cobalt(III) Ion

Basile Curchod, François Rotzinger

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EPFL2010

The Cause for Tremendous Acceleration of Chloride Substitution via Base Catalysis in the Chloro Pentaammine Cobalt(III) Ion

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2011