Abstract:The [3+2] cycloaddition (32CA) reactions of strongly nucleophilic norbornadiene (NBD) with simplest diazoalkane (DAA) and three DAAs of increased electrophilicity have been studied within the Molecular Electron Density Theory (MEDT) at the MPWB1K/6-311G(d,p) computational level. These pmr-type 32CA reactions follow an asynchronous one-step mechanism with activation enthalpies ranging from 17.7 to 27.9 kcal·mol-1 in acetonitrile. The high exergonic character of these reactions makes them irreversible… Show more
“…On the other hand, the cb‐type [6] 32CA reactions involving carbenoid centers characterized by the presence of non‐bonding electron density at a carbon integrating almost 2 e, cannot be related to the electronic structures proposed by Huisgen [7] and Firestone [8] for the TACs. MEDT has been recently applied to study the correlation between changes in electron density and the molecular reactivity to analyze various aspects of 32CA reactions, namely the strain promotion, [14,15] substituent effects, [16,17] chemo‐, [18,19] regio [5] ‐ and stereoselectivity, [5,20] catalysis, [21,22] etc.…”
The carbenoid‐type (cb‐type) intramolecular [3+2] cycloaddition (IM32CA) reactions of four fluorinated azomethine ylides (AYs) bearing an ester carbonyl substituent have been studied from the molecular electron density theory (MEDT) perspective. The presence of two fluorine atoms in these species changes the pseudodiradical structure of the simplest AY to that of a carbenoid one, according to the cb‐type molecular reactivity of these IM32CA reactions. These IM32CA reactions present low activation energies, lesser than 3.0 kcal ⋅ mol−1, and a strongly exothermic character, more than −34.0 kcal ⋅ mol−1, showing a complete chemo‐ and regioselectivity. The presence of the electron‐withdrawing −CN group at the aryl ester framework increases the global electron density transfer (GEDT) at the transition state structure (TS), which fluxes from the nucleophilic AY moiety to the electrophilic carbonyl ester, diminishing the activation energy by 2 kcal ⋅ mol−1 relative to that of the phenyl substituent. Electron Localization Function and Atom‐in‐Molecules topological analyses of the most favorable TSs show the early character of these cb‐type IM32CA reactions. The present MEDT study makes it possible to establish that the carbenoid structure of these fluorinated AYs together with their supernucleophilic character are responsible for the high reactivity and selectivities shown by these three‐atom‐components participating in cb‐type 32CA reactions towards carbonyl compounds.
“…On the other hand, the cb‐type [6] 32CA reactions involving carbenoid centers characterized by the presence of non‐bonding electron density at a carbon integrating almost 2 e, cannot be related to the electronic structures proposed by Huisgen [7] and Firestone [8] for the TACs. MEDT has been recently applied to study the correlation between changes in electron density and the molecular reactivity to analyze various aspects of 32CA reactions, namely the strain promotion, [14,15] substituent effects, [16,17] chemo‐, [18,19] regio [5] ‐ and stereoselectivity, [5,20] catalysis, [21,22] etc.…”
The carbenoid‐type (cb‐type) intramolecular [3+2] cycloaddition (IM32CA) reactions of four fluorinated azomethine ylides (AYs) bearing an ester carbonyl substituent have been studied from the molecular electron density theory (MEDT) perspective. The presence of two fluorine atoms in these species changes the pseudodiradical structure of the simplest AY to that of a carbenoid one, according to the cb‐type molecular reactivity of these IM32CA reactions. These IM32CA reactions present low activation energies, lesser than 3.0 kcal ⋅ mol−1, and a strongly exothermic character, more than −34.0 kcal ⋅ mol−1, showing a complete chemo‐ and regioselectivity. The presence of the electron‐withdrawing −CN group at the aryl ester framework increases the global electron density transfer (GEDT) at the transition state structure (TS), which fluxes from the nucleophilic AY moiety to the electrophilic carbonyl ester, diminishing the activation energy by 2 kcal ⋅ mol−1 relative to that of the phenyl substituent. Electron Localization Function and Atom‐in‐Molecules topological analyses of the most favorable TSs show the early character of these cb‐type IM32CA reactions. The present MEDT study makes it possible to establish that the carbenoid structure of these fluorinated AYs together with their supernucleophilic character are responsible for the high reactivity and selectivities shown by these three‐atom‐components participating in cb‐type 32CA reactions towards carbonyl compounds.
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