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Energetics and Mechanism of Organolanthanide-Mediated Aminoalkene Hydroamination/Cyclization. A Density Functional Theory Analysis

2004; American Chemical Society; Volume: 23; Issue: 17 Linguagem: Inglês

10.1021/om049666i

1520-6041

Alessandro Motta, Giuseppe Lanza, Ignazio L. Fragalà, Tobin J. Marks,

Chemical Reaction Mechanisms

This contribution focuses on organolanthanide-mediated hydroamination processes and analyzes the hydroamination/cyclization of a prototypical aminoalkene, NH2(CH2)3CHCH2, catalyzed by Cp2LaCH(TMS)2, using density functional theory. The reaction is found to occur in two steps, namely, cyclization to form La−C and C−N bonds, and subsequent La−C protonolysis. Calculations have been carried out for (i) insertion of the olefinic moiety into the La−N bond via a four-center transition state and (ii) protonolysis by a second substrate molecule. The cyclized amine then dissociates, thus restoring the active catalyst. DFT energy profiles have been determined for the turnover-limiting insertion of the 1-amidopent-4-ene CC double bond into the La−NH− bond. DFT calculations of geometries and the stabilities of reactants, intermediates, and products have been analyzed. The picture that emerges involves concerted, rate-limiting, slightly endothermic insertion of the alkene fragment into the La−N(amido) bond via a highly organized, seven-membered chairlike cyclic transition state (ΔH⧧calcd = 11.3 kcal/mol, ΔS⧧calcd = −14.6 cal/mol K). The resulting cyclopentylmethyl complex then undergoes exothermic protonolysis to yield an amine-amido complex, the resting state of the catalyst. Thermodynamic and kinetic estimates are in excellent agreement with experimental data.