Mechanistic and Performance Studies on the Ligand-Promoted
Ullmann Amination Reaction
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Abstract
Over the last two decades many different
auxiliary ligand systems
have been utilized in the copper-catalyzed Ullmann amination reaction.
However, there has been little consensus on the relative merits of
the varied ligands and the exact role they might play in the catalytic
process. Accordingly, in this work some of the most commonly employed
auxiliary ligands have been evaluated for C–N coupling using
reaction progress kinetic analysis (RPKA) methodology. The results
reveal not only the relative kinetic competencies of the different
auxiliary ligands but also their markedly different influences on
catalyst degradation rates. For the model Ullmann reaction between
piperidine and iodobenzene using the soluble organic base bis(tetra-<i>n</i>-butylphosphonium) malonate (TBPM) at room temperature, <i>N</i>-methylglycine was shown to give the best performance in
terms of high catalytic rate of reaction and comparatively low catalyst
deactivation rates. Further experimental and rate data indicate a
common catalytic cycle for all auxiliary ligands studied, although
additional off-cycle processes are observed for some of the ligands
(notably phenanthroline). The ability of the auxiliary ligand, base
(malonate dianion), and substrate (amine) to all act competitively
as ligands for the copper center is also demonstrated. On the basis
of these results an improved protocol for room-temperature copper-catalyzed
C–N couplings is presented with 27 different examples reported