Experimental studies on the mechanism
of copper-catalyzed amination
of aryl halides have been undertaken for the coupling of piperidine
with iodobenzene using a Cu(I) catalyst and the organic base tetrabutylphosphonium
malonate (TBPM). The use of TBPM led to high reactivity and high conversion
rates in the coupling reaction, as well as obviating any mass transfer
effects. The often commonly employed O,O-chelating ligand 2-acetylcyclohexanone
was surprisingly found to have a negligible effect on the reaction
rate, and on the basis of NMR, calorimetric, and kinetic modeling
studies, the malonate dianion in TBPM is instead postulated to act
as an ancillary ligand in this system. Kinetic profiling using reaction
progress kinetic analysis (RPKA) methods show the reaction rate to
have a dependence on all of the reaction components in the concentration
range studied, with first-order kinetics with respect to [amine],
[aryl halide], and [Cu]total. Unexpectedly, negative first-order
kinetics in [TBPM] was observed. This negative rate dependence in
[TBPM] can be explained by the formation of an off-cycle copper(I)
dimalonate species, which is also argued to undergo disproportionation
and is thus responsible for catalyst deactivation. The key role of
the amine in minimizing catalyst deactivation is also highlighted
by the kinetic studies. An examination of the aryl halide activation
mechanism using radical probes was undertaken, which is consistent
with an oxidative addition pathway. On the basis of these findings,
a more detailed mechanistic cycle for the C–N coupling is proposed,
including catalyst deactivation pathways.
[reaction: see text] Grubbs catalyst, Cl2(Cy3P)2Ru=CHPh, was found to catalyze the cross-metathesis of monosubstituted allenes to 1,3-disubstituted allenes in varying yields.
Films of HKUST-1 were fabricated, via interfacial synthesis, on polymer supports. MOF thin film composite membranes (MOF-TFCs) have similar solute retentions as in situ growth (ISG) membranes; but permeances are over 3 times higher.
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