Substituent Effects and Mechanistic Insights on the
Catalytic Activities of (Tetraarylcyclopentadienone)iron Carbonyl
Compounds in Transfer Hydrogenations and Dehydrogenations
posted on 2023-10-05, 21:06authored byBryn K. Werley, Xintong Hou, Evan P. Bertonazzi, Anthony Chianese, Timothy W. Funk
(Cyclopentadienone)iron
carbonyl compounds are catalytically active
in carbonyl/imine reductions, alcohol oxidations, and borrowing hydrogen
reactions, but the effect of cyclopentadienone electronics on their
activity is not well established. A series of (tetraarylcyclopentadienone)iron
tricarbonyl compounds with varied electron densities on the cyclopentadienone
were prepared, and their activities in transfer hydrogenations and
dehydrogenations were explored. Additionally, mechanistic studies,
including kinetic isotope effect experiments and modifications to
substrate electronics, were undertaken to gain insights into catalyst
resting states and turnover-limiting steps of these reactions. As
the cyclopentadienone electron density increased, both the transfer
hydrogenation and dehydrogenation rates increased. A catalytically
relevant, trimethylamine-ligated iron compound was isolated and characterized
and was observed in solution under both transfer hydrogenation and
dehydrogenation conditions. Importantly, it was catalytically active
in both reactions. Kinetic isotope effect data and initial rates in
transfer hydrogenation reactions with 4′-substituted acetophenones
provided evidence that hydrogen transfer from the catalyst to the
carbonyl substrate occurred during the turnover-limiting step, and
NMR spectroscopy supports the trimethylamine adduct as an off-cycle
resting state and the (hydroxycyclopentadienyl)iron hydride as an
on-cycle resting state. In transfer dehydrogenations of alcohols,
the use of electronically modified benzylic alcohols provided evidence
that the turnover-limiting step involves the transfer of hydrogen
from the alcohol substrate to the catalyst. The trimethylamine-ligated
compound was proposed as the primary catalyst resting state in dehydrogenations.