The reaction of pyridine (Py), pyrrole (Pyr), or acridine with the bis(dihydrogen) complex
[RuH2(η
2-H2)2(PCy3)2] (1) produces compounds containing heteroaromatic ([RuH2(η
2-H2)(η
1(N)-C5H5N)(PCy3)2] (2), [RuH(η
5-C4H4N)(PCy3)2]·Pyr (3)) or aromatic rings ([RuH2(η
4-C13H9N)(PCy3)2] (5)) coordinated in η
1(N) (2), η
5
(N,C) (3), or η
4(C,C) (5) modes for Py, Pyr, and acridine,
respectively. Complex 3 has been characterized by X-ray crystallography. Its protonation
by HBF4 affords the cationic dihydride complex [RuH2(η
5-C4H4N)(PCy3)2][BF4] (4). The
coordinated Py ligand in 2 and acridine in 5 can readily be displaced by dihydrogen, with
regeneration of 1. Regioselective hydrogenation of representative polynuclear heteroaromatic
nitrogen compounds is achieved in the presence of 1 under mild reaction conditions (80 °C,
3 bar of H2). Quinoline (Q) and isoquinoline (iQ) are hydrogenated to 5,6,7,8-tetrahydro
derivatives, while acridine is quickly reduced to 1,2,3,4-tetrahydroacridine followed by much
slower saturation to 1,2,3,4,5,6,7,8-octahydroacridine (8H-Acr), the nitrogen-containing
aromatic ring remaining intact. 8H-Acr has been isolated in analytically pure form and
characterized by 1H and 13C NMR as well as by X-ray crystallography. 5 is also active for
catalytic acridine hydrogenation and can be regarded as an intermediate in the catalytic
cycle. Saturation of a five-membered indole ring proceeds much slower than hydrogenation
of six-membered aromatic rings in Q and iQ. Pyridine, pyrrole, and 7,8-benzoquinoline are
not hydrogenated under the applied reaction conditions, as a result of the formation of new
stable complexes.
