The complexes Pt(PEt3)3 and
Pd(PEt3)3 cleave the C−C bond of
biphenylene to give
(PEt3)2Pt(2,2‘-biphenyl), 1, and
(PEt3)2Pd(2,2‘-biphenyl),
respectively. Heating
(PEt3)2Pt(2,2‘-biphenyl) in the
presence
of biphenylene leads to C−C cleavage of a second biphenylene to give
(PEt3)2Pt(2,2‘-tetraphenyl), 2,
via a
Pt(IV) intermediate. 2 reductively eliminates
tetraphenylene at 115 °C. At 120 °C the reaction is
catalytic;
Pt(PEt3)3 or 1 converts
biphenylene to tetraphenylene. The intermediates in the catalytic
cycle have been
identified, and 1 and 2 have been characterized
by X-ray analysis. Under catalytic conditions 1 and
2 approach
steady-state concentrations. Kinetic analysis reveals that the
steady-state concentration ratio, resting state
species, and overall rate of catalysis, k
obs,
depend on the ratio of biphenylene to PEt3. This
observation is
consistent with loss of PEt3 from 1, resulting
in the 14-electron species
(PEt3)Pt(2,2‘-biphenyl), I. At
130 °C,
I coordinates to PEt3 approximately 130 times
faster than it activates the C−C bond of biphenylene.
The
complex (depe)Pt(2,2‘-biphenyl), 7 (depe =
bis(diethylphosphino)ethane), does not cleave the C−C bond
of
biphenylene. Compound 2 is also capable of activating
the C−H bonds of benzene and biphenylene to give
trans-(PEt3)2Pt(α-biphenyl)(phenyl),
5, and
trans-(PEt3)2Pt(α-biphenyl)(α-biphenylenyl),
6, respectively.
Compounds 5 and 6 have been characterized by
X-ray analysis. Substitution of Pd for Pt results in
more
rapid catalysis;
(PEt3)2Pd(2,2‘-biphenyl) is a very
efficient catalyst (20 turnovers/h at 120 °C).