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A transition metal-catalyzed dimerization of norbornadiene
TetrahedronLcattersNo. 11, pp. 368-372, 1961. Pergamon Press Ltd. Printed in Great Britain.
A TRANSITIONMETAL-CATALYZEDDIMBRIZATION OF NORBORNADIENE David hi.Lemal and Kyung S. Shim Departmentof Chemistry,University of Wisconsin Madison 6, Wisconsin (Received2 June 1961)
IRRADIATIONwith a sunlamp of a mixture of iron pentacarbonyland norbornadiene leads to a complex mixture of products includingthe tricarbonyliron complex of the diene, a number of ketones, and unsaturateddimers of
. the diene.' In addition to these we have found a saturateddimer to which we have assigned either of the novel structuresI or II. It should be
noted that several of the reaction products are formed in the absence of light,1,2 but we have been unable to obtain the saturateddimer by heating 1 R. Pettit, J.Amer.Chem.Soc,&l, 1266 (19591 3 L C.W. Bird, R.C. Cookson and J. Hudec, Chem. & Ind. 20 (1960). l
368
Dimerization
No.11 the reactants to yield
in the dark.
Irradiation
this compound,3 indicating
carbonyl are required
in t-butanol.
of norbornadiene alone also fails
that both light
saturated dimer was isolated
chromatography on alumina or silica
gel,
Calc.
and the iron penta-
(Found:
in 2-38 yield5
by sublimation
C, 91.03%; H, 9.00%; mol. wt.,
the melting 175, CryoscoPic
for CT4H16: C, 91.25%; H, 8.75%; mol. wt.,
In the mass spectrum, the relative
by
on both of which it was Only very
After further purification
point was 165-165.5’
369
for the dimerization. 4
Tne highly volatile
weakly adsorbed.
of norbornadiene
intensities
184.)6
of the peaks at 184, 185
and 186 agree within experimental error with the isotopic
distribution
Iv 3 Since this dimerization is successful even when performed In a soft glass vessel, it is apparent that the wavelength range of the effective radiation is outside of the region in which norbornadiene absorbs appreciably. See C.F. Wilcox, Jr., S. Winstein and W.G. McMillan, J.Amer.Chem.Soc. &, 5450 (1960). 4 Professor R.C. Cookson has kindly informed us that this dimer is
5 6
also formed by reaction of the diene with iron enneacarbonyl in the dark, so light is apparently required only for the transformation of the penta- to the enneacarbonyl. For the latter reaction, see R.K. Sheline and K.S. Pitzer, J.Amer.Chem,Soc. a, 1107 (1950). It is of interest that irradiation of a mixture of norbornadiene with its iron tricarbonyl complex does not yield the saturated dlmer. This yield is based upon the diene, which has been used as diluent as well as reactant, and hence in large molar excess (2.511).
Carbon-hydrogen analyses were performed by the Scandinavian Mlcrochemical Laboratory, Copenhagen, Denmark.
Dimerization
370 anticipated the
fact
t
for the that
any other
of norbornadiene
ion C H 14 16 ’
the parent
Consistent
peak at 184 is
with
several
No.11 a cagelike
times
structure
more intense
is
than
peak in the spectrum.
Evidence inertness
for
the saturated
to bromine
hydrogen
character
and potassium
over Adams’ catalyst
Moreover,
there
bond stretching
in the
infrared
spectrum
in the ultraviolet
permanganate
in acetic
is no absorption
of this
acid
and its
excludes
includes
failure
containing
corresponding spectrum,
molecule
to consume
perchloric
to carbon-carbon
and the
beyond doubt
lack
its
acid. double
of end absorption
the presence
of unsatur-
ation. Structures
III
two norbornadiene systems,
can
nuclei-
magnetic
carbon
tetrachloride 9.30,
spectrum
range
absorption),
derivatives
The most cogent
simple,
of the
3.49,
stretching spectrum
evidence&we
7.73,
8.10,
8.16,
and the Nujol
mull
7.62,
with
a highly
is no band in the
and nortricyclenes
a band characteristic
region. frequency
of cyclo-
More compelling
is the
below 3.37~~ and the
at higher
field
can adduce
for
and in
and IV, there
in which many tricyclenes nor is there
infrared
taken
consistent
to III
of
diene
The former
6.90, this
a fact
by the coupling
homoconjugated
165’ dimer.
Incidentally,
in the 9.8-l+
in the n.m.r.
of their
of the
With regard
(a region
sense
consideration
spectra
and 11.51~.
of a carbon-hydrogen absorption
termini
has maxima at 3.37,
10.51,
show prominen: propane
resonance
structure. ‘rl
in a formal
through
are both relatively
symmetrical 12.3-12.5
the
eliminated
‘be
proton
8.46,
and IV, derived
lack
absence of
than 8.2<.8 structures
I,
heptacyclo-
” L.J. Bellamy, The Infrared Soectra of Comolex Molecules pp. 17, 29, 30. John Wiley, New York (1959). 8 J.A. Pople, W.G. Schneider and H.J. Bernstein, Hiah Resol tio n Nuclear Maunetic Resonance pp. 236, 237. McGraw-Hill, New York (;959)& G.V.D. Tiers, Characte r is tic Nuclear Maanetic Resonance ‘Shieldinq Values’ for Hvdroaen in Oraanic Structures. Minnesota Mining and Manufacturing Company, St. Paul, Minnesota (1958).
Dimerization
No.11
(5 . 5 . 11.
of
norbornadiene
or II,
. 4r100.2~60.3~110.5~90.8~12)-tetradecane,
(7.4.1132’80.3’70.4~120.6’11010913)-tetradecane, resolution
n.m.r.
two sharp,
symmetrical
and methylene
peaks
protons,
is
3.1.
of
optimum resolution,
No fine
is
at 7.55xand
structure
is
8.21-c
discernible
whether
the
conceive
of
provided
by the high
corresponding
As expected,
respectively.8
heptacyclo-
at 60 mc the spectrum
In pyridine
spectrum.
371
peak under
be pyridine
of
to methine
the intensity
in either
solvent
consists
ratio conditions
or carbon
tetra-
chloride. It which
is
possible
are not
knowledge
all
it
rigorously
determination
II
that
a decision
molecule X-ray
(i.e.
unit
possess
cell
could
been successful
because
single
this
proved
I and II of
virtually
of
X-ray
demand that not
only
in I,
by
crystal
the probable all
our
improbable
be reached
might
distinguish
but to
highly
alone If
CUH16
symmetry lacking
them could
considerations symmetry.)
of
for
above,
only y&
through
The determination
elucidation.
as yet
group
structures
outlined
a center
between
space
of
studies
saturated
by the data
possesses
probable
a center
diffraction
structure not
of the
other
from norbornadiene
structure
was conceivable
examination
excluded
are derivable
Since
pathways.
to
the
to be the case,
through space
complete
group
the crystals
has
we have
9 examined have been twinned. The thermal this
substance
packed
of
the cagelike
in a stream
of
nitrogen
with Pyrex
the major of
stability
portion
the pyrolysis
helices of
the dimer
has been passed to
temperatures
has crystallized
comment. through
in excess
unchanged
Vapor of
a Pyrex of
tube
SOO’,
in the cooler
and part
tube.
In summary, the
s
and heated
dimer merits
low adsorbability,
high volatility,
relatively
high
9 L. deVries and S. Winstein, J.Amer.Chem.Soc. &, 5363 (15%0), have encountered similar problems with the birdcage hydrocarbon, crystals disordered.” of which are “highly
Dimerization
372 melting
point,
are indicative
chemical of its
and mass spectral distinction
inertness, cagelike
of norbornadiene and thermal
character.
No.11 of the 165’ dimer
stability
Infrared,
data powerful support structure
n.m.r.,
I or II,
ultraviolet, but permit no
between them.
- It is a pleasure for us to acknowledge the kind;. Seymour Meyerson of the American Oil Companywho measured the mass speb.trum of the 165O dimer and of Mr. Kenneth Kawano who determined the n.m.r. spectra. The X-ray photographs were taken by Professor Lawrence Dahl who, like Professor Peter Yates, has offered valuable suggestions. We are grateful also for financial assistance from the National Science Foundation.
A TRANSITIONMETAL-CATALYZEDDIMBRIZATION OF NORBORNADIENE David hi.Lemal and Kyung S. Shim Departmentof Chemistry,University of Wisconsin Madison 6, Wisconsin (Received2 June 1961)
IRRADIATIONwith a sunlamp of a mixture of iron pentacarbonyland norbornadiene leads to a complex mixture of products includingthe tricarbonyliron complex of the diene, a number of ketones, and unsaturateddimers of
. the diene.' In addition to these we have found a saturateddimer to which we have assigned either of the novel structuresI or II. It should be
noted that several of the reaction products are formed in the absence of light,1,2 but we have been unable to obtain the saturateddimer by heating 1 R. Pettit, J.Amer.Chem.Soc,&l, 1266 (19591 3 L C.W. Bird, R.C. Cookson and J. Hudec, Chem. & Ind. 20 (1960). l
368
Dimerization
No.11 the reactants to yield
in the dark.
Irradiation
this compound,3 indicating
carbonyl are required
in t-butanol.
of norbornadiene alone also fails
that both light
saturated dimer was isolated
chromatography on alumina or silica
gel,
Calc.
and the iron penta-
(Found:
in 2-38 yield5
by sublimation
C, 91.03%; H, 9.00%; mol. wt.,
the melting 175, CryoscoPic
for CT4H16: C, 91.25%; H, 8.75%; mol. wt.,
In the mass spectrum, the relative
by
on both of which it was Only very
After further purification
point was 165-165.5’
369
for the dimerization. 4
Tne highly volatile
weakly adsorbed.
of norbornadiene
intensities
184.)6
of the peaks at 184, 185
and 186 agree within experimental error with the isotopic
distribution
Iv 3 Since this dimerization is successful even when performed In a soft glass vessel, it is apparent that the wavelength range of the effective radiation is outside of the region in which norbornadiene absorbs appreciably. See C.F. Wilcox, Jr., S. Winstein and W.G. McMillan, J.Amer.Chem.Soc. &, 5450 (1960). 4 Professor R.C. Cookson has kindly informed us that this dimer is
5 6
also formed by reaction of the diene with iron enneacarbonyl in the dark, so light is apparently required only for the transformation of the penta- to the enneacarbonyl. For the latter reaction, see R.K. Sheline and K.S. Pitzer, J.Amer.Chem,Soc. a, 1107 (1950). It is of interest that irradiation of a mixture of norbornadiene with its iron tricarbonyl complex does not yield the saturated dlmer. This yield is based upon the diene, which has been used as diluent as well as reactant, and hence in large molar excess (2.511).
Carbon-hydrogen analyses were performed by the Scandinavian Mlcrochemical Laboratory, Copenhagen, Denmark.
Dimerization
370 anticipated the
fact
t
for the that
any other
of norbornadiene
ion C H 14 16 ’
the parent
Consistent
peak at 184 is
with
several
No.11 a cagelike
times
structure
more intense
is
than
peak in the spectrum.
Evidence inertness
for
the saturated
to bromine
hydrogen
character
and potassium
over Adams’ catalyst
Moreover,
there
bond stretching
in the
infrared
spectrum
in the ultraviolet
permanganate
in acetic
is no absorption
of this
acid
and its
excludes
includes
failure
containing
corresponding spectrum,
molecule
to consume
perchloric
to carbon-carbon
and the
beyond doubt
lack
its
acid. double
of end absorption
the presence
of unsatur-
ation. Structures
III
two norbornadiene systems,
can
nuclei-
magnetic
carbon
tetrachloride 9.30,
spectrum
range
absorption),
derivatives
The most cogent
simple,
of the
3.49,
stretching spectrum
evidence&we
7.73,
8.10,
8.16,
and the Nujol
mull
7.62,
with
a highly
is no band in the
and nortricyclenes
a band characteristic
region. frequency
of cyclo-
More compelling
is the
below 3.37~~ and the
at higher
field
can adduce
for
and in
and IV, there
in which many tricyclenes nor is there
infrared
taken
consistent
to III
of
diene
The former
6.90, this
a fact
by the coupling
homoconjugated
165’ dimer.
Incidentally,
in the 9.8-l+
in the n.m.r.
of their
of the
With regard
(a region
sense
consideration
spectra
and 11.51~.
of a carbon-hydrogen absorption
termini
has maxima at 3.37,
10.51,
show prominen: propane
resonance
structure. ‘rl
in a formal
through
are both relatively
symmetrical 12.3-12.5
the
eliminated
‘be
proton
8.46,
and IV, derived
lack
absence of
than 8.2<.8 structures
I,
heptacyclo-
” L.J. Bellamy, The Infrared Soectra of Comolex Molecules pp. 17, 29, 30. John Wiley, New York (1959). 8 J.A. Pople, W.G. Schneider and H.J. Bernstein, Hiah Resol tio n Nuclear Maunetic Resonance pp. 236, 237. McGraw-Hill, New York (;959)& G.V.D. Tiers, Characte r is tic Nuclear Maanetic Resonance ‘Shieldinq Values’ for Hvdroaen in Oraanic Structures. Minnesota Mining and Manufacturing Company, St. Paul, Minnesota (1958).
Dimerization
No.11
(5 . 5 . 11.
of
norbornadiene
or II,
. 4r100.2~60.3~110.5~90.8~12)-tetradecane,
(7.4.1132’80.3’70.4~120.6’11010913)-tetradecane, resolution
n.m.r.
two sharp,
symmetrical
and methylene
peaks
protons,
is
3.1.
of
optimum resolution,
No fine
is
at 7.55xand
structure
is
8.21-c
discernible
whether
the
conceive
of
provided
by the high
corresponding
As expected,
respectively.8
heptacyclo-
at 60 mc the spectrum
In pyridine
spectrum.
371
peak under
be pyridine
of
to methine
the intensity
in either
solvent
consists
ratio conditions
or carbon
tetra-
chloride. It which
is
possible
are not
knowledge
all
it
rigorously
determination
II
that
a decision
molecule X-ray
(i.e.
unit
possess
cell
could
been successful
because
single
this
proved
I and II of
virtually
of
X-ray
demand that not
only
in I,
by
crystal
the probable all
our
improbable
be reached
might
distinguish
but to
highly
alone If
CUH16
symmetry lacking
them could
considerations symmetry.)
of
for
above,
only y&
through
The determination
elucidation.
as yet
group
structures
outlined
a center
between
space
of
studies
saturated
by the data
possesses
probable
a center
diffraction
structure not
of the
other
from norbornadiene
structure
was conceivable
examination
excluded
are derivable
Since
pathways.
to
the
to be the case,
through space
complete
group
the crystals
has
we have
9 examined have been twinned. The thermal this
substance
packed
of
the cagelike
in a stream
of
nitrogen
with Pyrex
the major of
stability
portion
the pyrolysis
helices of
the dimer
has been passed to
temperatures
has crystallized
comment. through
in excess
unchanged
Vapor of
a Pyrex of
tube
SOO’,
in the cooler
and part
tube.
In summary, the
s
and heated
dimer merits
low adsorbability,
high volatility,
relatively
high
9 L. deVries and S. Winstein, J.Amer.Chem.Soc. &, 5363 (15%0), have encountered similar problems with the birdcage hydrocarbon, crystals disordered.” of which are “highly
Dimerization
372 melting
point,
are indicative
chemical of its
and mass spectral distinction
inertness, cagelike
of norbornadiene and thermal
character.
No.11 of the 165’ dimer
stability
Infrared,
data powerful support structure
n.m.r.,
I or II,
ultraviolet, but permit no
between them.
- It is a pleasure for us to acknowledge the kind;. Seymour Meyerson of the American Oil Companywho measured the mass speb.trum of the 165O dimer and of Mr. Kenneth Kawano who determined the n.m.r. spectra. The X-ray photographs were taken by Professor Lawrence Dahl who, like Professor Peter Yates, has offered valuable suggestions. We are grateful also for financial assistance from the National Science Foundation.