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Borepin and its valence isomers
Tetrahedron Letters,Vol.24,No.l8,pp Printed in Creat Britain
1863-1866,1983
004n-4039/83/181863-04$03.00/0 01983 PerTamon Press Ltd.
BOREPIN AND ITS VALENCE ISOMERS
Raymond L. Disch, Michael L. Sabio, and Jerome M. Schulman" Department of Chemistry, City University of New York, Queens College, Flushing, New York 11367 Summary: A_b initio calculations show borepin to be planar and more stable than its valence isomers boranorbornadiene and boranorcaradiene by a considerable amount; the latter have C, symmetry. Borepin (I) is perhaps the most conspicuously absent member of the family of monocyclic 4n+2 pi-electron systems.
In contrast to the isoelectronic tropylium
cation, which is stable in aqueous solution, even alkylborepins are quite 4 unstable. l-3 Stable heptaarylborepins are known , however, as are benzo-fused borepins.5-7 In order to understand the energetics of the borepin system we have undertaken ah inif&
theoretical studies of borepin and
its valence isomers 7-borabicyclo[4.1.0lhepta-2,4-diene clo[2.2.11hepta-2,5-diene
I
(II) and 7-borabicy-
(III).
II
III
The geometries have been optimized at the STO-3G SCF level of calculation. Results for borepin have been reported previously8, while those for II and
1863
1864
III
are
given
CC bond
I.
69.1’
of
a tub-shaped and 4.7’,
i
1 are
in
1.521
i
1.526
CaCg
into
and C3C4
reasonable ii,
= 1.344
of
and C3Cq
p-pi
to
alternation
1.
The bond
with
their
elevation
II
lengths
X.
For
is
greater
in
at
is
II
a
we
of
we found than
BCI = 1.529
geometry
There
angles
structure in
alternating
orbital.
counterparts
The local
with
1.451
q
atomic
the
bond
respectively.
structure
bow and stern
similar
agreement
Q,,
1,
boron
with
1.481
q
a (planar)
the
quite
The extent
1.548
and
0.28e
respectively,
1.321
q
1;
has
$ structure
norcaradiene’. C2C3
Borepin
C2C3 = 1.345
delocalization
obtained
I:
Table
lengths:
modest
for
in
in
1 and ClC6
q
borirane”,
B in
II
is
nearly
planar. For
III
BPQ, where
angle 87.8'.
The
canting
of
P and Q are
the
midpoints
H7BP is
boron
to
X
short,
larger
1.88
remains
the
to
firmly
carbon-boron
levels
(a)
the
to
in
the
relative
several
(a),
which
clear
that
borepin
against
is
is
the
1-methylborepin3. tropilidene, we have
more
proposed Borepin which
found
is that
to
of
be
than
conversion is only
ca.
tropylium
length
both
of
1.353
il is
relatively
however,
the
almost
exactly
the
for II
and
least
stable
the
ca.
than
more is
more
(d)
in
Table
boron
37
II
6-31G*(SCF) energetics
compounds,
suggested
7 kcal/mol
cation
given
strained-ring
by at
more
and III
Discounting
(I-11)
markedly
of
X;
4-31C(RMP2)
drawn.
erroneous
stable
II,
I,
(c)
be
The
of
BC5 and BC6 are
1,
is
and an
a subject
2.48
The
8.
energies
conclusions
borirene
C5C6 bond
1.588
q
Cg=C6.
C5C6.
back-donation
BC2 and BC3 value,
4-31C(SCF);
known to
the
BC1
toward
to
with
toward
CICq and C5C6,
cation,
The distances
dimethylborane
(b)
of
counterpart
p orbital,
Cl and C4 since
length
of
level
However,
with
canted
pointed
7-norbornadienyl
boron ~2C3.
boron
hydrogen
Concommitant
of
STO-3G(SCF);
allows
argues
that
bonded bond
the
pure
compared
Examination the
nearly
the
a homoaromatic
studies.
than
i,
respective
177.4’with
furnishes
and theoreticall
0.041
with
with
counterpart
electrons
for
a Cs structure
angle
isoelectronic nmrl’
we obtained
kcal/mol.
at it
This
for II
stable stable
when compared than
norcaradiene.
than the
is
1866
hypothetical bicyclo[4.1.0lhepta-2,4-dien-7-yl
cation (the analog of II) by
101.5 kcal/mol and 112.7 kcal/mol at levels (b) and (cl, respectively.
This
suggests that borepin has 40-43% of the delocalization energy of tropylium, a conclusion consistent with that found in our earlier study.8 While the gap between I and II is unlikely to change substantially at higher levels of approximation, that between I and III undoubtedly would decrease further;
this is because inclusion of d-orbitals and electron
correlation work in tandem to diminish the relative energy of III.
Finally, the
asymmetric structure of III due to canting of the boron bridge probably adds somewhat to the complexity of the nmr of p-tolyl derivatives of III observed by Eisch and Galle13.
Table II. Relative Energies of Borepin and its Valence Isomers (kcal/mol) ----------.------~---__molecule STO-3G(SCF) 4-31G(SCF) 4-31GcRMP2) 6-3lG*(SCF) _______________________________~~~~~~_______~~~~~~_~_~~~~~~~~~~~~~~~~~~~~ I 0.0 0.0 0.0 0.0 II III
25.7
43.7
44.8
37.7
1.6
37.4
26.9 --__------
23.6
---
---------
References and Notes 1. 2. 3. 4. 5. 76:
8. 9.
IO.
11.
12. 13.
D. F. Halpern, Ph.D. Thesis, Queens College, CUNY, 1971. G. Axelrad and D. Halpern, Chem. Commun., 291 (1971). A. J. Leusink, W. Drenth, J. G. Noltes, and G. J. M. van der Kerk, Tetrahedron w., 1263 (1967). S. M. van der Kerk, J. Boersma, and G. J. M. van der Kerk, J. Organometal. Cu., a, 303 (1981). J. J. Eisch and J. E. Galle, J. A_m. Cm. &$., p3, 4436 (1975). E. E. van Tamelen, G. Brieger, and K. G. Untch, Tetrahedron w., 8, 14, (1960). R. van Veen and F. Bickelhaupt, J. Organomet. Cb., a,C51 (1971). P. Jutzi, Angew. Chemie, 83, 912 (1971). Ss., J. M. Schulman, R. L. Disch and M. L. Sabio, J. Am. Cm. 104, 3785 (1982). J. M. Schulman, M. L. Sabio and R. L Disch (to be published). K. Krogh-Jespersen, D. Cremer, J. D. Dill, J. A. Pople and &. , lu, 2589 (1981). P. v. R. Schleyer, J. &. Ca. (a) P. R. Story and M. Saunders, -J. Amer. Cb. Ss., 82, 6199 (1960); &,, 4876(1962); (b) P. R. Story, L. C. Snyder, D. C. Douglass, E. W. Anderson, and R. L. Kornegay, ibid, &, 3630 (1963); (c) R. K. Lustgarten, M. Brookhart, and S. Winstein, ibid, w, 2347 (1972). S. Yoneda, Z. Yoshida, and S. Winstein, Tetrahedron, 23, 2395(1972). m, C9 (1977). J. J. Eisch and J. E. Galle, J. Qraanometal. Ca.
(Received in USA 28 January 1983)
1863-1866,1983
004n-4039/83/181863-04$03.00/0 01983 PerTamon Press Ltd.
BOREPIN AND ITS VALENCE ISOMERS
Raymond L. Disch, Michael L. Sabio, and Jerome M. Schulman" Department of Chemistry, City University of New York, Queens College, Flushing, New York 11367 Summary: A_b initio calculations show borepin to be planar and more stable than its valence isomers boranorbornadiene and boranorcaradiene by a considerable amount; the latter have C, symmetry. Borepin (I) is perhaps the most conspicuously absent member of the family of monocyclic 4n+2 pi-electron systems.
In contrast to the isoelectronic tropylium
cation, which is stable in aqueous solution, even alkylborepins are quite 4 unstable. l-3 Stable heptaarylborepins are known , however, as are benzo-fused borepins.5-7 In order to understand the energetics of the borepin system we have undertaken ah inif&
theoretical studies of borepin and
its valence isomers 7-borabicyclo[4.1.0lhepta-2,4-diene clo[2.2.11hepta-2,5-diene
I
(II) and 7-borabicy-
(III).
II
III
The geometries have been optimized at the STO-3G SCF level of calculation. Results for borepin have been reported previously8, while those for II and
1863
1864
III
are
given
CC bond
I.
69.1’
of
a tub-shaped and 4.7’,
i
1 are
in
1.521
i
1.526
CaCg
into
and C3C4
reasonable ii,
= 1.344
of
and C3Cq
p-pi
to
alternation
1.
The bond
with
their
elevation
II
lengths
X.
For
is
greater
in
at
is
II
a
we
of
we found than
BCI = 1.529
geometry
There
angles
structure in
alternating
orbital.
counterparts
The local
with
1.451
q
atomic
the
bond
respectively.
structure
bow and stern
similar
agreement
Q,,
1,
boron
with
1.481
q
a (planar)
the
quite
The extent
1.548
and
0.28e
respectively,
1.321
q
1;
has
$ structure
norcaradiene’. C2C3
Borepin
C2C3 = 1.345
delocalization
obtained
I:
Table
lengths:
modest
for
in
in
1 and ClC6
q
borirane”,
B in
II
is
nearly
planar. For
III
BPQ, where
angle 87.8'.
The
canting
of
P and Q are
the
midpoints
H7BP is
boron
to
X
short,
larger
1.88
remains
the
to
firmly
carbon-boron
levels
(a)
the
to
in
the
relative
several
(a),
which
clear
that
borepin
against
is
is
the
1-methylborepin3. tropilidene, we have
more
proposed Borepin which
found
is that
to
of
be
than
conversion is only
ca.
tropylium
length
both
of
1.353
il is
relatively
however,
the
almost
exactly
the
for II
and
least
stable
the
ca.
than
more is
more
(d)
in
Table
boron
37
II
6-31G*(SCF) energetics
compounds,
suggested
7 kcal/mol
cation
given
strained-ring
by at
more
and III
Discounting
(I-11)
markedly
of
X;
4-31C(RMP2)
drawn.
erroneous
stable
II,
I,
(c)
be
The
of
BC5 and BC6 are
1,
is
and an
a subject
2.48
The
8.
energies
conclusions
borirene
C5C6 bond
1.588
q
Cg=C6.
C5C6.
back-donation
BC2 and BC3 value,
4-31C(SCF);
known to
the
BC1
toward
to
with
toward
CICq and C5C6,
cation,
The distances
dimethylborane
(b)
of
counterpart
p orbital,
Cl and C4 since
length
of
level
However,
with
canted
pointed
7-norbornadienyl
boron ~2C3.
boron
hydrogen
Concommitant
of
STO-3G(SCF);
allows
argues
that
bonded bond
the
pure
compared
Examination the
nearly
the
a homoaromatic
studies.
than
i,
respective
177.4’with
furnishes
and theoreticall
0.041
with
with
counterpart
electrons
for
a Cs structure
angle
isoelectronic nmrl’
we obtained
kcal/mol.
at it
This
for II
stable stable
when compared than
norcaradiene.
than the
is
1866
hypothetical bicyclo[4.1.0lhepta-2,4-dien-7-yl
cation (the analog of II) by
101.5 kcal/mol and 112.7 kcal/mol at levels (b) and (cl, respectively.
This
suggests that borepin has 40-43% of the delocalization energy of tropylium, a conclusion consistent with that found in our earlier study.8 While the gap between I and II is unlikely to change substantially at higher levels of approximation, that between I and III undoubtedly would decrease further;
this is because inclusion of d-orbitals and electron
correlation work in tandem to diminish the relative energy of III.
Finally, the
asymmetric structure of III due to canting of the boron bridge probably adds somewhat to the complexity of the nmr of p-tolyl derivatives of III observed by Eisch and Galle13.
Table II. Relative Energies of Borepin and its Valence Isomers (kcal/mol) ----------.------~---__molecule STO-3G(SCF) 4-31G(SCF) 4-31GcRMP2) 6-3lG*(SCF) _______________________________~~~~~~_______~~~~~~_~_~~~~~~~~~~~~~~~~~~~~ I 0.0 0.0 0.0 0.0 II III
25.7
43.7
44.8
37.7
1.6
37.4
26.9 --__------
23.6
---
---------
References and Notes 1. 2. 3. 4. 5. 76:
8. 9.
IO.
11.
12. 13.
D. F. Halpern, Ph.D. Thesis, Queens College, CUNY, 1971. G. Axelrad and D. Halpern, Chem. Commun., 291 (1971). A. J. Leusink, W. Drenth, J. G. Noltes, and G. J. M. van der Kerk, Tetrahedron w., 1263 (1967). S. M. van der Kerk, J. Boersma, and G. J. M. van der Kerk, J. Organometal. Cu., a, 303 (1981). J. J. Eisch and J. E. Galle, J. A_m. Cm. &$., p3, 4436 (1975). E. E. van Tamelen, G. Brieger, and K. G. Untch, Tetrahedron w., 8, 14, (1960). R. van Veen and F. Bickelhaupt, J. Organomet. Cb., a,C51 (1971). P. Jutzi, Angew. Chemie, 83, 912 (1971). Ss., J. M. Schulman, R. L. Disch and M. L. Sabio, J. Am. Cm. 104, 3785 (1982). J. M. Schulman, M. L. Sabio and R. L Disch (to be published). K. Krogh-Jespersen, D. Cremer, J. D. Dill, J. A. Pople and &. , lu, 2589 (1981). P. v. R. Schleyer, J. &. Ca. (a) P. R. Story and M. Saunders, -J. Amer. Cb. Ss., 82, 6199 (1960); &,, 4876(1962); (b) P. R. Story, L. C. Snyder, D. C. Douglass, E. W. Anderson, and R. L. Kornegay, ibid, &, 3630 (1963); (c) R. K. Lustgarten, M. Brookhart, and S. Winstein, ibid, w, 2347 (1972). S. Yoneda, Z. Yoshida, and S. Winstein, Tetrahedron, 23, 2395(1972). m, C9 (1977). J. J. Eisch and J. E. Galle, J. Qraanometal. Ca.
(Received in USA 28 January 1983)