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The determination of π-electron densities in azulene from C13 and H1 nuclear resonance shifts
Tetrahedron Letters in Great Britain.
No.
14,
468-472,
pp.
1961.
Pergamon
THE DETERMINATION OF n-ELECTRON DENSITIES FROM cl3
of
Pure
and
Chemistry,
THERE is
on substituted related
to
the
C7H:
lol:al
the we have
and
C8Hi-,
H1 resonances by Leto, Fig. density, are than
also
the and
relative
and
two
shifts
of monosubstituted as N.R.C. Leto,
the
F.A.
which
and
has
No.
of
molecules.
of
been
3 implies
have
are
some
parallelism
that
the
known.
The
measured Richards.2 n-electron
ref.
2 above
times
larger
the
resonance
of
in
C6H6,
the
fifteen
observed
C5H;,
and
in
to
electron
been
against
reported
order
and
is
McLachlan
plotted
shifts
series
density
Carter,
are
In shift
the
series
shifts
measurements
shifts
chemical
this
shifts
also
from
n-electron
The striking
benzenes,
the
resonances
resonance of
both
6345.
Cotton
G. Fraenkel, R.E. Carter, Sot. 82, 5846 (1960).
3 H. Spiesecke
local
Cl3
mainly Hl chemical
shifts
by Fraenkel,
H1 shifts. nuclei,
and
between
members
1961)
aromatic
H1 chemical
In magnitude
of
* Issued
in
C 13 chemical
The corresponding
the
that
the
three
Council,
29 June
derived C 13
density
of which
Waughl,
corresponding
1 J.R.
the
first
shifts
2
suggest
n-electron
form
evidence,
measured
shown.
the
of
Research
revised
13 resonance C
the
p.
in
relationship
of
1 shows
to
each
IN AZULENE
Canada
quantitative
in
Cotton
1961;
amount
benzenes,
investigate density
2 June
a considerable
Printed
W.G. Schneider National
Ottawa, (Received
Ltd.
AND H1 NUCLEAR RESONANCE SHIFTS*
H. Spiesecke Division
Press
and
J.S.
Waugh,
A. McLachlan
W.G. Schneider,
Nature.Lond. and J.H.
J.Chem.Phvs.
L68
18Q, Richards,
In
press
978 (1957). J.Amer.Chem. (1%).
The determination
No.14 nuclei
respond in a parallel
of a-electron
469
densities
way to the local n-electron
density on the
carbon atom.
+50
+ IO
53
t2
s
x !!?
0 +-I
IO
-
c E -B
0
t E v)
I0
-30 -1
< 2 3 3 t
-2
0.9
0.9
1.1.
1.0
I.2
FIG. 1. The slope of the averaged lines factors,
SC13 = 160,~ and Bhl = 10.6~.
deviation *
in Fig. 1 yields
of the individual
the proportionality
In both cases,
points from the linear
however, the
correlation
line exceeds
A value of 160 p.p.m. per electron has also been deduced from Cl’ shifts by Lauterbur (private communication) by an indirect pror
470
The determination
the experimental
error
deviations
slightly
in the {different
resonance ponding
is not immediately
cyclic
nor is there coupling
ring
of the carbon shifts.
However, olefins
hybridization
and the consequent
1) reveals
The latter
in bond
to contribute
to the
no discernable
of the correstrend
in the magnitudes
with ring
size,
of the C-H spin-
have been shown to reflect
changes
in bond
compounds. 4,5
in other
Table C13 Chemical
Relative
varies
changes
of the C13 shifts
examination
explanation
The bond angle
may be expected
pattern
N0.U
A satisfactory
apparent.
systems
orbitals
(Table
any consistent
constants.
densities
of the B-measurements.
of these
hybridization
of a-electron
1
Shifts
of CH Groups in Olefinic
and Aromatic
Compounds -r-
SC13 Compound
JCH (C/S)
(p.p.m. relative to benzene)
Cyclooctatetraene
-4.1
155
Cycloheptatriene
-2.9,1.3,7.6
156,154,161
1,3_Cyclohexadien$
2.4 -4.2
163
Cyclopentadien
&
-9.5
158
42.5
145
-27.6
171
Rutadien& Cyclooctatetraene Tropylium
dianion
ion
Cyclopentadienyl
170
157
25.7
anion
L
a Two broad doublets p No resolved E Terminal Subject employed
shift
CH2 (1,4
to these
to evaluate
4 J.N.
Shoolery,
5 N. Muller
unresolved between
position
positions),
limitations the
local
2 and 3
tll.5
p.p.m.
the calibration n-electron
d.Chem.Phvs.
and D.E. Pritchard,
&,
plots
densities 47
of Fig.
of other
aromatic
(1959).
J.Chem.Phvs.
2,
1 may be
768 (1959).
systems.
-8.9 4.6 -8.9
498
597
6
Q13
JCH 183 165 158 161 158
7.5 -7.7 4.2 -8.6
(c/s)
-5.9
Corr *a
-0.170
iD.280
-0.945
-0.067
-0.583
Meas.
-0.03
+0.48
-0.34
+0.58
-0.23
c0rr.a
oH1
0.997
1.045
0.968
1.055
0.978
1112 (1956).
d R.D. Brown and M.L. Heffernan,Aust.J.Chem.2,
E A. Julg, J.Chim.Phvs.I;i,377 (1955).
b R. Pariser,J.Chem.Phvs.g,
38 (1960).
P
0.938 1.042
0.879 1.049 0.948 1.013
0.967 1.041 0.962
1.034
0.908
1.049
1.096
1.061
0.997
’
0.998
0.%9
1.011
0.954
1.059
0.988
Heffernan
Brow&
calculated Jul$
0.979
Parises
0.977
derived from 6$3
6Hl
P
a Corrected for shift due to ring current of neighbourring.
9.10
8.8
-6.7
Meas.
3,1
2
Posit- L ion
(Chemicalshifts in p.p.m. relative to benzene)
Cl3 and Hl Chemical Shifts and n-ElectronDensities of Azulene
Table 2
The determination
4772 Table
2
shows the results
hydrocarbon,
authors
and H’ shifts,
ring
values, 7
approximation. to be about derived
occurs
ently
resolved
in the azulene
molecule,
shown in Table
2,
being
relaxation
shift
carried
out on 2-3
cation,
which was measured
in the carbonyl
Cl3 resonance
shifts
The H’ resonance cyclohexane,
6
7
molar
solutions
for
these
The
roughly
was not
estimated
deviation independ-
no satisfactory
positions,
particular
dipole
the values
The largest
So far
of
a simple
between
which may be
nuclei.
in tetrahydrofuran,
as tropylium
fluoroborate
hydrolysis.
This
point
systems
were
Dimethylcarbonate
in a saturated
solution
in a 5 mole $ solution
signal
serving
of
benzene
to be converted
as an internal in cyclohexane
relative
tropylium
in aqueous
were measured
were measured
ring
except
reference.
shifts
shifts
the aromatic
as an external
the solvent
all
of
group was used
a 5 mole % solution
permitted
signals.
the 9,lO
measurements
some -IBF to prevent 4
containing
ment of
times
is
13
investigated.
The Cl3 resonance
$3
values
the Cl3 signal
by other
C
circulation
by employing
final
reported
The relative
current
correspondence
for
values
and must be corrected.
which
have been obtained
the non-alternant density
from the H1 and Cl3 resonances.
and was overlapped
due to unfavorable
by ring
of the
for
NO.L$
columns.
were obtained
accuracy
at the 6-position,
signals
manner for
three
15%. There is a very close
(-&)
is
last
influenced
The overall
densities
the calculated
are
independently
resonance
in this
are shown in the
as measured,
the neighbor corrected
obtained
For comparison
azulene.6
by several
of n-electron
solution enriched
in
The azulene of
azuIene
in CS 2’
of azulene
in
reference. in a similar
Measuremanner
to benzene.
The Cl3 resonance shifts of azulene have recently been reported by bauterbur [J.Amer.Chem.Soc. a, 1838 (1961)] and correlated with the theoretically calculated charge densities in azulene. J.A. Pople, W.G. Schneider Maanetic Resonance p. 254.
and H.J. Bernstein, Hiah Resolution McGraw-Hill, New York (1959).
Nuclear
No.
14,
468-472,
pp.
1961.
Pergamon
THE DETERMINATION OF n-ELECTRON DENSITIES FROM cl3
of
Pure
and
Chemistry,
THERE is
on substituted related
to
the
C7H:
lol:al
the we have
and
C8Hi-,
H1 resonances by Leto, Fig. density, are than
also
the and
relative
and
two
shifts
of monosubstituted as N.R.C. Leto,
the
F.A.
which
and
has
No.
of
molecules.
of
been
3 implies
have
are
some
parallelism
that
the
known.
The
measured Richards.2 n-electron
ref.
2 above
times
larger
the
resonance
of
in
C6H6,
the
fifteen
observed
C5H;,
and
in
to
electron
been
against
reported
order
and
is
McLachlan
plotted
shifts
series
density
Carter,
are
In shift
the
series
shifts
measurements
shifts
chemical
this
shifts
also
from
n-electron
The striking
benzenes,
the
resonances
resonance of
both
6345.
Cotton
G. Fraenkel, R.E. Carter, Sot. 82, 5846 (1960).
3 H. Spiesecke
local
Cl3
mainly Hl chemical
shifts
by Fraenkel,
H1 shifts. nuclei,
and
between
members
1961)
aromatic
H1 chemical
In magnitude
of
* Issued
in
C 13 chemical
The corresponding
the
that
the
three
Council,
29 June
derived C 13
density
of which
Waughl,
corresponding
1 J.R.
the
first
shifts
2
suggest
n-electron
form
evidence,
measured
shown.
the
of
Research
revised
13 resonance C
the
p.
in
relationship
of
1 shows
to
each
IN AZULENE
Canada
quantitative
in
Cotton
1961;
amount
benzenes,
investigate density
2 June
a considerable
Printed
W.G. Schneider National
Ottawa, (Received
Ltd.
AND H1 NUCLEAR RESONANCE SHIFTS*
H. Spiesecke Division
Press
and
J.S.
Waugh,
A. McLachlan
W.G. Schneider,
Nature.Lond. and J.H.
J.Chem.Phvs.
L68
18Q, Richards,
In
press
978 (1957). J.Amer.Chem. (1%).
The determination
No.14 nuclei
respond in a parallel
of a-electron
469
densities
way to the local n-electron
density on the
carbon atom.
+50
+ IO
53
t2
s
x !!?
0 +-I
IO
-
c E -B
0
t E v)
I0
-30 -1
< 2 3 3 t
-2
0.9
0.9
1.1.
1.0
I.2
FIG. 1. The slope of the averaged lines factors,
SC13 = 160,~ and Bhl = 10.6~.
deviation *
in Fig. 1 yields
of the individual
the proportionality
In both cases,
points from the linear
however, the
correlation
line exceeds
A value of 160 p.p.m. per electron has also been deduced from Cl’ shifts by Lauterbur (private communication) by an indirect pror
470
The determination
the experimental
error
deviations
slightly
in the {different
resonance ponding
is not immediately
cyclic
nor is there coupling
ring
of the carbon shifts.
However, olefins
hybridization
and the consequent
1) reveals
The latter
in bond
to contribute
to the
no discernable
of the correstrend
in the magnitudes
with ring
size,
of the C-H spin-
have been shown to reflect
changes
in bond
compounds. 4,5
in other
Table C13 Chemical
Relative
varies
changes
of the C13 shifts
examination
explanation
The bond angle
may be expected
pattern
N0.U
A satisfactory
apparent.
systems
orbitals
(Table
any consistent
constants.
densities
of the B-measurements.
of these
hybridization
of a-electron
1
Shifts
of CH Groups in Olefinic
and Aromatic
Compounds -r-
SC13 Compound
JCH (C/S)
(p.p.m. relative to benzene)
Cyclooctatetraene
-4.1
155
Cycloheptatriene
-2.9,1.3,7.6
156,154,161
1,3_Cyclohexadien$
2.4 -4.2
163
Cyclopentadien
&
-9.5
158
42.5
145
-27.6
171
Rutadien& Cyclooctatetraene Tropylium
dianion
ion
Cyclopentadienyl
170
157
25.7
anion
L
a Two broad doublets p No resolved E Terminal Subject employed
shift
CH2 (1,4
to these
to evaluate
4 J.N.
Shoolery,
5 N. Muller
unresolved between
position
positions),
limitations the
local
2 and 3
tll.5
p.p.m.
the calibration n-electron
d.Chem.Phvs.
and D.E. Pritchard,
&,
plots
densities 47
of Fig.
of other
aromatic
(1959).
J.Chem.Phvs.
2,
1 may be
768 (1959).
systems.
-8.9 4.6 -8.9
498
597
6
Q13
JCH 183 165 158 161 158
7.5 -7.7 4.2 -8.6
(c/s)
-5.9
Corr *a
-0.170
iD.280
-0.945
-0.067
-0.583
Meas.
-0.03
+0.48
-0.34
+0.58
-0.23
c0rr.a
oH1
0.997
1.045
0.968
1.055
0.978
1112 (1956).
d R.D. Brown and M.L. Heffernan,Aust.J.Chem.2,
E A. Julg, J.Chim.Phvs.I;i,377 (1955).
b R. Pariser,J.Chem.Phvs.g,
38 (1960).
P
0.938 1.042
0.879 1.049 0.948 1.013
0.967 1.041 0.962
1.034
0.908
1.049
1.096
1.061
0.997
’
0.998
0.%9
1.011
0.954
1.059
0.988
Heffernan
Brow&
calculated Jul$
0.979
Parises
0.977
derived from 6$3
6Hl
P
a Corrected for shift due to ring current of neighbourring.
9.10
8.8
-6.7
Meas.
3,1
2
Posit- L ion
(Chemicalshifts in p.p.m. relative to benzene)
Cl3 and Hl Chemical Shifts and n-ElectronDensities of Azulene
Table 2
The determination
4772 Table
2
shows the results
hydrocarbon,
authors
and H’ shifts,
ring
values, 7
approximation. to be about derived
occurs
ently
resolved
in the azulene
molecule,
shown in Table
2,
being
relaxation
shift
carried
out on 2-3
cation,
which was measured
in the carbonyl
Cl3 resonance
shifts
The H’ resonance cyclohexane,
6
7
molar
solutions
for
these
The
roughly
was not
estimated
deviation independ-
no satisfactory
positions,
particular
dipole
the values
The largest
So far
of
a simple
between
which may be
nuclei.
in tetrahydrofuran,
as tropylium
fluoroborate
hydrolysis.
This
point
systems
were
Dimethylcarbonate
in a saturated
solution
in a 5 mole $ solution
signal
serving
of
benzene
to be converted
as an internal in cyclohexane
relative
tropylium
in aqueous
were measured
were measured
ring
except
reference.
shifts
shifts
the aromatic
as an external
the solvent
all
of
group was used
a 5 mole % solution
permitted
signals.
the 9,lO
measurements
some -IBF to prevent 4
containing
ment of
times
is
13
investigated.
The Cl3 resonance
$3
values
the Cl3 signal
by other
C
circulation
by employing
final
reported
The relative
current
correspondence
for
values
and must be corrected.
which
have been obtained
the non-alternant density
from the H1 and Cl3 resonances.
and was overlapped
due to unfavorable
by ring
of the
for
NO.L$
columns.
were obtained
accuracy
at the 6-position,
signals
manner for
three
15%. There is a very close
(-&)
is
last
influenced
The overall
densities
the calculated
are
independently
resonance
in this
are shown in the
as measured,
the neighbor corrected
obtained
For comparison
azulene.6
by several
of n-electron
solution enriched
in
The azulene of
azuIene
in CS 2’
of azulene
in
reference. in a similar
Measuremanner
to benzene.
The Cl3 resonance shifts of azulene have recently been reported by bauterbur [J.Amer.Chem.Soc. a, 1838 (1961)] and correlated with the theoretically calculated charge densities in azulene. J.A. Pople, W.G. Schneider Maanetic Resonance p. 254.
and H.J. Bernstein, Hiah Resolution McGraw-Hill, New York (1959).
Nuclear