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Long-range deuterium isotope effects in 13C NMR spectra of adamantane and 2-adamatanone
Journal of MolecularStructure, 267 (1992) 389-394 Elsevier Science Publishers B.V., Amsterdam
389
LONG-RANGE DEUTERIUM ISOTOPE EFFECTS IN 1% NMR SPECI’RA OF ADAMANTANE AND 2ADAMANTANONE
K. MLINARIhlAJERSKI,
V. VINKOVIC AND Z. ME16
Rudjer BoSkoviCInstitute,POB 1016,410Ol Zagreb, Croatia, Yugoslavia
P.G. GASSMAN AND L.J. CHYALL
Universityof Minnesota, Minneapolis, Minnesota 55455, USA
The availability of high field NMR instrumentation effects
(DIE)
knowledge mechanisms 2A
on carbon-13
chemical
of the dependence for transmittal
DIE on carbon-13
shifts (nA ) to receive
of DIE on chemical structure
molecules
in a few saturated
have been
to originate
explained
in molecular
from the
Long-range
conformations
and
effects of
systems. 3-5 DIE which are observed
by changes
1~
dependent
electron-releasing
that is other than through-bond.3l4
and the
Intrinsic
In contrast, 3~ effects appear to be orientation
or through a mechanism
isotope
study. Our
is still incomplete
shifts are well known and are believed
and their origin may be associated with either through-bond
have been observed
continued
of these effects are not fully understood.’
inductive effect of deuterium?
deuterium
has allowed deuterium
DIE
in flexible
which cause
secondary shifts over long distances.5 In this paper
we report long-range
spectra of adamantane
DIE through five bonds (5A ) in the r3C NMR
and 2-adamantanone.
We believe this to be the first example of a
5~ effect observed in a rigid saturated system. The
‘A
T2A ,3A ,4 A ,
shifts were determined
0022-2880/92/$05.00
and 5~ deuterium
for five monodeuterated
isotope effects in carbon-13 2-adamantanone
isotopomers
0 1992 Elsevier Science Publishers B.V. All rights reserved
chemical (1-S) and
390 for two dideuterated monodeuterated
Zadamantanone
adamantane
isotopomers
isotopomers
(6, 7), as well as for the two
availability of the dideuterated derivatives 6, 7, and 10 permitted additivity of the deuterium
1
(10). The
(8, 9) and for adamantane-2,242
us to evaluate
the
isotope effect on NMR shifts.
2
ff& f$$. D ‘D
Aydin
and
monodeuterated
Gunther
adamantanes
our measurements deuteriochloroform
nondeuterated
have
previously
reported
the
and nondeuterated
as the solvent, we were able to observe the as chemical
shifts of the carbon
Carbon-deuterium
the same solutions. At least three measurements The results of this study are listed in Table 1.
5~
resonances
relative to the chemical shifts of the corresponding compounds.
spectra
of
the
two
8 and 9,6 but failed to indicate any 5~ effect. By making
on a 3:l mixture of the deuterated
effects were measured compounds
10
7
6
adamantanes
effect. All isotope of the deuterated
carbon resonances
coupling constants were performed
in
were observed
of the using
for each isotopomer.
co.451
-22 tunres1 28 C(6)
LO.351
25 (C3)
to.01
27 (C5.7)
to.61
3A
t2J(13CD)1
~3)
(C5)
(~2)
(C4.9)
(C1.3)
t1.11
tunres1
(C3)
at 75.462 MHz. Values are given in ppb, digital resolution
0 (C2)
2.5
2 0.8 ppb.
5 (ca)
0 (C7)
0 (Cl)
(C’O)
Cl -25.1
+ 0.062 Hz. For 4A and 5A the coupling constants were zero or too small to permit resolution.
13C NMR spectra were recorded
2.5
2.5
(Ca)
0 (c7)
4 (C7) (Ca)
-20 5 (ca,lo)
4 (Cl)
0 (Cl)
0 (c6)
Cl.11
0 (Cl)
44
Il.251 13 (C’O)
(CIO)
(C9)
ktllreS1
61
tD.951
41 (C6)
32
(C9)
[unresl
(ca.9)
(C2)
kBW?Sl
-30
cunreS.1
II
El .‘I
32 (C4.10)
(C6)
0 C(2)
0 (C1,3)
tlKlWS1
43(c4,a,9,1D)
tli?l~~Sl
194 (C5.7)
0.2528
c19.41
a50
7 (Cl)
(c2.8.9)
(C3,5,7)
0 (C4,6,10)
co.91
32
co.51
128
0.2632
t2D.21
514
8
(~1.3)
4 (C6)
3 (C7)
0 (CS)
Cl.11
31 (ca.10)
~t8W~Sl
13 (C4.9)
to.51
loo
0.2515
t19.31
(C2)
9
s(i), of
440
(Hz)~ and the fractional s-character,
(C5)
wnres1
194
klnres1
170 (C3)
0.2593
34
(C2)
(C5.7)
0.lll~~Sl
97
0.2541
(~4)
c19.91
781
6
[I .I1 to.91
0%)
t19.51
424
5
(l-10).
27 (C9)
29 (C7)
LO.91
33
co.51
124 (C6)
co.41
119
0.2658
12 (C6)
10.71
-a
to.41
95
CO.61
a5
(CS)
C20.41
475
4
D (C4.10)
bDigitat resolution
%e
5A
4A
‘DO (C5)
122 (ca.9)
(C2)
CD.41
to.91
(C3)
a6
-41
(C2)
0.2606
0.2580
0.2750
(~4)
S(i)
389 c20.01
(~4)
tl9.81
389
c21.11
(Cl)
431
3
t’J(13CD)1
2
‘A
1
and 2-adamantanone
NMR isotope shifts (“A )a, the corresponding coupling constants
the 13CD-bond of deuterated adamantane
Deuterium-induced
Table 1
(C2)
(C1,3)
10 K6)
3 (C5.7)
to.651
46w4,a,9,10)
co.451
200
0.2515
119.31
aa3
10
392
Long-range
5~ effects were observed in the 1% NMR spectra of 2, 3, 6, 9 and
10.For both axial and equatorial
2-adamantanone-4dl
2 and 3, a 5~ effect of 2.5 ppb
was observed at C8. The additivity of these 5~ effects was demonstrated of 2-adamantanone-4,4d2 three compounds
(6) which showed an effect of 5 ppb. The 5A effect in these
were smaller in magnitude
10 (10 ppb). Experimentally,
than the related 5A effect in 9 (4 ppb) and
it is observed
that the presence
resulted in a decrease of the 5A isotope effect. Examination demonstrated
that
adamantane
the
introduction
skeleton
Presumably,
resulted
of an
of the
of the carbonyl
of molecular
sp2-hybridized
in a distortion
carbon structure
group
models clearly atom
into
the
of adamantane.
this structural distortion results in a decrease in the 5~ effect.
In general, it is observed 5A effects. The occurrence
across the adamantyl
E -carbon
4A DIE are similar or smaller in magnitude
electrons.
The observation
cage7 provides ample precedent
effect. In general
observation
that
of 5~ effects can be explained by a through-space
of the C-D dipole and the
isotope
by examination
is associated
-20 ppb was observed.
4~
effects range
interaction
of substituent
for this through-space
to
effects
deuterium
from O-5 ppb. The exception
to this
with C2 in compound 4 where an unusually large 4, effect of
Although
the carbonyl group is separated
from the deuterated
carbon in 4 by four bonds, the shift is at least four times as large as that observed for any other 4-bond
separation.
Again, examination and
n-orbital
Thus, a simple through-space
of the appropriate
of the carbonyl
“hyperconjugative”
interaction
group
molecular are
interaction
model indicated
aligned
in a manner
is unlikely that
for 4.
the C-D bond
which
permits
a
through the C3-C4 and Cl-C9 bonds.
The results listed in Table 1 illustrate the additivity of the 1~ -4~ DIE, as well as the geometrical
dependence
of the 3~
effects observed for compound compounds
and 4~ isotope effects. While examination
6 illustrates
the fairly rigorous additivity of the DIE for
2 and 3, it should be noted that the orientation
the carbonyl results in substantial
of the
of the deuterium
relative to
differences in the 3~ effects. To a first approximation,
393
the deuteriums membered
in 2 and 3 can be viewed as axial and equatorial
on a six-
ring, respectively.’
An additional dependence
feature
of our results is the demonstration
that an S-character
exists for the 1~ chemical shifts in the 1% NMR spectra for compounds
closely related structure, correlation methine
substituents
is observed
as was noted earlier, by Gunther for the
and methylene
correlations
are illustrated
1~
and co-workers.8
values and s-character
of
This useful
of the C-D hybrid for the
carbons of 1, 4, and 8 and of 2,3, 5 and 9, respectively.
These
in Figure 1.
‘A [ppbl
0.25
0.27
0.26
0.28
s (0
Figure 1. Correlation
between IA (1%) and fractional s-character9
of
8,
1 and 4
(A) and 9, 3, 2 and 5 (B).
In summary, we have illustrated that significant
5~ deuterium
isotope effects exist
in certain types of rigid molecules.
Acknowledgment.This work was supported by a grant from the Ministry of Science and Technology of the Republic of Croatia and by the National Science Foundation of the United States.
394
REFERENCES
For recent reviews see: P.E. Hansen, Jameson
Ann. Rep. NMR Spectr.
15 (1983) 105; C.J.
and H.J. Osten, Ann. Rep. NMR Spectr. 17 (1986) 1; P.E. Hansen,
NMR Spectr.
20 (1988) 207; S. Berger, “Isotope
Prog.
Effects in NMR Spectroscopy”,
Springer Verlag, 1990, chapter 1. H.S. Gutowsky,
J. Chem. Phys. 31 (1959) 1683; C.J. Jameson,
J. Chem.
Phys. 66
(1977) 4983; W.T. Raynes, Nucl. Magn. Reson. 8 (1979) 12. Z. Majerski, M. &.taniC and B. Metelko, J. Am. Chem. Sot. 107 (1985) 1721.
R. Aydin, W. Frankmolle,
D. Schmalz and H. Gunther,
Magn. Reson.
Chem. 26
(1988) 408. R. Aydin and H. Gunther, E. Lippmaa,
J. Am. Chem. Sot. 103 (1981) 1301; T. Pehk, A. Laht and
Org. Magn. Res. 19 (1982) 21; D. Jeremic, S. Milosavljevic
Mihailovic,
Tetrahedron
38 (1982)
3325; S. Milosavljevic,
and M.Lj.
D. JeremiC,
Mihailovic and F.W. Wehrli, Org. Magn. Reson. 17 (1981) 299; G.C. Andrews,
M.Lj. G.N.
Chmurny and E.B. Whipple, Org. Magn. Reson. 15 (1981) 324. R. Aydin and H. Gunther, H. Duddeck Feuerhelm,
Z. Naturforsch.
34B (1979) 528.
and P. Wolff, Org. Magn. Res. 9 (1977) 528; H. Duddeck Tetrahedron
J.R. Wesener,
36 (1980) 3009.
D. Moskau and H. Gunther, J. Am. Chem. Sot. 107 (1985) 7307.
s(i) was calculated Muller-Pritchard
and H.-T.
from the one-bond
13C-D coupling
constant
by the modified
relation: s(i) = 6.5144 1J(13CD)/500. N. Muller and D.E. Pritchard,
J. Chem. Phys. 31(1959) 768,147l.
389
LONG-RANGE DEUTERIUM ISOTOPE EFFECTS IN 1% NMR SPECI’RA OF ADAMANTANE AND 2ADAMANTANONE
K. MLINARIhlAJERSKI,
V. VINKOVIC AND Z. ME16
Rudjer BoSkoviCInstitute,POB 1016,410Ol Zagreb, Croatia, Yugoslavia
P.G. GASSMAN AND L.J. CHYALL
Universityof Minnesota, Minneapolis, Minnesota 55455, USA
The availability of high field NMR instrumentation effects
(DIE)
knowledge mechanisms 2A
on carbon-13
chemical
of the dependence for transmittal
DIE on carbon-13
shifts (nA ) to receive
of DIE on chemical structure
molecules
in a few saturated
have been
to originate
explained
in molecular
from the
Long-range
conformations
and
effects of
systems. 3-5 DIE which are observed
by changes
1~
dependent
electron-releasing
that is other than through-bond.3l4
and the
Intrinsic
In contrast, 3~ effects appear to be orientation
or through a mechanism
isotope
study. Our
is still incomplete
shifts are well known and are believed
and their origin may be associated with either through-bond
have been observed
continued
of these effects are not fully understood.’
inductive effect of deuterium?
deuterium
has allowed deuterium
DIE
in flexible
which cause
secondary shifts over long distances.5 In this paper
we report long-range
spectra of adamantane
DIE through five bonds (5A ) in the r3C NMR
and 2-adamantanone.
We believe this to be the first example of a
5~ effect observed in a rigid saturated system. The
‘A
T2A ,3A ,4 A ,
shifts were determined
0022-2880/92/$05.00
and 5~ deuterium
for five monodeuterated
isotope effects in carbon-13 2-adamantanone
isotopomers
0 1992 Elsevier Science Publishers B.V. All rights reserved
chemical (1-S) and
390 for two dideuterated monodeuterated
Zadamantanone
adamantane
isotopomers
isotopomers
(6, 7), as well as for the two
availability of the dideuterated derivatives 6, 7, and 10 permitted additivity of the deuterium
1
(10). The
(8, 9) and for adamantane-2,242
us to evaluate
the
isotope effect on NMR shifts.
2
ff& f$$. D ‘D
Aydin
and
monodeuterated
Gunther
adamantanes
our measurements deuteriochloroform
nondeuterated
have
previously
reported
the
and nondeuterated
as the solvent, we were able to observe the as chemical
shifts of the carbon
Carbon-deuterium
the same solutions. At least three measurements The results of this study are listed in Table 1.
5~
resonances
relative to the chemical shifts of the corresponding compounds.
spectra
of
the
two
8 and 9,6 but failed to indicate any 5~ effect. By making
on a 3:l mixture of the deuterated
effects were measured compounds
10
7
6
adamantanes
effect. All isotope of the deuterated
carbon resonances
coupling constants were performed
in
were observed
of the using
for each isotopomer.
co.451
-22 tunres1 28 C(6)
LO.351
25 (C3)
to.01
27 (C5.7)
to.61
3A
t2J(13CD)1
~3)
(C5)
(~2)
(C4.9)
(C1.3)
t1.11
tunres1
(C3)
at 75.462 MHz. Values are given in ppb, digital resolution
0 (C2)
2.5
2 0.8 ppb.
5 (ca)
0 (C7)
0 (Cl)
(C’O)
Cl -25.1
+ 0.062 Hz. For 4A and 5A the coupling constants were zero or too small to permit resolution.
13C NMR spectra were recorded
2.5
2.5
(Ca)
0 (c7)
4 (C7) (Ca)
-20 5 (ca,lo)
4 (Cl)
0 (Cl)
0 (c6)
Cl.11
0 (Cl)
44
Il.251 13 (C’O)
(CIO)
(C9)
ktllreS1
61
tD.951
41 (C6)
32
(C9)
[unresl
(ca.9)
(C2)
kBW?Sl
-30
cunreS.1
II
El .‘I
32 (C4.10)
(C6)
0 C(2)
0 (C1,3)
tlKlWS1
43(c4,a,9,1D)
tli?l~~Sl
194 (C5.7)
0.2528
c19.41
a50
7 (Cl)
(c2.8.9)
(C3,5,7)
0 (C4,6,10)
co.91
32
co.51
128
0.2632
t2D.21
514
8
(~1.3)
4 (C6)
3 (C7)
0 (CS)
Cl.11
31 (ca.10)
~t8W~Sl
13 (C4.9)
to.51
loo
0.2515
t19.31
(C2)
9
s(i), of
440
(Hz)~ and the fractional s-character,
(C5)
wnres1
194
klnres1
170 (C3)
0.2593
34
(C2)
(C5.7)
0.lll~~Sl
97
0.2541
(~4)
c19.91
781
6
[I .I1 to.91
0%)
t19.51
424
5
(l-10).
27 (C9)
29 (C7)
LO.91
33
co.51
124 (C6)
co.41
119
0.2658
12 (C6)
10.71
-a
to.41
95
CO.61
a5
(CS)
C20.41
475
4
D (C4.10)
bDigitat resolution
%e
5A
4A
‘DO (C5)
122 (ca.9)
(C2)
CD.41
to.91
(C3)
a6
-41
(C2)
0.2606
0.2580
0.2750
(~4)
S(i)
389 c20.01
(~4)
tl9.81
389
c21.11
(Cl)
431
3
t’J(13CD)1
2
‘A
1
and 2-adamantanone
NMR isotope shifts (“A )a, the corresponding coupling constants
the 13CD-bond of deuterated adamantane
Deuterium-induced
Table 1
(C2)
(C1,3)
10 K6)
3 (C5.7)
to.651
46w4,a,9,10)
co.451
200
0.2515
119.31
aa3
10
392
Long-range
5~ effects were observed in the 1% NMR spectra of 2, 3, 6, 9 and
10.For both axial and equatorial
2-adamantanone-4dl
2 and 3, a 5~ effect of 2.5 ppb
was observed at C8. The additivity of these 5~ effects was demonstrated of 2-adamantanone-4,4d2 three compounds
(6) which showed an effect of 5 ppb. The 5A effect in these
were smaller in magnitude
10 (10 ppb). Experimentally,
than the related 5A effect in 9 (4 ppb) and
it is observed
that the presence
resulted in a decrease of the 5A isotope effect. Examination demonstrated
that
adamantane
the
introduction
skeleton
Presumably,
resulted
of an
of the
of the carbonyl
of molecular
sp2-hybridized
in a distortion
carbon structure
group
models clearly atom
into
the
of adamantane.
this structural distortion results in a decrease in the 5~ effect.
In general, it is observed 5A effects. The occurrence
across the adamantyl
E -carbon
4A DIE are similar or smaller in magnitude
electrons.
The observation
cage7 provides ample precedent
effect. In general
observation
that
of 5~ effects can be explained by a through-space
of the C-D dipole and the
isotope
by examination
is associated
-20 ppb was observed.
4~
effects range
interaction
of substituent
for this through-space
to
effects
deuterium
from O-5 ppb. The exception
to this
with C2 in compound 4 where an unusually large 4, effect of
Although
the carbonyl group is separated
from the deuterated
carbon in 4 by four bonds, the shift is at least four times as large as that observed for any other 4-bond
separation.
Again, examination and
n-orbital
Thus, a simple through-space
of the appropriate
of the carbonyl
“hyperconjugative”
interaction
group
molecular are
interaction
model indicated
aligned
in a manner
is unlikely that
for 4.
the C-D bond
which
permits
a
through the C3-C4 and Cl-C9 bonds.
The results listed in Table 1 illustrate the additivity of the 1~ -4~ DIE, as well as the geometrical
dependence
of the 3~
effects observed for compound compounds
and 4~ isotope effects. While examination
6 illustrates
the fairly rigorous additivity of the DIE for
2 and 3, it should be noted that the orientation
the carbonyl results in substantial
of the
of the deuterium
relative to
differences in the 3~ effects. To a first approximation,
393
the deuteriums membered
in 2 and 3 can be viewed as axial and equatorial
on a six-
ring, respectively.’
An additional dependence
feature
of our results is the demonstration
that an S-character
exists for the 1~ chemical shifts in the 1% NMR spectra for compounds
closely related structure, correlation methine
substituents
is observed
as was noted earlier, by Gunther for the
and methylene
correlations
are illustrated
1~
and co-workers.8
values and s-character
of
This useful
of the C-D hybrid for the
carbons of 1, 4, and 8 and of 2,3, 5 and 9, respectively.
These
in Figure 1.
‘A [ppbl
0.25
0.27
0.26
0.28
s (0
Figure 1. Correlation
between IA (1%) and fractional s-character9
of
8,
1 and 4
(A) and 9, 3, 2 and 5 (B).
In summary, we have illustrated that significant
5~ deuterium
isotope effects exist
in certain types of rigid molecules.
Acknowledgment.This work was supported by a grant from the Ministry of Science and Technology of the Republic of Croatia and by the National Science Foundation of the United States.
394
REFERENCES
For recent reviews see: P.E. Hansen, Jameson
Ann. Rep. NMR Spectr.
15 (1983) 105; C.J.
and H.J. Osten, Ann. Rep. NMR Spectr. 17 (1986) 1; P.E. Hansen,
NMR Spectr.
20 (1988) 207; S. Berger, “Isotope
Prog.
Effects in NMR Spectroscopy”,
Springer Verlag, 1990, chapter 1. H.S. Gutowsky,
J. Chem. Phys. 31 (1959) 1683; C.J. Jameson,
J. Chem.
Phys. 66
(1977) 4983; W.T. Raynes, Nucl. Magn. Reson. 8 (1979) 12. Z. Majerski, M. &.taniC and B. Metelko, J. Am. Chem. Sot. 107 (1985) 1721.
R. Aydin, W. Frankmolle,
D. Schmalz and H. Gunther,
Magn. Reson.
Chem. 26
(1988) 408. R. Aydin and H. Gunther, E. Lippmaa,
J. Am. Chem. Sot. 103 (1981) 1301; T. Pehk, A. Laht and
Org. Magn. Res. 19 (1982) 21; D. Jeremic, S. Milosavljevic
Mihailovic,
Tetrahedron
38 (1982)
3325; S. Milosavljevic,
and M.Lj.
D. JeremiC,
Mihailovic and F.W. Wehrli, Org. Magn. Reson. 17 (1981) 299; G.C. Andrews,
M.Lj. G.N.
Chmurny and E.B. Whipple, Org. Magn. Reson. 15 (1981) 324. R. Aydin and H. Gunther, H. Duddeck Feuerhelm,
Z. Naturforsch.
34B (1979) 528.
and P. Wolff, Org. Magn. Res. 9 (1977) 528; H. Duddeck Tetrahedron
J.R. Wesener,
36 (1980) 3009.
D. Moskau and H. Gunther, J. Am. Chem. Sot. 107 (1985) 7307.
s(i) was calculated Muller-Pritchard
and H.-T.
from the one-bond
13C-D coupling
constant
by the modified
relation: s(i) = 6.5144 1J(13CD)/500. N. Muller and D.E. Pritchard,
J. Chem. Phys. 31(1959) 768,147l.