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Synthesis and tautomerism of persubstituted 1,3-dianils, and substituent rotation in their chiral nickel complexes
Tetrahedron Letters No. 5, pP 459-462, 1977.
SYNTHESIS AND
AND
TAUTOMERISM
SUBSTITUENT Rudolf
Institut
IN THEIR
Alfons
fiir Organische Karlstr.
Rinted in Great Britain.
OF PERSUBSTITUTED
ROTATION
Enorr,*
Pergsmn Press.
CHIRAL
WeiD,
Chemie
23, D-8000
1,3-DIANILS,
NICICEL COMPLEXES
and Heinz
Polzer
der UniversitPt
Miinchen
Miinchen 2, Germany
(Received 30 November 1976; received for publication 6 Jaaaary 1977) Whereas
malondianils
dialdehydes
be synthesized tion"3
from
takes
ents.
Therefore,
tion,
based
the primary is added
product
after
hydrolysis or may avoid
ca.
with
its
trans
The
liquid,
and
75$ s
coupling
as well
groin
employed
in CC14)
from
E
We performed lysis;
Yields
a structural
lation
normally
was
authentic not
substitu-
for
whereas
ppm,
?&
@
I-propanol were
follow
ppm,
After
70°C
symmetry in CC14.
to
of 2546 Lg 2
Because
atb = 7.70 (NH 3.72
(CH 3.57
Crystallization
equilibrium
of the
characterized
and NH resonance
(NH 12.5 ppm).
CH3Li
or distilled below
the
6 = 14 ppm'
60s
acid
Since
26-96s.
from
consists
The
is evolved.
is crystallized
contains
(NH 5.40
hours.
of 2, more
methane
or
stochio-
of the imidic
(E)-configuration
= 12 Hz9
with
two hours.)
for 40-80
regeneration
ara;out the
s/z
for
no more
of 0.2
of methyllithium
be refluxed
one equivalent
6a-e
by addition
instantaneously,
atmosphere
(in ethanol
J(R2,R3)
by ppm.
ppm)
ppm,
t with
from
concentration
li85%
1546).
proof
7146 of dipivaloyl-methane with
cyclization4
two bulky
the amount
(not optimized)
Kf assumes
to separate (CH 5.03
and
the dianil
pure lo mixture,g/a
ppm),
begin
2f must
until
work-up,
as the horseshoe
identified
added
with
the NH absorption
constant
of C/N-condensa-
out in ether
not
by 2 with
(Z)-structures
analytically (CH2 3.35
was
in ether
as the perchlorate
and/or
malon-
(Ri + H) cannot
quinoline only
lithio-N,N-diis&opyl-amide
ca. 30 hours
R' substituent,
J P 7 Hz)
are
or Cl) in an inert
formation4).
spectrum
of its bulky
does
7 is deprotonated
The horseshoe-shaped 'H nmr
2 is carried
of methane
ice and basic
be purified quinoline
methods
for 5g with
(Pinacolone-anil
15 and
5
synthetic method with C/C-condensa6 5 by Marekov, Stork, and Wittig. 7
heated
(X = OC2H5
2
substituted
a different
of pre-formed
salt 2 is then
derivative
from
1,3-dianils
the Beyer-Combea
even
of N,N-diisopropyl-amine
amounts
lithium
5,
is true
work
increased.
accessible
acyclic
1. If conventional
of azomethines
If evolution
correspondingly metric
This
we designed
on previous
equivalents
easily
to nmono-anilsn
place.
deprotonation
methyllithium.
are
persubstituted
1,3-diketones
are applied
invariably
The
like &
?_ (R1=R3=H),
of C/C-condensation lg were
specimens.
The
observed. 459
isolated alternate
for
7/8g by acid
as the cip&r possibility
complex
hydroand
of N-iminoalky-
No. 5
P’
R2 R3
R'
0
II \Hp
Ph
Ld
/N
0 R’\c/CH
+CH3Li
>
II
-CH/+
cs
1 R2
2
H R2
//
R3
/,
R3
R’
> PhHN
a
H
b
/\ 8 / CH3 23
126-128
Ii
1-1
CH3
8\/
CH3
CH3
SCgH5
CH3
(CH2)G
112-113
H
H
=4H9
H
tc4H9
86s
with
C2H5
nC3H7
cH3
‘6”5
=4H9
CH
c6H5
*C4H9
fully
yields
from
the
in THP
with
hexane
aipitation
with
ethanol
Projecting
ligands 2
(e)
B configuration.
3
102-103.5
1,3-dianils
[(C2H5)4N]2NiBr4
symmetrical
[140/10’3
11
paramagnetic
extraotion
with
98-99.5
nC3H7
Tetrahedral,
H‘N\Ph
CH3
tc4B9
3
N\Ph
($)
\
CH3
R3
Li@
PhAN
?
X\C/
(jg
93-95
nickel
complexes
by treatment
for
or benzene,
.
12-86
hours
with under
,9 crystallize8
*
2 10
2 were
methyllithium 12 After N2. from
dry
prepared
in 0 -
and heating evaporation and
ethyl
acetate
(pre-
We select here cases 9a, Et and 2 with if necessary). 13914 ) for a study of substituent rotation. chirality along the axis C3Ni.C3' from the right, one obtains Jl_
(axial 14
The
cyclohexenyl
double
bonds
are
symbolised
by two
No. 5
461
9a 12, s
11, R
one above
wedges
4,
(rear)
chelate
hydrogen) one for
we 4
expect due
lohexenyl will
Since
nickel
may
of the anilino
(C12CD)29
in reasonable
with
Due AG+
having
0
(2)
one
to the left
of the vertical
q
axis
(C,). Rotations
z
ligand
with
more
interchanged
than
be obtained
in E.
agreement
similar
with
the a/b We find barriers
methyl/hydrogen
repulsions, in
23 kcal/mol, from
moieties
nmr
by
as a whole
coalescence AG* for
repulsions
the relevant
nickel
cyc-
inver-
chemical shifts a and b. 13 the smaller barrier of
non-equivalences
(C12CD)2;
180~ of the rear (i.e.,
of the p-hydro-
= 16 kcal/mol
(320 K)
2,2'-dimethyl-biphenyl in a planar
transition
in IJ disappear J values"
(ppm)
at 240K are
shown
= 2-H and 4-H. 16 l-phenyl-naphthalene whose rotatiofor the non-planar 17 Enantiomeriaation requires AG* = 15.2 kcal/mol at ia unknown.
is a model
nal barrier K in
to weaker
= 9.8 kcal/mol
12 for
351
needs
signals
state.
e
symmetry
enantiomer
rotation
and
chemically equivalent groups (CHg or aromatic p1 Ii nmr absorptions (a,b) of equal intensity, but only
or of the rear
inversion
derivatives15
in
two
to the
produce
cyclohexenyl
in
the horizontal For
substituent
sion)
gen
ring.
(C12CD),.
to nitrogen
is n:t
-389
Hindered
rotation
observed
for 2
of the phenyl (e)
-379
groups
but detectable
_
about
for jJ
their
(12;
bonds
AG'
=
462
No.
12.1 kcal/mol mol
at 238 K), 2
(17.7 kcal/mol
(12;
(340 K) found
2
12.8 kcal/
at 253 K).
The highest (C12CD)2 group
barrier
deserves
about
the bond
transition
state
process.
We gratefully
Deutsohe
AG8
special
the latter
and
= 17.4 kcal/mol attentiun.
It could
to C3 or to Inversion therefore
acknowledge
constitutes
support
be due
for
(9d) in
to rotation
of the SC H 65 a linear
of divalent sulfur via 18 another lower energy
by the Stiftung
limit
Volkswagenwerk
for
and
the
Forschungsgemeinschaft.
REFERENCES 1.
G. Scheibe,
2.
Ii. Bredereck,
E, 3.
at 330 I(), and z
5
4036
Ber.Dtsch.Chem.Ges., F. Effenberger,
AND
NOTES
2,
137 (1923).
D. Zeyfang,
and K. A. Hirsch,
Chem.Ber.,
(1968).
S. G. McGeachin,
4.
Compare
5*
N. Marekov
46,
Canad.J.Chem.,
J. M. F. Gagan
and D. Lloyd,
and N. Petsev,
1903
(1968). C, 2488
J.Chem.Soc.
C.R.Acad.Bulgare
Sci.,
2,
(1970).
47
(1960);
ref.
d (1961).
C.A. 2,
8331
6.
0. Stork
and
79
G. Wittig
and I-I.D. Frommeld,
H. Reiff,
Angew.Chem.,
8.
W. J. Barry,
9.
K. Feldmann,
S. R. Dowd,
J.Amer.Chem.Soc.,
2,
Chem.Ber.,
8 (1968);
2, z,
2178 3548
(1963).
(1964);
G. Wittig
Angew.Chem.Int.Ed.Engl.,
I. L. Finar,
and E. F. Mooney,
E. Daltroeso,
and G. Scheibe,
2,
Spectrochim.Acta,
and
7 (1968)
21,
1095
(1965). (1967); 1140
E. Daltroazo
Correct
11.
R. Knorr,
12.
J. E. Parks
13.
R. Knorr,
14.
IDPAC Cabn,
elemental
analyses
H. Polaer,
A. WeiD,
C. Ingold,
W. Theilacker
and R. Hopp,
Angew.Chem.,
E,
79,
E. Rusconi,
H. Keller,
(1967)~
1408
derivatives.
97, 643
(1975).
(1968).-
35,
2849
ET413
in press.
(1970);
(1966);
R. S.
Angew.Chem.
92, 2293
B,
J.C.S.
1551
W.
Theilacker
Faraday
Trans.
II, 2,
g,
Chem.Comm.,
871
D. S. N.
1679
2498
(1972).
(1954);
(1970).
475
and
251
L. Radom,
1 C. L. Cheng,
J.Chem.Soc.,
Tetrahedron, J.C.S.
5,
R. J. W. LeFivre,
(1968)
and E. E. Turner,
and W. Rundel,
(1959);
zgew.Chem.Int.Ed.Engl.,
M. J. Aroney,
J.Chem.Soc.
and M. Simonetta,
A. Rieker,
z,
Angew.Chem.,
Chem.Ber., 232
M. Rabinowitz,
S. Ridgwell,
or the
(1966).
and 0. L. D. Ritchie,
D. M. Hall, Gamba,
511
compounds
J.Amer.Chem.Soc.,
E, m.Chem.,
and V. Prelog,
,5, 385,
Murthy,
18.
722
and E. RLLpple, J.Amer.Chem.Soc.,
Section
Int.Ed.Engl.,
(1967). E. D. Bergmann,
for all
Inorg.Chem.,
H. Polzer,
Rules,
and G. L. D. Ritchie,
17.
obtained
and E. Bischler,
and R. H. Holm,
Tentative
H. BUun,
16.
z,
Z.Naturforsch.,
Ber.Bunsenges.Physik.Chem.,
(1968).
10.
15.
and K. Feldmann,
(1968).
A.
SYNTHESIS AND
AND
TAUTOMERISM
SUBSTITUENT Rudolf
Institut
IN THEIR
Alfons
fiir Organische Karlstr.
Rinted in Great Britain.
OF PERSUBSTITUTED
ROTATION
Enorr,*
Pergsmn Press.
CHIRAL
WeiD,
Chemie
23, D-8000
1,3-DIANILS,
NICICEL COMPLEXES
and Heinz
Polzer
der UniversitPt
Miinchen
Miinchen 2, Germany
(Received 30 November 1976; received for publication 6 Jaaaary 1977) Whereas
malondianils
dialdehydes
be synthesized tion"3
from
takes
ents.
Therefore,
tion,
based
the primary is added
product
after
hydrolysis or may avoid
ca.
with
its
trans
The
liquid,
and
75$ s
coupling
as well
groin
employed
in CC14)
from
E
We performed lysis;
Yields
a structural
lation
normally
was
authentic not
substitu-
for
whereas
ppm,
?&
@
I-propanol were
follow
ppm,
After
70°C
symmetry in CC14.
to
of 2546 Lg 2
Because
atb = 7.70 (NH 3.72
(CH 3.57
Crystallization
equilibrium
of the
characterized
and NH resonance
(NH 12.5 ppm).
CH3Li
or distilled below
the
6 = 14 ppm'
60s
acid
Since
26-96s.
from
consists
The
is evolved.
is crystallized
contains
(NH 5.40
hours.
of 2, more
methane
or
stochio-
of the imidic
(E)-configuration
= 12 Hz9
with
two hours.)
for 40-80
regeneration
ara;out the
s/z
for
no more
of 0.2
of methyllithium
be refluxed
one equivalent
6a-e
by addition
instantaneously,
atmosphere
(in ethanol
J(R2,R3)
by ppm.
ppm)
ppm,
t with
from
concentration
li85%
1546).
proof
7146 of dipivaloyl-methane with
cyclization4
two bulky
the amount
(not optimized)
Kf assumes
to separate (CH 5.03
and
the dianil
pure lo mixture,g/a
ppm),
begin
2f must
until
work-up,
as the horseshoe
identified
added
with
the NH absorption
constant
of C/N-condensa-
out in ether
not
by 2 with
(Z)-structures
analytically (CH2 3.35
was
in ether
as the perchlorate
and/or
malon-
(Ri + H) cannot
quinoline only
lithio-N,N-diis&opyl-amide
ca. 30 hours
R' substituent,
J P 7 Hz)
are
or Cl) in an inert
formation4).
spectrum
of its bulky
does
7 is deprotonated
The horseshoe-shaped 'H nmr
2 is carried
of methane
ice and basic
be purified quinoline
methods
for 5g with
(Pinacolone-anil
15 and
5
synthetic method with C/C-condensa6 5 by Marekov, Stork, and Wittig. 7
heated
(X = OC2H5
2
substituted
a different
of pre-formed
salt 2 is then
derivative
from
1,3-dianils
the Beyer-Combea
even
of N,N-diisopropyl-amine
amounts
lithium
5,
is true
work
increased.
accessible
acyclic
1. If conventional
of azomethines
If evolution
correspondingly metric
This
we designed
on previous
equivalents
easily
to nmono-anilsn
place.
deprotonation
methyllithium.
are
persubstituted
1,3-diketones
are applied
invariably
The
like &
?_ (R1=R3=H),
of C/C-condensation lg were
specimens.
The
observed. 459
isolated alternate
for
7/8g by acid
as the cip&r possibility
complex
hydroand
of N-iminoalky-
No. 5
P’
R2 R3
R'
0
II \Hp
Ph
Ld
/N
0 R’\c/CH
+CH3Li
>
II
-CH/+
cs
1 R2
2
H R2
//
R3
/,
R3
R’
> PhHN
a
H
b
/\ 8 / CH3 23
126-128
Ii
1-1
CH3
8\/
CH3
CH3
SCgH5
CH3
(CH2)G
112-113
H
H
=4H9
H
tc4H9
86s
with
C2H5
nC3H7
cH3
‘6”5
=4H9
CH
c6H5
*C4H9
fully
yields
from
the
in THP
with
hexane
aipitation
with
ethanol
Projecting
ligands 2
(e)
B configuration.
3
102-103.5
1,3-dianils
[(C2H5)4N]2NiBr4
symmetrical
[140/10’3
11
paramagnetic
extraotion
with
98-99.5
nC3H7
Tetrahedral,
H‘N\Ph
CH3
tc4B9
3
N\Ph
($)
\
CH3
R3
Li@
PhAN
?
X\C/
(jg
93-95
nickel
complexes
by treatment
for
or benzene,
.
12-86
hours
with under
,9 crystallize8
*
2 10
2 were
methyllithium 12 After N2. from
dry
prepared
in 0 -
and heating evaporation and
ethyl
acetate
(pre-
We select here cases 9a, Et and 2 with if necessary). 13914 ) for a study of substituent rotation. chirality along the axis C3Ni.C3' from the right, one obtains Jl_
(axial 14
The
cyclohexenyl
double
bonds
are
symbolised
by two
No. 5
461
9a 12, s
11, R
one above
wedges
4,
(rear)
chelate
hydrogen) one for
we 4
expect due
lohexenyl will
Since
nickel
may
of the anilino
(C12CD)29
in reasonable
with
Due AG+
having
0
(2)
one
to the left
of the vertical
q
axis
(C,). Rotations
z
ligand
with
more
interchanged
than
be obtained
in E.
agreement
similar
with
the a/b We find barriers
methyl/hydrogen
repulsions, in
23 kcal/mol, from
moieties
nmr
by
as a whole
coalescence AG* for
repulsions
the relevant
nickel
cyc-
inver-
chemical shifts a and b. 13 the smaller barrier of
non-equivalences
(C12CD)2;
180~ of the rear (i.e.,
of the p-hydro-
= 16 kcal/mol
(320 K)
2,2'-dimethyl-biphenyl in a planar
transition
in IJ disappear J values"
(ppm)
at 240K are
shown
= 2-H and 4-H. 16 l-phenyl-naphthalene whose rotatiofor the non-planar 17 Enantiomeriaation requires AG* = 15.2 kcal/mol at ia unknown.
is a model
nal barrier K in
to weaker
= 9.8 kcal/mol
12 for
351
needs
signals
state.
e
symmetry
enantiomer
rotation
and
chemically equivalent groups (CHg or aromatic p1 Ii nmr absorptions (a,b) of equal intensity, but only
or of the rear
inversion
derivatives15
in
two
to the
produce
cyclohexenyl
in
the horizontal For
substituent
sion)
gen
ring.
(C12CD),.
to nitrogen
is n:t
-389
Hindered
rotation
observed
for 2
of the phenyl (e)
-379
groups
but detectable
_
about
for jJ
their
(12;
bonds
AG'
=
462
No.
12.1 kcal/mol mol
at 238 K), 2
(17.7 kcal/mol
(12;
(340 K) found
2
12.8 kcal/
at 253 K).
The highest (C12CD)2 group
barrier
deserves
about
the bond
transition
state
process.
We gratefully
Deutsohe
AG8
special
the latter
and
= 17.4 kcal/mol attentiun.
It could
to C3 or to Inversion therefore
acknowledge
constitutes
support
be due
for
(9d) in
to rotation
of the SC H 65 a linear
of divalent sulfur via 18 another lower energy
by the Stiftung
limit
Volkswagenwerk
for
and
the
Forschungsgemeinschaft.
REFERENCES 1.
G. Scheibe,
2.
Ii. Bredereck,
E, 3.
at 330 I(), and z
5
4036
Ber.Dtsch.Chem.Ges., F. Effenberger,
AND
NOTES
2,
137 (1923).
D. Zeyfang,
and K. A. Hirsch,
Chem.Ber.,
(1968).
S. G. McGeachin,
4.
Compare
5*
N. Marekov
46,
Canad.J.Chem.,
J. M. F. Gagan
and D. Lloyd,
and N. Petsev,
1903
(1968). C, 2488
J.Chem.Soc.
C.R.Acad.Bulgare
Sci.,
2,
(1970).
47
(1960);
ref.
d (1961).
C.A. 2,
8331
6.
0. Stork
and
79
G. Wittig
and I-I.D. Frommeld,
H. Reiff,
Angew.Chem.,
8.
W. J. Barry,
9.
K. Feldmann,
S. R. Dowd,
J.Amer.Chem.Soc.,
2,
Chem.Ber.,
8 (1968);
2, z,
2178 3548
(1963).
(1964);
G. Wittig
Angew.Chem.Int.Ed.Engl.,
I. L. Finar,
and E. F. Mooney,
E. Daltroeso,
and G. Scheibe,
2,
Spectrochim.Acta,
and
7 (1968)
21,
1095
(1965). (1967); 1140
E. Daltroazo
Correct
11.
R. Knorr,
12.
J. E. Parks
13.
R. Knorr,
14.
IDPAC Cabn,
elemental
analyses
H. Polaer,
A. WeiD,
C. Ingold,
W. Theilacker
and R. Hopp,
Angew.Chem.,
E,
79,
E. Rusconi,
H. Keller,
(1967)~
1408
derivatives.
97, 643
(1975).
(1968).-
35,
2849
ET413
in press.
(1970);
(1966);
R. S.
Angew.Chem.
92, 2293
B,
J.C.S.
1551
W.
Theilacker
Faraday
Trans.
II, 2,
g,
Chem.Comm.,
871
D. S. N.
1679
2498
(1972).
(1954);
(1970).
475
and
251
L. Radom,
1 C. L. Cheng,
J.Chem.Soc.,
Tetrahedron, J.C.S.
5,
R. J. W. LeFivre,
(1968)
and E. E. Turner,
and W. Rundel,
(1959);
zgew.Chem.Int.Ed.Engl.,
M. J. Aroney,
J.Chem.Soc.
and M. Simonetta,
A. Rieker,
z,
Angew.Chem.,
Chem.Ber., 232
M. Rabinowitz,
S. Ridgwell,
or the
(1966).
and 0. L. D. Ritchie,
D. M. Hall, Gamba,
511
compounds
J.Amer.Chem.Soc.,
E, m.Chem.,
and V. Prelog,
,5, 385,
Murthy,
18.
722
and E. RLLpple, J.Amer.Chem.Soc.,
Section
Int.Ed.Engl.,
(1967). E. D. Bergmann,
for all
Inorg.Chem.,
H. Polzer,
Rules,
and G. L. D. Ritchie,
17.
obtained
and E. Bischler,
and R. H. Holm,
Tentative
H. BUun,
16.
z,
Z.Naturforsch.,
Ber.Bunsenges.Physik.Chem.,
(1968).
10.
15.
and K. Feldmann,
(1968).
A.