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Reduction of ketones with polydibenzo-18-crown-6-borohydride
Vol.32No.19.pi Briti
TeurheQonLataa F’rinted in Gny
215Wlao, 1991
oo4o-4039191 $3.00+ .oa
PergMvrnPre& plc
RRLRJCTIONOF KETONES WITH WLYDIBENP)-18_CROUN-~~RO~R~E A Sarkar*
B R Rao
and
Department of Applied Chemistry, Indian School of Mines, Dhanbad-826004, INDIA.
a condensation polymer of dibenzo18-crown-6 and formaldehyde has been used as support for borohydride ions in The reagent has been found to the reduction of few cyclic and acyclic ketones. be more stereoselective than dibenzo-18-crown-6-borohydride in the reduction of 4-J-butylcyclohexanone has been converted exclusively (100%) to cyclic ketones. trans-4-J-butylcyclohexanol.
Abstract: Polydibenzo-18-crown-6-(P-DB-18-C-6).
Supported
borohydrides
are
increasingly
being
used
in
syntheti;
organi;
chemistry . Apart from inert materials of inorganic origin such as alumina , clay , 3 polymeric anion exchangers have slso been used as support for boroetc., 4*5 and the resultant reagent used for reduction of a variety of organic hydride.
silica
functional some
groups!
However,
selectivity
in
in the reductions Apart
the
far
the
the
reduction
of
borohydride from
the
axial
attack
aided
nucleophile
like
on the
carbonyl
hindrance
The 6
(3.0
ml1
to
capacity the
in
dry
remove of
reagent
free
reagent
any
possesses
stereoselectivity
was benzene sodium
a
polymer
of
from
exactly
that
the
the
It
grafted
anion exchanged
equatorial
that
gmup side.
of more stable
out
‘naked
borohydride,
and stereoselectivity
was felt
carbonyl
is grafted
us to carry
P-DB-18-C-6
general)
reagent’,
borohydride
prompted
such
(in
supported
alcohols 10
such
P-DE18-C-6-
the
cyclohexanone
of
This
in
is
so
in case
because
the
of cyclohexa-
product
stability
control
, although
the
probabilities
of
an axial/equatorial
attack
in
the
steric
equal
(particularly
absence
for
a small
of any
on C3/C5). found
pulverised
dilute
this
hardly
when sodium
concerned.
bomhydride
BH6_ equivalent with
are
called
are
using
ketones
attack
than
so
substituents
reagent
though
has
on resin-bound
of
in the formation the
naked
of finely
gl
an
of
was perceived
ketones side
group
fmm
a mixture
by
that
it
bornhydride’
reductions
prefer
resulting
is
found
polydibenzo-18-crown-6’.
an improvement
cyclic axial
of It
of
might
more nones,
be
rates
been
groups7’,
advantages
‘naked
moieties
would
as
usual
investigations.
borohydride’ as
the
ether
has some
ketones5.
of obtaining
crown
present
of cyclic
fmm
the possibility on the
it
reducing
to
be
sodium (15
quite
ml).
The
bomhydride, of
sulphuric
the acid
stable.
bomhydride prepared dried
reagent, was 2157
It
(0.7 resin
in vacua determined
found
was
prepared
by
stirring
g) and polydibenzo-lfkcrownwas and by
to be (1.92
washed stored
with over
decomposing
meq/g).
THF (10 P205. a
part
The of
2158
Ketones reduced
by
and
resin
the
by
(cyclic
following (2.2
that faster
reductions
in
than
on carrying
ketones
in
benzene.
formed
in
the
locked
(80.8%)
found
usually
of equatorial
in reduction
with
ciated
with
resting
observation
in reduction
a mixture
following
were
Dn the
carried
other of
the
the
alcohol
(cis)
which
formation
of
may be mentioned
with benzene as solvent Table
other
equatorial
here,
1: Reduction
of axial
i.e.
of ketones
of equatorial in the same
attack
which
of greater results
alcohol/stable
alcohol.
of equatorial
than that obtained
which
is greater
(75%).
the reductions
percentage
improved
cyclohexanone,
with formation
1) was
cyclohexanones
in ethanol,
borohydride
In
case
percenobtained
were assoAnother
alcohol
inteformed
in ethanol.
with P-DB-la-C-6-BHq
Ethanol
Entry
of
ketones,
higher
(table
temperature
to the stereochemical
cyclic
is always
ketones
followed
in polymer
observed
room
a-Methyl
proceeded
is opposite
In all
at
were
(2 meq)
was
procedures
was
reductions
sodium
These
ketone
4-t-butylcyclohexanone,
with
the reduction
LiAIH4/NaBH4.
a preferential
reduction
the
reaction
The percentages
cyclic
In fact,
It out
hand,
underwent a preponderance in
of
standard GC.
stereoselectivity.
reductions
and benzene.
40°- 5O’C. The
NMR and
which
in benzene.
of 3,3,5-trimethylcyclohexanone tages
at
to 100% trans-4-J-butylcyclohexanol.
is not conformationally than
in ethanol
which
by
by
greater
out the reductions
was reduced
isolated
the
by
in
was stirred
characterised
was accompanied
(stabler)
solvent
of
ethanol
in benzene alcohol
were
were reduced
procedure
BH;)
The products,
reactions
the
a simple meq of
TLC monitoring.
supported
and acyclic)
Benzene
Time h
Yield %
6
100
89.6
24
95
100
22
90
53.9
56
85
57
5
85
76.7
22
80
80.8
12
88
72.5
48
82
75
96’
60
20+
96*
62
23.8+
4
95
18
90
26
90
55
85
20
75
50
70
26
92
66
88
reduction
+ Endo
1. 4-t-butylcyclo-
% of equatorial alcohol
Time h
Yield %
% of equatorial alcohol
hexanone 2. 3,3,5_trimethylcyclohexanone 3. I-methylcyclohexanone 4. 3-methylcyclohexanone 5. Camphor 6. Cyclohexanone 7.
Benzophenone
8. Acetophenone 9.
Fluorenone * Incomplete
A tentative
explanation
for the slower
reaction
rate and higher
stereoselectivity
2159
in
benzene
more
solvated
axial out
may in
ethanol
than
in
crown-bomhydride benzene.
Fig.Ib
on to the carbonyl
ethanol.
is
more
Moreover,
group is slightly the
possibility
Na+- P-DB-18-C-6 likely
to
cannot
diminish
the
stereoselectivity
of
formation
the
reagent
be
effect.
is
more exposed
relatively
on the of
[Fig. phenyl
of
cyclic
Ia
It appears and
group
advantage
ketones
18-crown-6-BHq Table
‘1 supports
case attack
this
with
hypothesis
become
BH; from
is carried
P-DB-18-C-6-BH4the by
liberated
BH:
following
the
of
the
those
due
to
stereochemical obtained
to a certain
fmm extent
outcome in the reduction
only
on the basis
the borohydride
group
DE18-C-6-bomhydride
a buckling
of formaldehyde
Entry
group results
reduction (Table
of cyclic
effect
caused
with different for
reduction
with dibenzo-
2). ketones.
1
Ethanol 0 trans
Yvent I I Benzene % trans
89.6
100
75
76.7
80.8
74
44.1
41
48
I Toluene*k % trans
hexanone 4-methylcyclohexanone 3,8,5-trimethylcyclohexanone ** Results ,
as reported
the
However,
in the normal
probably
of condensation
comparison
2 : Stereochemical
I-J-butylcyclo-
an axial
the
cannot be explained
occurs
our reagent
of
to
comparatively greater 13 dibenzo-18-crown-6-BH4 and exclusive
vis-a-vis
This
A
of
to us that in P-DB-18-C-6-BHg,
as a result
using
of
likely
when the reduction
In that
reduction.
than the same group
Ib).
dibenzo-crown.
out.
is
approach
dissociation
ruled
of trans-4-t-butylcyclohexanol
of a solvent complex
impeded
of
same mode as in case of sodium bomhydride
units
As a result,
Fig. Ia side
(100%)
complex
n
BHq and
ion
The
proposed.
u
in
into
be
by Matsuda et al.
ll.
2160
The
trend
of
stereochemical
the same trend
(though
percentages
equatorial
smaller the
of
effective
size
valid
reason
only
not have
improved
are 2.283
and 2.387
improved) the
in
has
been
reducing
this
to such
case
with our reagent follows 11 by Matsuda et al . Formation of greater by
in non-polar
the
(the
It appears
nature of the BH; ion in the present
reductions
rationalised
agent also,
an extent
at 2O’C).
of
as observed
alcohol
of
outcome
solvent
percentage
dielectric
those
of
toluene.
equatorial
constants
to us that probably
reagent the axial
workers
of
as
due
If that alcohol
benzene
to was
would
and toluene
due to the more exposed
attack
is more facile.
Acknorledgementk The fruiftul
authors
are
thankful
to
Prof.
Nasipuri
D.
of
I.I.C.B.,
Calcutta,
for
a
discussion.
References and Notest 1.
F.Hodosan
2.
A.Sarkar,
and N.Serban, B.R.Rao
Rev.
and
Roumaine,
M.M.Konar,
Chim,
14,121
Synthetic
(1969).
Comm,
19(13
6
14).
2313-2320
(1989). 3.
P.Tundo,
J.Chem.Soc.
Chem. Comm, 815 (1977).
4.
H. W. Gibson and F.C. Bailey,
5.
R.O.Hutchins,N.R.Natale
6.
A.R.Sande,M.H.Jagdale,R.B.Mane
7.
A.Nag,A.Sarkar.S.K.Sarkar
8.
A.McKillbp
9.
Polydibenzo-18-crown-6 tions :
J. Chem .Soc. Chem .Comm, 815(1977).
and I.M.Taffer,
and S.K.Palit,Synthetic
and D.Y.Young
Synthesis,
401-481
has been used
for
K.P.Janzen.
E.Blasius.
J.Chem.Soc.Chem.Comm.
and M.M.Salunkhe,
H.Klotz,
1086 (1978).
Tet.Lett.,25.3501(1984). Comm.17,1007(1987).
(1979).
reactions
under phase
A.Toussaint,
Macromol.
transfer
condi-
Chem.183,
140X-
1411 (1982). 10.
Felkin’s
model
the equatorial
axial
control. is
is
transfer 471-473
strain
is held
accepted
responsible
in place
for impeding
of product
development
Even then,
difficult
attack
metals
the torsional
is now generally
the exclusive formation of --trans-4-t-butylcycloexplain. It is probable that a kinetic preference for 12 (Fukui effect) , e.g., in the reduction of ketones with dissolving
(stability) hexanol
in which attack
to
operating
mechanism
here (See
and
the
Nasipuri
reduction
and Saha.
goes Indian
through Journal
a
single
electron
of Chemistry,
29B.
(1990).
11.
T.Matsuda
12.
K. Fukui.
and K.Koida, Theory
West Berlin),
of
1975.
(Received in UK21 February 1991)
Bull.Chem.
orientation
Sot.,
Japan,
and stereoselection,
46.2259-2260 Chap. 7.7
(1973). (Springer
Verlag ,
TeurheQonLataa F’rinted in Gny
215Wlao, 1991
oo4o-4039191 $3.00+ .oa
PergMvrnPre& plc
RRLRJCTIONOF KETONES WITH WLYDIBENP)-18_CROUN-~~RO~R~E A Sarkar*
B R Rao
and
Department of Applied Chemistry, Indian School of Mines, Dhanbad-826004, INDIA.
a condensation polymer of dibenzo18-crown-6 and formaldehyde has been used as support for borohydride ions in The reagent has been found to the reduction of few cyclic and acyclic ketones. be more stereoselective than dibenzo-18-crown-6-borohydride in the reduction of 4-J-butylcyclohexanone has been converted exclusively (100%) to cyclic ketones. trans-4-J-butylcyclohexanol.
Abstract: Polydibenzo-18-crown-6-(P-DB-18-C-6).
Supported
borohydrides
are
increasingly
being
used
in
syntheti;
organi;
chemistry . Apart from inert materials of inorganic origin such as alumina , clay , 3 polymeric anion exchangers have slso been used as support for boroetc., 4*5 and the resultant reagent used for reduction of a variety of organic hydride.
silica
functional some
groups!
However,
selectivity
in
in the reductions Apart
the
far
the
the
reduction
of
borohydride from
the
axial
attack
aided
nucleophile
like
on the
carbonyl
hindrance
The 6
(3.0
ml1
to
capacity the
in
dry
remove of
reagent
free
reagent
any
possesses
stereoselectivity
was benzene sodium
a
polymer
of
from
exactly
that
the
the
It
grafted
anion exchanged
equatorial
that
gmup side.
of more stable
out
‘naked
borohydride,
and stereoselectivity
was felt
carbonyl
is grafted
us to carry
P-DB-18-C-6
general)
reagent’,
borohydride
prompted
such
(in
supported
alcohols 10
such
P-DE18-C-6-
the
cyclohexanone
of
This
in
is
so
in case
because
the
of cyclohexa-
product
stability
control
, although
the
probabilities
of
an axial/equatorial
attack
in
the
steric
equal
(particularly
absence
for
a small
of any
on C3/C5). found
pulverised
dilute
this
hardly
when sodium
concerned.
bomhydride
BH6_ equivalent with
are
called
are
using
ketones
attack
than
so
substituents
reagent
though
has
on resin-bound
of
in the formation the
naked
of finely
gl
an
of
was perceived
ketones side
group
fmm
a mixture
by
that
it
bornhydride’
reductions
prefer
resulting
is
found
polydibenzo-18-crown-6’.
an improvement
cyclic axial
of It
of
might
more nones,
be
rates
been
groups7’,
advantages
‘naked
moieties
would
as
usual
investigations.
borohydride’ as
the
ether
has some
ketones5.
of obtaining
crown
present
of cyclic
fmm
the possibility on the
it
reducing
to
be
sodium (15
quite
ml).
The
bomhydride, of
sulphuric
the acid
stable.
bomhydride prepared dried
reagent, was 2157
It
(0.7 resin
in vacua determined
found
was
prepared
by
stirring
g) and polydibenzo-lfkcrownwas and by
to be (1.92
washed stored
with over
decomposing
meq/g).
THF (10 P205. a
part
The of
2158
Ketones reduced
by
and
resin
the
by
(cyclic
following (2.2
that faster
reductions
in
than
on carrying
ketones
in
benzene.
formed
in
the
locked
(80.8%)
found
usually
of equatorial
in reduction
with
ciated
with
resting
observation
in reduction
a mixture
following
were
Dn the
carried
other of
the
the
alcohol
(cis)
which
formation
of
may be mentioned
with benzene as solvent Table
other
equatorial
here,
1: Reduction
of axial
i.e.
of ketones
of equatorial in the same
attack
which
of greater results
alcohol/stable
alcohol.
of equatorial
than that obtained
which
is greater
(75%).
the reductions
percentage
improved
cyclohexanone,
with formation
1) was
cyclohexanones
in ethanol,
borohydride
In
case
percenobtained
were assoAnother
alcohol
inteformed
in ethanol.
with P-DB-la-C-6-BHq
Ethanol
Entry
of
ketones,
higher
(table
temperature
to the stereochemical
cyclic
is always
ketones
followed
in polymer
observed
room
a-Methyl
proceeded
is opposite
In all
at
were
(2 meq)
was
procedures
was
reductions
sodium
These
ketone
4-t-butylcyclohexanone,
with
the reduction
LiAIH4/NaBH4.
a preferential
reduction
the
reaction
The percentages
cyclic
In fact,
It out
hand,
underwent a preponderance in
of
standard GC.
stereoselectivity.
reductions
and benzene.
40°- 5O’C. The
NMR and
which
in benzene.
of 3,3,5-trimethylcyclohexanone tages
at
to 100% trans-4-J-butylcyclohexanol.
is not conformationally than
in ethanol
which
by
by
greater
out the reductions
was reduced
isolated
the
by
in
was stirred
characterised
was accompanied
(stabler)
solvent
of
ethanol
in benzene alcohol
were
were reduced
procedure
BH;)
The products,
reactions
the
a simple meq of
TLC monitoring.
supported
and acyclic)
Benzene
Time h
Yield %
6
100
89.6
24
95
100
22
90
53.9
56
85
57
5
85
76.7
22
80
80.8
12
88
72.5
48
82
75
96’
60
20+
96*
62
23.8+
4
95
18
90
26
90
55
85
20
75
50
70
26
92
66
88
reduction
+ Endo
1. 4-t-butylcyclo-
% of equatorial alcohol
Time h
Yield %
% of equatorial alcohol
hexanone 2. 3,3,5_trimethylcyclohexanone 3. I-methylcyclohexanone 4. 3-methylcyclohexanone 5. Camphor 6. Cyclohexanone 7.
Benzophenone
8. Acetophenone 9.
Fluorenone * Incomplete
A tentative
explanation
for the slower
reaction
rate and higher
stereoselectivity
2159
in
benzene
more
solvated
axial out
may in
ethanol
than
in
crown-bomhydride benzene.
Fig.Ib
on to the carbonyl
ethanol.
is
more
Moreover,
group is slightly the
possibility
Na+- P-DB-18-C-6 likely
to
cannot
diminish
the
stereoselectivity
of
formation
the
reagent
be
effect.
is
more exposed
relatively
on the of
[Fig. phenyl
of
cyclic
Ia
It appears and
group
advantage
ketones
18-crown-6-BHq Table
‘1 supports
case attack
this
with
hypothesis
become
BH; from
is carried
P-DB-18-C-6-BH4the by
liberated
BH:
following
the
of
the
those
due
to
stereochemical obtained
to a certain
fmm extent
outcome in the reduction
only
on the basis
the borohydride
group
DE18-C-6-bomhydride
a buckling
of formaldehyde
Entry
group results
reduction (Table
of cyclic
effect
caused
with different for
reduction
with dibenzo-
2). ketones.
1
Ethanol 0 trans
Yvent I I Benzene % trans
89.6
100
75
76.7
80.8
74
44.1
41
48
I Toluene*k % trans
hexanone 4-methylcyclohexanone 3,8,5-trimethylcyclohexanone ** Results ,
as reported
the
However,
in the normal
probably
of condensation
comparison
2 : Stereochemical
I-J-butylcyclo-
an axial
the
cannot be explained
occurs
our reagent
of
to
comparatively greater 13 dibenzo-18-crown-6-BH4 and exclusive
vis-a-vis
This
A
of
to us that in P-DB-18-C-6-BHg,
as a result
using
of
likely
when the reduction
In that
reduction.
than the same group
Ib).
dibenzo-crown.
out.
is
approach
dissociation
ruled
of trans-4-t-butylcyclohexanol
of a solvent complex
impeded
of
same mode as in case of sodium bomhydride
units
As a result,
Fig. Ia side
(100%)
complex
n
BHq and
ion
The
proposed.
u
in
into
be
by Matsuda et al.
ll.
2160
The
trend
of
stereochemical
the same trend
(though
percentages
equatorial
smaller the
of
effective
size
valid
reason
only
not have
improved
are 2.283
and 2.387
improved) the
in
has
been
reducing
this
to such
case
with our reagent follows 11 by Matsuda et al . Formation of greater by
in non-polar
the
(the
It appears
nature of the BH; ion in the present
reductions
rationalised
agent also,
an extent
at 2O’C).
of
as observed
alcohol
of
outcome
solvent
percentage
dielectric
those
of
toluene.
equatorial
constants
to us that probably
reagent the axial
workers
of
as
due
If that alcohol
benzene
to was
would
and toluene
due to the more exposed
attack
is more facile.
Acknorledgementk The fruiftul
authors
are
thankful
to
Prof.
Nasipuri
D.
of
I.I.C.B.,
Calcutta,
for
a
discussion.
References and Notest 1.
F.Hodosan
2.
A.Sarkar,
and N.Serban, B.R.Rao
Rev.
and
Roumaine,
M.M.Konar,
Chim,
14,121
Synthetic
(1969).
Comm,
19(13
6
14).
2313-2320
(1989). 3.
P.Tundo,
J.Chem.Soc.
Chem. Comm, 815 (1977).
4.
H. W. Gibson and F.C. Bailey,
5.
R.O.Hutchins,N.R.Natale
6.
A.R.Sande,M.H.Jagdale,R.B.Mane
7.
A.Nag,A.Sarkar.S.K.Sarkar
8.
A.McKillbp
9.
Polydibenzo-18-crown-6 tions :
J. Chem .Soc. Chem .Comm, 815(1977).
and I.M.Taffer,
and S.K.Palit,Synthetic
and D.Y.Young
Synthesis,
401-481
has been used
for
K.P.Janzen.
E.Blasius.
J.Chem.Soc.Chem.Comm.
and M.M.Salunkhe,
H.Klotz,
1086 (1978).
Tet.Lett.,25.3501(1984). Comm.17,1007(1987).
(1979).
reactions
under phase
A.Toussaint,
Macromol.
transfer
condi-
Chem.183,
140X-
1411 (1982). 10.
Felkin’s
model
the equatorial
axial
control. is
is
transfer 471-473
strain
is held
accepted
responsible
in place
for impeding
of product
development
Even then,
difficult
attack
metals
the torsional
is now generally
the exclusive formation of --trans-4-t-butylcycloexplain. It is probable that a kinetic preference for 12 (Fukui effect) , e.g., in the reduction of ketones with dissolving
(stability) hexanol
in which attack
to
operating
mechanism
here (See
and
the
Nasipuri
reduction
and Saha.
goes Indian
through Journal
a
single
electron
of Chemistry,
29B.
(1990).
11.
T.Matsuda
12.
K. Fukui.
and K.Koida, Theory
West Berlin),
of
1975.
(Received in UK21 February 1991)
Bull.Chem.
orientation
Sot.,
Japan,
and stereoselection,
46.2259-2260 Chap. 7.7
(1973). (Springer
Verlag ,