- Email: [email protected]
(+)-(S)-α-diethoxyphosphorylvinyl p-tolyl sulfoxide: A new chiral Michael acceptor and dienophile
Tmhedrw Prirmd
Asymmetry
in Grcti
Vol. 3. No. 12, pp.
1515-1518, 1992
09574166,92$500+.0(:
Brmin
PergamonPress Lid
(+)-(S)-a-D’ le th oxyphosphorylvinyl
p-Tolyl Sulfoxide:
a New Chiral Michael Acceptor and Dienophile Marian Hikolajcsyk+ and Wanda B. Midura
Centre of I4olecular and Macromolecular of Organic
Sulfur
Studies , Polish
Compounds,
of Sciences,
90-363 tddi, Sienkiewicza
(Received in UK6
Abstract:
Academy
Department
t12, Poland
October 1992)
The title reagent, (+)-(S)-1, was prepared from (+)-(S).-a-diethoxysulfoxide 7. by p-to1y1 phenylselenylation-deselenylation
phosphorylethyl
procedure. Its reactivity was demonstrated by diastereoselective Michael addition of ethanethiol
giving rise to 3, tandem Michael addition/intramolecular
-Wittig reaction with 2-formyl pyrrole leading to the corresponding
Horner-
pyrrolizine
sulfoxide 5 and cycloaddition with cyclopentadiene affording the diastereomeric adducts 6. The steric course of the Diels-Alder reaction is briefly discussed. Chiral oulfoxides have found a wide application as powerful ehiral auxiliaries
in
asymmetric synthesis and as chiral synthons.L Recently, chiral vinyl sulfoxides have been used as dienophiles in asymmetric Diels-Alder reactions.' However, because of a very Low reactivity of simple vinyl sulfoxides in Diels-Alder reactions, it was necessary to activate the carbon-carbon
double bond by introduction of an additional ele-
ctron-withdrawing group. Usually, the alkoxycarbonyl group is used for such a purpose.' In
this
phosphorylvinyl
paper
we
p-tolyl
would
like
sulfoxide
to
report
the
synthesis
(+)-(S)-a-diethoxy-
of
(1) and exemplify its reactivity
as a new type of
chiral Michael acceptor and dienophile.4 In contrast to other n- or p-substituted vinyl sulfoxides reported in the literature, the phosphoryl moiety in 1 functions not only as a double bond activating substituent but also allows the Homer-Wittig carried out following
the Michael addition. Moreover, the phosphoryl
reaction to be group,
like the
sulfinyl one, may be chiral thus allowing double asymmetric induction in the Michael and Diels-Alder reactions to be studied.
PhSe 1
X
n-BuLi
2 PhSeBr -(EtO!$
I
_
;/.+p
0
HZO*/CHZC1 K 63% &(Eto,,i
r"'-P
0 I
(+)-(S)-2, 6,,-22.7 and 21.1
1
3, sp-20.7
J (+)-(S)-1, 6p-9.9;
[aID -+157 (acetone) Scheme 1
1515
M. MIKOLAJCZYK and W. H. MIDLJKA
1516
A two-step involves mixture
synthesis
selenylation of
two
sulfoxide
affords
sulfoxide
1 is shown
in Scheme
(+)-(S,)-a-diethylphosphorylethyl with
diastereomers)'
PhSe-substituted elimination,
of the chiral of
3
phenylselenenyl
which,
the desired
after
bromide
subsequent
sulfoxide
1 which
1. The first step
p-tolyl
sulfoxide
to give
oxidativs
is obtained
the
2
(a
corresponding
benzeneselenenic
rn a pure
acid
form by column
chromatography. Preliminary nucleophilic presence
experiments
addition
revealed
easily.
of triethylamine
For
gave
that
example,
the
chiral
the
1 with
4 ae a 2:1 mixture
the adduct
sulfoxide
vinyl
renctiOI1of
1
undergoes
ethanethiol
in
the
of diaszereomers.
C-01,
P
A
rp
II 0
0
0
[aI,
5,
--SO.8
4, zP=20.1,
(acetone) Scheme
The
synthetic
condensed illustrated tandem
Michael
The
Table
Of
1
as
a
the
are
Diels-Alder
Reaction
collected
phosphoryl
1.
in
Table
2
H20/Ms2C0
3.
ZnCl2
4.
BF3'0Et2
cycloadducts and
25.4
column
CH2C12 CH2C12
6 was determined
ppm)'/ obtained
chromatography
in
(hexane:
or is the
of 1 with
into the carbonyl
1.
of
the
moiety
was found
ratio
of
salt
group.
in 1 considerably
The
sodium
in 5 may be enhanced
to occur
the
its
easily.
diastereomeric
of 1 with cyclopentadiene
Sulfoxide
Sulfide
(%)
a
b
c
d
(%)
ex0-?
endo-P
r.t
10d.
9.8
54.4
30.1
5.7
84.5
15.5
r.t.
2d.
13.2
53.6
27.5
5.7
85.3
14 7
-
74.5
25.5
18.4
31.5
68.5
-200
24h
25.5
74.5
-20"
Ih
46.4
10 7
by 31P NMH spectroscopy the
mono-
sulfoxide moiety 5' resulting from
sulfoxide
with cyclopentadiene
Temp. Time
CH2C12
construction
vinyl
vinyl
group
conditions
Solvent
the
reaction
Entry Catalyst
for
chiral
the chiral
or converted
of the
reaction
the
Homer-Wittig
is that
and cycloaddition
obtained
reagent
3H-pyrrolizine-2-sulfoxide
reactions
presence
key
containing
of tolyl
interest
asymmetric
reactivity
results
1
addition/intramolecular
expected,
dienophilic
of
carbocycles
synthesis
pyrrofe.
for further As
or
by the
of 2-formyl used
utility
hetero-
18.5 (2:lj
2
ZnC12-catalyzed
acetone,
24.5
and the two diastereomers
reaction
15:l). The endo/exo
(entry
3)
were
configuration
(sP=25.6
separated
by
(with respect
(+)-(S)-a-Diethaxyphosphorylvinyl
to P) of 6 absence
was assigned
(exe)
Additionally, cycloadducts
of
the
utilizing
coupling
the endofexo
the Quin's criterion'
constant
1517
p-tolyl sulfoxide
between
P
i.e. the presence
and
C(7)
in
ratio in all experiments was confirmed
6 to the corresponding
I%
(endo) or
NMR
spectra.
by reduction
of the
sulfides 7. Thermal elimination of p-toluenesulfenic
acid from 6 was also carried out and gave the chiral phosphonate 8.
~ (c%y P(OEt),
I\ (+)-(S)-1 -0
NaI,
STol-p 7,
STol-p
II
endo/exa
sP=28.3/29.3
0
6, a/b/c/d EP=25.6/25.4/25.3/24
7 A
8, ?$,=17.9 Scheme 3
An inspection
of the results
(entry 1) performed exe-selectivity moderate.
in methylene
[aID-+14 (acetone)
in Table chloride
1 reveals that the non-catalyzed
is very slow. Although
for the phosphoryl group is observed, the n-facial selectivity
An increase of the solvent polarity
may suggest a non-synchronous
(entry 2) accelerates
reaction
reactivity
occurs
Lewis
acid
of 1 and also improves n-facial
also with the predominant
two diaetereomers such
cycloaddition
which
selectivity.
exo-selectivity
increases the
In this
case the
for the P(O)-group
and only
are formed (31P NMR assay). On the contrary, the presence of a strong as
BFs'OEt>
(entry
favoures the endo phosphonate The above preliminary investigated
of
is rather
transition state with the advanced o-bond formation at the
b-carbon atom in 1. The addition of zinc chloride (entry 3) substantially dienophilic
reaction
the preponderance
4)
considerably
decreases
stereoselectivity
observations on the steric course of the Diels-Alder
may reasonably
and
moiety approach. be explained
reaction
in terms of steric factors and conformational
changes induced by Lewis acids. Thus, zinc chloride as a chelating agent links together both
polar
conformation
phosphoryl of the
boron trifluoride more
favoured
presence
of
BFg
sulfinyl
steric
reaction the
ratio
Therefore,
observed, of
in
1 what
On the other
results hand,
only one polar group, the
reasons. is
groups
dienophile.'
can coordinate
for
ZnC!l~-catalyzed
and
complexed
the
whereas
a
high
uncatalyzed 6
a
rigid
s-cis conformation
in
diastereomeric
in
s-trans
since one molecule
diastereoselectivity reflects
reaction
and
population
of
of 1 is in in of
the the both
conformers.
Acknowledgement. Research
Financial
support of this work by the State Committee
(Grant number 226709203) is gratefully acknowledged.
for Scientific
1518
References 1.
and
Notes
MikoXajczyk,M.;
Drabowicz,J.
’ an
Posner,G.,
"The
Stirling,C.J.M.; 2.
Kolzumi,T., therein;
3.
vinyl
reactions
by
and
5.
Mikotajczyk
6.
5:
Data
its
exo-6
Hz,
(less
(a3CH20,
d J=7
(d, CHzr
Jpc=11.5
been
Rappoport,Z.;
pp.823-849.
111
58,
efficiently
1991,
and
references
1991,
activated
ethoxy
cited
2, 93. for
sulfonium
Diels-Alder
salt;
Ronan,B.
2, 75.
sulfoxide
analog
1988,
Asymmetry,
corresponding
was
obtained
and by
Tetrahedron
W.,
Miller
3H);
4.45
IH);
in
Korbacz,K.
Durst
Lett.
21.4
Hz
and
1981,
Wiecrorek
(s, lH),
31P 25.6
(s, CHx);
C7);
126.6,
A.,
(m, 2H);
7.29
polar):
Hz);
CH3%20);
Hz,
(9,
6.1
1991,
13, 333. Patai.S.;
a
racemic
form
Tetrshedron coworkers 191)
22,
in
Lett.,
our
1981,
(Venugopnlan,B.,
by
oxidation
of
the
sulfide.
Midura
8: 2.39
has
Grzejszczak,S
@-phenyl
vinylic
Hz,
for
methyl
Chichester,
Tetrahedron
the
1982,
Sulfoxides",
Silicon,
Asymmetry,
Durst,T.,
M.,
lH NMR
Sons.
and
into
Tetrahedron
and
and
sulfoxide
conversion
and
corresponding
(dt J-2.1
Wiley
(Mikokajczyk,M.,
3097),
22,
and
Sulfones
Sulfur
u-Diethoxyphosphorylvinyl
Ham1et.A.B.
in Stereochemistry,
of
Carretero,J.C.,
p-tolyl
its
Kagan,H.B.;
laboratory
7.
John
Phosphorus,
Lopez,R.
Topics
Chemistry
Eds.,
Recently,
and 4.
md W. H. MKXJKA
M. MIKOLAICZYK
49.6
129.1,
7.29
ppm,
31.3
(d,
Tetrahedron,
(s, lH]; and
6.25
7.56
62.3
5=3.8
43, 2967.
c=O.8),
(d, J=5.2 Hz,
Hz,
IH);
6.49
4U aromatic).
(acetone 42.5
(d, J=6
Hz),
1987,
(dt 5=2.0
(AA'BE'
[0]~=+35.5
(s, CH2,C3)
(s, CH,Cl);
135.3
M.
5.93
Hz,
CH$H20);
13C NMR
16.3
CH,CQ);
45.9
62.5
137.5,
141.5,
142.2
2.32
(s, 3H);
2.68
(d, J=7
(aromatic
+
vinyl). IH NMR,
1.23
4.08
7.72
(AA'BB'
Data
for
15.7
(C3,
128.7,
(more
=3,C3);
CHsCH20);
1.5-2.2
5.93
polar):
42.0
63.1
6: 1.21
(d,
(dt, 6.28
31P
(9, CHC4); 5x6.7
(d, Jc11.2
(m, 4H);
Quin,L.D.,
6H,
411, CHsm20);
(m, 3H);
(m, lH,
vinyl);
6.28
(m,
lH,
(m,
Vinyl);
1H);
2.9
7.35
and
4H aromatic).
endo-
129.3
'H NMR 4.05
(dt,
(m,
CH3=20);
HZ,
8.
6:
1H)i
(m,
HZ);
6H);
HZ,
ppm,
(s, CH2,C7);
CH3a20);
139.0
(m,
1.45-2.4
4H)i
7.15
and
Cunkle,G.T.
[a]~=+lSl.S
70.1
(aromatic
(m, 2H vinyl),
Gallagher,N.J.,
25.4 48.6
(aCetOne
49.9
(de
Cc2.6);
(s, CHCl);
5~137.6
61.6
13C NMR (d, J=7.2
HZ,C2);
126.4,
(m, 1H);
3.45
128.3,
+ vinyl). 2.29 7.5
and
(s, 3H), (AA'BB'
2.97
(m, 1H);
4H aromatic).
Chesnut,D.B.,
J.Am.Chem.Soc.,
1980,
102,
not
only
A
high
3136. 9.
Zinc in
salts the
were
used
as chelating
Diels-Alder
stereoselectivity
observed
coworkers;
G.H.
New
York,
Posner, 1983;
~01.2,
agents
reaction in
but the
"Asymmetric Part
A, Ch.8,
for
a-substituted
also latter
in case
Synthesis"; p.225.
vinyl
conjugate was
sulfoxides additions.
rationalized
Morrison,J.D.,
Ed.;
by
Posner
Academic
and
Press:
Asymmetry
in Grcti
Vol. 3. No. 12, pp.
1515-1518, 1992
09574166,92$500+.0(:
Brmin
PergamonPress Lid
(+)-(S)-a-D’ le th oxyphosphorylvinyl
p-Tolyl Sulfoxide:
a New Chiral Michael Acceptor and Dienophile Marian Hikolajcsyk+ and Wanda B. Midura
Centre of I4olecular and Macromolecular of Organic
Sulfur
Studies , Polish
Compounds,
of Sciences,
90-363 tddi, Sienkiewicza
(Received in UK6
Abstract:
Academy
Department
t12, Poland
October 1992)
The title reagent, (+)-(S)-1, was prepared from (+)-(S).-a-diethoxysulfoxide 7. by p-to1y1 phenylselenylation-deselenylation
phosphorylethyl
procedure. Its reactivity was demonstrated by diastereoselective Michael addition of ethanethiol
giving rise to 3, tandem Michael addition/intramolecular
-Wittig reaction with 2-formyl pyrrole leading to the corresponding
Horner-
pyrrolizine
sulfoxide 5 and cycloaddition with cyclopentadiene affording the diastereomeric adducts 6. The steric course of the Diels-Alder reaction is briefly discussed. Chiral oulfoxides have found a wide application as powerful ehiral auxiliaries
in
asymmetric synthesis and as chiral synthons.L Recently, chiral vinyl sulfoxides have been used as dienophiles in asymmetric Diels-Alder reactions.' However, because of a very Low reactivity of simple vinyl sulfoxides in Diels-Alder reactions, it was necessary to activate the carbon-carbon
double bond by introduction of an additional ele-
ctron-withdrawing group. Usually, the alkoxycarbonyl group is used for such a purpose.' In
this
phosphorylvinyl
paper
we
p-tolyl
would
like
sulfoxide
to
report
the
synthesis
(+)-(S)-a-diethoxy-
of
(1) and exemplify its reactivity
as a new type of
chiral Michael acceptor and dienophile.4 In contrast to other n- or p-substituted vinyl sulfoxides reported in the literature, the phosphoryl moiety in 1 functions not only as a double bond activating substituent but also allows the Homer-Wittig carried out following
the Michael addition. Moreover, the phosphoryl
reaction to be group,
like the
sulfinyl one, may be chiral thus allowing double asymmetric induction in the Michael and Diels-Alder reactions to be studied.
PhSe 1
X
n-BuLi
2 PhSeBr -(EtO!$
I
_
;/.+p
0
HZO*/CHZC1 K 63% &(Eto,,i
r"'-P
0 I
(+)-(S)-2, 6,,-22.7 and 21.1
1
3, sp-20.7
J (+)-(S)-1, 6p-9.9;
[aID -+157 (acetone) Scheme 1
1515
M. MIKOLAJCZYK and W. H. MIDLJKA
1516
A two-step involves mixture
synthesis
selenylation of
two
sulfoxide
affords
sulfoxide
1 is shown
in Scheme
(+)-(S,)-a-diethylphosphorylethyl with
diastereomers)'
PhSe-substituted elimination,
of the chiral of
3
phenylselenenyl
which,
the desired
after
bromide
subsequent
sulfoxide
1 which
1. The first step
p-tolyl
sulfoxide
to give
oxidativs
is obtained
the
2
(a
corresponding
benzeneselenenic
rn a pure
acid
form by column
chromatography. Preliminary nucleophilic presence
experiments
addition
revealed
easily.
of triethylamine
For
gave
that
example,
the
chiral
the
1 with
4 ae a 2:1 mixture
the adduct
sulfoxide
vinyl
renctiOI1of
1
undergoes
ethanethiol
in
the
of diaszereomers.
C-01,
P
A
rp
II 0
0
0
[aI,
5,
--SO.8
4, zP=20.1,
(acetone) Scheme
The
synthetic
condensed illustrated tandem
Michael
The
Table
Of
1
as
a
the
are
Diels-Alder
Reaction
collected
phosphoryl
1.
in
Table
2
H20/Ms2C0
3.
ZnCl2
4.
BF3'0Et2
cycloadducts and
25.4
column
CH2C12 CH2C12
6 was determined
ppm)'/ obtained
chromatography
in
(hexane:
or is the
of 1 with
into the carbonyl
1.
of
the
moiety
was found
ratio
of
salt
group.
in 1 considerably
The
sodium
in 5 may be enhanced
to occur
the
its
easily.
diastereomeric
of 1 with cyclopentadiene
Sulfoxide
Sulfide
(%)
a
b
c
d
(%)
ex0-?
endo-P
r.t
10d.
9.8
54.4
30.1
5.7
84.5
15.5
r.t.
2d.
13.2
53.6
27.5
5.7
85.3
14 7
-
74.5
25.5
18.4
31.5
68.5
-200
24h
25.5
74.5
-20"
Ih
46.4
10 7
by 31P NMH spectroscopy the
mono-
sulfoxide moiety 5' resulting from
sulfoxide
with cyclopentadiene
Temp. Time
CH2C12
construction
vinyl
vinyl
group
conditions
Solvent
the
reaction
Entry Catalyst
for
chiral
the chiral
or converted
of the
reaction
the
Homer-Wittig
is that
and cycloaddition
obtained
reagent
3H-pyrrolizine-2-sulfoxide
reactions
presence
key
containing
of tolyl
interest
asymmetric
reactivity
results
1
addition/intramolecular
expected,
dienophilic
of
carbocycles
synthesis
pyrrofe.
for further As
or
by the
of 2-formyl used
utility
hetero-
18.5 (2:lj
2
ZnC12-catalyzed
acetone,
24.5
and the two diastereomers
reaction
15:l). The endo/exo
(entry
3)
were
configuration
(sP=25.6
separated
by
(with respect
(+)-(S)-a-Diethaxyphosphorylvinyl
to P) of 6 absence
was assigned
(exe)
Additionally, cycloadducts
of
the
utilizing
coupling
the endofexo
the Quin's criterion'
constant
1517
p-tolyl sulfoxide
between
P
i.e. the presence
and
C(7)
in
ratio in all experiments was confirmed
6 to the corresponding
I%
(endo) or
NMR
spectra.
by reduction
of the
sulfides 7. Thermal elimination of p-toluenesulfenic
acid from 6 was also carried out and gave the chiral phosphonate 8.
~ (c%y P(OEt),
I\ (+)-(S)-1 -0
NaI,
STol-p 7,
STol-p
II
endo/exa
sP=28.3/29.3
0
6, a/b/c/d EP=25.6/25.4/25.3/24
7 A
8, ?$,=17.9 Scheme 3
An inspection
of the results
(entry 1) performed exe-selectivity moderate.
in methylene
[aID-+14 (acetone)
in Table chloride
1 reveals that the non-catalyzed
is very slow. Although
for the phosphoryl group is observed, the n-facial selectivity
An increase of the solvent polarity
may suggest a non-synchronous
(entry 2) accelerates
reaction
reactivity
occurs
Lewis
acid
of 1 and also improves n-facial
also with the predominant
two diaetereomers such
cycloaddition
which
selectivity.
exo-selectivity
increases the
In this
case the
for the P(O)-group
and only
are formed (31P NMR assay). On the contrary, the presence of a strong as
BFs'OEt>
(entry
favoures the endo phosphonate The above preliminary investigated
of
is rather
transition state with the advanced o-bond formation at the
b-carbon atom in 1. The addition of zinc chloride (entry 3) substantially dienophilic
reaction
the preponderance
4)
considerably
decreases
stereoselectivity
observations on the steric course of the Diels-Alder
may reasonably
and
moiety approach. be explained
reaction
in terms of steric factors and conformational
changes induced by Lewis acids. Thus, zinc chloride as a chelating agent links together both
polar
conformation
phosphoryl of the
boron trifluoride more
favoured
presence
of
BFg
sulfinyl
steric
reaction the
ratio
Therefore,
observed, of
in
1 what
On the other
results hand,
only one polar group, the
reasons. is
groups
dienophile.'
can coordinate
for
ZnC!l~-catalyzed
and
complexed
the
whereas
a
high
uncatalyzed 6
a
rigid
s-cis conformation
in
diastereomeric
in
s-trans
since one molecule
diastereoselectivity reflects
reaction
and
population
of
of 1 is in in of
the the both
conformers.
Acknowledgement. Research
Financial
support of this work by the State Committee
(Grant number 226709203) is gratefully acknowledged.
for Scientific
1518
References 1.
and
Notes
MikoXajczyk,M.;
Drabowicz,J.
’ an
Posner,G.,
"The
Stirling,C.J.M.; 2.
Kolzumi,T., therein;
3.
vinyl
reactions
by
and
5.
Mikotajczyk
6.
5:
Data
its
exo-6
Hz,
(less
(a3CH20,
d J=7
(d, CHzr
Jpc=11.5
been
Rappoport,Z.;
pp.823-849.
111
58,
efficiently
1991,
and
references
1991,
activated
ethoxy
cited
2, 93. for
sulfonium
Diels-Alder
salt;
Ronan,B.
2, 75.
sulfoxide
analog
1988,
Asymmetry,
corresponding
was
obtained
and by
Tetrahedron
W.,
Miller
3H);
4.45
IH);
in
Korbacz,K.
Durst
Lett.
21.4
Hz
and
1981,
Wiecrorek
(s, lH),
31P 25.6
(s, CHx);
C7);
126.6,
A.,
(m, 2H);
7.29
polar):
Hz);
CH3%20);
Hz,
(9,
6.1
1991,
13, 333. Patai.S.;
a
racemic
form
Tetrshedron coworkers 191)
22,
in
Lett.,
our
1981,
(Venugopnlan,B.,
by
oxidation
of
the
sulfide.
Midura
8: 2.39
has
Grzejszczak,S
@-phenyl
vinylic
Hz,
for
methyl
Chichester,
Tetrahedron
the
1982,
Sulfoxides",
Silicon,
Asymmetry,
Durst,T.,
M.,
lH NMR
Sons.
and
into
Tetrahedron
and
and
sulfoxide
conversion
and
corresponding
(dt J-2.1
Wiley
(Mikokajczyk,M.,
3097),
22,
and
Sulfones
Sulfur
u-Diethoxyphosphorylvinyl
Ham1et.A.B.
in Stereochemistry,
of
Carretero,J.C.,
p-tolyl
its
Kagan,H.B.;
laboratory
7.
John
Phosphorus,
Lopez,R.
Topics
Chemistry
Eds.,
Recently,
and 4.
md W. H. MKXJKA
M. MIKOLAICZYK
49.6
129.1,
7.29
ppm,
31.3
(d,
Tetrahedron,
(s, lH]; and
6.25
7.56
62.3
5=3.8
43, 2967.
c=O.8),
(d, J=5.2 Hz,
Hz,
IH);
6.49
4U aromatic).
(acetone 42.5
(d, J=6
Hz),
1987,
(dt 5=2.0
(AA'BE'
[0]~=+35.5
(s, CH2,C3)
(s, CH,Cl);
135.3
M.
5.93
Hz,
CH$H20);
13C NMR
16.3
CH,CQ);
45.9
62.5
137.5,
141.5,
142.2
2.32
(s, 3H);
2.68
(d, J=7
(aromatic
+
vinyl). IH NMR,
1.23
4.08
7.72
(AA'BB'
Data
for
15.7
(C3,
128.7,
(more
=3,C3);
CHsCH20);
1.5-2.2
5.93
polar):
42.0
63.1
6: 1.21
(d,
(dt, 6.28
31P
(9, CHC4); 5x6.7
(d, Jc11.2
(m, 4H);
Quin,L.D.,
6H,
411, CHsm20);
(m, 3H);
(m, lH,
vinyl);
6.28
(m,
lH,
(m,
Vinyl);
1H);
2.9
7.35
and
4H aromatic).
endo-
129.3
'H NMR 4.05
(dt,
(m,
CH3=20);
HZ,
8.
6:
1H)i
(m,
HZ);
6H);
HZ,
ppm,
(s, CH2,C7);
CH3a20);
139.0
(m,
1.45-2.4
4H)i
7.15
and
Cunkle,G.T.
[a]~=+lSl.S
70.1
(aromatic
(m, 2H vinyl),
Gallagher,N.J.,
25.4 48.6
(aCetOne
49.9
(de
Cc2.6);
(s, CHCl);
5~137.6
61.6
13C NMR (d, J=7.2
HZ,C2);
126.4,
(m, 1H);
3.45
128.3,
+ vinyl). 2.29 7.5
and
(s, 3H), (AA'BB'
2.97
(m, 1H);
4H aromatic).
Chesnut,D.B.,
J.Am.Chem.Soc.,
1980,
102,
not
only
A
high
3136. 9.
Zinc in
salts the
were
used
as chelating
Diels-Alder
stereoselectivity
observed
coworkers;
G.H.
New
York,
Posner, 1983;
~01.2,
agents
reaction in
but the
"Asymmetric Part
A, Ch.8,
for
a-substituted
also latter
in case
Synthesis"; p.225.
vinyl
conjugate was
sulfoxides additions.
rationalized
Morrison,J.D.,
Ed.;
by
Posner
Academic
and
Press: