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Free radical type addition of toluenesulfonyl cyanide to unsaturated hydrocarbons
Tetrahedron Letters,Vo1.28,No.25,pp Printed in Great Britain
FREE RADICAL
TYPE ADDITION
OF TOLUENESULFONYL
TO UNSATURATED Jim-Min Department
Fang*
of Chemistry, Taipei,
0040-4039/87 $3.00 + .OO Pergamon Journals Ltd.
2853-2856,1987
Taiwan,
CYANIDE
HYDROCARBONS and Ming-Yi
Chen
National
Taiwan
University
Republic
of China
Summary: By catalysis of AIBN, tosyl cyanide adds in a regio- and stereoselective manner to unsaturated hydrocarbons, including alkenes, dienes and 1-hexyne. Accompanied intramolecular cyclization and ring cleavage were 1,5-cyclooctadiene and pinenes. effected in reactions with norbornadiene, Toluenesulfonyl
cyanide
(TsCN)
has been successfully
Due to the strong
induction
utilized
of the sulfonyl
in many
group,
TsCN
synthetic
aspects.
functions
as a CN transfer agent in reactions with C-, N-, 0- and S1 The reaction is thought to involve an addition-elimination
nucleophiles.
TsCN a12so undergoes
process. dipolar
species.
sulfonyl
group.
especially
cycloadditions
The reactivity
investigated
is greatly
The cycloaddition
us3eful intermediate
nucleosides.
However, except
readily
product
enhanced
for a preliminary
1,3-dienes
by the effect
and 1,3of the
from TsCN and cyclopentadiene
in preparation
the free radical
with
of the carbocyclic
type reaction
report
analogs
is an of
of TsCN was rarely
of the photochemical
reaction
of
TsCN with three alkenes, including an ambiguous stereochemical outcome in one 4 example. We thus further exploited the free radical type addition of TsCN to a variety Under appropriate benzene
of unsaturated an atmosphere unsaturated
hydrocarbons. of nitrogen, hydrocarbon
(or 1,2-dichlorobenzene,
Exclusion
of oxygen
analysis,
and the products
shown
in Table
fashion. account
were
I, the reaction
of TsCN
The reaction
isolated
with AIBN
was monitored
in a regio-
t
Me2C(CN1* Ts* Ts++
t
_N
TsCN
--3
P
2
scheme
2 Me2C(CN)* Ts*
t
)c=c:
+
Ts-+
t
--*
Ts+-+-CN
TsCN
2853
(0.25 mmol). by the TLC method.
As
and stereoselective
in the following
for this result. Me2C(CNlN=NC(CN)Me2
and an
in refluxing
by the chromatographic
proceeded
as depicted
(2.5 mmoll
was performed
25 mL) by initiation
was necessary.
A chain mechanism
the reaction (25 mmol)
Me2C(CNj2
+
Ts*
is proposed
to
2854
Table I, _
Real
3
4
5
Yield, %
18
80
20
70
80
6
[3$ X4% YmH: 72 @4$ X-H, Y=CN:6 c&d: 5
120
16
78
4
?I
0
6% 0 8;
I sotuted
80
I
2
ion
TlhR;e
*
6
ci9-
120
36
15
7
49 ~
120
36
16
60
24
68
60
24
80
36
8 9 0
X
(@I):
58
(9&
30
QQ.g): 31 (l0&:
29
2855
Entry Similar
2 indicated
this reaction
stereochemistry
was further
and 1,5-cyclooctadiene to norbornadiene
to give exe
thus provided
an intramolecular
diene,
On the other
(416
the strained Similar
Although
previous Thus,
conditions.
(%)
regioselective nearly
addition
and
addition
the cyano
functional
groups
the organic
synthesis
Corson,
Gratitude
A. M.; Jagt,
lx,
gave a single
product
also produced
unsuccessful
was realized
($1 in a the
attempt,4
by catalysis
isomers
(21
and
(3)
in
for preparation
Since
furthur
the chemistry
application
Shie-Ming
Peng
of compounds of these
of our method
Science
Council
(the National
in
for
Taiwan
J. C. Tetrahedron
J. Th. Tetrahedron Cm.
ll,
u.
lm,
w.
lz,
36, 1654.
967.
(b)
3763.
(cl
(dl Treuner,
U.
559. R. G.; Nyquist,
(bl Van Leusen,
Jagt,
J. C.; Van Leusen,
3. (al Cermak,
A. M. &.
R. G.; Evans,
J. C. Tetrahedron E.
R. Tetrahedron
N. J. ?I. Org.
Y. J. J. m.
Research
M. la
S. J.; Davies,
C&.
&.
and w Chem.
D. J. 2. Org.
J. K.; Singer,
35,
la,
(c)
92, 1343.
1974, 39,564.
Lett.ym,
(Ml,768
lz,
1970, 971.
des m-Bas
22, 2331.
1981, 46, 3268.
T. E. J. !&LII. a.
S. J.; Harrington,
F. P. J. w.
Chim. -A. M. 4. Org. Cm.
R. C.; Vince,
5. (a) Cristol,
E. B.; Corson,
A. M.; Jagt,
J. C.; Van Leusen,
B. L.; Oppenheimer,
Cristol,
cycloaddi-
and Notes:
4096.
4. Pews,
undergoes
for X-ray measurements.
2. (a) Pews,
Cherng,
(&I.
in the free radical
is due to the National
F. P.; Pews, R. G. 4. Org.
(d) Jagt,
that TsCN
method
groups.
developed, a is promising.
M. S. A.; Hackmann,
Synthesis,
(5-1 in a 71 % yield.
to previous
an expedient
and to Professor
1. (a) Van Leusen, Vrijland,
compound
an opening7of
of product
resulted
two geometric
of TsCN
1,5-cycloocta-
caused
2,3-dimethyl-1,3-butadiene
are well
support,
University)
compound
to cyclopentadiene
and sulfonyl
Acknowledgment. financial
norbornadiene
addition
With
(%I.'
a low yield
1,4-additions
with
with
to give the bicylic
has demonstrated
afforded
we provide
containing
References
to produce
of anti addition.
amounts.
summary,
In
product
of TsCN to 1-hexyne
but the reaction
equal
in reactions
of TsCN to 6-pinene
On contrary
(2).
in the manner Homoconjugative
occurred
afforded
report
The reaction
yield.
1,4-adducts of AIBN,
ring
a-pinene
1,3-dienes, 2 we found
tion with modest
the major
addition
hand,
with
revealed adducts.
cyclization
four-membered
reaction
occurred
m.
(c) Fang,
(b) Kam, J. M.;
(S), 180.
Commun.
w,
1397.
1964, 29, 1282.
M. S. J. cm.
&.
(b) lm, 88,
1529. 6. (al Dowbenko,
R. Tetrahedron
1964, 20, 1843.
(b) Dowbenko,
R. J. Am.
2856
m.
(c) Friedman,
l/$&l, 86, 946.
&.
(d) Winkler,
J. D.; Sridar,
L. 3. &I. m.
G .; Alvernhe,
G.; Laurent,
V. J. -Am. Chem. a. A. Tetrahedron u.
7. Oldroyd,
D. M.; Fisher,
G. S.; Goldblatt,
w,
&.
1964, 86,
108, 17Or
1885.
(e) Haufe,
1986, 27, 4449. L. G.
Am. Chem. ---
Sot.
1950,
72, 2407. 8. (a) Rappoport, Pub.
(b) Jones,
Oxford, 9.
(IR, (G),
1979, Vol. 3, pp 171-213.
All products
MS,
(4), (a)
'C (lit."
H-7),
1.85-2.07 s), 2.47 3.04
in CDC13)
1.75-1.78
(1 H, s, H-4), 3.01
crystalline (lit."
(i), mp 117-118'C;
of (3a) and (3) were
2.44
(1 H, m, H-l),
(2 H, m, H-5, H-6),
confirmed
are reported
(3 H, s), 2.51 7.36-7.75
in 6 values:
(4 H, m);
q
(Z), mp 136-138 (a),
(%),
mp 109-110 mp 96-97'C.
diffractions (a),
'H NMR
1.68
(1 H, t, J =
1.86 (1 H, cl, J = 1.2 Hz,
(1 H, s, H-3),
(1 H, ddd, J
7.34-7.74
123-124'C;
spectra
(z), (s),
Some of pertinent
(1 H, ddd, J = 15.4, 2.89
Products
compounds.
by X-ray
on request).
and compatible
211-212OC);
(G),
(2 H, m, H-l, H-2),
(1 H, s, H-5),
(5 H, m), 2.18
analyses
structures.
mp 212-214'C
data are available
(obtained
5.1 Hz, H-6),
elemental
are colorless
(a),
107-1lO'C);
(supplemental
HZ,
and (a)
133-135'C);
The structures spectra
had satisfactory
l3C NMR) for the proposed
'H and
OC (lit.4
2.39
z. Ed. The Chemistry -of the Cyan0 Group, x, Interscience D. N. Ed. In Comprehensive Organic Chemisry, PergaItIOn:
2.55
H-7),
(1 H, d, J = 12
(it,, 1.24-1.34
(2 H, m),
12.0, 5.5 Hz, H-3),
2.43
15.4, 12.5, 7.4 Hz, H-2),
(4 H, m);
(3 H, 2.98-
(z), 1.28 (3 H, s), 1.30 (3 H,
s), 1.66 (1 H, m), 2.44 (3 H, s), 3.66 (2 H, s, H-7), 5.45 (1 l-l,br s, H-2), 7.36-7.75 (4 H, m); (&), 2.41 (1 H, ddd, J = 14.7, 4.5, 4.2 HZ, H-4 ), 2.43 (3 H, s), 2.82
4.2,
2.7,
(1 H, ddd, J = 14.7, 8.4,
2.7 Hz, H-3),
4.32
dd, J = 5.6, 2.7 Hz, H-2), (4 H, m); 3.82
(2 H, s), 7.33-7.70
(3 H, s), 3.03 s), 2.79 2.63
J.
C.
q
(1 H, dd, J
(4 H, m);
(2 H, s), 3.80
(2 H, t), 6.82
(2 H, t), 6.23
lo. Jagt,
6.04
1.40 (1 H, s), 1.84
(B),
2.7 Hz, H-4 ), 3.60
(1 H, ddd, J
5.6, 2.1 Hz, H-l),
(2 H, s), 7.33-7.76 7.32-7.76
Ph. D. Thesis,
Groningen
78.
(Received in Japan 31 January 19871
H-5),
5.87
(1 H,
7.33-7.72
(3 H, s), 3.03
(2 H, s),
1.73 (1 H, s), 1.85 (1 H, s), 2.44
(1 H, s), 7.36-7.76
(1 H, $1,
q
(1 H, s), 2.42 (s),
(1 H, ddd, J =
6.4, 4.5, 2.1 Hz,
(4 H, m);
(4 H, m).
(s),
(E), 2.41
2.45
(3 H,
(3 H, s),
(4 H, m). University,
The Netherlands,
E,
FREE RADICAL
TYPE ADDITION
OF TOLUENESULFONYL
TO UNSATURATED Jim-Min Department
Fang*
of Chemistry, Taipei,
0040-4039/87 $3.00 + .OO Pergamon Journals Ltd.
2853-2856,1987
Taiwan,
CYANIDE
HYDROCARBONS and Ming-Yi
Chen
National
Taiwan
University
Republic
of China
Summary: By catalysis of AIBN, tosyl cyanide adds in a regio- and stereoselective manner to unsaturated hydrocarbons, including alkenes, dienes and 1-hexyne. Accompanied intramolecular cyclization and ring cleavage were 1,5-cyclooctadiene and pinenes. effected in reactions with norbornadiene, Toluenesulfonyl
cyanide
(TsCN)
has been successfully
Due to the strong
induction
utilized
of the sulfonyl
in many
group,
TsCN
synthetic
aspects.
functions
as a CN transfer agent in reactions with C-, N-, 0- and S1 The reaction is thought to involve an addition-elimination
nucleophiles.
TsCN a12so undergoes
process. dipolar
species.
sulfonyl
group.
especially
cycloadditions
The reactivity
investigated
is greatly
The cycloaddition
us3eful intermediate
nucleosides.
However, except
readily
product
enhanced
for a preliminary
1,3-dienes
by the effect
and 1,3of the
from TsCN and cyclopentadiene
in preparation
the free radical
with
of the carbocyclic
type reaction
report
analogs
is an of
of TsCN was rarely
of the photochemical
reaction
of
TsCN with three alkenes, including an ambiguous stereochemical outcome in one 4 example. We thus further exploited the free radical type addition of TsCN to a variety Under appropriate benzene
of unsaturated an atmosphere unsaturated
hydrocarbons. of nitrogen, hydrocarbon
(or 1,2-dichlorobenzene,
Exclusion
of oxygen
analysis,
and the products
shown
in Table
fashion. account
were
I, the reaction
of TsCN
The reaction
isolated
with AIBN
was monitored
in a regio-
t
Me2C(CN1* Ts* Ts++
t
_N
TsCN
--3
P
2
scheme
2 Me2C(CN)* Ts*
t
)c=c:
+
Ts-+
t
--*
Ts+-+-CN
TsCN
2853
(0.25 mmol). by the TLC method.
As
and stereoselective
in the following
for this result. Me2C(CNlN=NC(CN)Me2
and an
in refluxing
by the chromatographic
proceeded
as depicted
(2.5 mmoll
was performed
25 mL) by initiation
was necessary.
A chain mechanism
the reaction (25 mmol)
Me2C(CNj2
+
Ts*
is proposed
to
2854
Table I, _
Real
3
4
5
Yield, %
18
80
20
70
80
6
[3$ X4% YmH: 72 @4$ X-H, Y=CN:6 c&d: 5
120
16
78
4
?I
0
6% 0 8;
I sotuted
80
I
2
ion
TlhR;e
*
6
ci9-
120
36
15
7
49 ~
120
36
16
60
24
68
60
24
80
36
8 9 0
X
(@I):
58
(9&
30
QQ.g): 31 (l0&:
29
2855
Entry Similar
2 indicated
this reaction
stereochemistry
was further
and 1,5-cyclooctadiene to norbornadiene
to give exe
thus provided
an intramolecular
diene,
On the other
(416
the strained Similar
Although
previous Thus,
conditions.
(%)
regioselective nearly
addition
and
addition
the cyano
functional
groups
the organic
synthesis
Corson,
Gratitude
A. M.; Jagt,
lx,
gave a single
product
also produced
unsuccessful
was realized
($1 in a the
attempt,4
by catalysis
isomers
(21
and
(3)
in
for preparation
Since
furthur
the chemistry
application
Shie-Ming
Peng
of compounds of these
of our method
Science
Council
(the National
in
for
Taiwan
J. C. Tetrahedron
J. Th. Tetrahedron Cm.
ll,
u.
lm,
w.
lz,
36, 1654.
967.
(b)
3763.
(cl
(dl Treuner,
U.
559. R. G.; Nyquist,
(bl Van Leusen,
Jagt,
J. C.; Van Leusen,
3. (al Cermak,
A. M. &.
R. G.; Evans,
J. C. Tetrahedron E.
R. Tetrahedron
N. J. ?I. Org.
Y. J. J. m.
Research
M. la
S. J.; Davies,
C&.
&.
and w Chem.
D. J. 2. Org.
J. K.; Singer,
35,
la,
(c)
92, 1343.
1974, 39,564.
Lett.ym,
(Ml,768
lz,
1970, 971.
des m-Bas
22, 2331.
1981, 46, 3268.
T. E. J. !&LII. a.
S. J.; Harrington,
F. P. J. w.
Chim. -A. M. 4. Org. Cm.
R. C.; Vince,
5. (a) Cristol,
E. B.; Corson,
A. M.; Jagt,
J. C.; Van Leusen,
B. L.; Oppenheimer,
Cristol,
cycloaddi-
and Notes:
4096.
4. Pews,
undergoes
for X-ray measurements.
2. (a) Pews,
Cherng,
(&I.
in the free radical
is due to the National
F. P.; Pews, R. G. 4. Org.
(d) Jagt,
that TsCN
method
groups.
developed, a is promising.
M. S. A.; Hackmann,
Synthesis,
(5-1 in a 71 % yield.
to previous
an expedient
and to Professor
1. (a) Van Leusen, Vrijland,
compound
an opening7of
of product
resulted
two geometric
of TsCN
1,5-cycloocta-
caused
2,3-dimethyl-1,3-butadiene
are well
support,
University)
compound
to cyclopentadiene
and sulfonyl
Acknowledgment. financial
norbornadiene
addition
With
(%I.'
a low yield
1,4-additions
with
with
to give the bicylic
has demonstrated
afforded
we provide
containing
References
to produce
of anti addition.
amounts.
summary,
In
product
of TsCN to 1-hexyne
but the reaction
equal
in reactions
of TsCN to 6-pinene
On contrary
(2).
in the manner Homoconjugative
occurred
afforded
report
The reaction
yield.
1,4-adducts of AIBN,
ring
a-pinene
1,3-dienes, 2 we found
tion with modest
the major
addition
hand,
with
revealed adducts.
cyclization
four-membered
reaction
occurred
m.
(c) Fang,
(b) Kam, J. M.;
(S), 180.
Commun.
w,
1397.
1964, 29, 1282.
M. S. J. cm.
&.
(b) lm, 88,
1529. 6. (al Dowbenko,
R. Tetrahedron
1964, 20, 1843.
(b) Dowbenko,
R. J. Am.
2856
m.
(c) Friedman,
l/$&l, 86, 946.
&.
(d) Winkler,
J. D.; Sridar,
L. 3. &I. m.
G .; Alvernhe,
G.; Laurent,
V. J. -Am. Chem. a. A. Tetrahedron u.
7. Oldroyd,
D. M.; Fisher,
G. S.; Goldblatt,
w,
&.
1964, 86,
108, 17Or
1885.
(e) Haufe,
1986, 27, 4449. L. G.
Am. Chem. ---
Sot.
1950,
72, 2407. 8. (a) Rappoport, Pub.
(b) Jones,
Oxford, 9.
(IR, (G),
1979, Vol. 3, pp 171-213.
All products
MS,
(4), (a)
'C (lit."
H-7),
1.85-2.07 s), 2.47 3.04
in CDC13)
1.75-1.78
(1 H, s, H-4), 3.01
crystalline (lit."
(i), mp 117-118'C;
of (3a) and (3) were
2.44
(1 H, m, H-l),
(2 H, m, H-5, H-6),
confirmed
are reported
(3 H, s), 2.51 7.36-7.75
in 6 values:
(4 H, m);
q
(Z), mp 136-138 (a),
(%),
mp 109-110 mp 96-97'C.
diffractions (a),
'H NMR
1.68
(1 H, t, J =
1.86 (1 H, cl, J = 1.2 Hz,
(1 H, s, H-3),
(1 H, ddd, J
7.34-7.74
123-124'C;
spectra
(z), (s),
Some of pertinent
(1 H, ddd, J = 15.4, 2.89
Products
compounds.
by X-ray
on request).
and compatible
211-212OC);
(G),
(2 H, m, H-l, H-2),
(1 H, s, H-5),
(5 H, m), 2.18
analyses
structures.
mp 212-214'C
data are available
(obtained
5.1 Hz, H-6),
elemental
are colorless
(a),
107-1lO'C);
(supplemental
HZ,
and (a)
133-135'C);
The structures spectra
had satisfactory
l3C NMR) for the proposed
'H and
OC (lit.4
2.39
z. Ed. The Chemistry -of the Cyan0 Group, x, Interscience D. N. Ed. In Comprehensive Organic Chemisry, PergaItIOn:
2.55
H-7),
(1 H, d, J = 12
(it,, 1.24-1.34
(2 H, m),
12.0, 5.5 Hz, H-3),
2.43
15.4, 12.5, 7.4 Hz, H-2),
(4 H, m);
(3 H, 2.98-
(z), 1.28 (3 H, s), 1.30 (3 H,
s), 1.66 (1 H, m), 2.44 (3 H, s), 3.66 (2 H, s, H-7), 5.45 (1 l-l,br s, H-2), 7.36-7.75 (4 H, m); (&), 2.41 (1 H, ddd, J = 14.7, 4.5, 4.2 HZ, H-4 ), 2.43 (3 H, s), 2.82
4.2,
2.7,
(1 H, ddd, J = 14.7, 8.4,
2.7 Hz, H-3),
4.32
dd, J = 5.6, 2.7 Hz, H-2), (4 H, m); 3.82
(2 H, s), 7.33-7.70
(3 H, s), 3.03 s), 2.79 2.63
J.
C.
q
(1 H, dd, J
(4 H, m);
(2 H, s), 3.80
(2 H, t), 6.82
(2 H, t), 6.23
lo. Jagt,
6.04
1.40 (1 H, s), 1.84
(B),
2.7 Hz, H-4 ), 3.60
(1 H, ddd, J
5.6, 2.1 Hz, H-l),
(2 H, s), 7.33-7.76 7.32-7.76
Ph. D. Thesis,
Groningen
78.
(Received in Japan 31 January 19871
H-5),
5.87
(1 H,
7.33-7.72
(3 H, s), 3.03
(2 H, s),
1.73 (1 H, s), 1.85 (1 H, s), 2.44
(1 H, s), 7.36-7.76
(1 H, $1,
q
(1 H, s), 2.42 (s),
(1 H, ddd, J =
6.4, 4.5, 2.1 Hz,
(4 H, m);
(4 H, m).
(s),
(E), 2.41
2.45
(3 H,
(3 H, s),
(4 H, m). University,
The Netherlands,
E,