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A new access to phosphaindolizines by [3+2] cycloaddition of azomethine ylides onto phosphaalkynes
0040.4039192
TetrahedronLetkrs, Vol. 33. No. 8, pp. 1049.1052, 1992 Printed in Great Britain
Pcrgmon
A NEW ACCESS TO PHOSPHAINDOLIZINES
BY [3+2]
CYCLOADDITION
$3.00 + .oo
Press plc
OF AZOMETHINE
YLIDES ONTO PHOSPHAALKYNES’
Uwe BergstrBOer, Andreas Hoffmann, Fachbereich
Chemie der Universitht
Kaiserslautern,
and Manfred
Regitz*
Erwin-Schr6dinger_Stasse,
D-6750 Kaiserslautern,
Federal Republic of Germany
Abstract: Azomethine ylides such as 1 and 4 in which the nitrogen atom is incorporated undergo regiospecific [3 + 21 cycloadditions
with the phosphaakynes
in a six-membered heterocyclic ring
2a and b at 130-l 40 “C to furnish the phosphaindolizines
3 and 5a-c after elimination of ethyl formate or hydrogen cyanide, respectively.
In contrast. dipoles of the type 6 react
unspecifically with the phosphaalkyne 2a to yield the regioisomers 7 and 8.
Phospholes
with a X3,&phosphorus
role in the development are a structural
component
cyclocondensation4, cycloadditions
and other heteroatoms
of the chemistry
of all the phosphaindolizines
by O/P exchange
of mesoionic
both the latter procedures, With the previously alkynes 2, we now describe
of low coordinated
in oxazolium
compounds elimination
unknown
in the ring system play an important
phosphorus213.
to be discussed
salts with tris[trimethylsilyl]phosphine5,
to phosphaalkyne@
applicable
synthesis
c’
‘COzEt
1’
1A +
t5u-C,P
t
CO,Et A!!
2a
-
and by [3+2] In
reaction.
of the title compounds.
le
N’
by
ylides of the types 1, 4, and 6 with phospha-
@ CJ H
which
or of nitrile ylides to phosphaalkenes7.
reactions follow the actual ring-forming reaction of azomethine
a new and generally
1,3-Azaphospholes,
here, have been prepared
toluene, 130-1LOOC (glass pressure tube) -HCO*Et
1050
When
the
cycloaddition8 elimination
pyridinium
reaction
ylide
1 is heated
with
takes place and is followed,
of ethyl formate
the
phosphaalkyne
under the harsh reaction
to furnish the [1,3]azaphospholo[l,5-alpyridine
2a, a regiospecific
[3+2]
conditions
by an
3 (30% yield). The 3rP-NMR
chemical shift (6 = + 162.4) as well as the 13C-NMR signals of the azaphosphole coupling
constants
ring and their respective
[A = 133.4 (‘JC p = 47.3 Hz, C3); 155.1 (‘JC P = 45.1 Hz, Cl);
C8a)] agree very well with the values for the independently
preiared
employed,
142.1 (*Jcp
methyl derivative
= 9.2 Hz,
(3; Me in place of
tBu)g. lsoquinolinium
and phthalazinium
phosphaalkynes
2a and 2b via [3+2]
which, however,
necessitates
are obtained
(4a and b, respectively)
methylides cycloaddition
the addition
and elimination
of triethylamine)
react
similarly
(in this case of hydrogen
and the condensed
1,3-azaphospholes
with the cyanide
5a-c
(2.540% yield).
8 +
6
R-C,P tube)
-HCN
2
These reactions reactions
1 + 2a=e
The constitution unequivocally
Fig. 1.
are also regiospecific
5
although
the dipole orientation
is the reverse
R
of that in the
3. of 5b - and thus the direction
by an X-ray structure
of addition
of 4b to 2a - has been confirmed
analysis (Fig. 1)‘O.
Crystal structure of the phosphaindolizine and bond angles [“I
5b. - Selected bond lengths [A]
1051
Bond lengths N2 -Nl 1.375(4)
P -c2 N2 -03 Cl 2 -Cl3 Nl -Cl3
c3 C7 P c3
1.754(3) 1.286(4) 1.431(5) 1.365(4)
Bond angles c13-P -c2 C3 -c2 -P C2 -C3 -Nl C31 -C3 -Nl c21 -c2 -P
-c31 -C6 -Cl3 -c2
1.419(5) 1.428(5) 1.734(4) 1.371(5)
C12-Cl3 Cl3-Ni Nl -Cl3 Cl3-Ni c31 -c3
89.9(2) 111.5(3) 112.9(3) 117.6(3) 123.8(2)
-P -C3 -P -N2 -c2
c7 -Cl2 Nl -C3 C31 -N3 c2 -c21
131.2(3) 114.0(3) 111B(2) 126.5(3) 129.5(3)
c21 C3 N2 Cl2
-c2 -C31 -Ni -Cl3
1.392(5) 1.372(4) 1.140(5) 1.533(5)
-c3 -N3 -C3 -Nl
124.7(3) 178.6(4) 119.4(3) 117.1(3)
The bond lengths for P-C2 and P-Cl3 [1.754(3) and 1.734(4) A, respectively] are intermediate between those of P/C single and P/C double bonds and are indicative of electron delocalization in the phosphorus-containing
heteroaromatic
ring. The bond angle C13-P-C2 [89.9(2)“]
is in the region
characteristic for 1,3-azaphospholes2. When the 31P- and 13C-NMR data of the 1,9azaphosphole
systems of 5a-c are considered, it is
seen that they all lie in narrow absorption ranges [31P: 6 = +72.9 to +83.3; 13C: 6 = 104.9-109.7 (2Jc P = 5.5-6.1 Hz, C3); 153.9-161.8 (‘& = 42.3-59.9 Hz, C12a); 172.8-175.3 (1Jc,p = 54.3-55.3 Hz, C2)]. in conjunction with the crystal structure analysis of 5b, these data confirm that the products 5a-c all belong to the same structural type. Although the pyridinium, pyridazinium, and 1,4-diazinium dicyanomethylides
6a-c all react with the
phosphaalkyne 2a in the manner described above (the elimination of HCN is again promoted by the addition of 1 mol of NEt.J, the primary step is completely non-selective so that 1:l mixtures of 7a-c with 8a-c are formed (40-60% yield).
+2a,
toluene, 130-lLO°C
(glass -HCN
pressure
tube1
6-8 X Y
8
7
6 a
b
c
d
t
f
Q
h
i
CH CH
N CH
CH N
CH CMe
CH cteu
CH OiPr
CH C-CO,Me
CH C-CEN
CH C-COPh
When donor-substituents
were introduced into the 4 position of 6a, is was found that a methyl
group had no effect on the product ratio (7d:8d = 50:50) whereas tert-but+ and isopropoxy groups favoured the formation of the isomer 7 (7e:6e = 80:20; 7f:8f = 1OO:O).Acceptor substituents exhibited
1052
neutral effects (7g-i:8g-i = 50:50)“. 60, 0.015-0.049
Acknowledgements:
lndustrie for generous
References
and Notes
Organophosphorus
mixtures
can be separated
2:1), as has been demonstrated
We thank
Chemischen
1.
The product
mm, ether/pentane,
the
Deutsche
by MPLC (Merck silica gel 7a/8a.
for the example
Forschungsgemeinschaft
and
the
Fonds
der
financial support.
Compounds;
Part 54. For Part 53, see: Breit, B.; Memmesheimer,
H., Boese,
R.; Regitz, M. Chem. Ber. 1992, 725, in press. 2.
Schmidpeter,
A.; Karaghiosoff,
Elements (Roesky, 3.
Schmidpeter,
K. in Rings, Clusters and Polymers
H. W., ed), Elsevier, Amsterdam
A. in Multiple
of h-lain Group and Transition
1989, pp. 307-343.
Bonds and Low Coordination
in Phosphorus
Chemistry
(Regitz,
M.,
Scherer, 0. J., eds.), Thieme, Stuttgart 1990, pp. 258-286. 4.
See, e.g., Issleib, Issleib,
K.; Vollmer,
R. L
R.; Oehme,
Anorg.
A//g.
H.; Meyder, Chem.
Lett. 1978,
H. Tetrahedron
198:,
481,
22-32;
Heinicke,
79, 441-444;
J.; Tzschach,
A.
Lett. 1982, 23, 3643-3646.
Tetrahedron 5.
K.; Vollmer,
See, e.g., Mtirkl, G.; Dorfmeister,
G. Tetrahedron
Leff. 1986, 27, 4419-4442
as well as Tetrahedron
Lett. 1987, 28, 1089-1092. 6.
RGsch, W.; Richter, H.; Regitz, M. Chem. Ber. 1987, 120, 1809-1813;
Fuchs, E. P. 0.; Hermesdon, Chem. 1988, 338, 329-
M.; Schnurr, W.; Rosch, W.; Heydt, H.; Regitz, M.; Binger, P. J. Organomet. 340; see also Regitz, M. in Ref.3, pp. 73-74. 7.
M%kl, G.; Troetsch-Schaller, B. unpublished
8.
1990,90,
Lett. 1988, 29, 785788;
results with RC(OTms) = PTms, University
Reviews on the cycloaddition 1988, 100, 1541-1565;
9.
I.; Holzl, W. Tetrahedron reactivity
of Kaiserslautern,
of phosphaalkynes:
1989.
Regitz, M.; Binger,
Chem. lnt. Ed. Engl. 1988, 27, 1484-1508;
Angew.
Regitz M.; Burkhardt, P. Angew.
Chem.
Regitz, M. Chem. Rev.
191-213.
Cyclocondensation Schmidpeter,
of pyridinium
A.; Spindler,
salts with
PCI,:
Bansal,
R. K.; Karaghiosoff,
C. Chem. Ber. 1991, 124, 475-480. Further examples
K.; Gupta,
N.;
of this methodo-
logy are given therein. 10.
C,,H;,N,P.
M = 267.3 g.mol-‘,
orthorhombic.
13.780(2) A, V = 1325.5(6) A3, Z = 4, d,,,,. The measurements MO K,
radiation;
were performed
Pnma (No.62);
with an Enraf-Nonius
1116 independent
and the subsequent
refinement
CAD4 diffractometer
number of parameters
by direct
methods
bond
11.
angles,
as well as temperature Crystallographic
Cambridge
CB2 1 EW, U.K.
Phosphaindolizines
Data
of the structural
salts: MBrkl, G.; Pflaum, S. Tetrahedron
(Received in Germany 27 November
1991)
factors Centre,
c =
p = 1.9 cm-‘.
with monochromatic
are available University
type 8a were also obtained Lett. 1987,28,
151 l-1514.
converged
solution at R =
tables of bond lengths and
on request
Chemical
134. The structure
[SHElX-761
0.0474 and Rw = 0.0470. Further details such as atomic coordinates, Cambridge
b = 6.948(2),
coefficient
[h: 0 - > + 16; k: 0 -> + 7; I: 0 -> + 161 with 4.0” 5 28
reflections
I 50”, of which 985 with I > 2u(l) were observed; [SHElX86]
a = 13.844(4),
= 1.339 g cm3, absorption
from The Director
Laboratory,
Lensfield
by O/P exchange
of the Road,
in oxazolium
TetrahedronLetkrs, Vol. 33. No. 8, pp. 1049.1052, 1992 Printed in Great Britain
Pcrgmon
A NEW ACCESS TO PHOSPHAINDOLIZINES
BY [3+2]
CYCLOADDITION
$3.00 + .oo
Press plc
OF AZOMETHINE
YLIDES ONTO PHOSPHAALKYNES’
Uwe BergstrBOer, Andreas Hoffmann, Fachbereich
Chemie der Universitht
Kaiserslautern,
and Manfred
Regitz*
Erwin-Schr6dinger_Stasse,
D-6750 Kaiserslautern,
Federal Republic of Germany
Abstract: Azomethine ylides such as 1 and 4 in which the nitrogen atom is incorporated undergo regiospecific [3 + 21 cycloadditions
with the phosphaakynes
in a six-membered heterocyclic ring
2a and b at 130-l 40 “C to furnish the phosphaindolizines
3 and 5a-c after elimination of ethyl formate or hydrogen cyanide, respectively.
In contrast. dipoles of the type 6 react
unspecifically with the phosphaalkyne 2a to yield the regioisomers 7 and 8.
Phospholes
with a X3,&phosphorus
role in the development are a structural
component
cyclocondensation4, cycloadditions
and other heteroatoms
of the chemistry
of all the phosphaindolizines
by O/P exchange
of mesoionic
both the latter procedures, With the previously alkynes 2, we now describe
of low coordinated
in oxazolium
compounds elimination
unknown
in the ring system play an important
phosphorus213.
to be discussed
salts with tris[trimethylsilyl]phosphine5,
to phosphaalkyne@
applicable
synthesis
c’
‘COzEt
1’
1A +
t5u-C,P
t
CO,Et A!!
2a
-
and by [3+2] In
reaction.
of the title compounds.
le
N’
by
ylides of the types 1, 4, and 6 with phospha-
@ CJ H
which
or of nitrile ylides to phosphaalkenes7.
reactions follow the actual ring-forming reaction of azomethine
a new and generally
1,3-Azaphospholes,
here, have been prepared
toluene, 130-1LOOC (glass pressure tube) -HCO*Et
1050
When
the
cycloaddition8 elimination
pyridinium
reaction
ylide
1 is heated
with
takes place and is followed,
of ethyl formate
the
phosphaalkyne
under the harsh reaction
to furnish the [1,3]azaphospholo[l,5-alpyridine
2a, a regiospecific
[3+2]
conditions
by an
3 (30% yield). The 3rP-NMR
chemical shift (6 = + 162.4) as well as the 13C-NMR signals of the azaphosphole coupling
constants
ring and their respective
[A = 133.4 (‘JC p = 47.3 Hz, C3); 155.1 (‘JC P = 45.1 Hz, Cl);
C8a)] agree very well with the values for the independently
preiared
employed,
142.1 (*Jcp
methyl derivative
= 9.2 Hz,
(3; Me in place of
tBu)g. lsoquinolinium
and phthalazinium
phosphaalkynes
2a and 2b via [3+2]
which, however,
necessitates
are obtained
(4a and b, respectively)
methylides cycloaddition
the addition
and elimination
of triethylamine)
react
similarly
(in this case of hydrogen
and the condensed
1,3-azaphospholes
with the cyanide
5a-c
(2.540% yield).
8 +
6
R-C,P tube)
-HCN
2
These reactions reactions
1 + 2a=e
The constitution unequivocally
Fig. 1.
are also regiospecific
5
although
the dipole orientation
is the reverse
R
of that in the
3. of 5b - and thus the direction
by an X-ray structure
of addition
of 4b to 2a - has been confirmed
analysis (Fig. 1)‘O.
Crystal structure of the phosphaindolizine and bond angles [“I
5b. - Selected bond lengths [A]
1051
Bond lengths N2 -Nl 1.375(4)
P -c2 N2 -03 Cl 2 -Cl3 Nl -Cl3
c3 C7 P c3
1.754(3) 1.286(4) 1.431(5) 1.365(4)
Bond angles c13-P -c2 C3 -c2 -P C2 -C3 -Nl C31 -C3 -Nl c21 -c2 -P
-c31 -C6 -Cl3 -c2
1.419(5) 1.428(5) 1.734(4) 1.371(5)
C12-Cl3 Cl3-Ni Nl -Cl3 Cl3-Ni c31 -c3
89.9(2) 111.5(3) 112.9(3) 117.6(3) 123.8(2)
-P -C3 -P -N2 -c2
c7 -Cl2 Nl -C3 C31 -N3 c2 -c21
131.2(3) 114.0(3) 111B(2) 126.5(3) 129.5(3)
c21 C3 N2 Cl2
-c2 -C31 -Ni -Cl3
1.392(5) 1.372(4) 1.140(5) 1.533(5)
-c3 -N3 -C3 -Nl
124.7(3) 178.6(4) 119.4(3) 117.1(3)
The bond lengths for P-C2 and P-Cl3 [1.754(3) and 1.734(4) A, respectively] are intermediate between those of P/C single and P/C double bonds and are indicative of electron delocalization in the phosphorus-containing
heteroaromatic
ring. The bond angle C13-P-C2 [89.9(2)“]
is in the region
characteristic for 1,3-azaphospholes2. When the 31P- and 13C-NMR data of the 1,9azaphosphole
systems of 5a-c are considered, it is
seen that they all lie in narrow absorption ranges [31P: 6 = +72.9 to +83.3; 13C: 6 = 104.9-109.7 (2Jc P = 5.5-6.1 Hz, C3); 153.9-161.8 (‘& = 42.3-59.9 Hz, C12a); 172.8-175.3 (1Jc,p = 54.3-55.3 Hz, C2)]. in conjunction with the crystal structure analysis of 5b, these data confirm that the products 5a-c all belong to the same structural type. Although the pyridinium, pyridazinium, and 1,4-diazinium dicyanomethylides
6a-c all react with the
phosphaalkyne 2a in the manner described above (the elimination of HCN is again promoted by the addition of 1 mol of NEt.J, the primary step is completely non-selective so that 1:l mixtures of 7a-c with 8a-c are formed (40-60% yield).
+2a,
toluene, 130-lLO°C
(glass -HCN
pressure
tube1
6-8 X Y
8
7
6 a
b
c
d
t
f
Q
h
i
CH CH
N CH
CH N
CH CMe
CH cteu
CH OiPr
CH C-CO,Me
CH C-CEN
CH C-COPh
When donor-substituents
were introduced into the 4 position of 6a, is was found that a methyl
group had no effect on the product ratio (7d:8d = 50:50) whereas tert-but+ and isopropoxy groups favoured the formation of the isomer 7 (7e:6e = 80:20; 7f:8f = 1OO:O).Acceptor substituents exhibited
1052
neutral effects (7g-i:8g-i = 50:50)“. 60, 0.015-0.049
Acknowledgements:
lndustrie for generous
References
and Notes
Organophosphorus
mixtures
can be separated
2:1), as has been demonstrated
We thank
Chemischen
1.
The product
mm, ether/pentane,
the
Deutsche
by MPLC (Merck silica gel 7a/8a.
for the example
Forschungsgemeinschaft
and
the
Fonds
der
financial support.
Compounds;
Part 54. For Part 53, see: Breit, B.; Memmesheimer,
H., Boese,
R.; Regitz, M. Chem. Ber. 1992, 725, in press. 2.
Schmidpeter,
A.; Karaghiosoff,
Elements (Roesky, 3.
Schmidpeter,
K. in Rings, Clusters and Polymers
H. W., ed), Elsevier, Amsterdam
A. in Multiple
of h-lain Group and Transition
1989, pp. 307-343.
Bonds and Low Coordination
in Phosphorus
Chemistry
(Regitz,
M.,
Scherer, 0. J., eds.), Thieme, Stuttgart 1990, pp. 258-286. 4.
See, e.g., Issleib, Issleib,
K.; Vollmer,
R. L
R.; Oehme,
Anorg.
A//g.
H.; Meyder, Chem.
Lett. 1978,
H. Tetrahedron
198:,
481,
22-32;
Heinicke,
79, 441-444;
J.; Tzschach,
A.
Lett. 1982, 23, 3643-3646.
Tetrahedron 5.
K.; Vollmer,
See, e.g., Mtirkl, G.; Dorfmeister,
G. Tetrahedron
Leff. 1986, 27, 4419-4442
as well as Tetrahedron
Lett. 1987, 28, 1089-1092. 6.
RGsch, W.; Richter, H.; Regitz, M. Chem. Ber. 1987, 120, 1809-1813;
Fuchs, E. P. 0.; Hermesdon, Chem. 1988, 338, 329-
M.; Schnurr, W.; Rosch, W.; Heydt, H.; Regitz, M.; Binger, P. J. Organomet. 340; see also Regitz, M. in Ref.3, pp. 73-74. 7.
M%kl, G.; Troetsch-Schaller, B. unpublished
8.
1990,90,
Lett. 1988, 29, 785788;
results with RC(OTms) = PTms, University
Reviews on the cycloaddition 1988, 100, 1541-1565;
9.
I.; Holzl, W. Tetrahedron reactivity
of Kaiserslautern,
of phosphaalkynes:
1989.
Regitz, M.; Binger,
Chem. lnt. Ed. Engl. 1988, 27, 1484-1508;
Angew.
Regitz M.; Burkhardt, P. Angew.
Chem.
Regitz, M. Chem. Rev.
191-213.
Cyclocondensation Schmidpeter,
of pyridinium
A.; Spindler,
salts with
PCI,:
Bansal,
R. K.; Karaghiosoff,
C. Chem. Ber. 1991, 124, 475-480. Further examples
K.; Gupta,
N.;
of this methodo-
logy are given therein. 10.
C,,H;,N,P.
M = 267.3 g.mol-‘,
orthorhombic.
13.780(2) A, V = 1325.5(6) A3, Z = 4, d,,,,. The measurements MO K,
radiation;
were performed
Pnma (No.62);
with an Enraf-Nonius
1116 independent
and the subsequent
refinement
CAD4 diffractometer
number of parameters
by direct
methods
bond
11.
angles,
as well as temperature Crystallographic
Cambridge
CB2 1 EW, U.K.
Phosphaindolizines
Data
of the structural
salts: MBrkl, G.; Pflaum, S. Tetrahedron
(Received in Germany 27 November
1991)
factors Centre,
c =
p = 1.9 cm-‘.
with monochromatic
are available University
type 8a were also obtained Lett. 1987,28,
151 l-1514.
converged
solution at R =
tables of bond lengths and
on request
Chemical
134. The structure
[SHElX-761
0.0474 and Rw = 0.0470. Further details such as atomic coordinates, Cambridge
b = 6.948(2),
coefficient
[h: 0 - > + 16; k: 0 -> + 7; I: 0 -> + 161 with 4.0” 5 28
reflections
I 50”, of which 985 with I > 2u(l) were observed; [SHElX86]
a = 13.844(4),
= 1.339 g cm3, absorption
from The Director
Laboratory,
Lensfield
by O/P exchange
of the Road,
in oxazolium