Formation of a 1,2,4-dioxazolidine by electron-transfer photooxygenation of 1-butyl-2,3-diphenylaziridine

Tetrahedron Printed in

Letters,Vo1.24,No.30,pp Great Britain

FORMATION

3047-3050,1983

OF A 1,2,4-DIOXAZOLIDINE

PHOTOOXYGENATION

oo4o-4039/83 $3.00 + 01983 Pergamon Press

.oo Ltd.

BY ELECTRON-TRANSFER

OF l-BUTYL-2,3_DIPHENYLAZIRIDINE

* A. Paul Schaap, Department

Girija

Prasad,

and Steven D. Gagnon

of Chemistry, Wayne State University Detroit, Michigan 48202

Summary: Electron-transfer photooxygenation of l-butyl-2,3_diphenylaziridine with 9,10dicyanoanthracene in oxygen-saturated acetonitrile yields 4-butyl-3,5-diphenyl-1,2,4dioxazolidine. This peroxide is surprisingly stable in nonpolar solvents decomposing to benzaldehyde and N-butylbenzamide upon heating to 100°C in benzene. Treatment with triphenyl phosphine yields benzaldehyde and N-butyl-1-phenylmethanimine.

A variety solvents

in the presence

anthracene quenching

of organic

(DCA).

1

undergo

electron-transfer

of cyano-substituted

aromatic

The key step in this reaction

of the sensitizer

fore, been limited VS.

substrates

to easily

SCE in MeCN.lb

by the substrate. oxidized

We have, however,

involves

recently

described

be rapidly

phenyl-substituted

the corresponding

biphenyl

to yield

as a non-light-absorbing

Our results

cosensitizer

on the photochemical

tigate the DCA-sensitized the electron-transfer 1,2,4-dioxazolidine.

reaction

,-p N

in conjunction

conversion

of epoxides

of an aziridine

Photooxygenation

potentials by which

For example,

ozonides

of other heterocycles.

photooxygenation 435

oxidized.2

with DCA.

a compound

o-o

of

by use of

have led us to investhe first report of of the resulting

2,3_diphenylaziridine

o-o

that

3

We now provide

d/U

there-

photooxygenation

to ozonides

wgu

3047

have,

of less than 2V

can be effected

and the isolation

of -cis-1 -"-butyl-

fluorescence

photooxygenations

a method

in polar

such as 9,10-dicyano-

electron-transfer

with oxidation

does not quench DCA may nevertheless oxiranes

hydrocarbons

DCA-sensitized

substrates

photooxygenation

(L)7 was

3048

carried

out in dry MeCN with 1 x 10

-2

M 1 and 2 x 10

at 10°C under oxygen with a 450-W medium-pressure The reaction biphenyl

was complete

the fluorescence

was not necessary

of DCA in MeCN

(k 9

of the solvent under vacuum the formation hyde

corresponding absorption

tions.

2 was obtained

phenyl-substituted

(6 5.543)

isomer -2b absorbs reaction

by reverse

M-l

s-l

phase HPLC.

is tentatively

at

6 5.879.

No isomerization

1 was not oxidized

3b,9,10

assigned

Pure dioxazolidine

The material

decomposed

must be carried

occurs on silica

gel.

acidic potassium

iodide and ferrous ammonium

the higher The minor

In addition, sodium

condi-

aziridine

lamp in with 102.

as decomposition

by its positive

Treatment

thiocyanate.

of

in 25% yield by preparative

out rapidly

was shown to be a peroxide

field trans-

the reaction

that 1 does not react directly was obtained

to the

is independent

under

during photolysis.

of isomers)

The chromatography

By analogy

configuration.

for 4 h with a 400-W high-pressure

-2 (as a mixture

Removal

(1) along with benzalde-

of stereoisomers.

the cis-phenyl

indicating

quenches

in CDC13 by 300 MHz 'H NMR indicated

-2 are not significantly

Rose Bengal,

of 2

test with

of the mixture

of -2a and

-2b in C6D6 in an NMR tube with Ph3P at 100°C for 15 min gave 2 and imine 4 in quantitative yields.

_2 is remarkably

N-butylbenzamide

stable to thermolysis

(5)afterheating

exhibiting

only 35% decomposition

at 1OO'C for 6 h in C6D6. Cleavage

PhCH=NwBu

+

to -3 and

is more rapid in CDC13.

+

Ph,P=O

4

0 +

PhkNHn-Bu

P

We have reported diphenyloxirane stereochemical epoxides

that cosensitized

gives rise exclusively

involving

photooxygenation

of -cis- and trans-

to -cis-3,5-diphenyl-1,2,4-trioxolane.

result has led us to propose

to ozonides

2

electron-transfer

concerted

a mechanism

addition

of

1

8

of

SCE in MeCN).

the major product -2a with

of starting 1 was detected

MeCN containing

1 efficiently

We have found that the ratio of isomers

upon irradiation

TLC over silica gel.

as a 87:13 mixture

solution.

The addition

= 1.7 v vs.

, E;

of the products

ozonides,

time and that peroxides

oxygenated

lamp using a CuS04-filter

of 83% of 4-_n-butyl-3,5-diphenyl-1,2,4_dioxazolidine

Peroxide

(3).

The solution was irradiated

in this case as aziridine

= 8 . 2 x 10'

and analysis

M DCA.

mercury

in 1.5 h as determined

as a cosensitizer

-4

3b

This striking

for the photochemical

conversion

02 as a 1,3-dipolarophile

to an

of

3049

intermediate

carbonyl

photooxygenation DCA by -1 would isomer.

of aziridine

azomethine

electron

transfer

subsequently oxygen.

11

(Scheme 1).

transfer

azomethine

ylides by dipolarophiles.

by energy

stereochemistry

of

An alternative

transfer

1

excited

to be the most stable

02 to -7a and 7b would

mechanism

literature

on the trapping

from singlet

13

of photo-

involves

back

Ylides -7 could

of ylides 1 in the photooxygenation

and triplet

DCA to

of aziridine

and thermally

-1 is

generated

In some cases the ylides have also been detected

14

the mechanism

of this reaction

of -2a and -2b must remain

photochemical

cycloaddition

respectively.

intermediacy

with the extensive

assignments

1,3-Dipolar

-2a and 3,

consistent

Although

cation with -6a predicted

of singlet

from 02' to -6a and -6b could yield '02 and the corres-

'02 generated

The proposed

in the DCA-sensitized

quenching

from DCA' or 0 ' to 6 to form l and DCA or 302. 2 -

react with

spectroscopically.

may be operative

Electron-transfer

radical

ylides -7a and 7b.

form 1,2,4-dioxazolidines electron

1

form the open aziridine

Exothermic

ponding

A similar mechanism

ylide.

conversion

Acknowledgement.

tentative,

of an aziridine

of this reaction

Support

is not fully established

we have been able to demonstrate

to a 1,2,4-dioxazolidine.

with isomeric

aziridines

from the U.S. Army Research Scheme

hA

DCA

and the stereochemical

A

full

0,

Office

is gratefully

1

‘DCA*

0: +

+

DCA

rr-Bu

rr-Bu Ph Hyk$O

+

Ph 7b

H

‘0,

study of the

is in progress.

+

+

the first

---*

acknowledged.

3050

References

and Notes

(1)

(a) D. H. R. Barton, G. Leclerc, P. D. Magnus, and I. D. Mensies, J. Chem. Sot., Chem. COrnmUll.,447 (1972); (b) J. Eriksen, C. S. Foote, and T. L. Parker, J. Am. Chem. Sot., 99, 6455 (1977); (c) R. K. Haynes, Aust. J. Chem., 21, 121 (1978); (d) K. A. Brown-Wensley, S. L. Mattes, and S. Farid, J. Am. Chem. Sot., &I, 4162 (1978); (e) I. Saito, K. Tamoto, and T. Matsuura, Tetrahedron Lett., 2889 (1979); (f) N. Berenjian, P. deMayo, F. H. Phoenix, and A. C. Weedon, ibid., 4179 (1979); (g) W. Ando, T. Nagashima, K. Saito, and S. Kohmoto, J. Chem. Sot., Chem. Commun., 154 (1979); (h) S. L. Mattes and S. Farid, ibid., 126 (1980); (i) J. Eriksen and C. S. Foote, J. Am. Chem. Sot., 102, 6083 (1980); (j)L. T. Spada and C. S. Foote, ibid., 102, 391 (1980); (k) A. P. Schaap, K. A. Zaklika, B. Kaskar, and L. W.-M. Fung, ibid., 102, 389 (1980); (1) S. L. Mattes and S. Farid, ibid., 104, 1454 (1982); (m) A. P. Schaap, L. Lopez, S. D. Anderson, and S. D. Gagnon, Tetrahedron Lett., 5493 (1982); (n) W. Ando, Y. Kabe, and T. Takata, J. Am. Chem. Sot., 104, 7314 (1982); (0) S. Futamura, S. Kusunose, H. Ohta, and Y. Kaniya, J. Chem. Sot., Chem. Commun., 1223 (1983).

(2)

Presented in part at the IX IUPAC Symposium 1982, Abstr. No. ST 15.

(3)

A. P. Schaap, L. Lopez, and S. D. Gagnon, J. Am. Chem. Sot., 105, 663 (1983); Schaap, S. Siddiqui, S. D. Gagnon, and L. Lopez, ibid., submi=d.

(4)

N-unsubstituted 1,2,4_dioxazolidines can be prepared by the reaction of ketones with HO andNH3: E. G. E. Hawkins, J. Chem. Sot. C, 160 (1971). See also N. Duran, J2 &-g. Chem., 2, 1791 (1974).

(5)

M. V. George has reported that direct UV irradiation of several aziridines in the presence of oxygen gave rise to products that could be rationalized in terms of lO2 addition io azomethine ylides and subsequent decomposition of intermediate 1,2,4_dioxazolidines.

(6)

(a) V. Bhat and M. V. George, Tetrahedron George, J. Org. Chem., 44, 3288 (1979).

(7)

R. N. Loeppky

(8)

The l-cm path-length filter solution was prepared from 27 g of CuSO4.5 H20, 30 g of NaN02, and 50 mL of cont. NH40H diluted with water to 1000 mL.

(9)

on Photochemistry,

Lett.,

and D. H. Smith, J. Org. Chem., s,

4133

(1977);

Pau, France,

July 26,

(b) A. P.

(b) V. Bhat and M. V.

1578 (1976).

1 cis- and trans-3,5-Diphenyl-1,2,4_trioxolanes exhibit H NMR absorptions in CDC13 for the zg protons at 6 6.331 and 6.360, respectively.3b See also: J. H. Hall, R. Huisgen, C. H. Ross, and W. Scheer, J. Chem. Sot., Chem. Commun., 1188 (1971).

(10)

R. Criegee

and H. Korber,

Chem. Ber., 104,

(11)

Evidence

(12)

(a) J. Santamaria, Tetrahedron Lett., 4511 (1981);(b) L. E. Manring, C. Gu, and C. S. Foote, J. Phys. Chem., in press. We thank Professor Foote for a preprint of this paper.

(13)

(a) H. W. Heine and R. E. Peavy, Tetrahedron Lett., 3213 (1966); (b) R. Huisgen, W. Scheer, G. Szeimies, and H. Huber, ibid., 397 (1966); (c) R. Huisgen and H. Mader, Angew. Chem., Int. Ed. Engl., 8, 604 (1969).

(14)

(a). H. W. Heine, R. H. Weese, R. A. Cooper, and A. J. Durbetaki, J. Org. Chem., 2, 2708 (1967); (b) A. Padwa and L. Hamilton, J. Heterocycl. Chem., 4,118 (1967); (c) T. DoMinh and A. M. Troszolo, J. Am. Chem. Sot., 94, 4046 (1972); (d) A. M. Trossolo, T. M. Leslie, A. S. Sarpotdar, R. D. Small, G. J. Ferraudi, T. DoMinh, and R. L. Hartless, Pure Appl. Chem., 51, 261 (1979) and references therein.

for '02 generation

(Received

in

USA

28

1807

in DCA-sensitized

February

1983)

(1971).

photooxygenations

has been reported.

12