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Absolute rate constants for the additions of halophenylcarbenes to alkenes: a reactivity-selectivity relation
Tetrahedron Letters,Vo1.24,No.48,pp Printed in Great Britain
ABSOLUTE
RATE CONSTANTS TO ALKENES;
FOR THE ADDITIONS
b
aDepartment of Chemistry, Rutgers, New Brunswick, New Jersey 08903 Department of Chemistry, Columbia 10027
the relative
rates of their cycloadditions
flash photolytic activation
techniques
parameters
to the addition
of New Jersey,
New York, New York
they provide
its general
occurrence
Halophenylcarbenes flash photolysis isooctane
to various
variation
reactions.
for a "normal" Although
- &
solutions;
eq. (1).
bromite
or hypochlorite
obtained
by the action Appropriate
rines 1 in alkenes
oxidations
of benzamidine,5
of molten n-Bu4N+F-
cyclopropanes (A), and were
4 were
identified
whereas
(containing
isolated
and &
are important in
study.3
(A>300 nm) or
in alkene or alkene/ were prepared
fluorophenyldiazirine
0.1 equiv.
con-
of carbenic
correlation
by hypo-2a was
of H20) on neat -lc at
from steady state photolyses
by standard
5313
-la - & E
data which
in our Hammett
by steady state photolysis
Bromo and chlorodiazirines
correla-
has long been assumed,l
and it was not observable
(he, = 351 nm) of 3-halo-3-phenyldiazirines
Hammett
The new results
reactivity/selectivity
and
the new
of the dependence
such a relationship
were generated
applied
and have obtained
carbon.
nanosecond
rate constants
Here, we report kinetic
-at the carbenic
is controversial4 &
of absolute
by direct measurements,
from studies of
Now, however,
We have previously
of ClCPh with alkenes,2
obtained
of carbenes
a1kenes.l
the direct measurement
clear evidence
addition
and selectivity
of a series of E-X-PhCC1.3
on substituent
carbene/alkene
25°C.6
University,
a*
Robert A. Moss,
The State University
cycloadditions.
reactions
the first examples,
reactivity
permit
for carbene
tions for the additions
because
b
The absolute rate constants determined for the additions of FCPh, ClCPh, and BrCPh to Me2C=CMez, MepC=CHMe, trans-MeCH=CHEt, and n-BuCH=CH2 appear to follow a reactivity/selectivity pattern of the "normal" (inverse) type.
Much has been learned about the reactivity
stitute
RELATIdN
Nigel P. Hacker,
b
methods
OF HALOPHENYLCARBENES
A REACTIVITY-SELECTIVITY
D. Phillip C~X,~ Ian R. Gould, and Nicholas J. Turrob*
Summary.
0040-4039/83 $3.00 + .OO 01983 Perqamon Press Ltd.
5313-5316,1983
techniques.
2,7_10
of diazi-
5314
Rl
Ph
R2
hv
-1
-2
a,
R1=R~=R~=R+v,~
b, X=Cl
b, X=Cl
a,
R1=R2=R3=Me,
5, X=Br
2, X=Br
2,
R1=Me,
2,
II1 =~f-Bu,
5,
X=F
X=F
2,
Flash photolytic ClCPh.2
studies were carried
Each carbene
and its uv spectrum sient spectra or benzene
of the same carbene
solutions
at 23'C.
These
The spectra
are seen to be blue-shifted
order
is that expected
gens.12
The effect
The transient quenched
absorptions
tions of quencher,
as one proceeds
bimolecular
correlations
isooctane
to FCPh.
effects
from ClCPh
of sufficiently
The
of the halo-
to FCPh. were
high concentra-
was found to be pseudo-first-order.
of the decay rate constants
rate constants
tran-
(77 K, 23'C) in nm
carbenes 2 in isooctane
absorptions
at 77 K
FCPh, 270 ~300 (isooctane)."
and mesomeric
In the presence
the decay of the transient
matrix
in aerated
X,,, values
as one proceeds
of laser flash generated
for
with point-by-point
from BrCPh to ClCPh
mix of inductive
of alkenes -3a - 3d.
The slopes of the linear tions provided
was obtained:
pronounced
developed
in a 3-methylpentane
307, 310 (benzene);
for the differing
is particularly
upon addition
ClCPh,
generated
by laser flash photolysis
Good agreement
328, 330 (isooctane);
R2=R3=H
R2=R3=R4=R
spectra were compared
generated
were BrCPh,
R4=Et,
out in accord with procedures
was first photolytically
was determined.
R4=B
versus
(Table 1) for the reactions
alkene
concentra-
of carbenes
2 with
alkenes -3.12a As deduced
from the stereospecificity
carbenes -2a - 2c react with simple alkenes constants (&)I
(Table 1) is more than two orders
to the smallest
lute reactivity
order
based on anticipated singlet
carbene
[(.a) + (a)]
2p orbita1.l
as singlets.7y8.13 of magnitude;
rate constant
is Br > Cl > F, which halogen
of their additions
The overall
With each alkene,
stabilization
as measured
span of the rate
the ratio of the largest
is the inverse of the carbene
lone pair resonance Moreover,
is -400.
to cis- and trans-butenes,
by the "spread"
+
the XCPh abso-
stability
of an adjacent,
[(&I
order
vacant,
or ratio of the largest
5315
Table
1.
Absolute
rate constants
for additions
of XCPh to alkenesa
Carbene
, FCPhb
Alkene
t
CICPhC
BrCPhb
Me2C=CMe2
1.6
x lo8
2.8 x lOa
3.8 x lo8
MezC=CHMe
5.3
x 107
1.3 x 108
1.8 x lOa
trans-MeCH=CHEt
2.4
x 106
5.5 x 106
1.2 x 107
"-BuCH=CH2
0.93
x 106
2.2 x 106
4.0 x 106
0.83
0.70
d
0.89
%XY "spread ,,e
172
127
95
aRate constants are in L/mol-set and were determined in alkene/isooctane solution at ky laser flash pptolysis. Reproducibilities are <*lo%. See text and ref. 2. bThis From ref. 3. Carbene selectivity index determined at 25'C by relative reactivity scale , ECCl, = 1.00. See ref. 1, first citation. eRate constant ratio for additions Me2C=CMe2 vs. n-BuCH=CHz.
23OC work. studies; to
(Me2C=CMe2)
over
the common
to smallest
set of alkenes
is identical comparative
relative
"normal" cularly
of absolute
reactivity
type.4
cycloadditions
studies
indices
(m -CXY'
(Table 1) thus provides
direct evidence
and selectivity
reactions,
and interpretation
remain controversial,4
on theoretical
it is of particular afford
This order
1) derived
for an inverse
grounds
interest
correlation
to note that the reactions
data.15
Thus, with any given alkene,
CF is the least reactive
carbyne,
whereas
(greater
"spread")
discrim-
relationship of the
of such relationships,
and should be "normal"
from
= 1.00.1
with carbene/alkene
their occurrence
rate constant/carbyne/alkene
CF is more selective
see Table
or a reactivity/selectivity
the significance
(CF, CCL, CBr) with alkenes
of alkenes.15
of the carbenes
of XCPh and CC12 on a scale where m -Cc12 rate constants
is expected
In this context,
selectivity
carbene/alkene
Although
in solvolytic
the selectivities
also follow the inverse order, FCPh > ClCPh > BrCPh.
reactivity
(selectivity)
of absolute
rate constants,
to that of the carbene
The comparison ination
(BuCH=CHz)
parti-
in carbene/alkene for halocarbenes.14 of halocarbynes
data similar
to OUT carbene
and CBr the most reactive
than CBr over the available
set
5316
Activation mined,
parameters
and closely
These parameters
resemble
for the additions the reported
and their interpretation
Acknowledgment.
We are grateful
of &
values
and -lb to &
and z
for the additions
will be discussed
to the National
have also been deter-
of b
to these alkenes.'
at length in our full report.16
Science
Foundation
for financial
sup-
port.
References
and Notes
(1) R. A. Moss, Act. Chem. Res., 13, 58 (1980); R. A. Moss in "Carbenes," Vol. I, eds. M. Jones, Jr., and R. A. Moss, Wiley, New York, 1978, pp. 153ff.; R. A. Moss and M. Jones, Jr., in "Reactive Intermediates," Vol. 1, eds. M. Jones, Jr., and R. A. Moss, Wiley, New York, 1978, pp. 69ff.; Vol. 2, 1981, pp. 59ff. (2) N. J. Turro, J. A.-Butcher, Jr., R. A. MossTW. Guo, R. C. Munjal, and M. Fedorynski, J. Am. Chem. Sot., 102, 7576 (1980); N. J. Turro, G. F. Lehr, J. A. Butcher, Jr., R. A. Moss, and W. Guo, J. Am. Chem. Sot., 104, 1754 (1982). (3) R. A. Moss, L. A. Perez, N. J. Turro, I. R. Gould, and N. P. Hacker, Tetrahedron Lett., 6, 685 (1983). (4) C. D. Johnson, Tetrahedron, 36, 3461 (1980); G. W. Klumpp, "Reactivity in Organic Chemistry," Wiley, New York, 1982, pp. _. 219-222, 352-372. (5) W. Ht.Graham;.J. Am. Chem. Sot., 87, 4396 (1965). (6) R. A. Moss, D. P. Cox, and J. Terznski, J. Am. Chem. Sot., in press. Diazirine k was characterized by ir, lH, lgF, and 13C nmr, and uv spectroscopy, as well as by photolysis Spectroscopic and preparative details for & in alkenes to afford known FCPh adducts. are included in the manuscript in press. 2220 (1969). (7) R. A. Moss, J. R. Whittle, and P. Freidenreich, J. Org. Chem., 2, (8) R. A. Moss, Tetrahedron Lett., 4905 (1967). (9) R. A. Moss and J. R. Przybyla, Tetrahedron, 25, 647 (1969). for Dhotolvtic preparations of the (10) We thank Dr. J. Terninski and Mr. W. Lawrvnozcz adducts of 2c with 3c and 3d and of 2a wi;h 3b - 3d. . I . . (11) The transient spectrum of EPh couldnot be determined accurately below 300 nm because of interfering absorption by the diazirine precursor; good agreement between low and room temperature spectra was obtained in the spectral region above 300 nm. (12) J. N. Murrell, "The Theory of the Electronic Spectra of Organic Molecules," Wiley, New York, 1963, pp. 189-237. (12a) Available data'y13 permit comparisons of the ratios of absolute rate constants for carbene additions to Me2C=CMez vs. Me2C=CHMe (Table 1) with analogous classically determined' The data are (Labs ratio, lcrel): 3.0, 3.113 (competition) relative rate constants. With reproducibilities of *lo% in lcabs (FCPh); 2.2, 1.6 (ClCPh); and 2.1, 1.8 (BrCPh). (*14% in the ratios), the agreements are reasonable. (13) W. Lawrynowicz, unpublished study of 2a generated from @. (14) W. W. Schoeller, Angew. Chem. Int. EdFEngl., 0, 698 (1981); N. G. Rondan, K. N. Houk, and R. A. Moss, J. Am. Chem. sot., 102, 1770 (1980). (15) B. P. Ruzsicska, A. Jodhan, H. K. J. Choi, 0. P. Strausz, and T. N. Bell, J. Am. Chem. c., 105, 2489 (1983). (16) A full paper is being prepared for a symposium-in-print issue of Tetrahedron to be devoted to carbene chemistry and published in 1984. (Received
in
USA
22
August
1983)
ABSOLUTE
RATE CONSTANTS TO ALKENES;
FOR THE ADDITIONS
b
aDepartment of Chemistry, Rutgers, New Brunswick, New Jersey 08903 Department of Chemistry, Columbia 10027
the relative
rates of their cycloadditions
flash photolytic activation
techniques
parameters
to the addition
of New Jersey,
New York, New York
they provide
its general
occurrence
Halophenylcarbenes flash photolysis isooctane
to various
variation
reactions.
for a "normal" Although
- &
solutions;
eq. (1).
bromite
or hypochlorite
obtained
by the action Appropriate
rines 1 in alkenes
oxidations
of benzamidine,5
of molten n-Bu4N+F-
cyclopropanes (A), and were
4 were
identified
whereas
(containing
isolated
and &
are important in
study.3
(A>300 nm) or
in alkene or alkene/ were prepared
fluorophenyldiazirine
0.1 equiv.
con-
of carbenic
correlation
by hypo-2a was
of H20) on neat -lc at
from steady state photolyses
by standard
5313
-la - & E
data which
in our Hammett
by steady state photolysis
Bromo and chlorodiazirines
correla-
has long been assumed,l
and it was not observable
(he, = 351 nm) of 3-halo-3-phenyldiazirines
Hammett
The new results
reactivity/selectivity
and
the new
of the dependence
such a relationship
were generated
applied
and have obtained
carbon.
nanosecond
rate constants
Here, we report kinetic
-at the carbenic
is controversial4 &
of absolute
by direct measurements,
from studies of
Now, however,
We have previously
of ClCPh with alkenes,2
obtained
of carbenes
a1kenes.l
the direct measurement
clear evidence
addition
and selectivity
of a series of E-X-PhCC1.3
on substituent
carbene/alkene
25°C.6
University,
a*
Robert A. Moss,
The State University
cycloadditions.
reactions
the first examples,
reactivity
permit
for carbene
tions for the additions
because
b
The absolute rate constants determined for the additions of FCPh, ClCPh, and BrCPh to Me2C=CMez, MepC=CHMe, trans-MeCH=CHEt, and n-BuCH=CH2 appear to follow a reactivity/selectivity pattern of the "normal" (inverse) type.
Much has been learned about the reactivity
stitute
RELATIdN
Nigel P. Hacker,
b
methods
OF HALOPHENYLCARBENES
A REACTIVITY-SELECTIVITY
D. Phillip C~X,~ Ian R. Gould, and Nicholas J. Turrob*
Summary.
0040-4039/83 $3.00 + .OO 01983 Perqamon Press Ltd.
5313-5316,1983
techniques.
2,7_10
of diazi-
5314
Rl
Ph
R2
hv
-1
-2
a,
R1=R~=R~=R+v,~
b, X=Cl
b, X=Cl
a,
R1=R2=R3=Me,
5, X=Br
2, X=Br
2,
R1=Me,
2,
II1 =~f-Bu,
5,
X=F
X=F
2,
Flash photolytic ClCPh.2
studies were carried
Each carbene
and its uv spectrum sient spectra or benzene
of the same carbene
solutions
at 23'C.
These
The spectra
are seen to be blue-shifted
order
is that expected
gens.12
The effect
The transient quenched
absorptions
tions of quencher,
as one proceeds
bimolecular
correlations
isooctane
to FCPh.
effects
from ClCPh
of sufficiently
The
of the halo-
to FCPh. were
high concentra-
was found to be pseudo-first-order.
of the decay rate constants
rate constants
tran-
(77 K, 23'C) in nm
carbenes 2 in isooctane
absorptions
at 77 K
FCPh, 270 ~300 (isooctane)."
and mesomeric
In the presence
the decay of the transient
matrix
in aerated
X,,, values
as one proceeds
of laser flash generated
for
with point-by-point
from BrCPh to ClCPh
mix of inductive
of alkenes -3a - 3d.
The slopes of the linear tions provided
was obtained:
pronounced
developed
in a 3-methylpentane
307, 310 (benzene);
for the differing
is particularly
upon addition
ClCPh,
generated
by laser flash photolysis
Good agreement
328, 330 (isooctane);
R2=R3=H
R2=R3=R4=R
spectra were compared
generated
were BrCPh,
R4=Et,
out in accord with procedures
was first photolytically
was determined.
R4=B
versus
(Table 1) for the reactions
alkene
concentra-
of carbenes
2 with
alkenes -3.12a As deduced
from the stereospecificity
carbenes -2a - 2c react with simple alkenes constants (&)I
(Table 1) is more than two orders
to the smallest
lute reactivity
order
based on anticipated singlet
carbene
[(.a) + (a)]
2p orbita1.l
as singlets.7y8.13 of magnitude;
rate constant
is Br > Cl > F, which halogen
of their additions
The overall
With each alkene,
stabilization
as measured
span of the rate
the ratio of the largest
is the inverse of the carbene
lone pair resonance Moreover,
is -400.
to cis- and trans-butenes,
by the "spread"
+
the XCPh abso-
stability
of an adjacent,
[(&I
order
vacant,
or ratio of the largest
5315
Table
1.
Absolute
rate constants
for additions
of XCPh to alkenesa
Carbene
, FCPhb
Alkene
t
CICPhC
BrCPhb
Me2C=CMe2
1.6
x lo8
2.8 x lOa
3.8 x lo8
MezC=CHMe
5.3
x 107
1.3 x 108
1.8 x lOa
trans-MeCH=CHEt
2.4
x 106
5.5 x 106
1.2 x 107
"-BuCH=CH2
0.93
x 106
2.2 x 106
4.0 x 106
0.83
0.70
d
0.89
%XY "spread ,,e
172
127
95
aRate constants are in L/mol-set and were determined in alkene/isooctane solution at ky laser flash pptolysis. Reproducibilities are <*lo%. See text and ref. 2. bThis From ref. 3. Carbene selectivity index determined at 25'C by relative reactivity scale , ECCl, = 1.00. See ref. 1, first citation. eRate constant ratio for additions Me2C=CMe2 vs. n-BuCH=CHz.
23OC work. studies; to
(Me2C=CMe2)
over
the common
to smallest
set of alkenes
is identical comparative
relative
"normal" cularly
of absolute
reactivity
type.4
cycloadditions
studies
indices
(m -CXY'
(Table 1) thus provides
direct evidence
and selectivity
reactions,
and interpretation
remain controversial,4
on theoretical
it is of particular afford
This order
1) derived
for an inverse
grounds
interest
correlation
to note that the reactions
data.15
Thus, with any given alkene,
CF is the least reactive
carbyne,
whereas
(greater
"spread")
discrim-
relationship of the
of such relationships,
and should be "normal"
from
= 1.00.1
with carbene/alkene
their occurrence
rate constant/carbyne/alkene
CF is more selective
see Table
or a reactivity/selectivity
the significance
(CF, CCL, CBr) with alkenes
of alkenes.15
of the carbenes
of XCPh and CC12 on a scale where m -Cc12 rate constants
is expected
In this context,
selectivity
carbene/alkene
Although
in solvolytic
the selectivities
also follow the inverse order, FCPh > ClCPh > BrCPh.
reactivity
(selectivity)
of absolute
rate constants,
to that of the carbene
The comparison ination
(BuCH=CHz)
parti-
in carbene/alkene for halocarbenes.14 of halocarbynes
data similar
to OUT carbene
and CBr the most reactive
than CBr over the available
set
5316
Activation mined,
parameters
and closely
These parameters
resemble
for the additions the reported
and their interpretation
Acknowledgment.
We are grateful
of &
values
and -lb to &
and z
for the additions
will be discussed
to the National
have also been deter-
of b
to these alkenes.'
at length in our full report.16
Science
Foundation
for financial
sup-
port.
References
and Notes
(1) R. A. Moss, Act. Chem. Res., 13, 58 (1980); R. A. Moss in "Carbenes," Vol. I, eds. M. Jones, Jr., and R. A. Moss, Wiley, New York, 1978, pp. 153ff.; R. A. Moss and M. Jones, Jr., in "Reactive Intermediates," Vol. 1, eds. M. Jones, Jr., and R. A. Moss, Wiley, New York, 1978, pp. 69ff.; Vol. 2, 1981, pp. 59ff. (2) N. J. Turro, J. A.-Butcher, Jr., R. A. MossTW. Guo, R. C. Munjal, and M. Fedorynski, J. Am. Chem. Sot., 102, 7576 (1980); N. J. Turro, G. F. Lehr, J. A. Butcher, Jr., R. A. Moss, and W. Guo, J. Am. Chem. Sot., 104, 1754 (1982). (3) R. A. Moss, L. A. Perez, N. J. Turro, I. R. Gould, and N. P. Hacker, Tetrahedron Lett., 6, 685 (1983). (4) C. D. Johnson, Tetrahedron, 36, 3461 (1980); G. W. Klumpp, "Reactivity in Organic Chemistry," Wiley, New York, 1982, pp. _. 219-222, 352-372. (5) W. Ht.Graham;.J. Am. Chem. Sot., 87, 4396 (1965). (6) R. A. Moss, D. P. Cox, and J. Terznski, J. Am. Chem. Sot., in press. Diazirine k was characterized by ir, lH, lgF, and 13C nmr, and uv spectroscopy, as well as by photolysis Spectroscopic and preparative details for & in alkenes to afford known FCPh adducts. are included in the manuscript in press. 2220 (1969). (7) R. A. Moss, J. R. Whittle, and P. Freidenreich, J. Org. Chem., 2, (8) R. A. Moss, Tetrahedron Lett., 4905 (1967). (9) R. A. Moss and J. R. Przybyla, Tetrahedron, 25, 647 (1969). for Dhotolvtic preparations of the (10) We thank Dr. J. Terninski and Mr. W. Lawrvnozcz adducts of 2c with 3c and 3d and of 2a wi;h 3b - 3d. . I . . (11) The transient spectrum of EPh couldnot be determined accurately below 300 nm because of interfering absorption by the diazirine precursor; good agreement between low and room temperature spectra was obtained in the spectral region above 300 nm. (12) J. N. Murrell, "The Theory of the Electronic Spectra of Organic Molecules," Wiley, New York, 1963, pp. 189-237. (12a) Available data'y13 permit comparisons of the ratios of absolute rate constants for carbene additions to Me2C=CMez vs. Me2C=CHMe (Table 1) with analogous classically determined' The data are (Labs ratio, lcrel): 3.0, 3.113 (competition) relative rate constants. With reproducibilities of *lo% in lcabs (FCPh); 2.2, 1.6 (ClCPh); and 2.1, 1.8 (BrCPh). (*14% in the ratios), the agreements are reasonable. (13) W. Lawrynowicz, unpublished study of 2a generated from @. (14) W. W. Schoeller, Angew. Chem. Int. EdFEngl., 0, 698 (1981); N. G. Rondan, K. N. Houk, and R. A. Moss, J. Am. Chem. sot., 102, 1770 (1980). (15) B. P. Ruzsicska, A. Jodhan, H. K. J. Choi, 0. P. Strausz, and T. N. Bell, J. Am. Chem. c., 105, 2489 (1983). (16) A full paper is being prepared for a symposium-in-print issue of Tetrahedron to be devoted to carbene chemistry and published in 1984. (Received
in
USA
22
August
1983)