- Email: [email protected]
The amine assisted photo-dehalogenation of halo-aromatic hydrocarbons
Tetrahedron Letters,Vo1.24,No.50,pp Printed in Great Britain
THE AkINE ASSISTED Richard
Summary:
004O-4039/83 $3 00 + @ 1983 Pergamon Press
5673-5676,1983
PHOTO-DEHALOGENATION
OF HALO-AROMATIC
HYDROCARBONS
A. Beecroft, R. Stephen Davidson* and Dean Goodwin Department of Chemistry, The City University, Northampton Square, London EClV OHB.
The rate constants for quenching the triplet states of 4-chlorobiphenyl, l-chloronaphthalene and l-methylnaphthalene have been determined by use of the technique of laser flash photolysis. Evidence in favour of the quenching occurring by a charge transfer process, is presented.
The irradiation
of many halo-aromatic
leads to homolysis subsequently
compounds
of the aryl-halogen
abstract
hydrogen
Ar-Hal
hv
donating
in hydrogen
solvents
The aryl radicals
bond [l].
from the solvent to give the related
so formed, aromatic
hydrocarbon. +Ak
+
H-donating
Hal
+ H-Hal
,ArH
solvent
The rate of dechlorination polar solvents ethylamine
of many chloroaromatics
containing
A suggested
[2,3].
chloroaromatic
a tertiary
mechanism
acting as an electron ArCl*
+
Et3N
for this process
include
presented
--b
the solvent polarity fluorescence
1
[3,4] and (b) the finding
the intermediacy
[3,5].
Although,
of radical
ted by the finding
it had been tacitly
that the excited
constant
However,
Thus the case for quenching only been established
singlet
for fluorescence
the triplet
containing [4].
deuterium
oxide
Until recently
state of the chloroaroma-
and triplet quenching,
by plotting
[6,7] that
state on the being less than
the reciprocal
of the
of the amine concentration.
state of chloroaromatics
means. 5673
for
appears to have been valida-
singlet
versus the reciprocal
by indirect
quench the
fluorescence
it has now been claimed
the value for the slope of the line obtained for reaction
amines
no one has any direct evidence
into the products
can involve both the excited
basis of the Stern-Volmer
quantum yield
that tertiary
ions, their formation
state.
process
caused by increasing
and in some cases exciplex as yet,
of deuterium
assumed
tics is the only reactive the reactions
of a charge transfer
that the use of solvent mixtures
leads to the incorporation
tri-
the excited
Ar' + Cl- + Et3N+'
in the rate of dechlorination
of many chloroaromatics
can be observed
involves
[(ArC1)'(Et3N)+']*
in support of the occurrence
(a) the enhancement
by the use of containing
acceptor.
ArH + HCl + CH2 =CHNE$f--Arguments
is enhanced
amine, e.g. acetonitrile
by amines has
.oo Ltd.
We now report the rate constants chloronaphthalene
by several amines
with those for quenching obtained
by utilising
Measurements
triplet
the technique
of amine.
and these are shown in the Table,
of nanosecond
Rate constants
and ltogether
The rate constants
laser flash photolysis
of the various hydrocarbons
=-
were evaluated
were
[8].
in the pre-
using the
1
+ ki [Amine]
TO
where T = triplet
lifetime
in the presence
= triplet
lifetime
in the absence
and ki
4-chlorobiphenyl
: 1 -r
TO
triplet
l-methylnaphthalene.
were made of the lifetimes
sence of known amounts eauation
for quenching
= bimolecular
rate constant
of amine at a concentration
[Amine].
of amine.
for triplet
quenching.
TABLE Rate Constants Amines
for Quenching
in Acetonitrile
for Quenching
the Fluorescence Acetonitrile
4-Chlorobiphenyl -__---~ kT (M-l s-l) :4eNA 0
1.4
+ 0.20
Triplet
Solution
9.46? 0.48
2.18 1 0.20
24.3Ot1.16
I-Chloronaphthalene
+
2.75 f 2.0
/ 15.65? 0.47
x lo6 24.682 0.41
0.40
1.08 1 0.14 x lo8
x lo7 9.13 + 0.80
3 MeN
9.84 + 0.90
17.66? 0.82
8.6
30.3710.16
+ 0.70 x lo7
x lo7 29.87i 0.91
1.59 ? 1.20 x lo8
x lo7
for quenching
in
x lo7
3 MeN
(a) KS,
9.4
x lo7 5.45 t 0.55
Et3N
15.54+ 0.82
by Amines
kT (M-l s-l) M
x lo7
2.62 + O.lU
by
Constants
(Ksv)(a)
l-Methylnaphthalene
1 KSv W1) I
Hydrocarbons
of Chloroaromatics solution
x lo7
YeN3
Aromatic
(ki) and Stern-Volmer
of singlet
l-methylnaphthalene
not determined.
5675
For the cyclic
amines,
the order of reactivity
N-methylazacycloheptane
The reactivity
N-methyl-4-oxa-azacyclohexane.
of quenching
and whether
amines.
>
energies
of triethylamine
Quenching
to be
gives any clue as
via energy transfer
of the hydrocarbons
appears
arises as to the
this order of reactivity
to the nature of the mechanism. since the triplet
is
> N-methylazacyclohexane
The question
similar to that of N-methylazacyclopentane. mechanism
for the three hydrocarbons
> N-methylazacyclopentane
seems unlikely
should lie below those of the
It was found that the quenching of the triplet states by the amines
is much greater suggests
in acetonitrile
the occurrence
verify the production Further evidence
than in cyclohexane.
of a charge transfer
of radical
in support
excited
singlet states.
The Stern-Volmer
is more reactive
difference
in the conformation
quenching
for the complex
of excited
singlet process
for fluorescence
of ionisation
and oxidation
ever, the ionisation
which,
quenching.
process.
the are
for fluorescence
This may reflect
a
Since it is well established hydrocarbons
by amines
[9], it seems from the similarity
potentials
potential
comes
which gives rise to fluorescence
states of aromatic
and triplet
also occurs via a charge transfer
to
failed.
mechanism
the fluorescence
than N-methylazacyclopentane.
occurs via a charge transfer of reactivity
for quenching
is triethylamine
to that which causes triplet
that the quenching
quenching
is the same as that towards
constants
The only anomaly
shown in the Table.
all attempts
of the cyclic amines towards
states of the chloroaromatics
quenching,
However,
ions using laser flash photolysis
of the charge transfer
from the finding that the order of reactivity
triplet
This solvent effect
process.
quenching,
that triplet
Unfortunately
for the amines
in order
quenching
a comprehensive
is not available.
range How-
for N-methyl-4-oxa-azacyclohexane is considera10 and not surprisingly it is
bly higher than that of N-methylazacyclohexane the less efficient one electron reactive
quencher.
process
Chlorine
than N-methylazacyclohexane
azacyclopentane
is a better quencher
This work shows that the triplet amines.
unequivocal
proof that dechlorination
tion.
tertiary
amines
that -50%
At this latter concentration
via a
is more
The Table shows that the N-methyl-
than the N-methylazacyclohexane.
hydrocarbons
for quenching
of the triplets quenched
are quenched
this does not provide
occurs from the triplet
of the rate constant
of 2 x 10v4 M and -90%
Since dechlorination
[ll].
In the case of the chloroaromatics
nyl it can be calculated concentration
oxidises
states of aromatic
by tertiary
from a consideration
dioxide
and it was found that N-t-butylazacyclopentane
state.
triplet
are quenched
However,
4-chlorobipheat an amine
at a 10-S M amine concentra-
very little fluorescence
occurs at amine concentrations
quenching
occurs.
in the range of 10 -3 to
5676
1O-4 M it appears
reasonable
state. To get 50% quenching
to invoke reaction of the excited
tion of 4.5 x 10-2 M is required. excited
singlet
state quenching
Thus at high amine concentrations
plots of the reciprocal
versus the reciprocal
of the amine concentration
presented triplet
of reaction
are linear over a wide range
occur via the excited
data
singlet
and
[7].
Acknowledgements: financial
of the quantum yield
some quenching.
it must be, in the light of the rate constant
in this paper, that the reactions
states
via the triplet
states an amine concentra-
will occur and nearly total triplet
Since the Stern-Volmer
of amine concentrations
occurring
singlet
We thank the SERC for funds to purchase
support
(to R.A.B.)
and The City University
the laser and for
for a Fellowship
(to
D.G.).
References 1.
P.G. Sammes in "Chemistry of the Carbon-Halogen Bond", Ed. S. Patai, Part II, Chap. II, J. Wiley and Sons, New York (1973). R.K. Sharma and N. Kharasch, Angew. Chem. Int. Engl., 1968, L, 36. J. Grimshaw and A.P. de Silva, Chem. Sot. Rev., 1981, @, 181. R.S. Davidson, J.W. Goodin and G. Kemp, Adv. Phys. Org. Chem., 1984, 3. In the press.
2.
N.J. Bunce, Y. Kumar, L. Ravanal and S. Safe, J. Chem. Sot. Perkin Trans. g, 1978, 880. L.O. Ruzo, S. Safe and M.J. Zabuk, J. Agric. Food Chem., 1975, 23, 594. L.U. Ruzo, N.J. Bunce and S. Safe, Can. J. Chem., 1975,53, 688.
3.
N.J. Bunce, P. Pilon, L.O. Ruzo and D.J. Sturch, J. Org. Chem., 1976, 2, 3023.
4.
R.S. Davidson
and J.W. Goodin,
5.
M. Ohashi,
6.
N.J. Bunce, J. Org. Chem.,
7.
M. Ohashi
8.
The experimental set-up has been previously described:R.A. Beecroft, R.S. Davidson, D. Goodwin, J.E. Pratt, L.A. Chewter D. Phillips, Chem. Phys. Letters, 1982, 93, 468.
K. Tsujimoto
Tetrahedron
and K. Seki, J.C.S. 1982, 9,
and K. Tsujimoto,
Letters,
1981, 163.
Chem. Conun., 1973, 384.
1948.
Chem. Letters,
1983, 423.
and
9.
This subject has been comprehensively reviewed:R.S. Davidson in Molecular Association, Ed. R. Foster, Vol. I. Academic Press, London, 1975; N. Mataga and M. Ottolenghi in Molecular Association, Ed. R. Foster, Vol. II, Academic Press, London, 1979; R.S. Davidson Adv. Phys. Org. Chem., 1983, 19, 1.
10.
A.M. Halpern
11.
L.A. Hall, G.T. Davis, D.H. Rosenblatt 73, 2142.
and T. Gartman,
J. Amer. Chem. Sot., 1974, 96, 1393.
(Received in UK 30 September 1983)
and C-K. Mann, J. Phys. Chem.,
1969,
THE AkINE ASSISTED Richard
Summary:
004O-4039/83 $3 00 + @ 1983 Pergamon Press
5673-5676,1983
PHOTO-DEHALOGENATION
OF HALO-AROMATIC
HYDROCARBONS
A. Beecroft, R. Stephen Davidson* and Dean Goodwin Department of Chemistry, The City University, Northampton Square, London EClV OHB.
The rate constants for quenching the triplet states of 4-chlorobiphenyl, l-chloronaphthalene and l-methylnaphthalene have been determined by use of the technique of laser flash photolysis. Evidence in favour of the quenching occurring by a charge transfer process, is presented.
The irradiation
of many halo-aromatic
leads to homolysis subsequently
compounds
of the aryl-halogen
abstract
hydrogen
Ar-Hal
hv
donating
in hydrogen
solvents
The aryl radicals
bond [l].
from the solvent to give the related
so formed, aromatic
hydrocarbon. +Ak
+
H-donating
Hal
+ H-Hal
,ArH
solvent
The rate of dechlorination polar solvents ethylamine
of many chloroaromatics
containing
A suggested
[2,3].
chloroaromatic
a tertiary
mechanism
acting as an electron ArCl*
+
Et3N
for this process
include
presented
--b
the solvent polarity fluorescence
1
[3,4] and (b) the finding
the intermediacy
[3,5].
Although,
of radical
ted by the finding
it had been tacitly
that the excited
constant
However,
Thus the case for quenching only been established
singlet
for fluorescence
the triplet
containing [4].
deuterium
oxide
Until recently
state of the chloroaroma-
and triplet quenching,
by plotting
[6,7] that
state on the being less than
the reciprocal
of the
of the amine concentration.
state of chloroaromatics
means. 5673
for
appears to have been valida-
singlet
versus the reciprocal
by indirect
quench the
fluorescence
it has now been claimed
the value for the slope of the line obtained for reaction
amines
no one has any direct evidence
into the products
can involve both the excited
basis of the Stern-Volmer
quantum yield
that tertiary
ions, their formation
state.
process
caused by increasing
and in some cases exciplex as yet,
of deuterium
assumed
tics is the only reactive the reactions
of a charge transfer
that the use of solvent mixtures
leads to the incorporation
tri-
the excited
Ar' + Cl- + Et3N+'
in the rate of dechlorination
of many chloroaromatics
can be observed
involves
[(ArC1)'(Et3N)+']*
in support of the occurrence
(a) the enhancement
by the use of containing
acceptor.
ArH + HCl + CH2 =CHNE$f--Arguments
is enhanced
amine, e.g. acetonitrile
by amines has
.oo Ltd.
We now report the rate constants chloronaphthalene
by several amines
with those for quenching obtained
by utilising
Measurements
triplet
the technique
of amine.
and these are shown in the Table,
of nanosecond
Rate constants
and ltogether
The rate constants
laser flash photolysis
of the various hydrocarbons
=-
were evaluated
were
[8].
in the pre-
using the
1
+ ki [Amine]
TO
where T = triplet
lifetime
in the presence
= triplet
lifetime
in the absence
and ki
4-chlorobiphenyl
: 1 -r
TO
triplet
l-methylnaphthalene.
were made of the lifetimes
sence of known amounts eauation
for quenching
= bimolecular
rate constant
of amine at a concentration
[Amine].
of amine.
for triplet
quenching.
TABLE Rate Constants Amines
for Quenching
in Acetonitrile
for Quenching
the Fluorescence Acetonitrile
4-Chlorobiphenyl -__---~ kT (M-l s-l) :4eNA 0
1.4
+ 0.20
Triplet
Solution
9.46? 0.48
2.18 1 0.20
24.3Ot1.16
I-Chloronaphthalene
+
2.75 f 2.0
/ 15.65? 0.47
x lo6 24.682 0.41
0.40
1.08 1 0.14 x lo8
x lo7 9.13 + 0.80
3 MeN
9.84 + 0.90
17.66? 0.82
8.6
30.3710.16
+ 0.70 x lo7
x lo7 29.87i 0.91
1.59 ? 1.20 x lo8
x lo7
for quenching
in
x lo7
3 MeN
(a) KS,
9.4
x lo7 5.45 t 0.55
Et3N
15.54+ 0.82
by Amines
kT (M-l s-l) M
x lo7
2.62 + O.lU
by
Constants
(Ksv)(a)
l-Methylnaphthalene
1 KSv W1) I
Hydrocarbons
of Chloroaromatics solution
x lo7
YeN3
Aromatic
(ki) and Stern-Volmer
of singlet
l-methylnaphthalene
not determined.
5675
For the cyclic
amines,
the order of reactivity
N-methylazacycloheptane
The reactivity
N-methyl-4-oxa-azacyclohexane.
of quenching
and whether
amines.
>
energies
of triethylamine
Quenching
to be
gives any clue as
via energy transfer
of the hydrocarbons
appears
arises as to the
this order of reactivity
to the nature of the mechanism. since the triplet
is
> N-methylazacyclohexane
The question
similar to that of N-methylazacyclopentane. mechanism
for the three hydrocarbons
> N-methylazacyclopentane
seems unlikely
should lie below those of the
It was found that the quenching of the triplet states by the amines
is much greater suggests
in acetonitrile
the occurrence
verify the production Further evidence
than in cyclohexane.
of a charge transfer
of radical
in support
excited
singlet states.
The Stern-Volmer
is more reactive
difference
in the conformation
quenching
for the complex
of excited
singlet process
for fluorescence
of ionisation
and oxidation
ever, the ionisation
which,
quenching.
process.
the are
for fluorescence
This may reflect
a
Since it is well established hydrocarbons
by amines
[9], it seems from the similarity
potentials
potential
comes
which gives rise to fluorescence
states of aromatic
and triplet
also occurs via a charge transfer
to
failed.
mechanism
the fluorescence
than N-methylazacyclopentane.
occurs via a charge transfer of reactivity
for quenching
is triethylamine
to that which causes triplet
that the quenching
quenching
is the same as that towards
constants
The only anomaly
shown in the Table.
all attempts
of the cyclic amines towards
states of the chloroaromatics
quenching,
However,
ions using laser flash photolysis
of the charge transfer
from the finding that the order of reactivity
triplet
This solvent effect
process.
quenching,
that triplet
Unfortunately
for the amines
in order
quenching
a comprehensive
is not available.
range How-
for N-methyl-4-oxa-azacyclohexane is considera10 and not surprisingly it is
bly higher than that of N-methylazacyclohexane the less efficient one electron reactive
quencher.
process
Chlorine
than N-methylazacyclohexane
azacyclopentane
is a better quencher
This work shows that the triplet amines.
unequivocal
proof that dechlorination
tion.
tertiary
amines
that -50%
At this latter concentration
via a
is more
The Table shows that the N-methyl-
than the N-methylazacyclohexane.
hydrocarbons
for quenching
of the triplets quenched
are quenched
this does not provide
occurs from the triplet
of the rate constant
of 2 x 10v4 M and -90%
Since dechlorination
[ll].
In the case of the chloroaromatics
nyl it can be calculated concentration
oxidises
states of aromatic
by tertiary
from a consideration
dioxide
and it was found that N-t-butylazacyclopentane
state.
triplet
are quenched
However,
4-chlorobipheat an amine
at a 10-S M amine concentra-
very little fluorescence
occurs at amine concentrations
quenching
occurs.
in the range of 10 -3 to
5676
1O-4 M it appears
reasonable
state. To get 50% quenching
to invoke reaction of the excited
tion of 4.5 x 10-2 M is required. excited
singlet
state quenching
Thus at high amine concentrations
plots of the reciprocal
versus the reciprocal
of the amine concentration
presented triplet
of reaction
are linear over a wide range
occur via the excited
data
singlet
and
[7].
Acknowledgements: financial
of the quantum yield
some quenching.
it must be, in the light of the rate constant
in this paper, that the reactions
states
via the triplet
states an amine concentra-
will occur and nearly total triplet
Since the Stern-Volmer
of amine concentrations
occurring
singlet
We thank the SERC for funds to purchase
support
(to R.A.B.)
and The City University
the laser and for
for a Fellowship
(to
D.G.).
References 1.
P.G. Sammes in "Chemistry of the Carbon-Halogen Bond", Ed. S. Patai, Part II, Chap. II, J. Wiley and Sons, New York (1973). R.K. Sharma and N. Kharasch, Angew. Chem. Int. Engl., 1968, L, 36. J. Grimshaw and A.P. de Silva, Chem. Sot. Rev., 1981, @, 181. R.S. Davidson, J.W. Goodin and G. Kemp, Adv. Phys. Org. Chem., 1984, 3. In the press.
2.
N.J. Bunce, Y. Kumar, L. Ravanal and S. Safe, J. Chem. Sot. Perkin Trans. g, 1978, 880. L.O. Ruzo, S. Safe and M.J. Zabuk, J. Agric. Food Chem., 1975, 23, 594. L.U. Ruzo, N.J. Bunce and S. Safe, Can. J. Chem., 1975,53, 688.
3.
N.J. Bunce, P. Pilon, L.O. Ruzo and D.J. Sturch, J. Org. Chem., 1976, 2, 3023.
4.
R.S. Davidson
and J.W. Goodin,
5.
M. Ohashi,
6.
N.J. Bunce, J. Org. Chem.,
7.
M. Ohashi
8.
The experimental set-up has been previously described:R.A. Beecroft, R.S. Davidson, D. Goodwin, J.E. Pratt, L.A. Chewter D. Phillips, Chem. Phys. Letters, 1982, 93, 468.
K. Tsujimoto
Tetrahedron
and K. Seki, J.C.S. 1982, 9,
and K. Tsujimoto,
Letters,
1981, 163.
Chem. Conun., 1973, 384.
1948.
Chem. Letters,
1983, 423.
and
9.
This subject has been comprehensively reviewed:R.S. Davidson in Molecular Association, Ed. R. Foster, Vol. I. Academic Press, London, 1975; N. Mataga and M. Ottolenghi in Molecular Association, Ed. R. Foster, Vol. II, Academic Press, London, 1979; R.S. Davidson Adv. Phys. Org. Chem., 1983, 19, 1.
10.
A.M. Halpern
11.
L.A. Hall, G.T. Davis, D.H. Rosenblatt 73, 2142.
and T. Gartman,
J. Amer. Chem. Sot., 1974, 96, 1393.
(Received in UK 30 September 1983)
and C-K. Mann, J. Phys. Chem.,
1969,