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An improved and practical synthesis of 4-fluorobenzaldehyde by halogen-exchange fluorination reaction
Journal of Fluorine Chemistry, 44 (1989)291-298
291
Received: November22,1988;accepted: February 7, 1989
AN IMPROVED
AND PRACTICAL
HALOGEN-EXCHANGE
YASUO
YOSHIDA
Research
and YOSHIKAZU
and
Co., Ltd.,
SYNTHESIS
FLUORINATION
Development
Fujikawa-cho,
OF 4-FLUOROBENZALDEHYDE
BY
REACTION
KIMURA*
Department, Ihara-gun,
Ihara
Chemical
Shizuoka
Industry
421-33
(Japan)
SUMMARY
A process
which
benzaldehyde
was
benzaldehyde
with
solvents
the
plus
in
presence glycol
a large
from
potassium
polyethylene
reaction
can afford
developed
fluoride of
quantity
halogen-exchange in
of
4-fluoro-
of
4-chloro-
aromatic
hydrocarbon
tetraphenylphosphonium
dimethyl
ether.
The
bromide
features
of the
are discussed.
INTRODUCTION
In this paper, proceeds
smoothly
presence glycol
of
we show that halogen-exchange in
aromatic
dimethyl
formyl
compound group
for
The aldehyde
plus
in
a
be
easily
is an attractive
synthetic
probably
little
intermediate,
converted
due
to
other
to difficulties
on
the
synthesis
of
congeners
consist
of 1) an
oxidation
reaction
oxidation
of
acid
and
of
fluorotoluene
reaction
fluorobenzyl 3) reduction
0022-1139/89/$3.50
derivatives
[21 and alcohols of
would a
be
large
so far.
for
group
its
functional
which
4-fluorobenzaldehyde exploited
aromatic because
methods
methyl
the
polyethylene
reported
the Balz-Schiemann
[51,
(PFAD)
as
obtaining
it has been
scale,
the
can
However,
groups.
encountered
solvents
bromide
ether.
4-Fluorobenzaldehyde fluoride
hydrocarbon
tetraphenylphosphonium
fluorination
related [41 or
fluorobenzEl 1 of
synthesized
reactions
[3l,
by 2)
fluorophenylacetic
fluorobenzonitriles 0 Elsevier Sequoia/Printed
t61,
these
in The Netherlands
292
reactions tion
seem
to be inapplicable
of fluorobenzaldehyde El,
intermediates and many
toxic
synthetic
to the
derivatives anhydrous
steps
large
due
scale
to use
hydrogen
prepara-
of unstable
fluoride
[2-51,
[61.
Ph4PBr
0
Cl,-,CHO
+
KF
-
F
CHO
+
KC1
(1)
PEG 300-Me2
PCAD
PFAD
We have
recently
developed
4-fluorobenzaldehyde halogen-exchange tion
by
bromide
(Ph4PBr)
dimethyl
ether
bility
a
of
the
industrial
scale.
However,
be applied
and
N-methylpyrrolidone
amount
Therefore, gation
in dipolar
the
by
its
usually
to
be
availa-
experimental
is much
and
qlycol
seems
better
on an
reaction
could
such used
as
sulfolane
on a halogen-
instead
give
a
large
(vide infra).
our attention
of appropriate
and
solvents
are
to
the reac-
of the ready
fluorination
reactions
materials
method
because
aprotic
(PCAD)
in which
polyethylene
the
solvents
which
fluorination
of tarry
or
materials
of appropriate
not
exchange
chemistry
route
tetraphenylphosphonium
While
1).
starting
use
of
18-crown-6
(eq.
in synthetic
simplicity,
of solvent,
combination
plus [71
synthetic
4-chlorobenzaldehyde
in the absence
catalyzed
attractive
from
a convenient
was next
solvents
focused
for PFAD
on the investi-
synthesis
by halogen-
exchange. We now
report
the
solvent
effects
RESULTS
AND DISCUSSION
Treatment sulfolane The
system
on these
of PCAD
of
the
reaction
recently* developed
ed.
Thus,
was
stirred
a mixture
in sulfolane
spray
12 h gave
desired time.
of a comprehensive
study
of
fluoride
in
reactions.
with
at 200 OC for
yield
prolonged
results
dried PFAD
product
by Prof.
not
than
5% yield.
increase
of the Ph4PBr/KF
Clark
with reagent
[Sl was next attempt-
1.5 equiv.
at 210 OC in the presence or N-methylpyrrolidone.
in less
did
Application
of PCAD with
potassium
of spray
of 0.1 equiv. Although
dried
KF
of Ph4PBr
the reaction
in
293
sulfolane large
in the
amounts 11).
run
The
viscous
ethylene
glycol
We have
now
of
as
starting clean
PCAD
gave
without
tarry
of
an
average
runs
I-3).
strongly
1, runs
5 and 6).
A
further
solvents
is
(Ph4PX)
could
distillation graphic salt
mixture
the
small
amount
same
reaction
desired method 300-Me2.
was
off
recycling Thus,
found
of the
to
of
the
in the
of
unreacted
of
was Ph4PBr,
solvent
ether
300-Me2) alone
showed
solvents
except
for tetra-
Reaction
useful. of potassium
of
times
fluoride
aromatic
from
(Table
hydrocarbon
after
By ion chromato-
recovered
Ph4PF
phosphonium
recovered
Two
reuse
of
phosphonium
used
previously
as
the
2, run including residue
methods
recovered salt
catalyst
and
is a
was not present.
examined.
direct
(Table
halide
residue
I-chloronaphthalene
was next
residue
the
PCAD. the
distillation
1,
(Table
synthesis
1 :I).
was
no
system,
dimethyl
(PEG
very
for PFAD
in
was
slightly
the
this
Ph4PBr
use
(z.
as
tested
that
Ph4PBr as
KF
tetraphenylphosphonium
first
conditions fell
the
Ph4PX
The
of virgin
PFAD
were
performed
of expensive
1,
poly-
solvents
reaction
absence
300
than
recovered
and Ph4PC1
or
dried
glycol
and unreacted
it was
A mixture
catalyst.
weight
expensive easily
(Table
in good yield.
43%
The
In
Aromatic
of
give
in 1-chloronaphthalene with
polyethylene
upon the nature
reaction
attempted.
spray
1).
generally
of product
of Ph4PBr
Reuse were
be
analysis,
from
1.
not
Ph4PBr
aromatic
In the
solvents
advantage
that
of
observed.
were
depended
1, run
activity
in Table
hydronaphthalene
54%
molecular
Some other
as summarized
equiv.
materials.
greater
1,
a highly
18-crown-6
some
yield
and
yield,
(Table
did
to give PFAD
of Ph4PBr
Ph4PBr
significantly
of
in
was
49%
became
of
of
amounts
(Table
reaction
combination
use
1.5
PFAD
materials
detectable
having
with
in
produced
was not investigated.
was applicable
of catalytic
solvent
that
presence
effect
ether
found
Treatment presence
the
dimethyl
solvents
PFAD
also
gradually
in the
cases
less polar
gave
were
in N-methylpyrrolidone
even
these
Ph4PBr
mixture
Reaction
product
In
8).
of
materials
reaction
liquid.
the desired run
presence
of tarry
under
yield
2).
The
Ph4PX of
and
run
of
a
the the
second and
PEG
2 were
1
The reactions
were
L
L
L
L
L
L
M
Me
M
M
Kogyo
a mixture
Co.; L=spray
dried
3
5
5
8
5
14
KF purchased
5
f
63
Industry
Co..
KF
150 mmol dried
of PCAD, M=Spray
mmol
b
from Laporte
at 210 'C.
of 100
49
trace
10
54
7
f
f
58
-
31
15(11)
25
56
75
-_(61)
7
5
64(60)
43
unreacted
PCAD
bromidea
Yield/%c
J3(68)
54
PFAD
5
7
5
consisting
in 20 ml of solvent
by stirring
11
0
II
II
11
I,
11
II
PEG 300-Me2
d
Time h
by tetraphenylphosphonium
solvent.
by GLC using internal standard techniques, and those in parentheses d are for isolated products. 0.2 equiv. of tetraethylene glycol dimethyl ether was used. f e 1 .J8 equiv. of KF was used. Could not be determined by GLC because of overlap with the
' Yields
Kagaku
from Morita
were determined
purchased
none CH30(CH2CH20)4CH3
and additive
conducted
of KF, 10 mmol of Ph4PBr,
a
sulfolane
11
nonanonitrile
9
tetrahydronaphthalene
N-methylpyrrolidone
8
10
triethylene glycol dimethyl ether
7
II
3,4-dichlorotoluene
5
6
methylnaphthalene (mixture of l- and 2-j
11
M
Additive (0.05 equiv.)
KFb
(PFAD) catalyzed
(1.5 equiv.)
4
I,
3
1-chloronaphthalene
Solvent
of 4-fluorobenzaldehyde
2
1
Run
Preparation
TABLE
g D
295
added 2.
PCAD, The
KF, and the same amount
reaction
same conditions run
3).
The
good yield As cies
recycling
according
instance
conditions,
to these
strong
in organic
It is surprising
that
and KF can proceed tion
of
We
[IO].
0.05
overnight
synthesis
smoothly
the
to
PFAD
viscous
in only
The
precise
is at present reaction
in the recovered salt
is a real
its
We
[ill. through Ph4PBr
mixture
intermediate,
to
now
a
fluoride in
a
dried
The
in
Patent KF 215
at
results
mixture
became
do
salt.
(1)
catalytic
believe
Ph4PF
and
was
not
phospho-
salt
should
fluorination
agent
hygroscopic
catalytic
intermediate
substance
reaction
which
found
If Ph4PF
bromide.
phosphonium
very
this
phase-transfer
(2) The recovered
and
the
not
usual
is not a useful
that
novel
is
proceeds
stabilized
by
addition
of
reactivity
of
[121.
polyethylene the potassium
glycol
above,
we have
dimethyl
fluoride.
ether
The role
observed
of naked
fluoride
The new method
includes
the following
procedures.
(1)
that
enhances of the
a formation
original
[91.
corresponding
spray
the
the
the recovered
Meisenheimer
As mentioned
enhance
are
The prepara-
in sulfolane
We
by
of chloride
solubility
believe
the
reported
of
reasons.
(3) Ph4PF
lower
which
of cesium
with
under
of chloro-
derivatives
solvents. from
spe-
explored
literature.
unclear.
phosphonium
be the chloride. owing
been
and the reaction
proceeds
following
1:l
was
not
PCAD
mechanism
fluorination
nium
2,
give
in our hands.
reaction
the
reaction
fluorides
fluoride
the
4% yield
liquid
fluorination
for
of
to
reactive
of benzaldehyde
recently
according
seems
reactions
small amounts
reaction
the
(Table
experiments.
metal
derivatives
under
of PFAD
generally
have
as in run
stirring
residue
in aromatic
was
Ph4PBr
Cannizzaro
alkali
of cesium
afforded
mechanism
the
equiv.
a highly
are
the reaction
solvents
tried
containing OC
by
by KF containing aprotic
the
halogen-exchange
fluorobenzaldehyde
dipolar
of
preliminary
undergoing direct
with
73% yield
derivatives
derivatives
chlorides
heated
process
benzaldehyde bases
was
as run 1 to afford
benzaldehyde
for
basic
mixture
of virgin
the
polyether
may
be
to
[131. advantages
The us e of aromatic
solvents
over
the
is more
296
practical
in an industrial The
stirring.
original
not applicable
to large
ated
use
with
the
solvents
are
difficulties expensive
yield. recovered
because
of
after
in readily
and
salt salt
obtaining
associ-
are
that
such
decompose
at
high
ion,
and
present
purification.
(3) The
can be recovered
was decomposed in
of tarry
improved
is clearly
(Ph4PX)
of the desired
formation
these
fluoride
reaction
effective
solvent
(2) Problems
easily
separation
(4) Selectivity
employing
succeeded
presence
it allows
solvents
aprotic
toxic,
The phosphonium
of decreased
By
dipolar
in product
in high
solvent.
the
as
without
synthesis.
tetraphenylphosphonium
not
be
scale
expensive, in
temperature
of
preparation
procedure
or
product
was
could
without improved
materials.
synthetic
a large
and
sulfolane
methods,
quantity
of
we
have
PFAD
from
PCAD. TABLE
2
Recovery
of catalysta
Yield/% Run
Ph4Px
CH30(CH2CH20J4CH3 PFAD
PCAD
1
4.2 g of Ph4PBr
yes
73
15
2
3.0 g of recovered salt plus 1.2 g of virgin Ph4PBr
yes
66
21
3
after distillation of run 2 plus 1.2 g of virgin Ph4PBr
no
73
18
a The reaction was conducted by stirring a mixture consisting of 100 mmol of PCAD, 150 mmol of KF, 10 mmol of Ph4PBr, 20 mmol of tetraethylene glycol dimethyl ether, and 20 ml of lchloronaphthalene at 210 OC for 7 h. Yields were determined by GLC.
EXPERIMENTAL
Product 163 gas GC
on
mixtures
chromatograph Chromosorb
W
were using AW
analyzed
by GLC on a Hitachi
a 3 mm x 2 m column
DMCS
(used
of
Model
of Dexsil
cyclododecane
as
400 an
297
internal were
standard).
analyzed
graphic
on
Analyzer.
controlled
obtained
aid
stated
otherwise,
commercially
dried
of
and was
potassium
Industry
Co. and Morita ether
all
used
Kagaku
having were
respectively.
General
procedure
(8.7
g,
oil bath remove
mmol),
and
ether
toluene
toluene PCAD
the whole
ture
and
68%)
having
spectra
a
PFAD purchased
g,
20
100 mmol)
g,
was stirred
74-77
the
from Aldrich
precipitates
mmHg
then
Chemical
residue,
washed
with
vacuum
to
3.4
(84%)
was
in one
cooled
portion
to room
IR,
NMR,
to
a nitrotempera-
PFAD
those
to
and
Filtration
pure
The
in an
stirred
and
(8.4 g, and
Mass
of authentic
salt
diethyl of
Co.)
Co.
collected
cooled
g
was
flask
gave
with
charged
Kogyo
immersed
added.
[71.
and
tetraethylene
was
cooled
was
identical
were
was
for 7 h at 210 OC under was
were
Co.
a mechanical
Kagaku
the mixture
added
and
1-chloronaphthalene
flask
was
glycol 300
1, run 2)
with
mmol),
After
(120 ml)
OC/20
Kogyo
(Table
use.
Laporte
of
separator
by distillation
sample
yield
weight
10 mmol),
The
were
before
Polyethylene
(Morita
g,
of tetraphenylphosphonium
The
Electric
from
Daiichi
water
(4.2
(4.4
followed bp
Co..
fluoride
The mixture
of this
Recovery
and
(30 ml).
dichloromethane
concentration
was
purification.
purchased
equipped
azeotropically.
gen atmosphere.
used
chemicals
further
from
at 140 OC, and
(14.1
mixture
and
molecular
flask
Ph4PBr
maintained
100 oc,
Heater
for 4-fluorobenzaldehyde
potassium
dimethyl
ml),
was
obtained
four-necked
dried
150
glycol (20
Co.,
a thermometer,
spray
salts Chromato-
bath
by distillation
Kogyo
Kako
with
Ion
oil
Mini
without
an average
Sumikin
ml
the
reagents
purified
methylnaphthalene
A 100
of
Ricoh
fluoride
dimethyl
stirrer,
Electric
MH-10.
4-Chlorobenzaldehyde Spray
tetraphenylphosphonium
Hokushin
temperature
the
Model
Unless
Yokokawa The
with
Controller
Recovered
a
dry
by
filtration
ether,
and
from
dried
the
under
tetraphenylphosphonium
The IR spectrum
salt.
analysis
of halide
of bromide
was identical
with
The
that of Ph4PBr.
by ion chromatography
showed
a 1:l mixture
and chloride.
REFERENCES 1 a) K. Fukui, Nippon Collect 55
Czech
(1960)
Bentov, 2 a)
H.
3
a)
Chem.
1502.
Synth.
and
Commun ., 4 T.R.
'AZO
Beebe,
(1943)
C.C.
B.
J. Org. Vickery,
York
Aliphatic
M.
and b) H.
(1961).
1.
Vankar, 44
Chem., and
c)
D.T.
M.
Nojima,
I.
3872.
b)
W.D.
(1979)
A.
Bogardus,
J. Shadday,
Yates,
and
Y.D.
T. Sawada
Adkins,
and S.W.
3
J. Org.
R.L.
and
Flood,
295.
Welch,
785.
Webb (1978)
II,
Abstr.,
Kaliszyner
Chemistry, New
(1987)
P. Reinkinh,
Diazo
(1965)
Olah,
Hii,
A.
Chem.,
N. Yoneda,
17
5 F. Kaberia
and
Hudlicky,
M.
1199; Chem.
5418.
Interscience,
J.T.
J.A.
T. Fukuhara,
(1961)
Fluorine
Olah,
G.A.
Kerekes
(1960)
25
and H. Shirai,
b)
1428.
2. Pelchowicz,
c)
Coil.
Y. Inamoto
(1958)
Commun.,
Compounds' Adv.
79
Sot.,
Zollinger,
Suschzky,
T. Osaka,
Zasshi,
J. Chem.
Aromatic
Org.
H. Kitano,
Kagaku
Suzuki,
B.
Synth.
Champney,
Weatherfor
III,
P.S. M.W.
Chem., J.
48 (1983) 3126. Chem. Sot., Chem. Commun.,
459.
6 E. Klauke,
U. Petersen
and K. Grohe,
Ger.
Offen
DE
3 420 796
(1985). 7 Y. Yoshida 8 J.H.
and Y. Kimura,
Clark
(1987)
and
Merz
11 S.J.
Chem.
Lett.,
MacQuarrie,
(1988)
1355.
Tetrahedron
Lett.,
28 -
111.
9 G.G. Yakobson IO H.J.
D.J.
and N.E. Akhmetova,
and K. Warning,
Brown
and
J.H.
Synthesis,
Ger. Offen
Clark,
DE
3 637
J. Fluorine
(1983) 156
Chem.,
169.
(1988). 30
(1985)
251. 12
J.H. (I 987)
Clark
and
D.J.
Macquarrie,
J.
Fluorine
Chem.,
591.
13 T. Kitazume
and N. Ishikawa,
Chem.
Lett.,
(1978)
283.
35
291
Received: November22,1988;accepted: February 7, 1989
AN IMPROVED
AND PRACTICAL
HALOGEN-EXCHANGE
YASUO
YOSHIDA
Research
and YOSHIKAZU
and
Co., Ltd.,
SYNTHESIS
FLUORINATION
Development
Fujikawa-cho,
OF 4-FLUOROBENZALDEHYDE
BY
REACTION
KIMURA*
Department, Ihara-gun,
Ihara
Chemical
Shizuoka
Industry
421-33
(Japan)
SUMMARY
A process
which
benzaldehyde
was
benzaldehyde
with
solvents
the
plus
in
presence glycol
a large
from
potassium
polyethylene
reaction
can afford
developed
fluoride of
quantity
halogen-exchange in
of
4-fluoro-
of
4-chloro-
aromatic
hydrocarbon
tetraphenylphosphonium
dimethyl
ether.
The
bromide
features
of the
are discussed.
INTRODUCTION
In this paper, proceeds
smoothly
presence glycol
of
we show that halogen-exchange in
aromatic
dimethyl
formyl
compound group
for
The aldehyde
plus
in
a
be
easily
is an attractive
synthetic
probably
little
intermediate,
converted
due
to
other
to difficulties
on
the
synthesis
of
congeners
consist
of 1) an
oxidation
reaction
oxidation
of
acid
and
of
fluorotoluene
reaction
fluorobenzyl 3) reduction
0022-1139/89/$3.50
derivatives
[21 and alcohols of
would a
be
large
so far.
for
group
its
functional
which
4-fluorobenzaldehyde exploited
aromatic because
methods
methyl
the
polyethylene
reported
the Balz-Schiemann
[51,
(PFAD)
as
obtaining
it has been
scale,
the
can
However,
groups.
encountered
solvents
bromide
ether.
4-Fluorobenzaldehyde fluoride
hydrocarbon
tetraphenylphosphonium
fluorination
related [41 or
fluorobenzEl 1 of
synthesized
reactions
[3l,
by 2)
fluorophenylacetic
fluorobenzonitriles 0 Elsevier Sequoia/Printed
t61,
these
in The Netherlands
292
reactions tion
seem
to be inapplicable
of fluorobenzaldehyde El,
intermediates and many
toxic
synthetic
to the
derivatives anhydrous
steps
large
due
scale
to use
hydrogen
prepara-
of unstable
fluoride
[2-51,
[61.
Ph4PBr
0
Cl,-,CHO
+
KF
-
F
CHO
+
KC1
(1)
PEG 300-Me2
PCAD
PFAD
We have
recently
developed
4-fluorobenzaldehyde halogen-exchange tion
by
bromide
(Ph4PBr)
dimethyl
ether
bility
a
of
the
industrial
scale.
However,
be applied
and
N-methylpyrrolidone
amount
Therefore, gation
in dipolar
the
by
its
usually
to
be
availa-
experimental
is much
and
qlycol
seems
better
on an
reaction
could
such used
as
sulfolane
on a halogen-
instead
give
a
large
(vide infra).
our attention
of appropriate
and
solvents
are
to
the reac-
of the ready
fluorination
reactions
materials
method
because
aprotic
(PCAD)
in which
polyethylene
the
solvents
which
fluorination
of tarry
or
materials
of appropriate
not
exchange
chemistry
route
tetraphenylphosphonium
While
1).
starting
use
of
18-crown-6
(eq.
in synthetic
simplicity,
of solvent,
combination
plus [71
synthetic
4-chlorobenzaldehyde
in the absence
catalyzed
attractive
from
a convenient
was next
solvents
focused
for PFAD
on the investi-
synthesis
by halogen-
exchange. We now
report
the
solvent
effects
RESULTS
AND DISCUSSION
Treatment sulfolane The
system
on these
of PCAD
of
the
reaction
recently* developed
ed.
Thus,
was
stirred
a mixture
in sulfolane
spray
12 h gave
desired time.
of a comprehensive
study
of
fluoride
in
reactions.
with
at 200 OC for
yield
prolonged
results
dried PFAD
product
by Prof.
not
than
5% yield.
increase
of the Ph4PBr/KF
Clark
with reagent
[Sl was next attempt-
1.5 equiv.
at 210 OC in the presence or N-methylpyrrolidone.
in less
did
Application
of PCAD with
potassium
of spray
of 0.1 equiv. Although
dried
KF
of Ph4PBr
the reaction
in
293
sulfolane large
in the
amounts 11).
run
The
viscous
ethylene
glycol
We have
now
of
as
starting clean
PCAD
gave
without
tarry
of
an
average
runs
I-3).
strongly
1, runs
5 and 6).
A
further
solvents
is
(Ph4PX)
could
distillation graphic salt
mixture
the
small
amount
same
reaction
desired method 300-Me2.
was
off
recycling Thus,
found
of the
to
of
the
in the
of
unreacted
of
was Ph4PBr,
solvent
ether
300-Me2) alone
showed
solvents
except
for tetra-
Reaction
useful. of potassium
of
times
fluoride
aromatic
from
(Table
hydrocarbon
after
By ion chromato-
recovered
Ph4PF
phosphonium
recovered
Two
reuse
of
phosphonium
used
previously
as
the
2, run including residue
methods
recovered salt
catalyst
and
is a
was not present.
examined.
direct
(Table
halide
residue
I-chloronaphthalene
was next
residue
the
PCAD. the
distillation
1,
(Table
synthesis
1 :I).
was
no
system,
dimethyl
(PEG
very
for PFAD
in
was
slightly
the
this
Ph4PBr
use
(z.
as
tested
that
Ph4PBr as
KF
tetraphenylphosphonium
first
conditions fell
the
Ph4PX
The
of virgin
PFAD
were
performed
of expensive
1,
poly-
solvents
reaction
absence
300
than
recovered
and Ph4PC1
or
dried
glycol
and unreacted
it was
A mixture
catalyst.
weight
expensive easily
(Table
in good yield.
43%
The
In
Aromatic
of
give
in 1-chloronaphthalene with
polyethylene
upon the nature
reaction
attempted.
spray
1).
generally
of product
of Ph4PBr
Reuse were
be
analysis,
from
1.
not
Ph4PBr
aromatic
In the
solvents
advantage
that
of
observed.
were
depended
1, run
activity
in Table
hydronaphthalene
54%
molecular
Some other
as summarized
equiv.
materials.
greater
1,
a highly
18-crown-6
some
yield
and
yield,
(Table
did
to give PFAD
of Ph4PBr
Ph4PBr
significantly
of
in
was
49%
became
of
of
amounts
(Table
reaction
combination
use
1.5
PFAD
materials
detectable
having
with
in
produced
was not investigated.
was applicable
of catalytic
solvent
that
presence
effect
ether
found
Treatment presence
the
dimethyl
solvents
PFAD
also
gradually
in the
cases
less polar
gave
were
in N-methylpyrrolidone
even
these
Ph4PBr
mixture
Reaction
product
In
8).
of
materials
reaction
liquid.
the desired run
presence
of tarry
under
yield
2).
The
Ph4PX of
and
run
of
a
the the
second and
PEG
2 were
1
The reactions
were
L
L
L
L
L
L
M
Me
M
M
Kogyo
a mixture
Co.; L=spray
dried
3
5
5
8
5
14
KF purchased
5
f
63
Industry
Co..
KF
150 mmol dried
of PCAD, M=Spray
mmol
b
from Laporte
at 210 'C.
of 100
49
trace
10
54
7
f
f
58
-
31
15(11)
25
56
75
-_(61)
7
5
64(60)
43
unreacted
PCAD
bromidea
Yield/%c
J3(68)
54
PFAD
5
7
5
consisting
in 20 ml of solvent
by stirring
11
0
II
II
11
I,
11
II
PEG 300-Me2
d
Time h
by tetraphenylphosphonium
solvent.
by GLC using internal standard techniques, and those in parentheses d are for isolated products. 0.2 equiv. of tetraethylene glycol dimethyl ether was used. f e 1 .J8 equiv. of KF was used. Could not be determined by GLC because of overlap with the
' Yields
Kagaku
from Morita
were determined
purchased
none CH30(CH2CH20)4CH3
and additive
conducted
of KF, 10 mmol of Ph4PBr,
a
sulfolane
11
nonanonitrile
9
tetrahydronaphthalene
N-methylpyrrolidone
8
10
triethylene glycol dimethyl ether
7
II
3,4-dichlorotoluene
5
6
methylnaphthalene (mixture of l- and 2-j
11
M
Additive (0.05 equiv.)
KFb
(PFAD) catalyzed
(1.5 equiv.)
4
I,
3
1-chloronaphthalene
Solvent
of 4-fluorobenzaldehyde
2
1
Run
Preparation
TABLE
g D
295
added 2.
PCAD, The
KF, and the same amount
reaction
same conditions run
3).
The
good yield As cies
recycling
according
instance
conditions,
to these
strong
in organic
It is surprising
that
and KF can proceed tion
of
We
[IO].
0.05
overnight
synthesis
smoothly
the
to
PFAD
viscous
in only
The
precise
is at present reaction
in the recovered salt
is a real
its
We
[ill. through Ph4PBr
mixture
intermediate,
to
now
a
fluoride in
a
dried
The
in
Patent KF 215
at
results
mixture
became
do
salt.
(1)
catalytic
believe
Ph4PF
and
was
not
phospho-
salt
should
fluorination
agent
hygroscopic
catalytic
intermediate
substance
reaction
which
found
If Ph4PF
bromide.
phosphonium
very
this
phase-transfer
(2) The recovered
and
the
not
usual
is not a useful
that
novel
is
proceeds
stabilized
by
addition
of
reactivity
of
[121.
polyethylene the potassium
glycol
above,
we have
dimethyl
fluoride.
ether
The role
observed
of naked
fluoride
The new method
includes
the following
procedures.
(1)
that
enhances of the
a formation
original
[91.
corresponding
spray
the
the
the recovered
Meisenheimer
As mentioned
enhance
are
The prepara-
in sulfolane
We
by
of chloride
solubility
believe
the
reported
of
reasons.
(3) Ph4PF
lower
which
of cesium
with
under
of chloro-
derivatives
solvents. from
spe-
explored
literature.
unclear.
phosphonium
be the chloride. owing
been
and the reaction
proceeds
following
1:l
was
not
PCAD
mechanism
fluorination
nium
2,
give
in our hands.
reaction
the
reaction
fluorides
fluoride
the
4% yield
liquid
fluorination
for
of
to
reactive
of benzaldehyde
recently
according
seems
reactions
small amounts
reaction
the
(Table
experiments.
metal
derivatives
under
of PFAD
generally
have
as in run
stirring
residue
in aromatic
was
Ph4PBr
Cannizzaro
alkali
of cesium
afforded
mechanism
the
equiv.
a highly
are
the reaction
solvents
tried
containing OC
by
by KF containing aprotic
the
halogen-exchange
fluorobenzaldehyde
dipolar
of
preliminary
undergoing direct
with
73% yield
derivatives
derivatives
chlorides
heated
process
benzaldehyde bases
was
as run 1 to afford
benzaldehyde
for
basic
mixture
of virgin
the
polyether
may
be
to
[131. advantages
The us e of aromatic
solvents
over
the
is more
296
practical
in an industrial The
stirring.
original
not applicable
to large
ated
use
with
the
solvents
are
difficulties expensive
yield. recovered
because
of
after
in readily
and
salt salt
obtaining
associ-
are
that
such
decompose
at
high
ion,
and
present
purification.
(3) The
can be recovered
was decomposed in
of tarry
improved
is clearly
(Ph4PX)
of the desired
formation
these
fluoride
reaction
effective
solvent
(2) Problems
easily
separation
(4) Selectivity
employing
succeeded
presence
it allows
solvents
aprotic
toxic,
The phosphonium
of decreased
By
dipolar
in product
in high
solvent.
the
as
without
synthesis.
tetraphenylphosphonium
not
be
scale
expensive, in
temperature
of
preparation
procedure
or
product
was
could
without improved
materials.
synthetic
a large
and
sulfolane
methods,
quantity
of
we
have
PFAD
from
PCAD. TABLE
2
Recovery
of catalysta
Yield/% Run
Ph4Px
CH30(CH2CH20J4CH3 PFAD
PCAD
1
4.2 g of Ph4PBr
yes
73
15
2
3.0 g of recovered salt plus 1.2 g of virgin Ph4PBr
yes
66
21
3
after distillation of run 2 plus 1.2 g of virgin Ph4PBr
no
73
18
a The reaction was conducted by stirring a mixture consisting of 100 mmol of PCAD, 150 mmol of KF, 10 mmol of Ph4PBr, 20 mmol of tetraethylene glycol dimethyl ether, and 20 ml of lchloronaphthalene at 210 OC for 7 h. Yields were determined by GLC.
EXPERIMENTAL
Product 163 gas GC
on
mixtures
chromatograph Chromosorb
W
were using AW
analyzed
by GLC on a Hitachi
a 3 mm x 2 m column
DMCS
(used
of
Model
of Dexsil
cyclododecane
as
400 an
297
internal were
standard).
analyzed
graphic
on
Analyzer.
controlled
obtained
aid
stated
otherwise,
commercially
dried
of
and was
potassium
Industry
Co. and Morita ether
all
used
Kagaku
having were
respectively.
General
procedure
(8.7
g,
oil bath remove
mmol),
and
ether
toluene
toluene PCAD
the whole
ture
and
68%)
having
spectra
a
PFAD purchased
g,
20
100 mmol)
g,
was stirred
74-77
the
from Aldrich
precipitates
mmHg
then
Chemical
residue,
washed
with
vacuum
to
3.4
(84%)
was
in one
cooled
portion
to room
IR,
NMR,
to
a nitrotempera-
PFAD
those
to
and
Filtration
pure
The
in an
stirred
and
(8.4 g, and
Mass
of authentic
salt
diethyl of
Co.)
Co.
collected
cooled
g
was
flask
gave
with
charged
Kogyo
immersed
added.
[71.
and
tetraethylene
was
cooled
was
identical
were
was
for 7 h at 210 OC under was
were
Co.
a mechanical
Kagaku
the mixture
added
and
1-chloronaphthalene
flask
was
glycol 300
1, run 2)
with
mmol),
After
(120 ml)
OC/20
Kogyo
(Table
use.
Laporte
of
separator
by distillation
sample
yield
weight
10 mmol),
The
were
before
Polyethylene
(Morita
g,
of tetraphenylphosphonium
The
Electric
from
Daiichi
water
(4.2
(4.4
followed bp
Co..
fluoride
The mixture
of this
Recovery
and
(30 ml).
dichloromethane
concentration
was
purification.
purchased
equipped
azeotropically.
gen atmosphere.
used
chemicals
further
from
at 140 OC, and
(14.1
mixture
and
molecular
flask
Ph4PBr
maintained
100 oc,
Heater
for 4-fluorobenzaldehyde
potassium
dimethyl
ml),
was
obtained
four-necked
dried
150
glycol (20
Co.,
a thermometer,
spray
salts Chromato-
bath
by distillation
Kogyo
Kako
with
Ion
oil
Mini
without
an average
Sumikin
ml
the
reagents
purified
methylnaphthalene
A 100
of
Ricoh
fluoride
dimethyl
stirrer,
Electric
MH-10.
4-Chlorobenzaldehyde Spray
tetraphenylphosphonium
Hokushin
temperature
the
Model
Unless
Yokokawa The
with
Controller
Recovered
a
dry
by
filtration
ether,
and
from
dried
the
under
tetraphenylphosphonium
The IR spectrum
salt.
analysis
of halide
of bromide
was identical
with
The
that of Ph4PBr.
by ion chromatography
showed
a 1:l mixture
and chloride.
REFERENCES 1 a) K. Fukui, Nippon Collect 55
Czech
(1960)
Bentov, 2 a)
H.
3
a)
Chem.
1502.
Synth.
and
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'AZO
Beebe,
(1943)
C.C.
B.
J. Org. Vickery,
York
Aliphatic
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1.
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D.T.
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P. Reinkinh,
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Olah,
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5 F. Kaberia
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11 S.J.
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9 G.G. Yakobson IO H.J.
D.J.
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J.H. (I 987)
Clark
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D.J.
Macquarrie,
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13 T. Kitazume
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35