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Substitutive aromatic fluorination with chlorine pentafluoride
Journal of Fluorine Chemistry, 25 (1984)
435-446
435
Received: September30,1983;accepted: March24,1984
SUBSTITUTIVE AROMATIC FLUORINATION WITH CHLORINE PENTAFLUORIDE*
MAX M. BOUDAKIAN** AND GENE A. HYDE
Olin Chemicals, New Haven, Connecticut 06511 (U.S.A.)
SUMMARY
In contrast to limited substitutive fluorination of aromatics with halogen fluorides such as ClF, ClF3, BrF3 and IF5, fluorination is the predominant reaction path with ClF5. Under non-catalytic liquid phase conditions, benzene was converted to fluorobenzene (54% yield) and chlorobenzene (37% yield), respectively. For a heterocyclic substrate, i.e. 2,4,6-trifluoropyrimidine,substitutive fluorination predominated over chlorination. Three possible fluorinationmechanisms are discussed. A transition complex of ClF5 with benzene is favored. Enhanced exchange fluorination of Ccl& was effected with C1F5 (CF2C12>>CFC13>CF3C1)as compared with ClF3 (CFC13"CF$12).
INTRODUCTION
Growing applications for ring fluorinated aromatics [l] have created much interest in the development of new synthesis techniques. While early direct aromatic substitutionwith fluorine (F2) gave violent reactions involving ring scission, addition, coupling and polymerization,new fluorination techniques have been developed in recent years: molecular fluorine [2-51; xenon fluorides [6]; high valency metal fluorides such as silver difluoride [7,8] or cobaltic trifluoride [8]; organic hypofluorites
*
Based on an earlier presentation: 'Liquid Phase Aromatic Fluorination With Chlorine Pentafluoride,'162nd American Chemical Society Meeting, Washington, D.C.
September 1971. Paper No. 6 (Division of Fluorine
Chemistry) **
Rochester, New York 14611 (U.S.A.)
0022-1139/84/$3.00
OElsevier Sequoia/Printed in The Netherlands
436 such as CF30F 19,101 or CH3C02F [ll]; ionic hypofluorites such as CsS04F or RbS04F [12,13]; NFqBF41141; and, anodic fluorination by controlled potential electrolysis (151. With halogen fluorides such as ClF, ClF3, BrF3 and IF5, and aromatics, substitutive fluorination has been a minor reaction path (Table 1).
TABLE 1
Substitutive Aromatic Halogenation With Halogen Fluorides
Interhalogen
Substitution Product
Ref.
ccl4
C6H5C1
16
Solvent
Substrate
ClF
C6H6
C1F3
C6H6 'gHF5
BrF3
C6H6 'gHF5
ccl4
C6H5C1'C6H5F
17
HF
C6C1F5
18
CH3CN
C6H5BrF2
19
CFC12CF2C1;
C6BrF5
20
C6H51"C6H5F;
21
HF/S02C1F C6H6
IF5
C6H4FI 1,3,5-C3H3F3 'gHF5
Inert
22
Inert
22
Of the above halogen fluorides, C1F3 (or modifications) has been the most intensively studied reagent with aromatics. Ellis and Musgrave [17 a-c] established that substitutive chlorination predominated over fluorination when benzene was reacted with C1F3 (CC14 solvent) under catalytic (e.g. CoF2) or non-catalytic conditions in a steel reactor. (Side reactions such as ring addition, coupling and tar formation contributed to low yields). F
Cl
2.0
0 I
\
+ C1F3
,::,
L
6
>
4
(l)
/
(1)
(11)
431 A later modification discovery
of the ClF3-benzene
[23 a-c] that difluorochloronium
addition
of Lewis acids,
substitutive
fluorobenzene
ion, ClF2+
(generated
e.g. BF 3, to give ClF2+BF4-),
fluorination.
found that fluorinated
system was Pavlath's
In contrast,
aromatics,
Yakobson
by
enhanced
et al. [18,22] recently
e.g. 1,3,5_trifluorobenzene,
penta-
and 4-H-heptafluorotoluene,
do not undergo substitutive + aromatic fluorination with C1F2 + , BrF2+, BrF4+ and IF salts. 4 A major advance in recent halogen fluoride chemistry was the discovery of the new interhalogen, of alternate
synthesis
substitutive conditions
chlorine routes
halogenation
pentafluoride,
124-281.
patterns
and the rapid development
A study was undertaken
of ClF
5
with benzene
to assess
under 'liquid-phase'
[29].
RESULTS AND DISCUSSION
Substitutive
Fluorination
Substitutive non-catalytic
of Benzene With Chlorine
halogenation
Pentafluoride
studies with benzene
were conducted
under
in CC14 solvent at low and high C1F5
conditions
concentrations. At -low C1F5 concentrations nearly arising
from aromatic
over chlorination fluorobenzene
substitution
as evidenced
+
In contrast negligible
evidence
C1F5
showed no evidence
are reminiscent exchange substrate
between
Fluorination
(Table III).
3N2 17 cc14 O0
f
C1F3-benzene
examination
CC14),
predominated yields of
(I), respectively.
for side reactions
Infrared
N2:16.8
for as products
by 53.8% and 36.5% corrected
to the corresponding
polymerization.
C6H6:3.0
benzene was accounted
(II) and chlorobenzene
2.75
-134')
(1.0 C1F5:2.75
all (97%) of the consumed
arising
(II) >
system
1171, there was
from addition,
of the cold traps
of chlorofluoromethanes.
of Ellis and Musgrave's
findings
(2)
(I)
coupling
or
c-15', -78' and
(The latter observations 117 a,b] that halogen
Ccl4 and C1F3 did not occur if a more easily halogenated
such as benzene was present).
438 Attempts
failed
concentrations' benzene
to enhance
(1.0 ClF5:1.3
was consumed,
products
the maximum
products.
fluorination
CC14).
higher
to the absence
to further
competitive
fluorinate
fluorobenzene
was completely
consumed
catalyst/Ccl4
solvent),
were
Likewise,
the reaction
formed.
in complete
were found.
conversion
(Similar inability
liquid phase conditions
Grakauskas:
product
that
to non-volatile at low C1F5
Ccl4 exchange
polymer
formation
distribution
Substitutive
of p-difluorobenzene
fluorine
stoichiometry,
products
and C1F3
no substitution
to effect poly-substitutive
products
fluorination
(F2) were noted by
appreciable
was noted; at higher molar
was reversed
Fluorination
with C1F3 (CoF2 and addition
of the substrate;
with molecular
at low F2/benzene
to give polyfluoro-
117 bl found that, while
upon reaction
only R-chlorofluorobenzene
and minor
represented
of (II) suggests
by conversion
Ellis and Musgrave
is not surprising.
fluorobenzene
under
While all of the for as substitution
of chlorofluoromethanes
C1F5 levels effected
ClF5
to give CC13F and CC12F2).
The inability
resulted
at h&$
(5.2% yield)
The absence
of the latter was followed
(In contrast
concentrations,
N2:8.4
g- and/or P-Difluorobenzene
degree of fluorination.
generation
benzenes
C6H6:Z.O
fluorination
only 32.4% could be accounted
(Table IV).
in-situ --
substitutive
substitution
ratios,
this
[2]).
of 2,4,6-Trifluoropyrimidine
With Chlorine
Pentafluoride In contrast exhibit
slightly
sluggish
different
fluorination
pyrimidine
benzenes,
behavior
evidenced
toward halogen
(33.9% conversion)
(fluorination
path:
again predominating)
of the perfluorocyclic by quantitative
heterocyclics
fluorides.
For example,
was noted when 2,4,6-trifluoro-
2,4,5,6_tetrafluoropyrimidine
5-chloro-2,4,6_trifluoropyrimidine cleavage
fluorinated
was reacted with C1F5 in FLUORINERW
halogenation reaction
to fluorinated
Liquid
FC-75.
represented
Substitutive
a minor
(IV), 14.8% yield
(V), 8.7% yield
(corrected).
(corrected); (Ring
ether solvent by C1F5 is not possible
recovery
as
of FC-75 and C1F5 after 120 hours at 25').
F 7 ,I\ 'N
+
ClF5 c;;60
)
FaF
>
F&F
(3)
F
(III)
F
Cl
(IV)
QJ)
439
Mechanism
At least three potential fluorination paths could be considered.
(a) Fluorination via ClF, Dissociation -I Fluorination could arise from ClF5 dissociation products at O":
O0
ClF5
ClF3 +
/
F2
(4)
(5)
However, the negligible rate of ClF5 dissociation up to 200' (16 hours) reported by Bauer and Sheehan [30] does not support this mechanism.
(b) Self-Ionizationof C1F5 Self-ionizationof ClF5 to generate ClF4* as the active fluorinating species represents another reaction path: 2ClF5
ClF4+ +
+
ClF6-
(6)
This sequence does not appear likely. Meinert and Gross established the following order of decreasing self-ionizationwithin the halogen fluorides: BrF3>IF5>BrF5>C1F3>ClF51311. Moreover, the use of CC14 solvent, a medium of low dielectric constant employed in the substitutive fluorination of benzene, would not favor self-ionizationof ClF,.
(c) Transition Complex A transition complex with the aromatic ring was proposed by Musgrave for the non-catalyzed reaction of ClF3 and benzene 117 cl.
o+ oH .
U I
,
+
C1F3
-
0
_.F--C1F2 *
F
I
I' -
0
+HF+C:I
440 ClF would then erve as a chlorinating agent, in agreement with the likely ci5apolarization, Cl-F, to give chlorobenzene,as previously demonstrated by Gambaretto, et al. [16]. (A potential intermediate in Musgrave's transition complex mechanism could be C6H5C1F2. Nesmeyanov, et
[19] formed
phenylbromosodifluoride,C6H5BrF2, from benzene and BrF3/acetonitrile). A modified transition complex mechanism proceeding via an arenium cation could be envisaged for the correspondingnon-catalyzed ClF5-benzene system: + (I
a-
ClF3 generated from the above sequence would then participate by the Musgrave transition complex path with benzene depicted in equation (7) [17 c] 1321.
,Reaction of Chlorine Fluorides With Carbon Tetrachloride
ClF5 effected exchange fluorination of CC14 (absence of aromatic substrate) to give a mixture of chlorofluoromethanes: CF2C12>>CECL3 >CE3Cl (Table 2). The corresponding study by Ellis and Musgrave for C1F3 and CC14 gave chlorofluoromethanesof a lesser degree of fluorimation: CFC13>>CF2C12 117 b].
TABLE 2
Reaction of Chlorine Fluorides With CC14
Chlorine Fluoride
Ref.
ClF5
This Study
C1F3
117 b]
Molar Ratio CIFx CC14 N? 1.0
Temp.
Time (hr)
00
1.5
13.2
3.0
1.0
11.0
3.4
O"
6.8
1.0
10.7 4.1
25'
8.4
Molar Ratio CF,Cl CF2C12 CFC13_ 1.0
7.5
1.3
(--)
(--)
1.0
(--)
1.0
7.0
441
EXPERIMENTAL
Reagents
ClF5 Benzene,
(IR assay, > 99%) was prepared Baker & Adamson
Mallinckrodt prepared
(A.R. Grade).
FC-75, mainly
was obtained
15% Igepal CO880-Chromosorb
temp., 210°; detector
and
from 3M Co.
W (80/100 mesh);
75-250" at lO'/min.;
injection
temp., 210'; flow rate, 7 sec./l0
2,4,6_trifluoropyrimidine:
temp., 160'; flow rate, 6.3 sec./l0
column, port
cc.
15% SE30-Chromosorb
3 m., l/4 in.; column temp., 60"; injection
detector
[34].
perfluoro-(2-g-butyltetrahydrofuran)
2 m., l/4 in. i.d.; column temp.,
column,
(gc, 99.9%) was
Chromatography
ClF5 with benzene:
C1F5 with
tetrachloride,
and KF in sulfolane
perfluoro-(2-z-propyltetrahydropyran),
Gas Liquid
Carbon
2,4,6_Trifluoropyrimidine
from 2,4,6_trichloropyrimidine
FLUORINER'I@ Liquid
from KC1 and F2 [28 a,b].
(Reagent ACS Grade).
W (SO/l00 mesh);
port temp., 150";
cc.
Apparatus
The reactor was an adaptation [35] for gas-liquid
reactions
gauze 'micro-bubble' avoids
a high speed
The design
stirrer.
high spots and permits
of a type described
featuring
rapid mixing
features
by Miller,
et al
(3500 rpm) wire
of this apparatus
of the gaseous
and liquid
phases.
General
Fluorination
The substrate brought
Procedure
was mixed with
up to speed
(15 min.) and ClF5 flow started Cold traps reactor.
(-lS", -78O and -134O,
(15 min.),
to warm
in the individual
to 25".
(0') and the stirrer
(after nitrogen respectively)
At the end of the fluorination,
with nitrogen allowed
the solvent
The system was flushed with nitrogen
(3500 rpm).
flow had stabilized). were attached
the ice-bath
removed
and the reactor
The reaction
mixture
was processed
experiments.
to the
the system was again flushed contents
as described
442 Reaction
of Benzene with ClF5
(a) ClF5
Low ClF, Concentration J (0.0575 Mol, 7.50 g) was fed at a rate of 7.5 g/hr diluted
with nitrogen 65 standard
(C1F5 flow rate:
cc/min)
12.34 g) dissolved reactor.
in CC14
The reaction
100 ml of saturated
determined
TABLE
of benzene
(162 g) was successively
sodium bicarbonate
sulfate.
identical
ccfmin; N2 flow rate:
(0') solution
(0.964 Mol, 159.5 g) contained
mixture
aqueous
dried over magnesium productshad
21.5 standard
into a cooled
infrared
1:3
(0.1580 Mel, in a glass
treated with
(2 x), water
(3x) and
(The crude and treated reaction Product
spectra).
by GLC and mass spectroscopy
composition
was
(Table 3).
3
Low ClF5 Concentration:
Fluorination
of Benzene by C1F5
Starting Materials C1F5
0.0575
(moles)
Benzene cc14
(moles)
0.1580
(ml)
Molar Ratio Benzene
100 (Benzene/ClF5)
Consumed
2.7511
(moles)
0.0842
Moles
Corrected Yield
Fluorobenzene
0.0453
53.8%
R-Chlorofluorobenzene
0.0034
4.0%
-o-Chlorofluorobenzene
0.0022
2.6%
Chlorobenzene
0.0307
36.5%
C6H4F2,
Traces
--_
Products
Moles
C6H3F3 and C6H3C1F2
(Out)
0.0816
% Accountability (Based on benzene
96.9%
consumed)
443 IR spectroscopy no evidence Fractionation
showed significant
2:4 with nitrogen 60 standard
rate:
gave 1.23 g (0.0118 Mol) of SiF
(ClF5 flow rate:
cc/min)
4'
etching.
High ClF, Concentration -I (0.1795 Mol, 23.41 g) was fed at an average
C1F5 diluted
(combined wt, 6.58 g) showed
CF2C12 or CFC13; only CC14, C6H6 and SiF4 were present.
(-40°) of the trap contents
The glass reactor
(b)
of the cold trap contents
of CF3C1,
into a cooled
rate of 15.6 g/hr
45 standard
(0') solution
c∈
N2 flow
of benzene
(0.2338 Mol, 18.26 g) dissolved
in Ccl4
(1.50 Mol, 233.0 g) contained
The reaction
mixture
(231 g) was treated with potassium
a copper reactor. fluoride
(17 g) to remove HF.
assay identified compounds
the components
were also present
A combination
of mass spectral
listed in Table 4.
in trace quantities;
in
and GLC
At least 17 other
benzene
accountability
was only 32.4%.
TABLE
4
High C1F5 Concentration:
Starting C1F5
Fluorination
of Benzene
Materials 0.1795
(moles)
Benzene Ccl4
0.2338
(moles)
150
(ml)
Molar Ratio Benzene
by C1F5
1.30/l
(Benzene/C1F5)
Consumed
0.2338
(moles)
Moles
Products
___
Fluorobenzene
Corrected Yield
_--
-o- and/or pDifluorobenzene
0.0121
5.2%
pChlorofluorobenzene
0.0127
12.7%
g-Chlorofluorobenzene
0.0090
3.9%
Chlorobenzene
0.0298
5.4%
Dichlorobenzene
0.0121
5.2%
Moles
0.0757
(Out)
32.4%
% Accountability (Based on benzene
consumed)
444 IR spectroscopy showed
of the cold trap contents
the presence
contained
of 2,4,6_Trifluoropyrimidine
C1F5
(0.0519 Mol,
cc/min)
treated with
into a glass reactor
fluoropyrimidine
14.8%;
of Carbon
Chlorine
reactor. CC14.
a solution
(containing
dispersed
assayed
(0.0772 Mol,
1:3 with nitrogen
(c h aracteristic
Mol;
and
FLUORINERT@
(C1F5 flow rate:
of initial
19 standard
mixture
cc/min)
to 0' in a glass
(147 g) indicated
99.8 Mel %
(combined wt, 9.64 g)
(CF2C12>CFC13>CF3C1), along with trace amounts -1 bands at 732 and 786 cm ). IR and mass spectroscopy
product CF3C1,
Liquid
120 hr/25'
volatiles
8.7%.
identical
gave the following 0.00995
2,4,5,6-tetre-
10.07 g) was fed at a rate of
GLC assay of the -40°, -134O and -196O traps
of C1F5
2,4,6-tri-
Pentafluoride
(1.0195 Mol, 157 g) cooled
VPC assay of the reaction
Liquid
solids) was
by GLC:
yields:
With Chlorine
1:3
60
(O") of
20.16 g) and FLUORINERT@
33.9%; corrected
Tetrachloride
tetrachloride
were qualitatively
after
containing
5-chloro-2,4,6_trifluoropyrimidine,
pentafluoride
6.7 g/hr diluted into carbon
mixture
cc/ruin; N2 flow rate:
KF and the solution
conversion,
fluoropyrimidine,
Reaction
(0.150 Mol,
The reaction
anhydrous
KF.
6.77 g) was fed at a rate of 6.7 g/hr diluted
2,4,6_trifluoropyrimidine (538 g).
with anhydrous
With ClF5
(C1F5 flow rate: 19 standard
with nitrogen
FC-75
The trap contents
HF (5.10 g, 0.2549 Mol) based on treatment
Reaction
standard
(combined wt, 26.01 g)
of CC14, CC13F and CC12F2.
distribution:
CF2C12,
0.0587 Mol; CFC13,
0.00785 Mol. FC-75 was inert
in a KEL-F@
gave quantitative
reactor. recovery
to C1F5 Vacuum
of C1F5.
charge) was found by IR spectroscopy
(3.1/l molar
transfer
ratio)
(O") of the
The residual
liquid
to be identical
(98%
to FC-75.
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M. M. Boudakian, Encyclopedia New York,
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(1961) 112 for interpretation
F2 with organic aromatics:
F 2 solubility
an essentially
'heterogeneous
interface
the gaseous
solution."
makes
process'
reagent
system Chem.,
in Fluorine
fluorination
of
for recent studies with 'liquid phase' fluorination occurring
is bubbled
at the gas-liquid
through
the substrate
151
30
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31
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32
Generation
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"....low
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[23], from by-products
fluorination
path.
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HF and C1F3, represents
Hyman,
et,
+HF
ah
another
1331 have reported
the following
equilibrium: C1F3 33
T. Surles, L. A. Quaterman
34
M. M. Boudakian
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C1F2+
+
HF2
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G. Fuller
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J. Am. Chem.
435-446
435
Received: September30,1983;accepted: March24,1984
SUBSTITUTIVE AROMATIC FLUORINATION WITH CHLORINE PENTAFLUORIDE*
MAX M. BOUDAKIAN** AND GENE A. HYDE
Olin Chemicals, New Haven, Connecticut 06511 (U.S.A.)
SUMMARY
In contrast to limited substitutive fluorination of aromatics with halogen fluorides such as ClF, ClF3, BrF3 and IF5, fluorination is the predominant reaction path with ClF5. Under non-catalytic liquid phase conditions, benzene was converted to fluorobenzene (54% yield) and chlorobenzene (37% yield), respectively. For a heterocyclic substrate, i.e. 2,4,6-trifluoropyrimidine,substitutive fluorination predominated over chlorination. Three possible fluorinationmechanisms are discussed. A transition complex of ClF5 with benzene is favored. Enhanced exchange fluorination of Ccl& was effected with C1F5 (CF2C12>>CFC13>CF3C1)as compared with ClF3 (CFC13"CF$12).
INTRODUCTION
Growing applications for ring fluorinated aromatics [l] have created much interest in the development of new synthesis techniques. While early direct aromatic substitutionwith fluorine (F2) gave violent reactions involving ring scission, addition, coupling and polymerization,new fluorination techniques have been developed in recent years: molecular fluorine [2-51; xenon fluorides [6]; high valency metal fluorides such as silver difluoride [7,8] or cobaltic trifluoride [8]; organic hypofluorites
*
Based on an earlier presentation: 'Liquid Phase Aromatic Fluorination With Chlorine Pentafluoride,'162nd American Chemical Society Meeting, Washington, D.C.
September 1971. Paper No. 6 (Division of Fluorine
Chemistry) **
Rochester, New York 14611 (U.S.A.)
0022-1139/84/$3.00
OElsevier Sequoia/Printed in The Netherlands
436 such as CF30F 19,101 or CH3C02F [ll]; ionic hypofluorites such as CsS04F or RbS04F [12,13]; NFqBF41141; and, anodic fluorination by controlled potential electrolysis (151. With halogen fluorides such as ClF, ClF3, BrF3 and IF5, and aromatics, substitutive fluorination has been a minor reaction path (Table 1).
TABLE 1
Substitutive Aromatic Halogenation With Halogen Fluorides
Interhalogen
Substitution Product
Ref.
ccl4
C6H5C1
16
Solvent
Substrate
ClF
C6H6
C1F3
C6H6 'gHF5
BrF3
C6H6 'gHF5
ccl4
C6H5C1'C6H5F
17
HF
C6C1F5
18
CH3CN
C6H5BrF2
19
CFC12CF2C1;
C6BrF5
20
C6H51"C6H5F;
21
HF/S02C1F C6H6
IF5
C6H4FI 1,3,5-C3H3F3 'gHF5
Inert
22
Inert
22
Of the above halogen fluorides, C1F3 (or modifications) has been the most intensively studied reagent with aromatics. Ellis and Musgrave [17 a-c] established that substitutive chlorination predominated over fluorination when benzene was reacted with C1F3 (CC14 solvent) under catalytic (e.g. CoF2) or non-catalytic conditions in a steel reactor. (Side reactions such as ring addition, coupling and tar formation contributed to low yields). F
Cl
2.0
0 I
\
+ C1F3
,::,
L
6
>
4
(l)
/
(1)
(11)
431 A later modification discovery
of the ClF3-benzene
[23 a-c] that difluorochloronium
addition
of Lewis acids,
substitutive
fluorobenzene
ion, ClF2+
(generated
e.g. BF 3, to give ClF2+BF4-),
fluorination.
found that fluorinated
system was Pavlath's
In contrast,
aromatics,
Yakobson
by
enhanced
et al. [18,22] recently
e.g. 1,3,5_trifluorobenzene,
penta-
and 4-H-heptafluorotoluene,
do not undergo substitutive + aromatic fluorination with C1F2 + , BrF2+, BrF4+ and IF salts. 4 A major advance in recent halogen fluoride chemistry was the discovery of the new interhalogen, of alternate
synthesis
substitutive conditions
chlorine routes
halogenation
pentafluoride,
124-281.
patterns
and the rapid development
A study was undertaken
of ClF
5
with benzene
to assess
under 'liquid-phase'
[29].
RESULTS AND DISCUSSION
Substitutive
Fluorination
Substitutive non-catalytic
of Benzene With Chlorine
halogenation
Pentafluoride
studies with benzene
were conducted
under
in CC14 solvent at low and high C1F5
conditions
concentrations. At -low C1F5 concentrations nearly arising
from aromatic
over chlorination fluorobenzene
substitution
as evidenced
+
In contrast negligible
evidence
C1F5
showed no evidence
are reminiscent exchange substrate
between
Fluorination
(Table III).
3N2 17 cc14 O0
f
C1F3-benzene
examination
CC14),
predominated yields of
(I), respectively.
for side reactions
Infrared
N2:16.8
for as products
by 53.8% and 36.5% corrected
to the corresponding
polymerization.
C6H6:3.0
benzene was accounted
(II) and chlorobenzene
2.75
-134')
(1.0 C1F5:2.75
all (97%) of the consumed
arising
(II) >
system
1171, there was
from addition,
of the cold traps
of chlorofluoromethanes.
of Ellis and Musgrave's
findings
(2)
(I)
coupling
or
c-15', -78' and
(The latter observations 117 a,b] that halogen
Ccl4 and C1F3 did not occur if a more easily halogenated
such as benzene was present).
438 Attempts
failed
concentrations' benzene
to enhance
(1.0 ClF5:1.3
was consumed,
products
the maximum
products.
fluorination
CC14).
higher
to the absence
to further
competitive
fluorinate
fluorobenzene
was completely
consumed
catalyst/Ccl4
solvent),
were
Likewise,
the reaction
formed.
in complete
were found.
conversion
(Similar inability
liquid phase conditions
Grakauskas:
product
that
to non-volatile at low C1F5
Ccl4 exchange
polymer
formation
distribution
Substitutive
of p-difluorobenzene
fluorine
stoichiometry,
products
and C1F3
no substitution
to effect poly-substitutive
products
fluorination
(F2) were noted by
appreciable
was noted; at higher molar
was reversed
Fluorination
with C1F3 (CoF2 and addition
of the substrate;
with molecular
at low F2/benzene
to give polyfluoro-
117 bl found that, while
upon reaction
only R-chlorofluorobenzene
and minor
represented
of (II) suggests
by conversion
Ellis and Musgrave
is not surprising.
fluorobenzene
under
While all of the for as substitution
of chlorofluoromethanes
C1F5 levels effected
ClF5
to give CC13F and CC12F2).
The inability
resulted
at h&$
(5.2% yield)
The absence
of the latter was followed
(In contrast
concentrations,
N2:8.4
g- and/or P-Difluorobenzene
degree of fluorination.
generation
benzenes
C6H6:Z.O
fluorination
only 32.4% could be accounted
(Table IV).
in-situ --
substitutive
substitution
ratios,
this
[2]).
of 2,4,6-Trifluoropyrimidine
With Chlorine
Pentafluoride In contrast exhibit
slightly
sluggish
different
fluorination
pyrimidine
benzenes,
behavior
evidenced
toward halogen
(33.9% conversion)
(fluorination
path:
again predominating)
of the perfluorocyclic by quantitative
heterocyclics
fluorides.
For example,
was noted when 2,4,6-trifluoro-
2,4,5,6_tetrafluoropyrimidine
5-chloro-2,4,6_trifluoropyrimidine cleavage
fluorinated
was reacted with C1F5 in FLUORINERW
halogenation reaction
to fluorinated
Liquid
FC-75.
represented
Substitutive
a minor
(IV), 14.8% yield
(V), 8.7% yield
(corrected).
(corrected); (Ring
ether solvent by C1F5 is not possible
recovery
as
of FC-75 and C1F5 after 120 hours at 25').
F 7 ,I\ 'N
+
ClF5 c;;60
)
FaF
>
F&F
(3)
F
(III)
F
Cl
(IV)
QJ)
439
Mechanism
At least three potential fluorination paths could be considered.
(a) Fluorination via ClF, Dissociation -I Fluorination could arise from ClF5 dissociation products at O":
O0
ClF5
ClF3 +
/
F2
(4)
(5)
However, the negligible rate of ClF5 dissociation up to 200' (16 hours) reported by Bauer and Sheehan [30] does not support this mechanism.
(b) Self-Ionizationof C1F5 Self-ionizationof ClF5 to generate ClF4* as the active fluorinating species represents another reaction path: 2ClF5
ClF4+ +
+
ClF6-
(6)
This sequence does not appear likely. Meinert and Gross established the following order of decreasing self-ionizationwithin the halogen fluorides: BrF3>IF5>BrF5>C1F3>ClF51311. Moreover, the use of CC14 solvent, a medium of low dielectric constant employed in the substitutive fluorination of benzene, would not favor self-ionizationof ClF,.
(c) Transition Complex A transition complex with the aromatic ring was proposed by Musgrave for the non-catalyzed reaction of ClF3 and benzene 117 cl.
o+ oH .
U I
,
+
C1F3
-
0
_.F--C1F2 *
F
I
I' -
0
+HF+C:I
440 ClF would then erve as a chlorinating agent, in agreement with the likely ci5apolarization, Cl-F, to give chlorobenzene,as previously demonstrated by Gambaretto, et al. [16]. (A potential intermediate in Musgrave's transition complex mechanism could be C6H5C1F2. Nesmeyanov, et
[19] formed
phenylbromosodifluoride,C6H5BrF2, from benzene and BrF3/acetonitrile). A modified transition complex mechanism proceeding via an arenium cation could be envisaged for the correspondingnon-catalyzed ClF5-benzene system: + (I
a-
ClF3 generated from the above sequence would then participate by the Musgrave transition complex path with benzene depicted in equation (7) [17 c] 1321.
,Reaction of Chlorine Fluorides With Carbon Tetrachloride
ClF5 effected exchange fluorination of CC14 (absence of aromatic substrate) to give a mixture of chlorofluoromethanes: CF2C12>>CECL3 >CE3Cl (Table 2). The corresponding study by Ellis and Musgrave for C1F3 and CC14 gave chlorofluoromethanesof a lesser degree of fluorimation: CFC13>>CF2C12 117 b].
TABLE 2
Reaction of Chlorine Fluorides With CC14
Chlorine Fluoride
Ref.
ClF5
This Study
C1F3
117 b]
Molar Ratio CIFx CC14 N? 1.0
Temp.
Time (hr)
00
1.5
13.2
3.0
1.0
11.0
3.4
O"
6.8
1.0
10.7 4.1
25'
8.4
Molar Ratio CF,Cl CF2C12 CFC13_ 1.0
7.5
1.3
(--)
(--)
1.0
(--)
1.0
7.0
441
EXPERIMENTAL
Reagents
ClF5 Benzene,
(IR assay, > 99%) was prepared Baker & Adamson
Mallinckrodt prepared
(A.R. Grade).
FC-75, mainly
was obtained
15% Igepal CO880-Chromosorb
temp., 210°; detector
and
from 3M Co.
W (80/100 mesh);
75-250" at lO'/min.;
injection
temp., 210'; flow rate, 7 sec./l0
2,4,6_trifluoropyrimidine:
temp., 160'; flow rate, 6.3 sec./l0
column, port
cc.
15% SE30-Chromosorb
3 m., l/4 in.; column temp., 60"; injection
detector
[34].
perfluoro-(2-g-butyltetrahydrofuran)
2 m., l/4 in. i.d.; column temp.,
column,
(gc, 99.9%) was
Chromatography
ClF5 with benzene:
C1F5 with
tetrachloride,
and KF in sulfolane
perfluoro-(2-z-propyltetrahydropyran),
Gas Liquid
Carbon
2,4,6_Trifluoropyrimidine
from 2,4,6_trichloropyrimidine
FLUORINER'I@ Liquid
from KC1 and F2 [28 a,b].
(Reagent ACS Grade).
W (SO/l00 mesh);
port temp., 150";
cc.
Apparatus
The reactor was an adaptation [35] for gas-liquid
reactions
gauze 'micro-bubble' avoids
a high speed
The design
stirrer.
high spots and permits
of a type described
featuring
rapid mixing
features
by Miller,
et al
(3500 rpm) wire
of this apparatus
of the gaseous
and liquid
phases.
General
Fluorination
The substrate brought
Procedure
was mixed with
up to speed
(15 min.) and ClF5 flow started Cold traps reactor.
(-lS", -78O and -134O,
(15 min.),
to warm
in the individual
to 25".
(0') and the stirrer
(after nitrogen respectively)
At the end of the fluorination,
with nitrogen allowed
the solvent
The system was flushed with nitrogen
(3500 rpm).
flow had stabilized). were attached
the ice-bath
removed
and the reactor
The reaction
mixture
was processed
experiments.
to the
the system was again flushed contents
as described
442 Reaction
of Benzene with ClF5
(a) ClF5
Low ClF, Concentration J (0.0575 Mol, 7.50 g) was fed at a rate of 7.5 g/hr diluted
with nitrogen 65 standard
(C1F5 flow rate:
cc/min)
12.34 g) dissolved reactor.
in CC14
The reaction
100 ml of saturated
determined
TABLE
of benzene
(162 g) was successively
sodium bicarbonate
sulfate.
identical
ccfmin; N2 flow rate:
(0') solution
(0.964 Mol, 159.5 g) contained
mixture
aqueous
dried over magnesium productshad
21.5 standard
into a cooled
infrared
1:3
(0.1580 Mel, in a glass
treated with
(2 x), water
(3x) and
(The crude and treated reaction Product
spectra).
by GLC and mass spectroscopy
composition
was
(Table 3).
3
Low ClF5 Concentration:
Fluorination
of Benzene by C1F5
Starting Materials C1F5
0.0575
(moles)
Benzene cc14
(moles)
0.1580
(ml)
Molar Ratio Benzene
100 (Benzene/ClF5)
Consumed
2.7511
(moles)
0.0842
Moles
Corrected Yield
Fluorobenzene
0.0453
53.8%
R-Chlorofluorobenzene
0.0034
4.0%
-o-Chlorofluorobenzene
0.0022
2.6%
Chlorobenzene
0.0307
36.5%
C6H4F2,
Traces
--_
Products
Moles
C6H3F3 and C6H3C1F2
(Out)
0.0816
% Accountability (Based on benzene
96.9%
consumed)
443 IR spectroscopy no evidence Fractionation
showed significant
2:4 with nitrogen 60 standard
rate:
gave 1.23 g (0.0118 Mol) of SiF
(ClF5 flow rate:
cc/min)
4'
etching.
High ClF, Concentration -I (0.1795 Mol, 23.41 g) was fed at an average
C1F5 diluted
(combined wt, 6.58 g) showed
CF2C12 or CFC13; only CC14, C6H6 and SiF4 were present.
(-40°) of the trap contents
The glass reactor
(b)
of the cold trap contents
of CF3C1,
into a cooled
rate of 15.6 g/hr
45 standard
(0') solution
c∈
N2 flow
of benzene
(0.2338 Mol, 18.26 g) dissolved
in Ccl4
(1.50 Mol, 233.0 g) contained
The reaction
mixture
(231 g) was treated with potassium
a copper reactor. fluoride
(17 g) to remove HF.
assay identified compounds
the components
were also present
A combination
of mass spectral
listed in Table 4.
in trace quantities;
in
and GLC
At least 17 other
benzene
accountability
was only 32.4%.
TABLE
4
High C1F5 Concentration:
Starting C1F5
Fluorination
of Benzene
Materials 0.1795
(moles)
Benzene Ccl4
0.2338
(moles)
150
(ml)
Molar Ratio Benzene
by C1F5
1.30/l
(Benzene/C1F5)
Consumed
0.2338
(moles)
Moles
Products
___
Fluorobenzene
Corrected Yield
_--
-o- and/or pDifluorobenzene
0.0121
5.2%
pChlorofluorobenzene
0.0127
12.7%
g-Chlorofluorobenzene
0.0090
3.9%
Chlorobenzene
0.0298
5.4%
Dichlorobenzene
0.0121
5.2%
Moles
0.0757
(Out)
32.4%
% Accountability (Based on benzene
consumed)
444 IR spectroscopy showed
of the cold trap contents
the presence
contained
of 2,4,6_Trifluoropyrimidine
C1F5
(0.0519 Mol,
cc/min)
treated with
into a glass reactor
fluoropyrimidine
14.8%;
of Carbon
Chlorine
reactor. CC14.
a solution
(containing
dispersed
assayed
(0.0772 Mol,
1:3 with nitrogen
(c h aracteristic
Mol;
and
FLUORINERT@
(C1F5 flow rate:
of initial
19 standard
mixture
cc/min)
to 0' in a glass
(147 g) indicated
99.8 Mel %
(combined wt, 9.64 g)
(CF2C12>CFC13>CF3C1), along with trace amounts -1 bands at 732 and 786 cm ). IR and mass spectroscopy
product CF3C1,
Liquid
120 hr/25'
volatiles
8.7%.
identical
gave the following 0.00995
2,4,5,6-tetre-
10.07 g) was fed at a rate of
GLC assay of the -40°, -134O and -196O traps
of C1F5
2,4,6-tri-
Pentafluoride
(1.0195 Mol, 157 g) cooled
VPC assay of the reaction
Liquid
solids) was
by GLC:
yields:
With Chlorine
1:3
60
(O") of
20.16 g) and FLUORINERT@
33.9%; corrected
Tetrachloride
tetrachloride
were qualitatively
after
containing
5-chloro-2,4,6_trifluoropyrimidine,
pentafluoride
6.7 g/hr diluted into carbon
mixture
cc/ruin; N2 flow rate:
KF and the solution
conversion,
fluoropyrimidine,
Reaction
(0.150 Mol,
The reaction
anhydrous
KF.
6.77 g) was fed at a rate of 6.7 g/hr diluted
2,4,6_trifluoropyrimidine (538 g).
with anhydrous
With ClF5
(C1F5 flow rate: 19 standard
with nitrogen
FC-75
The trap contents
HF (5.10 g, 0.2549 Mol) based on treatment
Reaction
standard
(combined wt, 26.01 g)
of CC14, CC13F and CC12F2.
distribution:
CF2C12,
0.0587 Mol; CFC13,
0.00785 Mol. FC-75 was inert
in a KEL-F@
gave quantitative
reactor. recovery
to C1F5 Vacuum
of C1F5.
charge) was found by IR spectroscopy
(3.1/l molar
transfer
ratio)
(O") of the
The residual
liquid
to be identical
(98%
to FC-75.
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1
M. M. Boudakian, Encyclopedia New York,
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ual,
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The term, 'liquid-phase' may be a misnomer. 2
(1968). fluorination,
(See J. M. Tedder,
(1961) 112 for interpretation
F2 with organic aromatics:
F 2 solubility
an essentially
'heterogeneous
interface
the gaseous
solution."
makes
process'
reagent
system Chem.,
in Fluorine
fluorination
of
for recent studies with 'liquid phase' fluorination occurring
is bubbled
at the gas-liquid
through
the substrate
151
30
H. Bauer and D. F. Sheehan,
31
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32
Generation
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"....low
when
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Inorg. Chem., 5 (1967) 1736.
[23], from by-products
fluorination
path.
Chem., 2 (1972/73) 381. + , an aromatic fluorinating
ion, C1F2
HF and C1F3, represents
Hyman,
et,
+HF
ah
another
1331 have reported
the following
equilibrium: C1F3 33
T. Surles, L. A. Quaterman
34
M. M. Boudakian
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C1F2+
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HF2
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