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Catalysis by metal fluoride surfaces: the adsorption of [35s] sulphur tetrafluoride by caesium and thallium(i) fluorides and the reaction between c
Applied Cotalyeb, Elsevier Scientific
CATALYSIS
BY METAL FLUORIDE
BY CAESIUM
Department
of Chemistry,
aPermanent
address:
(Received
BY CAESIUM
BETWEEN
CHLORINE MONOFLUORIDE
FLUORIDE
WEBB and John M. WINFIELO
The University,
National
19 September
OF [35S] SULPHUR TETRAFLUORIDE
AND THE REACTION
CATALYSED
Geoffrey
- Printed in The Netherlands
THE ADSORPTION
FLUORIDES
TETRAFLUORIOE
George A. KOLTAa,
Amsterdam
SURFACES:
AND THALLIUM(I)
AND SULPHUR
257
2 (1982) 257-266 Publishing Company.
Research
Glasgow
Centre,
1981, accepted
612 8QQ, Scotland.
Dokki, Cairo,
11 December
Egypt.
1981)
ABSTRACT The reaction temperature
pentafluoride, involving
monofluoride
behaving
less marked. thallium(I) behaviour
tetrafluoride
with chlorine
of caesium
fluoride,
has been shown to be a true surface
[36Cl] chlorine
of chlorine compound
of sulphur
and in the presence
monofluoride by caesium
as a catalyst
fluoride
fluoride
is ascribed
to differences
at ambient
but retention
from experiments Retention
and results
of sulphur
tetrafluoride
between
in the
tetrafluoride
is
are both adsorbed
does not behave as a catalyst. in the bonding
chloride
tetrafluoride.
is significant
and sulphur
but the compound
and the metal fluoride
reaction
and [35S] sulphur
poison,
Chlorine monofluoride
monofluoride,
to give sulphur
sulphur
by
The different tetrafluoride
surface.
INTRODUCTION Ionic metal fluorides, used as catalysts and inorganic catalyse
fluorine
the addition
to give sulphur with chlorine
fluoroanion
postulate of Group
compounds
appeared
believed
monofluoride
that such reactions
proceed
order Cs >> Rb > K > Na 2 Li, which
organic
fluoride
tetrafluoride
will
at 293 K
of carbonyl
fluoride
at 253 K [3].
through
of the type SF5- and CF30-.
in exchange
are widely
involving
caesium
to sulphur
[2], and the reaction
to have been obtained
0166-9834/82/000O-O000/$02.75
and potassium,
reactions
to form chlorooxytrifluoromethane
intermediates
I metal fluorides
addition
[l]. Thus, for example,
pentafluoride
monofluoride
those of caesium
or oxidative
of chlorine
chloride
It is generally surface
particularly
in addition
the formation
Evidence
of
for this
from the observation that the activities 18 [4] or F2C0 [53 were in the
with S18F4
is also the order of catalytic
0 Elaevier Scientific
Publishing Company
activity
observed
258 in synthetic work. However, subsequent investigations of the exchange of S18F4 and 18 F2C0 with a variety of mono-, di- and trivalent fluorides [6] showed that the situation
was more complex.
fluorides
between exchange
SF4, this is not general structural
a correlation
and no correlation
adsorption.
ability
correlated
caesium
pretreatment
fluoride,
The studies described
for the retention
provide an interesting
in an attempt
surfaces
of caesium
were chosen since earlier
and informative
their structures
proven catalyst,
surface,
[7] that
contrast
are significantly
TlF is not catalytically
to clarify
further
of sulphur
tetrafluoride
and retention fluoride
studies
different
of 36C1F, 35SF4
and thallium
(I)
[63 had shown that they
in behaviour.
exchange with S18F and both appear to retain small amounts However,
by 85Kr
effect on its surface structure.
the chemisorption
pretreated
These fluorides
and either
Not unexpectedly,
of S18F4 by the fluoride
using the chlorofluorination
by studying
and SF536 Cl on variously
activity
was established.
below were undertaken
of the catalysis,
as the model reaction,
exchange
of ClF with
and this may be related to the observation
of CsF has a significant
the mechanism
of the reaction
with the B.E.T. surface area as measured
Evidence was obtained
particularly
exists for the alkali metal
between
type or any single cation property
the exchange
fluoride.
Although
with S18F4 and catalysis
'8F_
Both undergo
of SF4 following
[8] and, whereas
exchange.
CsF is a
active.
EXPERIMENTAL Experiments
in which non-radioactive
fluoride were used were performed with chlorine were stored
trifluoride
in stainless
in Monel metal vessels by pressure
(Matheson
Inc.)
fall using a Bourdon gauge
system being calibrated
monofluoride
tetra-
vessels
and gaseous
fluorides
samples
were stored
over predried NaF. Reactions were monitored (Heise
, *1 tort-), each section of the vacuum
before use to allow reaction
from pressure measurements.
and sulphur
Inc.) before use. The metal fluoride
steel pressure
(both Hoke
chlorine
in a Monel metal vacuum system which was passivate'd
stoichiometries
Gas uptake by the metal fluorides
to be determined
was also determined
from pressure measurements. Where appropriate, pentafluoride
by low temperature, measurements
reaction mixtures
were analysed
containing
by separating
trap-to-trap
ClF, SF4 and sulphur
them into their individual
distillation,
ClF being identified
[9], and SF4 and SFSCl by their infrared
weight determination Experiments
after transfer
involving
radioactivity fluoride
with two intercalibrated
to be determined
samples were placed
by vapour pressure
ClO,ll] and molecular
to a Pyrex vacuum system.
the use of redioactively
labelled
and SF536 Cl, were carried out in a Pyrex glass vacuum vessel equipped
spectra
chloride
components
directly,
Geiger-Muller as described
in the vessel
species,
36C1F, 35SF4
system incorporating detectors elsewhere
a reaction
to allow the surface [12]. The metal
in vacua via a side arm and were contained
in a Pyrex glass boat which could be positioned
under the Geiger-Muller
detectors.
259 A linear relationship the labelled determined
substrates;
was found between reaction
from these calibrations.
carefully
dried, no problems
Provided
with hydrolysis
gas uptake by the solid determined
were handled
that reagents
in an argon atmosphere
[‘I] by (a) heating
were encountered
the different
after grinding,
after each period, or (b) reaction
acetonitrile,
followed
Chlorine
decomposition
employed.
fluoride
(Alfa, 99 %)
Co., H20 < 10 ppm)
or were pretreated
as previously
periods of 24 h at 423 K
with hexafluoroacetone of any adduct formed,
(B.D.H. Ltd., 99.9 %) was dried by treatment
potassium
from H36C1
in dry or (c) heating
with P205 before use.
(100 uCi, The Radiochemical
permanganate.
It was purified
KMn04 and P205. ClF was prepared
Centre, Amersham)
and dried by treatment
and
with solid
Cl2 and ClF3 [13], typical reaction 36 being 423 - 543 K for 48 h, initial pressure 400 - 600 torr. ClF was
conditions prepared
were
for 3 h at 573 K or, for CsF at 773 K.
36C12 was prepared aqueous
techniques
Engineering
in vacua for two successive
by thermal
were
and the results for
measuring
glove box (Lintott
with grinding
in dry nitrogen
for each of
and the equipment
(B.D.H. Ltd., Optran Grade) and thallium(I)
They were either used as supplied, described
and radioactivity
in gas uptake experiments
in the Pyrex glass system and the metal vacuum
despite
system were in good agreement, Caesium fluoride
pressure
stoichiometries
in a similar manner
use. It contained this was removed 35
from equimolar
[14]. SF4 (PCR Inc.) was treated with dry NaF before
a small quantity via the formation 35S
SF::pC;":,Er~~:~~~e~r~~om
of SOF2 as an impurity and in some experiments and decomposition
of the SF4.BF3 adduct
and iodine pentafluoride
as described
[15].
elsewhere
[16].
31C12, SF4 and CsF [173.
RESULTS Interaction Admission samples
of ClF, SF,, and SF&Cl with metal fluorides of 500 torr (6.40 mmol) of chlorine
of caesium
fluoride,
rapid initial uptake,
followed
by a relatively
The total uptake of ClF, after a contact in Table
monofluoride
which had been variously
to 2 g (13.17 mmol)
pretreated,
slow process,
36ClF tracer experiments
fluoride
or by heating
samples which
had been pretreated
in vacua at 423 K for 48 h, showed that
at room temperature,
even on evacuating
Over the range 40 - 300 torr the total uptake of ClF, measured
after
for 2 h.
1.5 h, varied
with the initial ClF pressure.
The behaviour
of ClF towards
with caesium
to a smaller
fluoride,
samples except
of thallium(I)
fluoride
that, as shown in Table
extent and the effect of sample pretreatment
The interaction similar
1.
time of 1.5 h, by each sample was as shown
using caesium
the uptake of ClF was irreversible
observed
in a
1.
either with hexafluoroacetone
linearly
resulted
as shown in Figure
behaviour
of SF4 with caesium to that observed
fluoride
to that
1, the uptake occurs
is much less marked.
and thallium(I)
with ClF, although
was similar
fluoride
the quantities
showed
of SF4 involved
260
Time bin)
FIGURE
1
Uptake of ClF by CsF pretreated
as follows:
48 h; 3) (CF3)2C0 t MeCN; 4) N2, 573 K, 3 h;
TABLE
1) none; 2) vacua, 423 K,
5) N2, 773 K, 3 h.
1
Uptake of ClF or SF4 by CsF or TIFa Pretreatment
ClF uptake after
SF4 uptake after
SF4 uptake after ClF
1.5 h/mm01
1.5 h/mmol
pretreatment/mm01
CsF
TlF
1. None
2.7
1.3
2. Vacua, 432 K,
2.9
1.3
0.1
0.1
2.4
0.1
3.0
1.4
0.2
0.2
2.9
0.2
4. N2, 573 K, 3 h
0.8
1.2
0.2
0.2
2.9
0.1
5. N2, 773 K, 3 h
0.3
CsF
TlF
TlF
CsF 0.8
48 h 3. (CF3)2C0 + MeCN
ausing
0.1
0.4
ClF = SF4 = 500 torr = 6.40 mmol; MF = 2.0 g = 13.17 mm01
(CsF), 8.95 mmol
01~).
were considerably
smaller
than the corresponding
amounts
of ClF (see Table
1 and
Figure 2). Using [35S] labelled
SF4 very small uptakes,
were found using untreated on the untreated
thallium
both caesium fluoride
caesium fluoride.
and thallium
fluoride
In contrast fluoride,
not detectable
samples;
by pressure measurement, was detected
no uptake of SF
to the behaviour
of
46
ClF towards
most of the 35SF4 adsorbed
on either
261
OO I
30 I
60 8
I
90 , 1
I
Time (mid
FIGURE 2
Uptake of SF4 by CsF pretreated
&sorption 9
75
60 l= 2= 3* 4=
Admission
0
pretreated
caesium
fluoride
was removed
for caesium
fluoride
pretreated
of a further
the first adsorption
15
Time 6nin)
23*1 % of the initial uptake of 35 SF sample of
- desorption
being retained 45
with
(CF3)2C0 + MeCN
by evacuation with
resulted
fluoride
at room temperature + MeCN in Figure 3,
fluoride. sample,
in a saturation
in the first cycle
of this second sample gave a surface
(CF3)2C0
by caesium
SF4 to a caesium
cycle,
rate which was less than that obtained evacuation
30
1st. Adsorption 1st. Lksorption 2nd.Pdwption 2nd.t&znptii
5.8 mmol 35SF4 was used in each case.
or untreated
This is illustrated
1.
bin)
Uptake of 35 SF4 by CsF (13.17 mmol),
and its desorption.
pretreated
Time 45
Wsorption
FIGURE 3
as Figure
following
surface count
(see Figure 3). Subsequent
count rate identical
to that obtained
following
the first evacuation.
(I) fluoride Admission resulted
No evidence
of SF536 Cl to a pretreated
caesium
in a small uptake of radioactivity
completely
Reaction
removed by evacuation
warm to ambient
fluoride
temperature
[Z], has generally
However,
presented
ClF and the caesium fluoride being an intermediate
were allowed
and, in consequence,
caesium
fluoride
fluoride
and thallium
and thallium
with caesium fluoride
fluoride
ClF by SF4 occurred
fluoride,
pretreated
as shown in Table 1,
temperature
for 1.5 h. After
treated
fluoride
The adsorption
in the SF4 - CsF system.
fluoride
with ClF
with thallium
by SF4 could be carried out several
fluoride
for
which had been pretreated
with
is greater
for the (CF3)2C0 pretreated
of SF4 is characterised process,
behaviour
by an initial,
very similar
rapid uptake
to that observed
In the case of ClF, there is a rapid initial adsorption,
by a more complex
process
adsorption
by the caesium
constant.
pretreated
of SF4 corresponded
in vacua at 423 K for 48 h.
by a slower adsorption
and SF4 retained
by
of adsorbed
Table 2 shows the results obtained
the amount of gas adsorbed
as further
fluoride
of the thallium(I)
with ClF followed
using samples of caesium
(CF3)2C0 + MeCN or by heating
fluoride.
enhanced
uptake of SF4. No SF5C1 was observed
times using the same sample of catalyst.
As expected,
(I) fluoride.
no displacement
of SF4 to caesium
of
in this manner.
of caesium
six such reactions
a small quantity
but not with thallium
Pretreatment
had no effect upon the subsequent (I) fluoride
to the pretreated
in [36C1] surface count rate on admission
to the amount of SF5 36C1 formed.
effectively
ClF
the
which had been
the extent of uptake of SF4 was considerably
as shown by admission
with 36 ClF; the decrease
decreasing
between
of adsorbed
by examining
fluoride
of ClF, as shown in Table 1. However,
the preadsorption
followed
to
to occur by formation
the possibility
of SF5Cl was explored
to react with 6.40 mmol ClF at ambient
With caesium
followed
by condensing
the mixture
of this species with ClF.
of the gas phase ClF, 6.40 mmol of SF4 were admitted
SF5Cl was obtained
caesium
been proposed
reaction
performed
and allowing
After 1.5 h the gas phase was removed and analysed;
Reaction
this was
with ClF.
Samples of caesium
evacuation
temperature
above show that there is a strong interaction
in the formation
of SF4 towards
pretreated
However,
of CsF, typically
at low temperature
species and subsequent
the results
sample at ambient
of metal fluorides
of a Cs+SF5- surface
behaviour
of SF4 by the thallium
temperature.
of SF4 in the presence
SF4 and ClF on to caesium
fluoride
by the surface.
at ambient
of SF,, with ClF in the presence
Chlorofluorination
surface.
for any retention
samples was obtained.
in which the pressure
occurs. fluoride,
slightly
before
and the yield of SF5C1 at each step, are
After six cycles the compositions
to the mole ratios CsF:C1F:SF4,
increased
As shown in Table 2, the amounts of ClF
11.85:9.3:7.45
of the solids correspond
and 11.85:3.75:3.1
for hexafluoro-
263 TABLE 2 Repeated
addition
of ClF (359 torr : 4.6 mmol) then SF4 (359 torr f 4.6 mm011 to
CsF (11.85 mmol) at room temperature Step
CsF pretreatment
Gas
time
gas
yield
time
gas
yield
/h
retained
SF5Cl
/h
retained
SF5C1
2
3
4
5
6
acetone
ClF
1.5
1.9
1.5
0.8
1.5
1.4
0.15
2.0
0.7
ClF
2.0
1.8
0.05
2.0
0.65
0.05
SF4
1.5
1.15
0.1
2.0
0.8
0.2
ClF
2.0
1.8
0.05
2.0
0.8
0.1
SF4
1.5
1.0
0.1
2.0
0.8
0.2
ClF
2.0
1.7
0.35
2.0
1.0
0.1
sF4
18.0
3.4
0.25
18.0
1.1
0.15
ClF
2.0
1.8
0.15
2.0
1.0
0.4
SF4
2.0
1.15
0.1
2.0
0.7
0.1
ClF
2.0
1.95
0.2
2.0
1.1
0.2
SF4
2.0
1.0
0.15
2.0
0.6
0.1
pretreated
and vacuum
heated samples
these solids at room temperature,
333 K. Progressively
heating
in the production
Addition results
/mm01
SF4
by pumping
resulted
/mm01
/llmlol
/mm01 1
423 K, vacua, 48 h
(CF312C0 + MeCN
added
of a mixture
in different
with
were followed
by change
the SF5C1 separated of experiments
of SF4 and ClF to caesium from that described fluoride
+ MeCN, at ambient in pressure.
from unchanged
in which
but was evolved
slowly by pumping
at
of 1.65 and 0.9 mmol SF5Cl respectively.
behaviour
(CF3)2C0
SF5C1 was not evolved
the solids from 333 K to 393 K over a 12 h period
SF4 and ClF were added to caesium pretreated
respectively.
After
samples.
fluoride
at ambient
above. Appropriate
temperature mixtures
of
13.17 mmol in each case,
temperature
and the subsequent
1.5 h volatile
material
reactions
was removed,
ClF and SF4 and its yield determined.
The results
the ClF varies from 0.64 to 3.20 mmol while SF4 is constant
at 3.20 mm01 are shown in Figure 4. For a 1:l mole ratio the yield of SF5C1 is 77 % and very little ClF + SF4 is retained at lower mole ratios. approximately
retention
With ClF at 0.64 mmol the fraction
becomes
significant
of gas retained
15 % of the total initial gas. The yield of SF5C1 increases
when ClF > 3.20 am101 and the fraction is markedly
by CsF, however
of SF4 + ClF retained
by caesium
is slightly
fluoride
increased.
Similar effects
on the yield of SF5C1 and the fraction
of ClF + SF4 retained
264
FIGURE 4
Changes
pretreated
in % composition
for SF4 + ClF -f SF5Cl over CsF (13.17 mmol),
(CF3)2C0 + MeCN. SF4 = 3.20 mmol,
with
(ClF + SF4)(g) and (ClF + SF4)(retained)
by caesium
fluoride
ClF is constant
are observed
when SF4 is varied
at 3.20 mmol. However,
SF4 concentration
is significantly
fluoride
the fraction
The surface concentrations
at low
of SF4 and ClF in a I:1 mole ratio is added
at room temperature.
less than that in the absence
from 0.64 to 3.20 mmol while of ClF + SF4 retained
higher than at low ClF concentration.
No SF5Cl is formed when a mixture to thallium(I)
SF5Cl % of initial ClF,
% of total initial gas.
The quantity
of gas retained
is a little
of SF4. of ClF and SF4 under reaction
conditions
were examined
reaction of 36C1F + SF 4 or 36 ClF + SF4 over caesium ClF + 35SF4 mixtures. Some typical results obtained with 36 ClF in the absence of SF4 is fluoride are shown in Figure 5: the behaviour of by monitoring
the activity
of the surface during
included for comparison. The [36Cl] surface activity followed
accurately.
Evacuation
behaviour
is complete
was observed
at a rate too rapid to be
reaching
surface activities
occurred
according
the second order rate constants [35SF4], after correction
complete,
Table 3 shows that
for the removal of adsorbed
for permanently
retained
except
the surface count
in both the [36Cl] and [35S]
to a second order process.
derived
value after ~1.24 h
had no effect upon the final
The decrease
zero; see Figure.6.
a constant
with 35SF 4 + ClF reaction mixtures
1.25 h, when the reaction was effectively
rate was effectively
agreement.
increased
it decreased,
of the system after reaction
count rate. Similar that, after
initially
Thereafter
radioactivity
[36ClF] and
are in good
Variation
FIGURE 5
36
of
Cl surface
activity
with time (i) for 36C1F
with
+ SF4 (161 torr) over CsF pretreated
in vacua at 423 K, (iii) 36C1F (198 t.Orr)
Variation
FIGURE 6 35SF4
with
+ MeCN,
(161 torr)
t SF4 (168 torr) over CsF pretreated
over CsF pretreated
(CF3)2C0
(168 ton-1
(ii) for 36C1F
(CF3)2C0 + MeCN.
of the 35 S surface activity
(187 torr) over CsF pretreated
with
with time for ClF (185 torr) t
(CF3)2C0
+ MeCN.
DISCUSSION The results caesium reaction
presented
fluoride between
above show that the genarally
catalysed
chlorofluorination
Cs'SF5- and gaseous
accepted
of sulphur
chlorine
mechanism
tetrafluoride,
for the
involving
monofluoride;
SF4(g) t CsF(s) c' Cs+SF5-(s) Cs+SF5-
+ ClF(g) + SF5Cl(g)
is incorrect chlorine
+ CsF(s)
in that such a mechanism
monofluoride
The results pentafluoride
and the caesium
presented
in Table 3 indicate
is a true surface
and adsorbed
sulphur
monofluoride
to sulphur
photochemically
reaction
tetrafluoride
induced reactions
the reaction
between
surface.
that the formation
involving
An excited
tetrafluoride.
adsorbed
molecular
has been reported
of sulphur
chlorine
addition
chloride
monofluoride
of chlorine
for the thermal
and
[18].
Our results may best be interpreted reactions:
does not take into account fluoride
by considering
the following
equilibrium
TABLE 3 Second order rate constants
for the reactions
ClF + 35SF4 + 35SF,C1 Initial pressure of 36C1F
Second order rate
36C1F + SF4 -f SF536C1 and
261 CsF(s)
+ SF4(g) -f Cs+SF5-(s)
rather than via equilibrium Admission fluoride
of sulphur
(2).
tetrafluoride
to chlorine
led only to very small yields
to those obtained
when the reactants
were admitted
However,
there was a marked
fluoride
when the caesium
leading,
in the case of the hexafluoroacetone
composition reactions
increase
fluoride
monofluoride
of sulphur chloride
pretreated
pentafluoride,
simultaneously
in the extent of retention
surface was pretreated
(CSF),_,~(C~F),.,,(SF~),.
pretreated
Together
caesium relative
to the catalyst. of sulphur
with chlorine catalyst,
these observations
tetra-
monofluoride
to a solid with indicate
that
of the type
Cs+ClF2-(s)
+ CsF.SF4(ads,) + SF5Cl(g)
+ 2CsF(s)
and
(cStclF2--sF4)
where
+
sF5ci(g)
+ cSF(S)
(Cs 'C1F2- -SF4) represents
monofluoride suggest
pretreated
the uptake of sulphur
catalyst,
that the (CstC1F2- -SF4) entity exists
and which only decomposes elevated
their reaction
monofluoride,
with thallium(I) monofluoride
to sulphur
presumably
observations
retention
fluoride
chloride
as TltC1F2-,
of sulphur tetrafluoride between
difference
in the bonding
caesium
in the reactive
fluoride between
at
adsorbed
fluorine
atom. Reaction formulated
coordination
between
this species
as Cs+F-...ClF
of the sulphur of sulphur
may be an important
formulated
surface
to equation
in contrast
temperature.
fluoride
tetrafluoride
geometry
[213, therefore
adsorbed
or Cs+F- . ..FCl [20], is readily
to the thallium(I)
interaction.
(5) has no obvious
to a
and the metal
studies of Cs+SF5'
as having a (Cs')F-...SF4 and reactive,
previously
the reactive bridging
chlorine monoenvisaged
via
[63 that
cation via its lone pair
In this situation a surface reaction mechanism.
to
[6], no The
we ascribe substrate
spectroscopic
lone pair. We have suggested
tetrafluoride
although
of chlorine
sulphur tetrafluoride
state. Vibrational
that the anion has square pyramidal
this solid it would not
Retention
at ambient
and thallium(I)
the sulphur
state may be reasonably
participation
pentafluoride.
was observed
indicate
analogous
on the catalyst,
tetrafluoride,
was also observed,
adsorbed
fluoride,
We further
pentafluoride
show that whereas
and sulphur
at 423 K using ['*F]-labelled
difference
fluoride
chloride
by the chlorine extent.
temperature.
The results obtained
previous
as a stable species
slowly to CsF and sulphur
would adsorb both chlorine catalyse
tetrafluoride
cannot occur to any appreciable
C.J. Schick, R.D. Wilson and'M.G. Warner,.J. Chem..Sec., Chem. Comm., (1969) 1110, D.E. Gould, L.R. Anderson , D.E. Young and W.B. Fox, J. Am. Chem. Sot., 91 (1969) 1310; C.J. Schack and W. Maya, ibid, 91 (1969) 2902. C.J.W. Fraser, D.W.A. Sharp, G. Webb and J.M. Winfield, J. Chem. Sot., Dalton Trans., (1972) 2226. C.J.W. Fraser, D.W.A. Sharp, G. Webb and J.M. Winfield, J. Chem. Sot., Dalton Trans., (1974) 112. C.J.W. Fraser, D.W.A. Sharp, R.A. Sule, G. Webb and J.M. Winfield, J. Chem. Res., S (1978) 2. G.A. Kolta, G. Webb and J.M. Winfield, J. Fluorine Chem., 14 (1979) 331. N.W. Akcock and H.D.B. Jenkins, J. Chem. Sot., Dalton Trans., (1974) 1907. H. Schmitz and H.J. Schumacher, Z. Naturforsch., A 2 (1947) 359. R.L. Redington and C.V. Berney, J. Chem. Phys., 43 (1965) 2020. J.E. Griffiths. Soectrochim. Acta.. Part A. 23 (1967) 2145. A.S. Al-Ammar and'G. Webb, J. Chem: Sot., Faraday Trans. 1, 74 (1978) 195. C.J. Schack and R.D. Wilson, Synth. React. Inorg. Met.-Org. Chem., 3 (1973) 393. M.T. Rogers, J.C. Sternberg and J.P. Phelps, J. Inorg. Nucl. Chem., Supplement (1976) 149. N. Bartlett and P.L. Robinson, J. Chem. Sot., (1961) 3417. G.A. Kolta, G. Webb and J.M. Winfield, J. Fluorine Chem., in press. C.W. Tullock, D.D. Coffman and E.L. Mutterties, J. Am. Chem. Sot., 86 (1964) 357. C. Naulin and R. Bougon, J. Chem. Phys., 72 (1980) 2155. K.O. Christie and J.P. Guertin, Inorg. Chem., 4 (1965) 1785; K.O. Christie, W. Sawodny and J.P. Guertin, ibid, 6 (1967) 1159. B.S. Ault and L. Andrews, Inorg. Chem., 16 (1977) 2024. L.F. Drullinger and J.E. Griffiths, Spectrochim. Acta., Part A, 27 (1971) 1793; K.O. Christie, E.L. Curtis, C.J. Schack and D. Pilipovich, Inorg. Chem., 11 (1972) 1679.
CATALYSIS
BY METAL FLUORIDE
BY CAESIUM
Department
of Chemistry,
aPermanent
address:
(Received
BY CAESIUM
BETWEEN
CHLORINE MONOFLUORIDE
FLUORIDE
WEBB and John M. WINFIELO
The University,
National
19 September
OF [35S] SULPHUR TETRAFLUORIDE
AND THE REACTION
CATALYSED
Geoffrey
- Printed in The Netherlands
THE ADSORPTION
FLUORIDES
TETRAFLUORIOE
George A. KOLTAa,
Amsterdam
SURFACES:
AND THALLIUM(I)
AND SULPHUR
257
2 (1982) 257-266 Publishing Company.
Research
Glasgow
Centre,
1981, accepted
612 8QQ, Scotland.
Dokki, Cairo,
11 December
Egypt.
1981)
ABSTRACT The reaction temperature
pentafluoride, involving
monofluoride
behaving
less marked. thallium(I) behaviour
tetrafluoride
with chlorine
of caesium
fluoride,
has been shown to be a true surface
[36Cl] chlorine
of chlorine compound
of sulphur
and in the presence
monofluoride by caesium
as a catalyst
fluoride
fluoride
is ascribed
to differences
at ambient
but retention
from experiments Retention
and results
of sulphur
tetrafluoride
between
in the
tetrafluoride
is
are both adsorbed
does not behave as a catalyst. in the bonding
chloride
tetrafluoride.
is significant
and sulphur
but the compound
and the metal fluoride
reaction
and [35S] sulphur
poison,
Chlorine monofluoride
monofluoride,
to give sulphur
sulphur
by
The different tetrafluoride
surface.
INTRODUCTION Ionic metal fluorides, used as catalysts and inorganic catalyse
fluorine
the addition
to give sulphur with chlorine
fluoroanion
postulate of Group
compounds
appeared
believed
monofluoride
that such reactions
proceed
order Cs >> Rb > K > Na 2 Li, which
organic
fluoride
tetrafluoride
will
at 293 K
of carbonyl
fluoride
at 253 K [3].
through
of the type SF5- and CF30-.
in exchange
are widely
involving
caesium
to sulphur
[2], and the reaction
to have been obtained
0166-9834/82/000O-O000/$02.75
and potassium,
reactions
to form chlorooxytrifluoromethane
intermediates
I metal fluorides
addition
[l]. Thus, for example,
pentafluoride
monofluoride
those of caesium
or oxidative
of chlorine
chloride
It is generally surface
particularly
in addition
the formation
Evidence
of
for this
from the observation that the activities 18 [4] or F2C0 [53 were in the
with S18F4
is also the order of catalytic
0 Elaevier Scientific
Publishing Company
activity
observed
258 in synthetic work. However, subsequent investigations of the exchange of S18F4 and 18 F2C0 with a variety of mono-, di- and trivalent fluorides [6] showed that the situation
was more complex.
fluorides
between exchange
SF4, this is not general structural
a correlation
and no correlation
adsorption.
ability
correlated
caesium
pretreatment
fluoride,
The studies described
for the retention
provide an interesting
in an attempt
surfaces
of caesium
were chosen since earlier
and informative
their structures
proven catalyst,
surface,
[7] that
contrast
are significantly
TlF is not catalytically
to clarify
further
of sulphur
tetrafluoride
and retention fluoride
studies
different
of 36C1F, 35SF4
and thallium
(I)
[63 had shown that they
in behaviour.
exchange with S18F and both appear to retain small amounts However,
by 85Kr
effect on its surface structure.
the chemisorption
pretreated
These fluorides
and either
Not unexpectedly,
of S18F4 by the fluoride
using the chlorofluorination
by studying
and SF536 Cl on variously
activity
was established.
below were undertaken
of the catalysis,
as the model reaction,
exchange
of ClF with
and this may be related to the observation
of CsF has a significant
the mechanism
of the reaction
with the B.E.T. surface area as measured
Evidence was obtained
particularly
exists for the alkali metal
between
type or any single cation property
the exchange
fluoride.
Although
with S18F4 and catalysis
'8F_
Both undergo
of SF4 following
[8] and, whereas
exchange.
CsF is a
active.
EXPERIMENTAL Experiments
in which non-radioactive
fluoride were used were performed with chlorine were stored
trifluoride
in stainless
in Monel metal vessels by pressure
(Matheson
Inc.)
fall using a Bourdon gauge
system being calibrated
monofluoride
tetra-
vessels
and gaseous
fluorides
samples
were stored
over predried NaF. Reactions were monitored (Heise
, *1 tort-), each section of the vacuum
before use to allow reaction
from pressure measurements.
and sulphur
Inc.) before use. The metal fluoride
steel pressure
(both Hoke
chlorine
in a Monel metal vacuum system which was passivate'd
stoichiometries
Gas uptake by the metal fluorides
to be determined
was also determined
from pressure measurements. Where appropriate, pentafluoride
by low temperature, measurements
reaction mixtures
were analysed
containing
by separating
trap-to-trap
ClF, SF4 and sulphur
them into their individual
distillation,
ClF being identified
[9], and SF4 and SFSCl by their infrared
weight determination Experiments
after transfer
involving
radioactivity fluoride
with two intercalibrated
to be determined
samples were placed
by vapour pressure
ClO,ll] and molecular
to a Pyrex vacuum system.
the use of redioactively
labelled
and SF536 Cl, were carried out in a Pyrex glass vacuum vessel equipped
spectra
chloride
components
directly,
Geiger-Muller as described
in the vessel
species,
36C1F, 35SF4
system incorporating detectors elsewhere
a reaction
to allow the surface [12]. The metal
in vacua via a side arm and were contained
in a Pyrex glass boat which could be positioned
under the Geiger-Muller
detectors.
259 A linear relationship the labelled determined
substrates;
was found between reaction
from these calibrations.
carefully
dried, no problems
Provided
with hydrolysis
gas uptake by the solid determined
were handled
that reagents
in an argon atmosphere
[‘I] by (a) heating
were encountered
the different
after grinding,
after each period, or (b) reaction
acetonitrile,
followed
Chlorine
decomposition
employed.
fluoride
(Alfa, 99 %)
Co., H20 < 10 ppm)
or were pretreated
as previously
periods of 24 h at 423 K
with hexafluoroacetone of any adduct formed,
(B.D.H. Ltd., 99.9 %) was dried by treatment
potassium
from H36C1
in dry or (c) heating
with P205 before use.
(100 uCi, The Radiochemical
permanganate.
It was purified
KMn04 and P205. ClF was prepared
Centre, Amersham)
and dried by treatment
and
with solid
Cl2 and ClF3 [13], typical reaction 36 being 423 - 543 K for 48 h, initial pressure 400 - 600 torr. ClF was
conditions prepared
were
for 3 h at 573 K or, for CsF at 773 K.
36C12 was prepared aqueous
techniques
Engineering
in vacua for two successive
by thermal
were
and the results for
measuring
glove box (Lintott
with grinding
in dry nitrogen
for each of
and the equipment
(B.D.H. Ltd., Optran Grade) and thallium(I)
They were either used as supplied, described
and radioactivity
in gas uptake experiments
in the Pyrex glass system and the metal vacuum
despite
system were in good agreement, Caesium fluoride
pressure
stoichiometries
in a similar manner
use. It contained this was removed 35
from equimolar
[14]. SF4 (PCR Inc.) was treated with dry NaF before
a small quantity via the formation 35S
SF::pC;":,Er~~:~~~e~r~~om
of SOF2 as an impurity and in some experiments and decomposition
of the SF4.BF3 adduct
and iodine pentafluoride
as described
[15].
elsewhere
[16].
31C12, SF4 and CsF [173.
RESULTS Interaction Admission samples
of ClF, SF,, and SF&Cl with metal fluorides of 500 torr (6.40 mmol) of chlorine
of caesium
fluoride,
rapid initial uptake,
followed
by a relatively
The total uptake of ClF, after a contact in Table
monofluoride
which had been variously
to 2 g (13.17 mmol)
pretreated,
slow process,
36ClF tracer experiments
fluoride
or by heating
samples which
had been pretreated
in vacua at 423 K for 48 h, showed that
at room temperature,
even on evacuating
Over the range 40 - 300 torr the total uptake of ClF, measured
after
for 2 h.
1.5 h, varied
with the initial ClF pressure.
The behaviour
of ClF towards
with caesium
to a smaller
fluoride,
samples except
of thallium(I)
fluoride
that, as shown in Table
extent and the effect of sample pretreatment
The interaction similar
1.
time of 1.5 h, by each sample was as shown
using caesium
the uptake of ClF was irreversible
observed
in a
1.
either with hexafluoroacetone
linearly
resulted
as shown in Figure
behaviour
of SF4 with caesium to that observed
fluoride
to that
1, the uptake occurs
is much less marked.
and thallium(I)
with ClF, although
was similar
fluoride
the quantities
showed
of SF4 involved
260
Time bin)
FIGURE
1
Uptake of ClF by CsF pretreated
as follows:
48 h; 3) (CF3)2C0 t MeCN; 4) N2, 573 K, 3 h;
TABLE
1) none; 2) vacua, 423 K,
5) N2, 773 K, 3 h.
1
Uptake of ClF or SF4 by CsF or TIFa Pretreatment
ClF uptake after
SF4 uptake after
SF4 uptake after ClF
1.5 h/mm01
1.5 h/mmol
pretreatment/mm01
CsF
TlF
1. None
2.7
1.3
2. Vacua, 432 K,
2.9
1.3
0.1
0.1
2.4
0.1
3.0
1.4
0.2
0.2
2.9
0.2
4. N2, 573 K, 3 h
0.8
1.2
0.2
0.2
2.9
0.1
5. N2, 773 K, 3 h
0.3
CsF
TlF
TlF
CsF 0.8
48 h 3. (CF3)2C0 + MeCN
ausing
0.1
0.4
ClF = SF4 = 500 torr = 6.40 mmol; MF = 2.0 g = 13.17 mm01
(CsF), 8.95 mmol
01~).
were considerably
smaller
than the corresponding
amounts
of ClF (see Table
1 and
Figure 2). Using [35S] labelled
SF4 very small uptakes,
were found using untreated on the untreated
thallium
both caesium fluoride
caesium fluoride.
and thallium
fluoride
In contrast fluoride,
not detectable
samples;
by pressure measurement, was detected
no uptake of SF
to the behaviour
of
46
ClF towards
most of the 35SF4 adsorbed
on either
261
OO I
30 I
60 8
I
90 , 1
I
Time (mid
FIGURE 2
Uptake of SF4 by CsF pretreated
&sorption 9
75
60 l= 2= 3* 4=
Admission
0
pretreated
caesium
fluoride
was removed
for caesium
fluoride
pretreated
of a further
the first adsorption
15
Time 6nin)
23*1 % of the initial uptake of 35 SF sample of
- desorption
being retained 45
with
(CF3)2C0 + MeCN
by evacuation with
resulted
fluoride
at room temperature + MeCN in Figure 3,
fluoride. sample,
in a saturation
in the first cycle
of this second sample gave a surface
(CF3)2C0
by caesium
SF4 to a caesium
cycle,
rate which was less than that obtained evacuation
30
1st. Adsorption 1st. Lksorption 2nd.Pdwption 2nd.t&znptii
5.8 mmol 35SF4 was used in each case.
or untreated
This is illustrated
1.
bin)
Uptake of 35 SF4 by CsF (13.17 mmol),
and its desorption.
pretreated
Time 45
Wsorption
FIGURE 3
as Figure
following
surface count
(see Figure 3). Subsequent
count rate identical
to that obtained
following
the first evacuation.
(I) fluoride Admission resulted
No evidence
of SF536 Cl to a pretreated
caesium
in a small uptake of radioactivity
completely
Reaction
removed by evacuation
warm to ambient
fluoride
temperature
[Z], has generally
However,
presented
ClF and the caesium fluoride being an intermediate
were allowed
and, in consequence,
caesium
fluoride
fluoride
and thallium
and thallium
with caesium fluoride
fluoride
ClF by SF4 occurred
fluoride,
pretreated
as shown in Table 1,
temperature
for 1.5 h. After
treated
fluoride
The adsorption
in the SF4 - CsF system.
fluoride
with ClF
with thallium
by SF4 could be carried out several
fluoride
for
which had been pretreated
with
is greater
for the (CF3)2C0 pretreated
of SF4 is characterised process,
behaviour
by an initial,
very similar
rapid uptake
to that observed
In the case of ClF, there is a rapid initial adsorption,
by a more complex
process
adsorption
by the caesium
constant.
pretreated
of SF4 corresponded
in vacua at 423 K for 48 h.
by a slower adsorption
and SF4 retained
by
of adsorbed
Table 2 shows the results obtained
the amount of gas adsorbed
as further
fluoride
of the thallium(I)
with ClF followed
using samples of caesium
(CF3)2C0 + MeCN or by heating
fluoride.
enhanced
uptake of SF4. No SF5C1 was observed
times using the same sample of catalyst.
As expected,
(I) fluoride.
no displacement
of SF4 to caesium
of
in this manner.
of caesium
six such reactions
a small quantity
but not with thallium
Pretreatment
had no effect upon the subsequent (I) fluoride
to the pretreated
in [36C1] surface count rate on admission
to the amount of SF5 36C1 formed.
effectively
ClF
the
which had been
the extent of uptake of SF4 was considerably
as shown by admission
with 36 ClF; the decrease
decreasing
between
of adsorbed
by examining
fluoride
of ClF, as shown in Table 1. However,
the preadsorption
followed
to
to occur by formation
the possibility
of SF5Cl was explored
to react with 6.40 mmol ClF at ambient
With caesium
followed
by condensing
the mixture
of this species with ClF.
of the gas phase ClF, 6.40 mmol of SF4 were admitted
SF5Cl was obtained
caesium
been proposed
reaction
performed
and allowing
After 1.5 h the gas phase was removed and analysed;
Reaction
this was
with ClF.
Samples of caesium
evacuation
temperature
above show that there is a strong interaction
in the formation
of SF4 towards
pretreated
However,
of CsF, typically
at low temperature
species and subsequent
the results
sample at ambient
of metal fluorides
of a Cs+SF5- surface
behaviour
of SF4 by the thallium
temperature.
of SF4 in the presence
SF4 and ClF on to caesium
fluoride
by the surface.
at ambient
of SF,, with ClF in the presence
Chlorofluorination
surface.
for any retention
samples was obtained.
in which the pressure
occurs. fluoride,
slightly
before
and the yield of SF5C1 at each step, are
After six cycles the compositions
to the mole ratios CsF:C1F:SF4,
increased
As shown in Table 2, the amounts of ClF
11.85:9.3:7.45
of the solids correspond
and 11.85:3.75:3.1
for hexafluoro-
263 TABLE 2 Repeated
addition
of ClF (359 torr : 4.6 mmol) then SF4 (359 torr f 4.6 mm011 to
CsF (11.85 mmol) at room temperature Step
CsF pretreatment
Gas
time
gas
yield
time
gas
yield
/h
retained
SF5Cl
/h
retained
SF5C1
2
3
4
5
6
acetone
ClF
1.5
1.9
1.5
0.8
1.5
1.4
0.15
2.0
0.7
ClF
2.0
1.8
0.05
2.0
0.65
0.05
SF4
1.5
1.15
0.1
2.0
0.8
0.2
ClF
2.0
1.8
0.05
2.0
0.8
0.1
SF4
1.5
1.0
0.1
2.0
0.8
0.2
ClF
2.0
1.7
0.35
2.0
1.0
0.1
sF4
18.0
3.4
0.25
18.0
1.1
0.15
ClF
2.0
1.8
0.15
2.0
1.0
0.4
SF4
2.0
1.15
0.1
2.0
0.7
0.1
ClF
2.0
1.95
0.2
2.0
1.1
0.2
SF4
2.0
1.0
0.15
2.0
0.6
0.1
pretreated
and vacuum
heated samples
these solids at room temperature,
333 K. Progressively
heating
in the production
Addition results
/mm01
SF4
by pumping
resulted
/mm01
/llmlol
/mm01 1
423 K, vacua, 48 h
(CF312C0 + MeCN
added
of a mixture
in different
with
were followed
by change
the SF5C1 separated of experiments
of SF4 and ClF to caesium from that described fluoride
+ MeCN, at ambient in pressure.
from unchanged
in which
but was evolved
slowly by pumping
at
of 1.65 and 0.9 mmol SF5Cl respectively.
behaviour
(CF3)2C0
SF5C1 was not evolved
the solids from 333 K to 393 K over a 12 h period
SF4 and ClF were added to caesium pretreated
respectively.
After
samples.
fluoride
at ambient
above. Appropriate
temperature mixtures
of
13.17 mmol in each case,
temperature
and the subsequent
1.5 h volatile
material
reactions
was removed,
ClF and SF4 and its yield determined.
The results
the ClF varies from 0.64 to 3.20 mmol while SF4 is constant
at 3.20 mm01 are shown in Figure 4. For a 1:l mole ratio the yield of SF5C1 is 77 % and very little ClF + SF4 is retained at lower mole ratios. approximately
retention
With ClF at 0.64 mmol the fraction
becomes
significant
of gas retained
15 % of the total initial gas. The yield of SF5C1 increases
when ClF > 3.20 am101 and the fraction is markedly
by CsF, however
of SF4 + ClF retained
by caesium
is slightly
fluoride
increased.
Similar effects
on the yield of SF5C1 and the fraction
of ClF + SF4 retained
264
FIGURE 4
Changes
pretreated
in % composition
for SF4 + ClF -f SF5Cl over CsF (13.17 mmol),
(CF3)2C0 + MeCN. SF4 = 3.20 mmol,
with
(ClF + SF4)(g) and (ClF + SF4)(retained)
by caesium
fluoride
ClF is constant
are observed
when SF4 is varied
at 3.20 mmol. However,
SF4 concentration
is significantly
fluoride
the fraction
The surface concentrations
at low
of SF4 and ClF in a I:1 mole ratio is added
at room temperature.
less than that in the absence
from 0.64 to 3.20 mmol while of ClF + SF4 retained
higher than at low ClF concentration.
No SF5Cl is formed when a mixture to thallium(I)
SF5Cl % of initial ClF,
% of total initial gas.
The quantity
of gas retained
is a little
of SF4. of ClF and SF4 under reaction
conditions
were examined
reaction of 36C1F + SF 4 or 36 ClF + SF4 over caesium ClF + 35SF4 mixtures. Some typical results obtained with 36 ClF in the absence of SF4 is fluoride are shown in Figure 5: the behaviour of by monitoring
the activity
of the surface during
included for comparison. The [36Cl] surface activity followed
accurately.
Evacuation
behaviour
is complete
was observed
at a rate too rapid to be
reaching
surface activities
occurred
according
the second order rate constants [35SF4], after correction
complete,
Table 3 shows that
for the removal of adsorbed
for permanently
retained
except
the surface count
in both the [36Cl] and [35S]
to a second order process.
derived
value after ~1.24 h
had no effect upon the final
The decrease
zero; see Figure.6.
a constant
with 35SF 4 + ClF reaction mixtures
1.25 h, when the reaction was effectively
rate was effectively
agreement.
increased
it decreased,
of the system after reaction
count rate. Similar that, after
initially
Thereafter
radioactivity
[36ClF] and
are in good
Variation
FIGURE 5
36
of
Cl surface
activity
with time (i) for 36C1F
with
+ SF4 (161 torr) over CsF pretreated
in vacua at 423 K, (iii) 36C1F (198 t.Orr)
Variation
FIGURE 6 35SF4
with
+ MeCN,
(161 torr)
t SF4 (168 torr) over CsF pretreated
over CsF pretreated
(CF3)2C0
(168 ton-1
(ii) for 36C1F
(CF3)2C0 + MeCN.
of the 35 S surface activity
(187 torr) over CsF pretreated
with
with time for ClF (185 torr) t
(CF3)2C0
+ MeCN.
DISCUSSION The results caesium reaction
presented
fluoride between
above show that the genarally
catalysed
chlorofluorination
Cs'SF5- and gaseous
accepted
of sulphur
chlorine
mechanism
tetrafluoride,
for the
involving
monofluoride;
SF4(g) t CsF(s) c' Cs+SF5-(s) Cs+SF5-
+ ClF(g) + SF5Cl(g)
is incorrect chlorine
+ CsF(s)
in that such a mechanism
monofluoride
The results pentafluoride
and the caesium
presented
in Table 3 indicate
is a true surface
and adsorbed
sulphur
monofluoride
to sulphur
photochemically
reaction
tetrafluoride
induced reactions
the reaction
between
surface.
that the formation
involving
An excited
tetrafluoride.
adsorbed
molecular
has been reported
of sulphur
chlorine
addition
chloride
monofluoride
of chlorine
for the thermal
and
[18].
Our results may best be interpreted reactions:
does not take into account fluoride
by considering
the following
equilibrium
TABLE 3 Second order rate constants
for the reactions
ClF + 35SF4 + 35SF,C1 Initial pressure of 36C1F
Second order rate
36C1F + SF4 -f SF536C1 and
261 CsF(s)
+ SF4(g) -f Cs+SF5-(s)
rather than via equilibrium Admission fluoride
of sulphur
(2).
tetrafluoride
to chlorine
led only to very small yields
to those obtained
when the reactants
were admitted
However,
there was a marked
fluoride
when the caesium
leading,
in the case of the hexafluoroacetone
composition reactions
increase
fluoride
monofluoride
of sulphur chloride
pretreated
pentafluoride,
simultaneously
in the extent of retention
surface was pretreated
(CSF),_,~(C~F),.,,(SF~),.
pretreated
Together
caesium relative
to the catalyst. of sulphur
with chlorine catalyst,
these observations
tetra-
monofluoride
to a solid with indicate
that
of the type
Cs+ClF2-(s)
+ CsF.SF4(ads,) + SF5Cl(g)
+ 2CsF(s)
and
(cStclF2--sF4)
where
+
sF5ci(g)
+ cSF(S)
(Cs 'C1F2- -SF4) represents
monofluoride suggest
pretreated
the uptake of sulphur
catalyst,
that the (CstC1F2- -SF4) entity exists
and which only decomposes elevated
their reaction
monofluoride,
with thallium(I) monofluoride
to sulphur
presumably
observations
retention
fluoride
chloride
as TltC1F2-,
of sulphur tetrafluoride between
difference
in the bonding
caesium
in the reactive
fluoride between
at
adsorbed
fluorine
atom. Reaction formulated
coordination
between
this species
as Cs+F-...ClF
of the sulphur of sulphur
may be an important
formulated
surface
to equation
in contrast
temperature.
fluoride
tetrafluoride
geometry
[213, therefore
adsorbed
or Cs+F- . ..FCl [20], is readily
to the thallium(I)
interaction.
(5) has no obvious
to a
and the metal
studies of Cs+SF5'
as having a (Cs')F-...SF4 and reactive,
previously
the reactive bridging
chlorine monoenvisaged
via
[63 that
cation via its lone pair
In this situation a surface reaction mechanism.
to
[6], no The
we ascribe substrate
spectroscopic
lone pair. We have suggested
tetrafluoride
although
of chlorine
sulphur tetrafluoride
state. Vibrational
that the anion has square pyramidal
this solid it would not
Retention
at ambient
and thallium(I)
the sulphur
state may be reasonably
participation
pentafluoride.
was observed
indicate
analogous
on the catalyst,
tetrafluoride,
was also observed,
adsorbed
fluoride,
We further
pentafluoride
show that whereas
and sulphur
at 423 K using ['*F]-labelled
difference
fluoride
chloride
by the chlorine extent.
temperature.
The results obtained
previous
as a stable species
slowly to CsF and sulphur
would adsorb both chlorine catalyse
tetrafluoride
cannot occur to any appreciable
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