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Kinetic investigation of the reaction: CO+Cl2⇌COCl2 over ZSM-5 zeolites with transition metal ions
467
CatalysisToday, 3 (1988) 467-473 Printed in The Netherlands
Elsevier Science Publishers B.V., Amsterdam -
OVERZSM-5 ZEOLITESWITH
KINETIC INVESTIGATION OF THEREACTION:CO+C+ -COC12 TRANSITIONMETALIONS
P. FEJES, c. HAJOU,A. GILOE, Gy. SCH&EL, K. VARGAand I. HANNUS Applied Chemistry Department, Jozsef
Attila
University,
Szeged (Hungary)
ABSTRACT
The CO+Cl CrCOCl reaction was studied over a ZSM-5 zeolite (SiO /Al 0 = .s. A . . X Be= 80.0) contai ing tra sition metal ions. An Eley-Rideal type rate equ 2tie scribes the observed rates with acceptable accuracy. The proposed mechanism takes into account the interaction of CO arriving from the gas phase with cheyisorbed chlorine. 1.r. spectra convincingly show the presence of a charged COCl species under reaction conditions.
INTROOUCTION Because our paper deals primarily formation, discovery
we have to skip the history by Oavy (181’2) till
the production
of pigments,
its
another formulation
finds
Zeolites,
and 0.63 nm provide As regards
both easy access
that charcoals
phosgene with have hetero-
to the active
have to
pore openings between 0.6 sites
in the interior
of the
and easy removal of the product. sites,
by analogy with similar
mistry , ions of the Group 8 of the periodic they have partially
from its including
causes problems when spent catalysts those exhibiting
active
applications
for producing
in the fact
particularly
for the reactants
phosgene
and polymers.
as catalyst
explanation
of catalytic
important intermediate
present-day
herbicides
charcoal
channel systems and this
be replaced. grains
its
of this
extensive
dyes,
The idea to try to replace -disperse
with the kinetics
filled
orbitals
table
reactions
in organic
seem to be appropriate
for the interaction
che-
because
with CO and C12.
THERMOOYNAMICS OF THEREACTION.NON-CATALYTIC TRANSFORMATION Given the overall CO(gas) + C12(gas) the equilibrium the initial for defining
phosgene-forming
*COC12(gas)
constant
partial
(1)
of the reaction
pressures
the activities
lue of the extent
of overall
(pi),
can most conveniently
the pressure
(PO), the reactor reaction
Ka = exp(-A Gi T/RT) = P” yg(pEo-
3
Considering
reaction:
in the selected
by
standard state
volume (V) and the equilibrium
va-
(E >: FE)-‘(pFl-
FE)_1 2
that the Gibbs’
be expressed
free
energy of formation
(2) for phosgene from CO
468 = -46.61
and Cl2 at 473 K (200 ‘C), AG: CoCl that
the equilibrium
the reaction
is compleiely
can be regarded
kJ/mol,
‘displaced
it
follows
to the right
as irreversible
Tram equ. (2)
(Ka=1.4f3.105);
even at the highest
hence
experimental
temperature. Though the homogeneous, was not negligible
(it
times of reaction),
non-catalytic
because unavoidable
below this
level.
to the observed
about 5 % at the highest
reached
no correction
formation”
contribution
was applied errors
temperature
for this
of other
and longest
“empty reactor
origin
rate trans-
could not be diminished
EXPERIMENTAL The catalyst a molar ratio
base material
was a ZSM-5 zeolite
Si02/A1203 = 80.0,
Na+ ions of the as synthesized temperature
before
burning
using
with
bromide as template.
were exchanged for NH: ions at room
product
off the organics.
By ion exchange in aqueous COG’+ and RhC13 solutions,
specimen synthesized
tetrapropyl-ammonium
four catalyst
La(N03)3, Pd(NH3)4C12, Pt(NH3j4C12
specimens
were prepared
with the approximate
compositions: H(Na)l 14Pt0 59 (A102)2e32(Si02)92
Sample 1.:
2': H(Na)0.74C00.65La0.09
(A102)2.32(sio2)92.68
3.: H(Na)0.16Pd1.08
(A102)2.32(sio2)92.68
4 .: H(Na)0.15Rh0.72
(A102)2. 32(sio2)92.
The acidity -exchange
(H+> values capacity
the respective Provided
are uncertain
of the zeolite
that
every active their
For infrared
studies
Pt
(i.e.
2+
2+ , Co , etc.
concentration, of less
analysis
of
self-supporting
lying
up to 700 K and contacting
permitting
between 0.103 2 ny 5
cell
was connected
in situ
to a high vacuum
gas reservoires. heat-treatment
the wafer with the gaseous reactants
were recorded
was accessib-
wafers of about 5-10 mg/cm2 thickness
The infrared
facility
ions)
than 2.
pump and to the respective
with a heating Spectra
site
by a factor
from the powders.
system with oil-diffusion
temperatures.
(=0.412 meq/g> and the elemental
initial
5 0.188 mmol/g, would differ were pressed
68
as they were computed from the known ion-
specimen.
le for the reactants,
provided
68
at beam temperature
using
It
was
in vacua at preselected
a Specord 75-IR
type spectrometer. The reaction
was carried
out in a batch reactor
over catalyst
samples of approximately
parated)
of the reactor
part
the preparation
(volume:
of gas mixtures
with gas recirculation
1 g (~0.025 g). Vl =
(CO and Cl,)
The unheated
(and se-
0.0891 dm3, Tl = 29823 K) permitted of known amount and composition.
469
After
admission of the mixture into
~0.02%
dm3), the reaction
pressure
using a special
ducer,
the heated part of the reactor
was followed
by continuous
sensor for agressive
(volume:V2
registration
gases (Datametrics
of the total pressure
trans-
type 1590 A).
Approximate extents
of adsorption
for each component were obtained
metric measurements on the same catalyst the threshold
of detection
adsorption
and linearity
tent of the overall
KT and KT (see
reaction
by volu-
of CO was below The isotherms
was also presumed to be valid
These data were used for determining
coefficients,
unreacted
The adsorption
even at the lowest temperature applied.
for Cl2 and COC12 were linear the mixtures.
samples.
later)
the equilibrium
for
values of
for Cl2 and COC12. The final
(or the conversion
ex-
of CO) was determined from the
out the Cl2 and COC12. This was used for checking the
CO by freezing
value of Kg. THERATE EQUATION Gaseous chlorine
(and also phosgene)
ALPO-s even at elevated CO are therefore theoretical
fully
is strongly
(T >500 K) temperatures; occupied
bound in zeolites
potential
adsorption
by C12. This has to be considered
and sites
for
when deriving
a
rate equation.
The interaction
between CO and Cl2 can be visualized
as follows,
ki/ki, Lc1I
i=l
iz1 + Cl2 _-.
2
2
[C121+ co
k2/k2 c
3
cc0c1,3
.
k;/k3
*
COC12 + [zl
specifically
where 1.. . I : stands for sorbed species,
(4)
[COC121
iZ] for unoccupied active
sites. The catalytically cavities tion,
active
in interaction
sites
are unspecified
with chemisorbed chlorine.
above a few tenths of 1 mnol/g,
be responsible).
Reaction
and the surface coverage
chlorine,
corresponds
This picture pressed
2
this
2
r2 = k2%12PC0 - ki%OCl,
The actual
phosgene
mechanism which can be ex-
formalism: (6)
(fast> (rate
may
from the “gas” phase
equilibrium.
is in accord with an Eley-Rideal
- ki”C1
high sorp-
over the “oxygen-lattice”
step being rate-determining.
mathematical
in the zeolitic
(For the relatively
between CO arriving
to the adsorption
by the following
‘1 = kl~p~l
takes place
physisorption
ions present
determining)
(7)
(8)
(fast.1 where the ej-s free
active
partial
(j=Cl,, sites
COC12) are coverages,
and the pi-s
f+ is the relative
proportion
(i=CO, Cl2, COC12) are the corresponding
of actual
pressures. Kinetic
equation, fined
and balance
expressing
as: AP = p:l
equations
the rate
can be transformed
into
a single
differential
(in mol/s> by the change of the total
+ pEo - p; the pp-s are initial
partial
pressure
pressures,
(de-
and p is
2 the actual cients,
pressure,
so: AP 201,
equilibrium
constants
d(A
P> _ k2KT a - + a~cl; “2 where
are adsorption
and
equilibrium
constants
; yzl+Ky
As approximate tion
experiments,
determined
parameters
(rate
coeffi-
(9)
K”3= “~oc12’“coc12
ve amounts in the adsorbed Pzl+K;
constant
- + AP)(P;~ -
dt
KY = $.12/nC12
and containing
etc.):
defined
and gas phase, andazP/y
values kg/n;
in a closed
and the Greek letters
stand
for
+Ky
(10)
for KY and KY are available
es n2
system by the respecti-
(s-1 kPa-1)
from (9) by the method of linear
and k$/r$ least
from independent s
H; (s-l>
adsorp-
can be
squares.
RESULTSAN0 DISCUSSION A representative (r) as a function
example showing the of t is given in Fig.
BP*
t curve and the computed rates
1.
50.0
.0
-2 m %
+++-+
=
XXXX =
2
PRESSURE RflTE
-4
f
Fig.
~.AP -
t and r ++
t curves
for catalyst
(ny = 0.103 nnrol; T = 363 K).
No.1 (Pt)
471
The evaluation and (10).
of data strictly
The derivatives
approximation
of the
followed
the mathematical
were obtained
from a fourth
AP versus t curve followed
and xi from the linear by nultiplying
dAP/dt regression
by analytical
were transformed
by the amount of active
The most important equilibrium termined from two or three parallel
sites
expressions
into
derivation.
actual
for each catalyst
data and kinetic
(9)
degree polynomial ~2
rate coefficients ($1.
parameters,
as averages de-
runs, are summarized in Table 1.
TABLE1 Sorption
coefficients
Catalyst No.
1 (Pt)
t-$=0.103 mmol No. 2 (Co) ny=O.lll
mm01
No. 3 (Pd) r$=0.182 mm01 No. 4 (Rh) n0=0.118 mm01 2
and rate constants
for the catalytic
k2*10’/(mol/s
kPa)
phosgene formation ki*107/(mol/s)
T/K
K?
K;
363 383 399 418
0.65 0.45 0.32 0.22
0.97 0.66 0.81 0.56
6.90 9.51 7.57 12.13
0.71 0.59 2.4-l 1.85
363 383 398 418
0.82 0.46 0.32 0.20
0.95 0.80 0.60 0.40
3.25 5.15 9.15 17.98
0.42 0.75 1.17 1.90
365 383 400 418
0.46 0.25 0.21 0.13
0.70 0.65 0.45 0.19
1.19 1.52 8.46 21.15
2.19 1.46 1.51 2.59
364 385 398 419
0.53 0.33 0.27 0.16
0.72 0.50 0.38 0.22
1.11 4.43 8.24 19.82
0.71 0.86 1.07 1.98
From (2) and (7) follows
that Ka = P’(k,/ki)(K;/K;);
as K;/K; changes with-
in one order of magnitude, the value of k2 should exceed that of k; by at least 2-3 orders ptotic
of magnitude which does not materialize
behaviour
tardation
of the
AP+
t curves
by COC12 which should be considered
In order to rationalize (see e.g.
the same authors
zeolites:
of phosgene is actually are dealing
with phosgene,
ward two similar racteristic
ionic
and the asym-
of product re-
the kinetics.
to phosgene formation interactions
it should
are dominating
ref.1).
The formation zeolites
environments
This fact
indication
in refining
the pathways leading
be remembered that in zeolitic
here.
are a clear
with since
Fejes et al.
an “overture”
(refs.2-3)
and Lok et al.
mechanisms which can be modified
for the interactions
to dealumination
about 1980. As concerns to express
which
dealumination (ref.41
put for-
the main steps
taking place between some halogen,
of
X2, and
cha-
{ A104,2- 1. Me+ + X2-+ ({ A104,2- 1. Me+. . .X While the indicated orine,
steps with a highly
lead to completion
even at Ts350
mation stops at the intermediate Infrared
spectra
6-_
x6+
) --t{AlO+}.X-+
electronegative K (cf.
MeX + 0
J
X2 as reactant,
Lok), with chlorine
(11)
like
flu-
the transfor-
stage.
registered
at beam temperature with sample 2. in the pre-
sence of CO+C12 mixtures, equal intensity
or COC12 alone, exhibit two intense features of nearly -1 as shown in Fig. 2. They can be assigned at 1805 and 1718 cm
to the
01 vibration node (symmetric stretching; in gaseous phosgene absorbing -1 at 1827 cm ; see ref.5) in Fermi resonance with the overtone 2 04 ( “4 being an asymmetric stretching 01/2
o2 diad.
giving
The position
rise
to absorption
at 845 cm-l)
of the two bands differ
570 and 281 cm-’ found by Jacox et al. ces at 14 K and interpreted
(ref.61
which results
in an
markedly from those at 1880,
in irradiated
solid
as being due to the free radical
CO+HClmatri-
COCl’.
80
40
lj50
1 sQ0
Fig.
2. Infrared
wawenumber (cm-‘>
spectrum of the COCl+ spec?ls
Fermi-resonance It is believed rise
17BE
at 1718 and 1805 cm
that in the case of zeolites
the surface
to the bands mentioned is the ion COCl+, in fact
form of phosgene: by Eaily
ID-CO It/a
species
a stabilized
which gives mesomeric
of which was postulated
already
(ref. 5) -
As a consequence, that’the
I-, the existence
showing
.
lone electron
by interaction
the i.r.
data give support to the previous
pair of CO may cause complete heterolysis
with the Cl6 + end of the molecule.
mediate Cl-CO+*Cl- either
(with AlOCl, MeCl and CO2 as products) As pretreatment
The relatively
desorbs as COC12, or else
picture
in
of Cl6 --Cl6 stable
+
inter-
causes “dealumination”
above about 600 K.
in high vacua at 773 K reduced the level
sample 2. by about 40 %, also Erdnsted acid sites
are active
of activity
of
in forming phosgene.
473 Though the most active previous Y> attain
reasonings
follows
a large
(e.g.
of charcoals
number of questions
had to be clarified
working catalysts
varieties
that the best catalyst
or even exceed the activity
from Japan), etc.)
catalyst
before
by zeolitic
sample 2.;
from the
were an H+-type ultrastable (e.g.
that of type H6W-761
(time on stream effects,
even suggestions
hint:
can be raised
regeneration to replace
the
materials.
REFERENCES 1 2 3 4 5 6
J.A. Rabo, P.E. Pickert, D.N. Stamires, J.E. Boyle, Deuxikme International Congrks de Catalyse (Editions Technip, Paris, 1960); Section II. p. 104 P. Fejes, I. Kiricsi, I. Hannus, A. Kiss and Gy. SchBbel, React. Kinet. Catal. Lett., 14 (1980) 481. P. Fejes, I. Hannus, I. Kiricsi, Zeolites, 4 (1984) 73. 8.M. Lok, F.P. Gortsema, C.A. Messina, H. Rastelli, ACS Symposium Series, No. 218 (Intrazeolite Chemistry), 1982; p. 41. C.R. Bailey, J.8. Hale, Phil. Mag., 25 (1983) 274. M.E. Jacox, D.E. Milligan, J. Chem. Phys., 43 (1965) 886.
CatalysisToday, 3 (1988) 467-473 Printed in The Netherlands
Elsevier Science Publishers B.V., Amsterdam -
OVERZSM-5 ZEOLITESWITH
KINETIC INVESTIGATION OF THEREACTION:CO+C+ -COC12 TRANSITIONMETALIONS
P. FEJES, c. HAJOU,A. GILOE, Gy. SCH&EL, K. VARGAand I. HANNUS Applied Chemistry Department, Jozsef
Attila
University,
Szeged (Hungary)
ABSTRACT
The CO+Cl CrCOCl reaction was studied over a ZSM-5 zeolite (SiO /Al 0 = .s. A . . X Be= 80.0) contai ing tra sition metal ions. An Eley-Rideal type rate equ 2tie scribes the observed rates with acceptable accuracy. The proposed mechanism takes into account the interaction of CO arriving from the gas phase with cheyisorbed chlorine. 1.r. spectra convincingly show the presence of a charged COCl species under reaction conditions.
INTROOUCTION Because our paper deals primarily formation, discovery
we have to skip the history by Oavy (181’2) till
the production
of pigments,
its
another formulation
finds
Zeolites,
and 0.63 nm provide As regards
both easy access
that charcoals
phosgene with have hetero-
to the active
have to
pore openings between 0.6 sites
in the interior
of the
and easy removal of the product. sites,
by analogy with similar
mistry , ions of the Group 8 of the periodic they have partially
from its including
causes problems when spent catalysts those exhibiting
active
applications
for producing
in the fact
particularly
for the reactants
phosgene
and polymers.
as catalyst
explanation
of catalytic
important intermediate
present-day
herbicides
charcoal
channel systems and this
be replaced. grains
its
of this
extensive
dyes,
The idea to try to replace -disperse
with the kinetics
filled
orbitals
table
reactions
in organic
seem to be appropriate
for the interaction
che-
because
with CO and C12.
THERMOOYNAMICS OF THEREACTION.NON-CATALYTIC TRANSFORMATION Given the overall CO(gas) + C12(gas) the equilibrium the initial for defining
phosgene-forming
*COC12(gas)
constant
partial
(1)
of the reaction
pressures
the activities
lue of the extent
of overall
(pi),
can most conveniently
the pressure
(PO), the reactor reaction
Ka = exp(-A Gi T/RT) = P” yg(pEo-
3
Considering
reaction:
in the selected
by
standard state
volume (V) and the equilibrium
va-
(E >: FE)-‘(pFl-
FE)_1 2
that the Gibbs’
be expressed
free
energy of formation
(2) for phosgene from CO
468 = -46.61
and Cl2 at 473 K (200 ‘C), AG: CoCl that
the equilibrium
the reaction
is compleiely
can be regarded
kJ/mol,
‘displaced
it
follows
to the right
as irreversible
Tram equ. (2)
(Ka=1.4f3.105);
even at the highest
hence
experimental
temperature. Though the homogeneous, was not negligible
(it
times of reaction),
non-catalytic
because unavoidable
below this
level.
to the observed
about 5 % at the highest
reached
no correction
formation”
contribution
was applied errors
temperature
for this
of other
and longest
“empty reactor
origin
rate trans-
could not be diminished
EXPERIMENTAL The catalyst a molar ratio
base material
was a ZSM-5 zeolite
Si02/A1203 = 80.0,
Na+ ions of the as synthesized temperature
before
burning
using
with
bromide as template.
were exchanged for NH: ions at room
product
off the organics.
By ion exchange in aqueous COG’+ and RhC13 solutions,
specimen synthesized
tetrapropyl-ammonium
four catalyst
La(N03)3, Pd(NH3)4C12, Pt(NH3j4C12
specimens
were prepared
with the approximate
compositions: H(Na)l 14Pt0 59 (A102)2e32(Si02)92
Sample 1.:
2': H(Na)0.74C00.65La0.09
(A102)2.32(sio2)92.68
3.: H(Na)0.16Pd1.08
(A102)2.32(sio2)92.68
4 .: H(Na)0.15Rh0.72
(A102)2. 32(sio2)92.
The acidity -exchange
(H+> values capacity
the respective Provided
are uncertain
of the zeolite
that
every active their
For infrared
studies
Pt
(i.e.
2+
2+ , Co , etc.
concentration, of less
analysis
of
self-supporting
lying
up to 700 K and contacting
permitting
between 0.103 2 ny 5
cell
was connected
in situ
to a high vacuum
gas reservoires. heat-treatment
the wafer with the gaseous reactants
were recorded
was accessib-
wafers of about 5-10 mg/cm2 thickness
The infrared
facility
ions)
than 2.
pump and to the respective
with a heating Spectra
site
by a factor
from the powders.
system with oil-diffusion
temperatures.
(=0.412 meq/g> and the elemental
initial
5 0.188 mmol/g, would differ were pressed
68
as they were computed from the known ion-
specimen.
le for the reactants,
provided
68
at beam temperature
using
It
was
in vacua at preselected
a Specord 75-IR
type spectrometer. The reaction
was carried
out in a batch reactor
over catalyst
samples of approximately
parated)
of the reactor
part
the preparation
(volume:
of gas mixtures
with gas recirculation
1 g (~0.025 g). Vl =
(CO and Cl,)
The unheated
(and se-
0.0891 dm3, Tl = 29823 K) permitted of known amount and composition.
469
After
admission of the mixture into
~0.02%
dm3), the reaction
pressure
using a special
ducer,
the heated part of the reactor
was followed
by continuous
sensor for agressive
(volume:V2
registration
gases (Datametrics
of the total pressure
trans-
type 1590 A).
Approximate extents
of adsorption
for each component were obtained
metric measurements on the same catalyst the threshold
of detection
adsorption
and linearity
tent of the overall
KT and KT (see
reaction
by volu-
of CO was below The isotherms
was also presumed to be valid
These data were used for determining
coefficients,
unreacted
The adsorption
even at the lowest temperature applied.
for Cl2 and COC12 were linear the mixtures.
samples.
later)
the equilibrium
for
values of
for Cl2 and COC12. The final
(or the conversion
ex-
of CO) was determined from the
out the Cl2 and COC12. This was used for checking the
CO by freezing
value of Kg. THERATE EQUATION Gaseous chlorine
(and also phosgene)
ALPO-s even at elevated CO are therefore theoretical
fully
is strongly
(T >500 K) temperatures; occupied
bound in zeolites
potential
adsorption
by C12. This has to be considered
and sites
for
when deriving
a
rate equation.
The interaction
between CO and Cl2 can be visualized
as follows,
ki/ki, Lc1I
i=l
iz1 + Cl2 _-.
2
2
[C121+ co
k2/k2 c
3
cc0c1,3
.
k;/k3
*
COC12 + [zl
specifically
where 1.. . I : stands for sorbed species,
(4)
[COC121
iZ] for unoccupied active
sites. The catalytically cavities tion,
active
in interaction
sites
are unspecified
with chemisorbed chlorine.
above a few tenths of 1 mnol/g,
be responsible).
Reaction
and the surface coverage
chlorine,
corresponds
This picture pressed
2
this
2
r2 = k2%12PC0 - ki%OCl,
The actual
phosgene
mechanism which can be ex-
formalism: (6)
(fast> (rate
may
from the “gas” phase
equilibrium.
is in accord with an Eley-Rideal
- ki”C1
high sorp-
over the “oxygen-lattice”
step being rate-determining.
mathematical
in the zeolitic
(For the relatively
between CO arriving
to the adsorption
by the following
‘1 = kl~p~l
takes place
physisorption
ions present
determining)
(7)
(8)
(fast.1 where the ej-s free
active
partial
(j=Cl,, sites
COC12) are coverages,
and the pi-s
f+ is the relative
proportion
(i=CO, Cl2, COC12) are the corresponding
of actual
pressures. Kinetic
equation, fined
and balance
expressing
as: AP = p:l
equations
the rate
can be transformed
into
a single
differential
(in mol/s> by the change of the total
+ pEo - p; the pp-s are initial
partial
pressure
pressures,
(de-
and p is
2 the actual cients,
pressure,
so: AP 201,
equilibrium
constants
d(A
P> _ k2KT a - + a~cl; “2 where
are adsorption
and
equilibrium
constants
; yzl+Ky
As approximate tion
experiments,
determined
parameters
(rate
coeffi-
(9)
K”3= “~oc12’“coc12
ve amounts in the adsorbed Pzl+K;
constant
- + AP)(P;~ -
dt
KY = $.12/nC12
and containing
etc.):
defined
and gas phase, andazP/y
values kg/n;
in a closed
and the Greek letters
stand
for
+Ky
(10)
for KY and KY are available
es n2
system by the respecti-
(s-1 kPa-1)
from (9) by the method of linear
and k$/r$ least
from independent s
H; (s-l>
adsorp-
can be
squares.
RESULTSAN0 DISCUSSION A representative (r) as a function
example showing the of t is given in Fig.
BP*
t curve and the computed rates
1.
50.0
.0
-2 m %
+++-+
=
XXXX =
2
PRESSURE RflTE
-4
f
Fig.
~.AP -
t and r ++
t curves
for catalyst
(ny = 0.103 nnrol; T = 363 K).
No.1 (Pt)
471
The evaluation and (10).
of data strictly
The derivatives
approximation
of the
followed
the mathematical
were obtained
from a fourth
AP versus t curve followed
and xi from the linear by nultiplying
dAP/dt regression
by analytical
were transformed
by the amount of active
The most important equilibrium termined from two or three parallel
sites
expressions
into
derivation.
actual
for each catalyst
data and kinetic
(9)
degree polynomial ~2
rate coefficients ($1.
parameters,
as averages de-
runs, are summarized in Table 1.
TABLE1 Sorption
coefficients
Catalyst No.
1 (Pt)
t-$=0.103 mmol No. 2 (Co) ny=O.lll
mm01
No. 3 (Pd) r$=0.182 mm01 No. 4 (Rh) n0=0.118 mm01 2
and rate constants
for the catalytic
k2*10’/(mol/s
kPa)
phosgene formation ki*107/(mol/s)
T/K
K?
K;
363 383 399 418
0.65 0.45 0.32 0.22
0.97 0.66 0.81 0.56
6.90 9.51 7.57 12.13
0.71 0.59 2.4-l 1.85
363 383 398 418
0.82 0.46 0.32 0.20
0.95 0.80 0.60 0.40
3.25 5.15 9.15 17.98
0.42 0.75 1.17 1.90
365 383 400 418
0.46 0.25 0.21 0.13
0.70 0.65 0.45 0.19
1.19 1.52 8.46 21.15
2.19 1.46 1.51 2.59
364 385 398 419
0.53 0.33 0.27 0.16
0.72 0.50 0.38 0.22
1.11 4.43 8.24 19.82
0.71 0.86 1.07 1.98
From (2) and (7) follows
that Ka = P’(k,/ki)(K;/K;);
as K;/K; changes with-
in one order of magnitude, the value of k2 should exceed that of k; by at least 2-3 orders ptotic
of magnitude which does not materialize
behaviour
tardation
of the
AP+
t curves
by COC12 which should be considered
In order to rationalize (see e.g.
the same authors
zeolites:
of phosgene is actually are dealing
with phosgene,
ward two similar racteristic
ionic
and the asym-
of product re-
the kinetics.
to phosgene formation interactions
it should
are dominating
ref.1).
The formation zeolites
environments
This fact
indication
in refining
the pathways leading
be remembered that in zeolitic
here.
are a clear
with since
Fejes et al.
an “overture”
(refs.2-3)
and Lok et al.
mechanisms which can be modified
for the interactions
to dealumination
about 1980. As concerns to express
which
dealumination (ref.41
put for-
the main steps
taking place between some halogen,
of
X2, and
cha-
{ A104,2- 1. Me+ + X2-+ ({ A104,2- 1. Me+. . .X While the indicated orine,
steps with a highly
lead to completion
even at Ts350
mation stops at the intermediate Infrared
spectra
6-_
x6+
) --t{AlO+}.X-+
electronegative K (cf.
MeX + 0
J
X2 as reactant,
Lok), with chlorine
(11)
like
flu-
the transfor-
stage.
registered
at beam temperature with sample 2. in the pre-
sence of CO+C12 mixtures, equal intensity
or COC12 alone, exhibit two intense features of nearly -1 as shown in Fig. 2. They can be assigned at 1805 and 1718 cm
to the
01 vibration node (symmetric stretching; in gaseous phosgene absorbing -1 at 1827 cm ; see ref.5) in Fermi resonance with the overtone 2 04 ( “4 being an asymmetric stretching 01/2
o2 diad.
giving
The position
rise
to absorption
at 845 cm-l)
of the two bands differ
570 and 281 cm-’ found by Jacox et al. ces at 14 K and interpreted
(ref.61
which results
in an
markedly from those at 1880,
in irradiated
solid
as being due to the free radical
CO+HClmatri-
COCl’.
80
40
lj50
1 sQ0
Fig.
2. Infrared
wawenumber (cm-‘>
spectrum of the COCl+ spec?ls
Fermi-resonance It is believed rise
17BE
at 1718 and 1805 cm
that in the case of zeolites
the surface
to the bands mentioned is the ion COCl+, in fact
form of phosgene: by Eaily
ID-CO It/a
species
a stabilized
which gives mesomeric
of which was postulated
already
(ref. 5) -
As a consequence, that’the
I-, the existence
showing
.
lone electron
by interaction
the i.r.
data give support to the previous
pair of CO may cause complete heterolysis
with the Cl6 + end of the molecule.
mediate Cl-CO+*Cl- either
(with AlOCl, MeCl and CO2 as products) As pretreatment
The relatively
desorbs as COC12, or else
picture
in
of Cl6 --Cl6 stable
+
inter-
causes “dealumination”
above about 600 K.
in high vacua at 773 K reduced the level
sample 2. by about 40 %, also Erdnsted acid sites
are active
of activity
of
in forming phosgene.
473 Though the most active previous Y> attain
reasonings
follows
a large
(e.g.
of charcoals
number of questions
had to be clarified
working catalysts
varieties
that the best catalyst
or even exceed the activity
from Japan), etc.)
catalyst
before
by zeolitic
sample 2.;
from the
were an H+-type ultrastable (e.g.
that of type H6W-761
(time on stream effects,
even suggestions
hint:
can be raised
regeneration to replace
the
materials.
REFERENCES 1 2 3 4 5 6
J.A. Rabo, P.E. Pickert, D.N. Stamires, J.E. Boyle, Deuxikme International Congrks de Catalyse (Editions Technip, Paris, 1960); Section II. p. 104 P. Fejes, I. Kiricsi, I. Hannus, A. Kiss and Gy. SchBbel, React. Kinet. Catal. Lett., 14 (1980) 481. P. Fejes, I. Hannus, I. Kiricsi, Zeolites, 4 (1984) 73. 8.M. Lok, F.P. Gortsema, C.A. Messina, H. Rastelli, ACS Symposium Series, No. 218 (Intrazeolite Chemistry), 1982; p. 41. C.R. Bailey, J.8. Hale, Phil. Mag., 25 (1983) 274. M.E. Jacox, D.E. Milligan, J. Chem. Phys., 43 (1965) 886.