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Isomerization of n-butane over zeolites depending on catalyst structure
223
Applied Catalysis, 25 (1986) 223-230 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
ISOMERIZATION OF n-BUTANE
MICHAEL
ST6CKERa'*,
JOSTEIN
K. GREPSTADc
OVER ZEOLITES
PETER HEMMERSBACHa,
DEPENDING
ON CATALYST
STRUCTURE
JOHAN HENRIK RIEDERb'** AND
aDepartment of Petrochemistry, Center for Industrial P.O.Box 350 Blindern, N-0314 Oslo 3 (Norway),
Research,
bDepartment of Chemistry, University of Oslo, P.O.Box 1033 Blindern, N-0315 Oslo 3 (Norway) and 'National Laboratory for Surface Technology, N-7034 Trondheim-NTH
Studies (NALOS), Norwegian (Norway)
Institute
of
ABSTRACT The isomerization of n-butane in the gasphasg , catalyzed by H-Y zeolite, RE-Y zeolite, H- and Na-offretite, was studied at 200 C and atmospheric pressure. The rate of isobutane formation was found to be higher for the Y zeolites (H- and cation-Y) than for the corresponding offretites (H- and cation-offretite), indicating some sterical restrictions of the offretites due to their smaller pore sizes and possible stacking faults. The protonated zeolites showed higher rates of isobutane formation than the corresponding cation exchanged catalysts. The selectivities of the zeolites during the first 20 h of the reaction were found to exceed 75%, whereas the maximum yield of isobutane for the active catalysts was in the range of 33-43%. Several physical and spectroscopical characterization methods were applied. The appropriate crystal structures of the offretite samples were verified by X-ray diffraction measurements. Furth ore te ahedrally coordinated Si- and Al-sites were identified by solid-state sgi_ ind $5 Al-MAS NMR spectroscopy, in both the offretites and the Y zeolites. Scanning electron microscopy (SEM) and chemical analysis disclosed the formation of coke during isomerization. Finally, XPS-measurements indicate the coexistence of exchangeable and non-exchangeable Na-ions in Na-offretite, the latter being located in a more electron-rich environment in the zeolite lattice.
INTRODUCTION Several
attempts
have been made to study the isomerization
cially with regard to arrive at a compromise since this parameter years,
of different
in n-butane zeolites *Author **Present
of research
catalysts,
isomerization
as catalysts
0166-9834/86/$03.60
and, consequently,
for this type of reaction.
In recent
on the acid of super-acids
report the use of
Their discussion
is mainly
should be addressed.
Det norske Veritas,
0
the application
very few authors
P.O.Box
300, N-1322 Hijvik (Norway).
1986 Elsevier Science Publishers B.V.
espe-
temperature,
control.
in this field has been focused
[l-lo]. Furthermore,
to whom correspondence address:
the reaction
plays a vital role in product distribution
the main interest
strength
concerning
of n-butane,
based
224
. I
on kinetic arguments Little
effort
isomerization this paper,
[ll-141. has been devoted
and the application we report
H- and Na-offretite, work
structure
to the study of sterical
of shape-selective
data on the catalytic with emphasis
aspects
zeolites
behaviour
of n-butane
in this reaction.
of H-Y zeolite,
on the influence.of
acidic
In
RE-Y zeolite,
sites and the frame-
of the zeolite.
EXPERIMENTAL The synthesis ported
of the catalysts
previously
(Philips
structure
NMR spectroscopy,
The scanning
of Namur,
have been re-
was verified
the Na-offretite
by X-ray
dif-
was checked
shift of the tetrahedrally
by
coordinated
operating
at
Belgium).
micrographs
were recorded
eV) and Mg KCZ (1253.6
were obtained
on a Vacuum
on a JEOL JSM-50A
Generators
ESCALAB
instrument,
Mk II,
using AL
eV) X-rays.
AND DIiCUSSION
Isomerization
tests
The isomerization
TABLE
and the chemical
electron
and the XPS-spectra
spheric
samples
Furthermore,
to 53.9 ppm (Bruker CXP 200 NMR spectrometer,
52.1 MHz, University
RESULTS
of the offretite
PW 1710 instrument).
Al was determined
Ku (1486.6
procedure
[151.
The appropriate fraction 27 Al-MAS
and the isomerization
pressure.
of n-butane
The results
in thegasphase
was studied
of the test runs are shown
at 200 'C and atmo-
in Table
1.
1
Isomerization
of n-butane
over zeolites
at 200 'C
Reaction
Catalyst
ratesa
(lo-6 mol g-' h-l)
15.7
H-V zeolite
2.8
RE-Y zeolite H-offretite
5.3
"‘('
0.1
Na-offretite
aDetermined at 15% conversion, Na-offretite.
In addition products
to the isomerization
(propane,
isopentane
fines was not detected. isomerization
of n-butane,
and n-pentane)
As an example,
of n-butane
is shown
except
for the
disproportionation
were observed.
the time dependence
and cracking
The formation of composition
in Fig. 1 for H-Y zeolite.
of olein the
225 The rate of isobutane cation-Y) eating
some sterical
and possible higher lysts
formation
proved
than for the corresponding restrictions
stacking
faults.
rates of isobutane
to be higher
offretites
in the offretites
The protonated
formation
for the Y zeolites
(H- and cation-offretite), due to their
zeolites
(stronger
than the corresponding
smaller
(H- and indi-
pore sizes
acid sites)
cation
exchanged
showed cata-
(RE-Y and Na-offretite).
n-Butan o lsobutane l
0 Pentanes
FIGURE
Time dependence
1
of composition
in the reaction
of n-butane
at 200 'C over
H-Y zeol ite.
of the catalyzed
The mechanism
[13,16].
ly described
as the (intramolecular)
other
is described
carbenium
proceeds
ring mechanism
would
form a primary
carbenium
counts
For strongly
The product
rization cular
require
acidic
the opening
on zeolites
process
carbenium
is probably
ions as more
The
formation
In both reaction
as compared studies
because
three-membered
this energy
it involves and these
argument
ac-
n-alkanes
that n-butane
process
isome-
1131. The bimole-
the fOrWtiOn species
ring to
and hence
to that of other
indicate
by an intramolecular
intermediates,
cyclopropane
very unfavourable,
like super acids,
and kinetic
preferred
stable
dimer
to the intramolecular
of the protonated
of butane
does not occur
one normal-
ring mechanism.
promotes
ring system).
is energetically
systems,
distribution
cyclopropane which
has been extensively
can be indicated,
intermediates.
according
ion. ThSs
for the slow isomerization
11,21.
mechanism,
via a cyclopropane
of n-butane
of n-butane
patterns
protonated
ions are.thq,crucial
The isomerization
unlikely.
two reaction
as the bimolecular
(also this mechanism schemes
Typically,
isomerization
investigated
of octYT
can rearrange
easily.
226 The dimers ments,
are cracked
with a high selectivity
but the additional
Ii-offretite, however, channel
there
intersections.
than in H-Y zeolite formation cerning
makes
formation
As a consequence,
the discrete
channel
the loss of acidic be related
sites.
systems
To a minor
to the smaller
ions, Our findings ports
the reaction caused
cannot
rate is lower
extent,
The dimer
sensitive
are, of course,
this lowering
caused
of a transition-state
in H-offretite
acidities).
much more
In
state at the
con-
state.
and Na-offretite
pore sizes,
of C4-frag-
be prevented.
transition
by different
in zeolites
of the transition
The lower rates for RE-Y zeolite
may
the formation
is less space for a bimolecular
(beside differences
shape selectivity
towards
of C3- and C5-fragments
of the reaction
by the ion exchange
selectivity
mainly
due to
rates
to larger
are in line with
recent
cat-
re-
[17]. The selectivity
Y zeolites
to isobutane
(see Fig. 2) has been found
than for the offretites,
indicating
a higher
to be higher
shape
selectivity
for the in Y
zeolites. The n-butane highest
activity
butane
disproportionation (H-Y zeolite).
over H-Y zeolite
equimolar pected
ratios
of propane
probably
Characterization Several
previously
and pentanes
mechanism.
atoms,
[15,18,191.
retite
electron
other
energy. energy
microscopy
belonging
Si-sites,
25%, as exformation
is
of the C3-fragment.
to the Y-group
surrounded
showed
of the framework
After
obtained [20-221.
chemical
shifts
of n-butane
formed
XPS-measurements
energies
(SEM) and chemical
for the deactivated
to 0.5% for H-Y zeolite
zeolites
through
of zeolites
of offretite
the conversion
were observed
Finally,
binding
stability
with
methods have been applied for the char29 Si-MAS NMR studies have been published
coordinated
pattern
(see Fig. 4), which
energies
Solid-state
The framework
the signal
tion of coke during
compared
propane
the of n-
contains
by up to four Al-
two different
tetrahedrally
Si-sites.
Scanning
particles
reaction
of about
conversions,
thermodynamic
and spectroscopical
of the zeolites.
whereas
with
of the catalysts
only one type of tetrahedrally
coordinated
simple
up to conversions
At higher
due to the higher
physical
acterization
for the catalyst
in Fig. 3, the disproportionation
took place as a stoichiometrically
from the suggested
preferred,
has been studied
As shown
amount
the forma-
to a different
in particular
zeolites,
the highest
were performed
elements
of coke
extent.
Coke
for the H-off-
(about 2% carbon,
to determine
cations
Si2p and 01s correspond two types
in the Nals binding to H-offretite, kinetic
in order
and the zeolite
For Na-offretite,
ion exchange
, although
unveiled
as
and 0.2% for RE-Y zeolite).
for A12p,
and the higher Auger
analysis
energy
energy
the binding
(see Table
of Na-sites
with
were disclosed
and the NaKLL Auger
only the lower photoelectron sites-remained
2). The
to those observed
occupied,
kinetic binding
in reduced
221
10
FIGURE
2
Selectivity
200 'C over different
FIGURE lite.
3
20
90 30 40 CONVERSION(*/. 1
to isobutane
vs. conversion
90
70
in the reaction
of n-butane
at
zeolites.
Yield vs. conversion
in the reaction
of n-butane
at 200 'C over H-Y zeo-
b
FIGURE
4
Scanning
electron
microqraphs
of (a) H-offretite
and
(b) deactivated
H-offretite.
H-offretite
FIGURE spectra
5
NaKL2,3L2,3
electron
for H- and Na-offretite
(AlKa-X-rays).
996.6 966.6 976.6 Auger kinetic energy (eVJ
Auger
229
amounts,
though
exchangeable a more
TABLE
(cf. Fig. 5). This observation
and exchangeable
electron-rich
Na-ions
environment
indicates
the existence
of both non-
in Na-offretite, the former being locatedin
in the zeolite
framework.
2
Binding
energies
and Auger
Catalyst
kinetic
Binding
energies
A12p
SiZp
H-Y zeolite
74.3
102.3
532.2
H-offretite
74.5
102.7
532.1
Na-offretite
74.2
102.6
531.8
Binding
energy
aReference:
energies
01s
of zeolitesa
(eV)
Nals(1)
Auger
Nals(I1)
kinetic
NaKLi,3L2,3(I)
energies
NaKL2,3L2,3(II)
1071.3 1072.5
(eV)
990.2
1071.3
987.9
of Cls = 284.6 eV, experimental
990.3
error * 0.2 eV.
CONCLUSION The isomerization fluence
of acidic
relationships tained.
results
between
the isomerization
From the examination
of reactor catalytic
testing
progress,
of zeolites.
structure
especially
Further
some useful
structure
it is concluded
methods
measurements
lattice
description
concerning
on the catalytic
(IR-
about
the in-
Further,
some
were ob-
that the combined
give a detailed
investigations
of offretite/erionite
acidity
information
of the zeolites.
test runs and the zeolite
of our results
and characterization
behaviour
of framework
have provided
sites and the framework
use
of the
the influence
activity
are under
and TPD-studies).
ACKNOWLEDGEMENTS We are indebted
to the Royal
Research
for financial
carrying
out the NMR-measurement.
support
Norwegian
Council
and to Dr. J.B.
Nagy
for Scientific (University
and
Industrial
of Namur)
for
REFERENCES : : ; 7 8 9 iy
12
M. SWcker, J. Mol. Catal., 29 (1985) 371. M. Stb'cker and B.P. Nilsen, Acta Chem. Stand. B39 (1985) 153. K. Tanabe and h. Hattori, Chem. Lett., (1976) 625. H. Hattori, 0. Takahashi, M. Takagi and K. Tanabe, J. Catal., 68 (1981) 132. M. Hino and K. Arata, Chem. Commun., (1979) 1148 and (1980) 851. M. Hino, S. Kobayashi and K. Arata, J. Am. Chem. Sot., 101 (1979) 6439. K. Arata and M. Hino, React. Kinet. Catal. Lett., 25 (1984) 143. V.L. Magnotta and B.C. Gates, J. Catal., 46 (1977) 266. G.A. Fuentes, J.V. Boegel and B.C. Gates, J. Catal., 78 (1982) 436. E.A. Crathorne, I.V. Howell and R.C. Pitkethly, U.S. Pat. 3 975 299 (1976): N.N. Kruplna, A.Z. Dorogochinskii, N.F. Meged and V.I. Shmailova, React. Klnet. Catal. Lett., 23 (1983) 273. T.M. Tri, J. Massardier, P. Gallezot and B. Imelik, J. Catal., 85 (1984) 244.
230 13 14
1: 1: 19 20 21 22
C. Bearez, F. Chevalier and M. Guisnet, React. Kinet. Catal. Lett., 22 (1983) 405. P. Hilaireau, C. Bearez, F. Chevalier, G. Perot and M. Guisnet, Zeolites, 2 (1982) 69. M. Stb'cker and J.H. &der, Finn. Chem. Lett., (1984) 159. W.C. van Zijll Langhout, Proc. 9th World Petrol. Congr., 5 (1975) 197. S.M. Csicsery, Zeolites, 4 (1984) 202. J.H. -T&der; Zeolites, 4 (1984) 311. C.A. Fyfe, G.C. Gobbi, G-J. Kennedy, J.D. ,Graham, R.S. Ozubko, W.J. Murphy, A. Bothner-By, J. Dadok and A.S. Chesnick, Zeolites, 5 (1985) 179. P. Lorenz, J. Finster, G. Wendt, J.V. Salyn, E.K. Zumadilov and V.I. Nefedov, J. Electron Spectrosc. Relat. Phenom., 16 (1979) 267. 5. Narayanan, Zeolites, 4 (1984) 231. B.A. Sexton, T.D. Smith and J.V. Sanders, J. Electron. Spectrosc. Relat. Phenom., 35 (1985) 27.
Applied Catalysis, 25 (1986) 223-230 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
ISOMERIZATION OF n-BUTANE
MICHAEL
ST6CKERa'*,
JOSTEIN
K. GREPSTADc
OVER ZEOLITES
PETER HEMMERSBACHa,
DEPENDING
ON CATALYST
STRUCTURE
JOHAN HENRIK RIEDERb'** AND
aDepartment of Petrochemistry, Center for Industrial P.O.Box 350 Blindern, N-0314 Oslo 3 (Norway),
Research,
bDepartment of Chemistry, University of Oslo, P.O.Box 1033 Blindern, N-0315 Oslo 3 (Norway) and 'National Laboratory for Surface Technology, N-7034 Trondheim-NTH
Studies (NALOS), Norwegian (Norway)
Institute
of
ABSTRACT The isomerization of n-butane in the gasphasg , catalyzed by H-Y zeolite, RE-Y zeolite, H- and Na-offretite, was studied at 200 C and atmospheric pressure. The rate of isobutane formation was found to be higher for the Y zeolites (H- and cation-Y) than for the corresponding offretites (H- and cation-offretite), indicating some sterical restrictions of the offretites due to their smaller pore sizes and possible stacking faults. The protonated zeolites showed higher rates of isobutane formation than the corresponding cation exchanged catalysts. The selectivities of the zeolites during the first 20 h of the reaction were found to exceed 75%, whereas the maximum yield of isobutane for the active catalysts was in the range of 33-43%. Several physical and spectroscopical characterization methods were applied. The appropriate crystal structures of the offretite samples were verified by X-ray diffraction measurements. Furth ore te ahedrally coordinated Si- and Al-sites were identified by solid-state sgi_ ind $5 Al-MAS NMR spectroscopy, in both the offretites and the Y zeolites. Scanning electron microscopy (SEM) and chemical analysis disclosed the formation of coke during isomerization. Finally, XPS-measurements indicate the coexistence of exchangeable and non-exchangeable Na-ions in Na-offretite, the latter being located in a more electron-rich environment in the zeolite lattice.
INTRODUCTION Several
attempts
have been made to study the isomerization
cially with regard to arrive at a compromise since this parameter years,
of different
in n-butane zeolites *Author **Present
of research
catalysts,
isomerization
as catalysts
0166-9834/86/$03.60
and, consequently,
for this type of reaction.
In recent
on the acid of super-acids
report the use of
Their discussion
is mainly
should be addressed.
Det norske Veritas,
0
the application
very few authors
P.O.Box
300, N-1322 Hijvik (Norway).
1986 Elsevier Science Publishers B.V.
espe-
temperature,
control.
in this field has been focused
[l-lo]. Furthermore,
to whom correspondence address:
the reaction
plays a vital role in product distribution
the main interest
strength
concerning
of n-butane,
based
224
. I
on kinetic arguments Little
effort
isomerization this paper,
[ll-141. has been devoted
and the application we report
H- and Na-offretite, work
structure
to the study of sterical
of shape-selective
data on the catalytic with emphasis
aspects
zeolites
behaviour
of n-butane
in this reaction.
of H-Y zeolite,
on the influence.of
acidic
In
RE-Y zeolite,
sites and the frame-
of the zeolite.
EXPERIMENTAL The synthesis ported
of the catalysts
previously
(Philips
structure
NMR spectroscopy,
The scanning
of Namur,
have been re-
was verified
the Na-offretite
by X-ray
dif-
was checked
shift of the tetrahedrally
by
coordinated
operating
at
Belgium).
micrographs
were recorded
eV) and Mg KCZ (1253.6
were obtained
on a Vacuum
on a JEOL JSM-50A
Generators
ESCALAB
instrument,
Mk II,
using AL
eV) X-rays.
AND DIiCUSSION
Isomerization
tests
The isomerization
TABLE
and the chemical
electron
and the XPS-spectra
spheric
samples
Furthermore,
to 53.9 ppm (Bruker CXP 200 NMR spectrometer,
52.1 MHz, University
RESULTS
of the offretite
PW 1710 instrument).
Al was determined
Ku (1486.6
procedure
[151.
The appropriate fraction 27 Al-MAS
and the isomerization
pressure.
of n-butane
The results
in thegasphase
was studied
of the test runs are shown
at 200 'C and atmo-
in Table
1.
1
Isomerization
of n-butane
over zeolites
at 200 'C
Reaction
Catalyst
ratesa
(lo-6 mol g-' h-l)
15.7
H-V zeolite
2.8
RE-Y zeolite H-offretite
5.3
"‘('
0.1
Na-offretite
aDetermined at 15% conversion, Na-offretite.
In addition products
to the isomerization
(propane,
isopentane
fines was not detected. isomerization
of n-butane,
and n-pentane)
As an example,
of n-butane
is shown
except
for the
disproportionation
were observed.
the time dependence
and cracking
The formation of composition
in Fig. 1 for H-Y zeolite.
of olein the
225 The rate of isobutane cation-Y) eating
some sterical
and possible higher lysts
formation
proved
than for the corresponding restrictions
stacking
faults.
rates of isobutane
to be higher
offretites
in the offretites
The protonated
formation
for the Y zeolites
(H- and cation-offretite), due to their
zeolites
(stronger
than the corresponding
smaller
(H- and indi-
pore sizes
acid sites)
cation
exchanged
showed cata-
(RE-Y and Na-offretite).
n-Butan o lsobutane l
0 Pentanes
FIGURE
Time dependence
1
of composition
in the reaction
of n-butane
at 200 'C over
H-Y zeol ite.
of the catalyzed
The mechanism
[13,16].
ly described
as the (intramolecular)
other
is described
carbenium
proceeds
ring mechanism
would
form a primary
carbenium
counts
For strongly
The product
rization cular
require
acidic
the opening
on zeolites
process
carbenium
is probably
ions as more
The
formation
In both reaction
as compared studies
because
three-membered
this energy
it involves and these
argument
ac-
n-alkanes
that n-butane
process
isome-
1131. The bimole-
the fOrWtiOn species
ring to
and hence
to that of other
indicate
by an intramolecular
intermediates,
cyclopropane
very unfavourable,
like super acids,
and kinetic
preferred
stable
dimer
to the intramolecular
of the protonated
of butane
does not occur
one normal-
ring mechanism.
promotes
ring system).
is energetically
systems,
distribution
cyclopropane which
has been extensively
can be indicated,
intermediates.
according
ion. ThSs
for the slow isomerization
11,21.
mechanism,
via a cyclopropane
of n-butane
of n-butane
patterns
protonated
ions are.thq,crucial
The isomerization
unlikely.
two reaction
as the bimolecular
(also this mechanism schemes
Typically,
isomerization
investigated
of octYT
can rearrange
easily.
226 The dimers ments,
are cracked
with a high selectivity
but the additional
Ii-offretite, however, channel
there
intersections.
than in H-Y zeolite formation cerning
makes
formation
As a consequence,
the discrete
channel
the loss of acidic be related
sites.
systems
To a minor
to the smaller
ions, Our findings ports
the reaction caused
cannot
rate is lower
extent,
The dimer
sensitive
are, of course,
this lowering
caused
of a transition-state
in H-offretite
acidities).
much more
In
state at the
con-
state.
and Na-offretite
pore sizes,
of C4-frag-
be prevented.
transition
by different
in zeolites
of the transition
The lower rates for RE-Y zeolite
may
the formation
is less space for a bimolecular
(beside differences
shape selectivity
towards
of C3- and C5-fragments
of the reaction
by the ion exchange
selectivity
mainly
due to
rates
to larger
are in line with
recent
cat-
re-
[17]. The selectivity
Y zeolites
to isobutane
(see Fig. 2) has been found
than for the offretites,
indicating
a higher
to be higher
shape
selectivity
for the in Y
zeolites. The n-butane highest
activity
butane
disproportionation (H-Y zeolite).
over H-Y zeolite
equimolar pected
ratios
of propane
probably
Characterization Several
previously
and pentanes
mechanism.
atoms,
[15,18,191.
retite
electron
other
energy. energy
microscopy
belonging
Si-sites,
25%, as exformation
is
of the C3-fragment.
to the Y-group
surrounded
showed
of the framework
After
obtained [20-221.
chemical
shifts
of n-butane
formed
XPS-measurements
energies
(SEM) and chemical
for the deactivated
to 0.5% for H-Y zeolite
zeolites
through
of zeolites
of offretite
the conversion
were observed
Finally,
binding
stability
with
methods have been applied for the char29 Si-MAS NMR studies have been published
coordinated
pattern
(see Fig. 4), which
energies
Solid-state
The framework
the signal
tion of coke during
compared
propane
the of n-
contains
by up to four Al-
two different
tetrahedrally
Si-sites.
Scanning
particles
reaction
of about
conversions,
thermodynamic
and spectroscopical
of the zeolites.
whereas
with
of the catalysts
only one type of tetrahedrally
coordinated
simple
up to conversions
At higher
due to the higher
physical
acterization
for the catalyst
in Fig. 3, the disproportionation
took place as a stoichiometrically
from the suggested
preferred,
has been studied
As shown
amount
the forma-
to a different
in particular
zeolites,
the highest
were performed
elements
of coke
extent.
Coke
for the H-off-
(about 2% carbon,
to determine
cations
Si2p and 01s correspond two types
in the Nals binding to H-offretite, kinetic
in order
and the zeolite
For Na-offretite,
ion exchange
, although
unveiled
as
and 0.2% for RE-Y zeolite).
for A12p,
and the higher Auger
analysis
energy
energy
the binding
(see Table
of Na-sites
with
were disclosed
and the NaKLL Auger
only the lower photoelectron sites-remained
2). The
to those observed
occupied,
kinetic binding
in reduced
221
10
FIGURE
2
Selectivity
200 'C over different
FIGURE lite.
3
20
90 30 40 CONVERSION(*/. 1
to isobutane
vs. conversion
90
70
in the reaction
of n-butane
at
zeolites.
Yield vs. conversion
in the reaction
of n-butane
at 200 'C over H-Y zeo-
b
FIGURE
4
Scanning
electron
microqraphs
of (a) H-offretite
and
(b) deactivated
H-offretite.
H-offretite
FIGURE spectra
5
NaKL2,3L2,3
electron
for H- and Na-offretite
(AlKa-X-rays).
996.6 966.6 976.6 Auger kinetic energy (eVJ
Auger
229
amounts,
though
exchangeable a more
TABLE
(cf. Fig. 5). This observation
and exchangeable
electron-rich
Na-ions
environment
indicates
the existence
of both non-
in Na-offretite, the former being locatedin
in the zeolite
framework.
2
Binding
energies
and Auger
Catalyst
kinetic
Binding
energies
A12p
SiZp
H-Y zeolite
74.3
102.3
532.2
H-offretite
74.5
102.7
532.1
Na-offretite
74.2
102.6
531.8
Binding
energy
aReference:
energies
01s
of zeolitesa
(eV)
Nals(1)
Auger
Nals(I1)
kinetic
NaKLi,3L2,3(I)
energies
NaKL2,3L2,3(II)
1071.3 1072.5
(eV)
990.2
1071.3
987.9
of Cls = 284.6 eV, experimental
990.3
error * 0.2 eV.
CONCLUSION The isomerization fluence
of acidic
relationships tained.
results
between
the isomerization
From the examination
of reactor catalytic
testing
progress,
of zeolites.
structure
especially
Further
some useful
structure
it is concluded
methods
measurements
lattice
description
concerning
on the catalytic
(IR-
about
the in-
Further,
some
were ob-
that the combined
give a detailed
investigations
of offretite/erionite
acidity
information
of the zeolites.
test runs and the zeolite
of our results
and characterization
behaviour
of framework
have provided
sites and the framework
use
of the
the influence
activity
are under
and TPD-studies).
ACKNOWLEDGEMENTS We are indebted
to the Royal
Research
for financial
carrying
out the NMR-measurement.
support
Norwegian
Council
and to Dr. J.B.
Nagy
for Scientific (University
and
Industrial
of Namur)
for
REFERENCES : : ; 7 8 9 iy
12
M. SWcker, J. Mol. Catal., 29 (1985) 371. M. Stb'cker and B.P. Nilsen, Acta Chem. Stand. B39 (1985) 153. K. Tanabe and h. Hattori, Chem. Lett., (1976) 625. H. Hattori, 0. Takahashi, M. Takagi and K. Tanabe, J. Catal., 68 (1981) 132. M. Hino and K. Arata, Chem. Commun., (1979) 1148 and (1980) 851. M. Hino, S. Kobayashi and K. Arata, J. Am. Chem. Sot., 101 (1979) 6439. K. Arata and M. Hino, React. Kinet. Catal. Lett., 25 (1984) 143. V.L. Magnotta and B.C. Gates, J. Catal., 46 (1977) 266. G.A. Fuentes, J.V. Boegel and B.C. Gates, J. Catal., 78 (1982) 436. E.A. Crathorne, I.V. Howell and R.C. Pitkethly, U.S. Pat. 3 975 299 (1976): N.N. Kruplna, A.Z. Dorogochinskii, N.F. Meged and V.I. Shmailova, React. Klnet. Catal. Lett., 23 (1983) 273. T.M. Tri, J. Massardier, P. Gallezot and B. Imelik, J. Catal., 85 (1984) 244.
230 13 14
1: 1: 19 20 21 22
C. Bearez, F. Chevalier and M. Guisnet, React. Kinet. Catal. Lett., 22 (1983) 405. P. Hilaireau, C. Bearez, F. Chevalier, G. Perot and M. Guisnet, Zeolites, 2 (1982) 69. M. Stb'cker and J.H. &der, Finn. Chem. Lett., (1984) 159. W.C. van Zijll Langhout, Proc. 9th World Petrol. Congr., 5 (1975) 197. S.M. Csicsery, Zeolites, 4 (1984) 202. J.H. -T&der; Zeolites, 4 (1984) 311. C.A. Fyfe, G.C. Gobbi, G-J. Kennedy, J.D. ,Graham, R.S. Ozubko, W.J. Murphy, A. Bothner-By, J. Dadok and A.S. Chesnick, Zeolites, 5 (1985) 179. P. Lorenz, J. Finster, G. Wendt, J.V. Salyn, E.K. Zumadilov and V.I. Nefedov, J. Electron Spectrosc. Relat. Phenom., 16 (1979) 267. 5. Narayanan, Zeolites, 4 (1984) 231. B.A. Sexton, T.D. Smith and J.V. Sanders, J. Electron. Spectrosc. Relat. Phenom., 35 (1985) 27.