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v ratio on the phase composition and catalytic activity of vanadium phosphate based catalysts
231
Applied Catalysts, 6 (1983) 231-244 Elsevier Science Publishers B.V., Amsterdam
INFLUENCE
- Printed in The Netherlands
OF P/V RATIO ON THE PHASE COMPOSITION
VANADIUM
PHOSPHATE
B.K. HODNETTa,
AND CATALYTIC
Ph. PERMANNE
Groupe de Physico-chimie
OF
and 8. OELMON
Min&ale
et de Catalyse,
Universite
Louvain,
Place Croix du Sud 1, B-1348 Louvain-la-Neuve,
aPresent
address:
Ontario,
ACTIVITY
BASED CATALYSTS
Oepartment
of Chemistry,
University
Catholique
de
Belgium. of Waterloo,
Waterloo,
Canada N2L 361.
(Received
10 November
1982, accepted
15 March
1983)
ABSTRACT The influence of the bulk P/V ratio of V-P-O catalysts on their phase composition, surface P/V ratio and catalytic activity for n-butane partial oxidation is reported. Catalysts were prepared by reduction of V2O5 in lactic acid followed by addition of o-H3P04. Excess lactic acid was evaporated off and the solid precursor calcined in air at 773 K. The bulk P/V ratio was varied in the range 0.94 to 1.07. This range was sufficient to bring about large variations in the nature of the final catalvst obtained. Catalvsts with low P/V ratios formed as BVPO5 with vanadium in the +5 oxidation siate. Those with high P/V ratios formed in a phase which we label B in which vanadium was in the +4 oxidation state. Scanning electron microscopy indicated that the catalysts increased in crystallinity as the P/V ratio decreased and EPMA indicated that the P/V ratio was homogeneous throughout each catalyst. Overall conversion of n-butane was at a maximum for P/V close to unity whereas selectivity was highest for the highest P/V ratio studied . The XPS study indicated that the surface P/V ratio did not change in the range of bulk compositions in which selectivity increased from ca. 10 to 50%. Arguments are presented which suggest that it is the solid state properties of these catalysts which largely determine selectivity and that the primary interaction of the hydrocarbon occurs with the aid of a V+5 related surface phase.
INTRODUCTION Whereas originated
in the past most of the world's from benzene,
costly and recent years describing
maleic
phosphate
patented
material
clearcut
understanding
many studies or phases,
and the growing
through
11, 21. industrial
of maleic
growth
has
in the number of patents
n-butane
However,
or butene oxidation
of selective to this problem
of this process,
oxidation has
has been placed on trying
no
on this catalyst
been attempted.
to identify which
are active or selective
0 1983 Elsevier Science Publishers B.V.
over
in spite of the bulk of
importance
of approaches
in these catalysts,
anhydride
have made this process more
of the mechanism
a strong emphasis
present
0166-9834/83/$03.00
synthesis
based catalysts
A variety
production
developments
have seen an enormous
anhydride
vanadium
has emerged.
economic
In phase
for this reaction
232 [ 3-71 .
Some of these phases,
such as aVPO5 18, 101 (with principal
d spacings
in
at 3.57, 3.07 and 3.01), BVP05 [9, 101 (d = 3.48, 3.40 and 3.07) and (VO)2P2O7 [lOI
(d = 3.87, 3.14 and 2.99) have already
activity
has sometimes
a'VPO5 [lo]
been assigned
been fully determined,
to less well determined
(d = 3.10, 3.00 and 1.96), a phase simply
3.07 and 3.00) which appears
identical
but catalytic
phases
labelled
such as
X [61
(d = 3.57,
to nVPO5 [8] or a phase labelled
6 [3,4]
(d = 3.90, 3.13 and 2.99) which Trifiro
et al.have
the R phase [ll] structure
to it.
(VO)2P207
[ 101.
seems to contain a mixture of V+4 and V+5. +4 the V containing part of this B phase [3, 41 as
labelled
(d = 3.87, 3.14 and 2.98) and have assigned On the other hand, Bordes
for catalysts
poorly crystalline
material
The oxidation
heating
in air.
Some workers neous catalysts must become
calcined
at 773 K.
with principal
state of vanadium
involved
state [9] and the other such as (V0)2P207,with studies
has suggested
anhydride
have emphasized
determining
selectivity
selectivity
by stabilizing
a large concentration
the importance
is in its +5 oxidation
vanadium
in the +4 oxidation
indicated
that there is a good
the +4 oxidation
of V+4 favours
selectivity oxidation
for butene partial
process
Our approach catalysts
involved
solid state chemistry vanadium addition, measured
has been to prepare
with
vanadium
that Naka-
that the
phosphate
in the range 0.94 to 1.07.
known crysthllographic
states of vanadium.
in n-butane
but
devoid of Vt5 showed lower
the P/V ratio to a small rBnge we hoped to prepare
terised oxidation
It appears
process
oxidation.from which they concluded +5_v+4 redox couple.
to this problem
could readily be compared
activity
totally
oxidation
ratio in to enhance
the V
with P/V ratios which varied
to restrict
state of vanadium.
the selective
mura et al. [13] have shown that catalysts
interconvension
of the P/V atomic
High P/V ratios are reported
[13, 141.
that
is the interface
fit at the interface between these two phases thus facilitating +5_v+4 between the V redox couple. Some studies
on heteroge-
states of vanadium
Thus Bordes
to maleic
one such as gVPO5,in which vanadium
crystallographic
in
into @VP05 upon
oxidation
least two oxidation
in the process [7, 10, 131.
Detailed
it forms
6' [12].
have taken the view that since selective is a redox process,at
has been observed
In general
d values at 4.67, 4.07, 3.14 and
This phase will thus be labelled
two phases;
state [lo].
B phase (111 with
is +4 and it transforms
the "active phase" for l-butene oxidation between
the
In addition, another phase of V-P-O catalysts
in this laboratory
2.52.
has equated
a tripolyphosphate
oxidation
and the results
properties,
and the homogeneity
These catalysts
notably
were tested
are compared
phese composition,
by XPS, were also studied.
principally
catalysts
which
phases with well charac-
of the P/V ratio throughout
some surface properties,
based
By choosing
for catalytic
with some of their oxidation
the samples.
the surface
state of In
P/V ratio, as
233 EXPERIMENTAL Preparation
of catalysts
The catalysts
used in this work were prepared
150 grams of lactic acid in water and stirring
by adding
9.1 grams of V205 to
the resulting
suspension
at
reflux for 16 hours, at which stage a blue solution, characteristic of the for+4 complex, had developed. Thereafter the appropriate amount of 85% mation of V H3P04 in water was added and this solution The solvent was then
4 hours.
solid material
which
remained
were prepared
and the
about by the finely
divided
and sieved, with those particles
the range 0.035 to 0.5 mm being retained catalysts
stirring
at 773 K for 16 hours in air. In
drops brought
it was pellitized,broken
at reflux for a further
off with constant
was calcinated
order to avoid very high pressure solid obtained,
was stirred
evaporated
for catalytic
in this way with P/V atomic ratios
in
In all,five
testing.
in the range 0.94
to
1.07.
Characterization X-ray diffractograms
of fresh and worked
Philips
X-ray diffractometer
filtered
through
Surface
by double
areas were determined
oxidation
titration
by the BET method
using nitrogen
as adsorbate
state of vanadium
against
KMn04.
in 100 ml of 2M H2SO4 at 350 K.
to Vt4
of FeS04(NH4)2S04
(equation
(a t b t c) Vt5 An excess
2).
to ferric [15]. 3) gave a measure (a t b t c) Vt4 The average
using a radiation
About
with the aid of a SETARAM
(AV) in the catalysts
+
was cooled +
Thereafter
was the quantitative
a second titration
oxidation
(a t b t c)e-
+
of all the Vt5
to close to 273K in ice water.
t4 (a t b t c) V
of the total vanadium -
(1) reduction
t Fe
t2
was then added to the cool solution.
which occured
was dissolved
was thus carried out +4 in the of all Vt3 and V
was then added to achieve
(a t b t c)e-
was determined
100 mg of each catalyst
The first titration
The solution
of (NH4)2S208
the only reaction
using Cub
at 77 K.
(volume 1) which effectively involved the oxidation +5 solution to V i.e. +3 +5 * (a t b t c) Vt5 + b Vt4 + cv aV An excess
were recorded
counter
nickel.
MLB 10-8 microbalance The average
catalysts
with Geiger-MBller
in excess
(2)
In these conditions
oxidation
of ferrous
ions
(volume 2) with KMn04 (equation
content
of the solid.
(a t b t c) Vt5
state of vanadium
(3)
(AV) was calculated
after equation
4
t131.
A,, =
3a + 2b + C = at
btc
5
(2a t b) atbtc
=
5 _ Volume
1
Volume 2
(4)
234 XPS measurements a signal averager sided adhesive
were carried
out using a V.G. ESCA 3 apparatus
(TRACOR NORTHERN
tape.
Excitation
energies were referenced
TN 1710).
Samples
equipped
were supported
was with the AlKo line (1486.6 eV).
to the CIs line (B.E. 285 eV).
with
on double Binding
The spectra
of CIs,
were recorded in this sequence for each sample studied. 02s' P2p' "2s and c1s Tbe relative intensities,i.e. the P/V ratio,were taken as the simple relation between the areas under the P For the electron
microscopy
2P
with a KEVEX E.D.S. was used. (STEM) facilities analysis
provided
of thin electron
and the V2s peaks. study, a JEOL 100 CX TEMSCAN The Scanning
Transmission
a highly focussed transparent
electron
microscope
Electron
equipped
Microscope
probe which made possible
samples with a resolution
of ca. 20 nm.
In general, the local P/V ratios of areas of the catalysts of diameter 0.1 to 1 um were checked
by Electron
Probe Micro Analysis
(EPMA) at ca. 50 different
spots for each sample.
Catalytic
activity
: apparatus and measurement
procedures
RF
G.C. -a R
Apparatus
Figure 1 R:
M
reactor;
The apparatus of the various n-butane
ment
outlinedhereabove
vanadium
phosphate
flow reactor
the catalyst
(R).
was packed
of the temperature
catalyst
BI_7
was outgassed
: valves;
: rotaflowmeter
to maleic anhydride.
differential which
RF
within
;
: 6-way injection valves;
: gas chromatograph.
was used to measure catalysts
, 03 ‘& . : 8s .
tests.
VI-2
G.C.
86
B7 . .
used to carry out catalytic
: gas mixer;
: flowmeters; Fl-2
,
the catalytic
for the partial
A charge of 3 grams of catalyst This reactor and featured the catalyst
consisted
a thermowell bed.
activities
oxidation
of
was placed
of a Pyrex U-tube which allowed
In normal operation,
in situ for 16 hours at 723 K, cooled to the
in the into
measurethe
reaction
235 temperature
(673 K) and then sealed off from the remainder
means of the 3 way valves BI and B2.
of the system by
Feed gases for the reaction,
comprising
1.3 vol % n-butane in air,were composed as follows : a large flow of air (1500 -1 ml min ) was established via valve B4 and,with B7 closed,this flow was vented to the atmosphere
via B6.
value, the required measured
When this gas flow had stabilized
flow of n-butane
at the desired
(19.5 ml min-') was set via B3 and
with the aid of the calibrated
rotaflowmeter
(RF).
Finally,
any
desired
part of this gas mixture could be flowed through the reactor via B7. -1 A flowrate of 90 ml min , corresponding to a gas hourly space velocity (GHSV) of 4680 hr-', was used throughout be checked suitable
this study.
The composition
by means of the G.C. system prior to its exposure
manipulation
Analysis
products
using an INTERSMAT
rometer
detector
reactor
with the chromatograph
was carried
one of two 6-way valves.
gas.
of reaction
Gases were injected
via
The first of these led to a 0.5 m x 2 nnn stainless
components
Oil 500 on chromosorb
was separated
the
steel and this was heated
products.
and flowed
on which
from all other
n-butane
was separated
into one cell of the detectors.
The second 6-way valve led to a 2 m x 4 mm stainless 20% Silicon
gas
fitted with a kata-
The piping which connected
was of 4 mm stainless
packed with PORAPAK Q, 80-100 mesh,
from all other gaseous
out by means of on-line
IGC 1214 gas chromatograph
using helium as carrier
at 100°C to avoid condensation
steel column
by
of BI and B2.
of the reaction
chromatography
of the gas could to the catalyst
steel column
packed with
WHP, 80-100 mesh, on which maleic
reaction
products.
These
separations
anhydride were carried
out at 368 K. In what follows, Y
=
yield % (Y) in maleic
No of moles of product No of moles of reactant
Conversion c
=
=
is defined
as
x 100
introduced
% (C) as
N" of moles of reactant
consumed
N" of moles of reactant
introduced
and selectivity s
anhydride
formed
(Y/C)
% (S) in maleic
anhydride
x 100
as
x 100
RESULTS X-ray diffractograms measured
directly
of the catalysts
after calcination
values of AV and specific presented
in table
1.
surface
with P/V ratios
are presented areas, measured
before
These data show the influence
P/V ratio on the composition
of the final catalyst
of 0.97 and 1.07
in figure
2.
In addition,
catalytic
of slight
testing,are
changes
and on its textural
in the proper-
236 ties.
Thus it can be clearly
phosphorus
seen from figure 2 that a slight deficiency
from the stoichiometric
crystallised phosphorus
1:l ratio promoted
phase with AV of ca. +5. strongly
stabilized
Figure 2
TABLE
state of vanadium
of a material
in
of a well
On the other hand, a slight excess
the +4 oxidation
nation at 773 K and led to the formation diffraction
the formation
during
of calci-
with very broad X-ray
lines.
X-ray diffractograms
of catalysts
with P/V of 0.97 and 1.07
1
Measured
values
and phases
of AV, before and after catalytic
P/V ratio AV before
testing,
specific
surface
present
testing
AV after
testing
S ecific m 5 g-1
surface
Phases present testing
area
0.94
0.97
1.0
1.03
1.07
4.97
4.90
4.86
4.39
4.04
4.98
4.92
4.90
4.59
4.24
2.7
5.6
9.6
4.9
4.9
t3VP05
;v,o,
Bn BVP05
iVPO5
w
before BVPO5
W
area
237 The results Measurements recorded
of the catalytic
at 673 K are presented
rature were
subject
across
measurements
However
the whole temperature in selectivity
for the catalyst
here since measurements
the general
range.
and yield
in figure 3.
Only those data
made above this tempe-
of maleic
trends observed
anhydride
were
on the
identical
The data recorded at 673 K show that a
for maleic
with the highest
the lowest P/V ratio
are presented
range 663 to 703 K.
to errors due to decomposition
walls of the reactor.
maximum
activity
were made in the temperature
anhydride
formation
was observed
P/V ratio tested and that the catalyst
(0.94) exhibited
with
zero selectivity.
P/V RATIO
Figure 3
Influence
(S) for maleic
By contrast, products
in overall
for intermediate
in surface areas
some oxidation
lines from catalysts
favour of SVPO5.
testing occured
catalysts
during
in the relative
recorded
tures as high as 703 K.
changes
to move towards
small changes were observed
of n-butane
P/V ratios.
By contrast,
P/V ratios less than unity. changes,tending
conversion
after catalytic
The data reveal that no significant
ting theoccurrenceof
(Y) and selectivity
to all reaction
This maximum
coincided
with
(table 1).
The values of AV measured
signficant
(C), yield
formation.
the maximum
was observed
the maximum
of P/V ratio on conversion
anhydride
after testing
are presented
in table 1.
in AV for catalysts
having
with P/V > 1 exhibited
higher values
for AV,thereby
the testing. intensities
In addition,
indicasome
of X-ray diffraction
for catalytic
activity
to tempera-
In general these showed a loss of the 6' phase in
238 The data presented tivity
in maleic
diffractograms
in figure 4 represent
anhydride
formation
before testing
used because
it was thought
tions during
testing
tions observed
an attempt
with the phases observed
for catalytic
activity.
that these were more
probably
occured
the selec-
in the X-ray
These diffractograms
representative
at 673 K, since the small changes
after testing
to correlate
were
of the composi-
in AV and phase composi-
at the highest temperatures
used.
WV RATIO
Influence
Figure 4 @PO6
of P/V ratio on the relative
(0) and (upper traces) AV before
curve marked
S replots
the selectivity
amounts
(a) and after
of the 13" phase
(0) catalytic
data of figure
(O),
testing.
3 for comparison
The
(same
scale).
However
the general
recorded after
trend was not affected
catalytic
testing.
in the X-ray diffractograms amount of each phase
selectivity
could
and a maximum Electron catalytic revealed
were taken directly For comparison
present.
and after testing,are
activity
these curves with data
of figure 4, the peak heights
as a relative measure
of the
the values of AV, measured
before
Thus the maximum in on the same diagrams. 4+ oxidation state present V with a maximum in
also presented
be correlated
in the phase labelled
microscopic
by plotting
For the purpose
examination
confirmed
6" in figure
2.
of these materials
the findings
that as the P/V ratio increased,
before
testing
of the X-ray diffraction the crystallinity
for
study and
of the catalysts
239
Figure 5
Scanning
electron
micrograph
of the catalyst
with P/V = 0.94
Figure 6
Scanning
electron
micrograph
of the catalyst
with P/V = 0.97
240
Fiqure 7
Scanninq
electron
microqraph
of the catalyst
with P/V = 1.03
Fiqure 8
Scanning
electron
micrograph
of the catalyst
with P/V = 1.07
241 As shown in figure 5, the catalyst
decreased.
large particles
of a well crystallized
(figures 6 - 8), the amount extent
samples
material
were almost
Measurements
A summary presented
the different
of the ratio of intensities
in figure
these catalysts ;
below
9.
remained
relatively
presence
of any V2O5 in this catalyst.
layers,but
of the XPS study,the
at the extremes
It should
(greater than of
did not reveal the
be pointed
out here that for to cover the
the shape of the curve in figure 9. However i.e. those with P/V ratios of 0.9 and
activity.
a9
l.0
1
PNRATIO Influence
each catalyst
in the proportion
P/V ratio used was expanded
of the range,
1.1, were not tested for catalytic
increase
the X-ray diffractograms
range 0.9 to 1.1 in order to confirm
Figure 9
throughout
present.
of the PZp and the VZs XPS lines is
this value there was a drastic
06
that for all the
stable for high P/V ratios
in the surface
the samples
to such an
These data show that the P/V ratio at the surface of
vanadium
the purposes
increased
absent from the catalyst
by EPMA revealed
types of particles
of
but as the P/V ratio increased,
crystallized
particles
P/V ratio.
with P/V = 0.94 consisted
of the series the P/V ratio was homogeneous
and throughout
0.97)
of poorly
that well crystallized
with the highest
material
(BULK)
of the bulk P/V ratio on the ratio of the PZp to VZs XPS
peaks.
DISCUSSION Influence
of P/V ratio on phase composition
A striking
feature of the results
ratio was restricted catalysts
obtained
ratios favoured
presented
to a small range,its
and their catalytic
the formation
above is that,although
influence
activity
the P/V
on the nature of the final
was very pronounced.
of BVPO5 [9] with AV values
close to +5.
Low P/V On the
242 other hand, high P/V ratios favoured B"[ 12] and AV values close to +4. with P/V = 1.07 was composed Little
information
rial with a similar were not presented transforms strongly
XRD pattern
dependent
after calcination
influence
at 773 K[12j
The phase labelled
study confirmed
of calcination of reducing
mation or otherwise
agent,
B phase
13, 41&
In this
phase
The
of the SW phase as of this phase as
elsewhere
1121.
The
i.e. lactic acid, HCl or oxalic acid, on the for-
of the 0' phase is not yet fully understood.
The XPS data indicate
that some surface enrichment
samples with P/V ratios of less than about 0.97.
in vanadium
However
tion factors
( 17j , a surface P/V ratio of 2.4 was observed in the plateau Large errors
i.e. above 0.97.
vanadium
on the surface
ions on the surface,
in view of the uncertainties
are often associated
associated
between
Following
the arguments
outlined
position between
during
testing
selectivity
at 673 K.
for maleic
observed mostly
for catalysts
1181.
However
this aspect
activity presented
in figures
which did not change markedly
strong correlation
anhydride
phase and V+4 in these catalysts.
was
below.
above the results
A
this type
of individual
their selectivity
with these calculations,
P/V ratio and catalytic
and 4 can be taken to refer to catalysts
with
that phosphorus
to bring about isolation
thus increasing
of the results will not be pursued further
Relationship
cross section photoioniza-
but these data could be an indication
acting as a diluent
for
inten-
116 1 were calculated
of calculation
using the Scofield
occured
when absolute
sity values
region,
1111
work, only at 773 K.
of the evolution
will be presented
is
it is not observed
the poor crystallinity
conditions
and slowly
appearance
Its
after calcination
Full details
A mate-
but full details
precursor
.
in such circumstances.
by its XRD pattern.
a function
from an amorphous
of this phase were observed
microscopy
indicated
previously,
the P/V ratio, but in general,
above 873 K.
of the catalyst
of this material.
has been reported
calcination
[lo] is observed
trace amounts electron
upon
of a phase which we label
as to the nature of the 6' phase.
It originates
into 4VP05 during
or (VO)2P2O7
almost entirely
is available
[ 61 .
the formation
The X-ray diffractograms
formation
Conversely
was thus observed
and the presence
a minimum
3
in com-
of the BW
in selectivity
was
with P/V ratios less than 1, i.e. which were composed
of 6VPO6.
The very poor selectivity understood
of the catalyst
in terms of the XPS data.
point where a marked
drop in surface
much more pronounced
than the corresponding
surface enrichment selectivity
in vanadium
with P/V = 0.94 can be further
This composition
P/V ratio was observed. diminution
would be expected
since it is phosphorus
coincides
which
This drop was
in bulk P/V ratio. Any
to strongly
is believed
with the
decrease
the
to render these catalysts
243 selective 1191,
an opinion
which
is fully confirmed
by our data for catalysts
with P/V > 1. A feature most,
of these results
i.e. between
variant,
within
P/V = 0.97 to 1.07,the
experimental
ratio is a necessary phosphate
are apparent
that the oxidation
influenced
by excess
the V+4 [17,
condition
surface
contention
phosphorus
in-
plateau
for a selective
P/V
vanadium
i.e. since excess
ratio in the P/V range where
phosphorus
inhibits
inhibits
reoxidation
lysts and strongly Reports
in the patent is the B phase
that selective
maleic
literature
[ 3, 41.
anhydride
phosphorus
strongly.
energies
changed
formation
of the catalysts of excess
It has been shown else-
of the bulk of these cata-
of the bulk of reduced
catalysts [ 20] .
that the active phase in V-P-O
The results
presented
here would
from n-butane
to this phase since the 6' phase was also selective.
amorphous
phases
have been reported
indicate
is not a property
exclusive
of V-P-O catalysts
catalysts.
selectivity
of the influence
the reduction
This
for the V2s and V2p peaks calcined
of the system.
indicate
stabilizes
selectivity
with bigh P/V ratios must have been a consequence
that excess
but
it can be
an invariant
that the increased
on the solid state chemistry
at the surface Secondly,
P/V ratio indicated
in this P/V range for freshly indicated
composition.
at the surface was not strongly
surface
is borne out by the XPS binding
phosphorus
surface
become concentrated
state of vanadium
bulk phosphorus,
These consideraions
catalysts
changed
(XPS) remained
into the bulk of the catalyst.
191 state the invariant
which were unchanged
where
P/V ratio
as a result of the invariant
little of the excess
vi5/C4
surface
Thus it seems that a certain
but not sufficient
must have been incorporated argued
error.
selectivity
based catalyst.
Two factors Firstly,
is that in the range where
Indeed reduced
in the literature
[ 111 .
Thus what would or otherwise the surface indicating
seem important is not the exact phase involved but the presence +4 . However the arguments presented above would indicate that of V
layers of the catalysts that the direct
of the catalyst excess
are in a fairly oxidized condition thus +5 phase. interaction occured with a V The AV value
could be seen as a consequence
phosphorus
which controls
the mobility
of the stabilizing of oxygen
anions
effect
through
of the
lattice [ 20] . An interesting version
feature
of n-butane
correlated
was observed
with a maximum
and their reducibility determines
overall
lattice oxygen
of these results
in
for intermediate
specific
by hydrogen
activity
P/V ratios.
in overall
This finding
[20].
indicates
of the catalyst
con-
This maximum
surface area for these samples
is the ability
in a non-selective
is that the maximum
(table 1)
that what
to give up its bulk
way such as it does in reacting
with hydrogen.
In summary, the results of this study indicate that it is not only the B phase which can be selective
for maleic
anhydride
formation.
The Bw phase is
244 also selective. catalytic
However
conditions,
direct interaction with the hydrocarbon may occur, in +5 with a V phase on the surface of these catalysts. Thus
the AV values shown by the catalysts
are the result of the influence
phosphorus surface
on the solid state processes, i.e. reduction-oxidation. +5 +4 ratios were effected by changes P/V ratio nor the V /V
for the bulk of these catalysts Further
details
selectivity
in the range where selectivity
of the mode of action of excess
will be presented
phosphorus
of excess Neither
the
in the former
was changed
in determining
most. the
soon.
ACKNOWLEDGEMENTS One of us (B.K. HODNETT) Politique
Scientifique"
for running
the scanning
wishes
(Belgium) electron
to thank the "Service de Programmation for a fellowship. micrographs
We also thank Michel
de la Genet
and for help with the XPS measure-
ments.
REFERENCES 1 2 3 4 5 6 7 8 9 10 lla b 12 13 14 15 16 17 18 19 20
K. Wohlfahrt and G. Emig, Hydrocarbon Processing, (1980) June, 83 D.A. De Maio, Chemical Engineering, 87(10) (1980) 104 R.A. Mount and H. Rafelson, US Patent B 330.354 (1975) R.A. Schneider, US Patent 3.864.280 (1975) Chevron Research, Dutch Patent 7.308.517 (1973) Imperial Chemical Industries, Belgian Patent 867.189 (1978) E. Bordes and P. Courtine, J. Catal., 57 (1979) 236 B. Jordon and C. Calvo, Can. J. Chem., 51 (1973) 2621 R. Gopal and C. Calvo, J. Solid State Chem., 5 (1972) 432 E. Bordes, Thesis, Universite de Technologie de Compiegne (1979) G. Poli, I. Resta, 0. Ruggeri and F. Trifiro, Appl. Catal., 1 (1981) 395 G. Poli, 0. Ruggeri and F. Trifiro, 9th Intl Symp. Reactivity of Solids, Cracow (1980) 512 B.K. Hodnett and B. Delmon, unpublished results M. Nakamura, K. Kawai and Y. Fujirawa, J. Catal., 34 (1974) 345 G. Centi, F. Trifiro, A. Vaccari, G.M. Pajonk and S.J. Teichner, Bull. Sot. Chim. Fr., (1981) I-293 A.I. Vogel, Quantitative Inorganic Analysis, Longman (London) (1962) p. 646 J.C. Vedrine, Analusis, 9 (1981) 199 J.H. Scofield, J. of Electron Spectrosc. and Related Phenom., 8 (1976) 129 J.L. Callahan and R.K. Grasselli, A.I.Ch.E., 9 (1963) 755 M. Ai, Bull. Chem. Sot. Japan, 43 (1970) 3490 B.K. Hodnett and B. Delmon, submitted for publication
Applied Catalysts, 6 (1983) 231-244 Elsevier Science Publishers B.V., Amsterdam
INFLUENCE
- Printed in The Netherlands
OF P/V RATIO ON THE PHASE COMPOSITION
VANADIUM
PHOSPHATE
B.K. HODNETTa,
AND CATALYTIC
Ph. PERMANNE
Groupe de Physico-chimie
OF
and 8. OELMON
Min&ale
et de Catalyse,
Universite
Louvain,
Place Croix du Sud 1, B-1348 Louvain-la-Neuve,
aPresent
address:
Ontario,
ACTIVITY
BASED CATALYSTS
Oepartment
of Chemistry,
University
Catholique
de
Belgium. of Waterloo,
Waterloo,
Canada N2L 361.
(Received
10 November
1982, accepted
15 March
1983)
ABSTRACT The influence of the bulk P/V ratio of V-P-O catalysts on their phase composition, surface P/V ratio and catalytic activity for n-butane partial oxidation is reported. Catalysts were prepared by reduction of V2O5 in lactic acid followed by addition of o-H3P04. Excess lactic acid was evaporated off and the solid precursor calcined in air at 773 K. The bulk P/V ratio was varied in the range 0.94 to 1.07. This range was sufficient to bring about large variations in the nature of the final catalvst obtained. Catalvsts with low P/V ratios formed as BVPO5 with vanadium in the +5 oxidation siate. Those with high P/V ratios formed in a phase which we label B in which vanadium was in the +4 oxidation state. Scanning electron microscopy indicated that the catalysts increased in crystallinity as the P/V ratio decreased and EPMA indicated that the P/V ratio was homogeneous throughout each catalyst. Overall conversion of n-butane was at a maximum for P/V close to unity whereas selectivity was highest for the highest P/V ratio studied . The XPS study indicated that the surface P/V ratio did not change in the range of bulk compositions in which selectivity increased from ca. 10 to 50%. Arguments are presented which suggest that it is the solid state properties of these catalysts which largely determine selectivity and that the primary interaction of the hydrocarbon occurs with the aid of a V+5 related surface phase.
INTRODUCTION Whereas originated
in the past most of the world's from benzene,
costly and recent years describing
maleic
phosphate
patented
material
clearcut
understanding
many studies or phases,
and the growing
through
11, 21. industrial
of maleic
growth
has
in the number of patents
n-butane
However,
or butene oxidation
of selective to this problem
of this process,
oxidation has
has been placed on trying
no
on this catalyst
been attempted.
to identify which
are active or selective
0 1983 Elsevier Science Publishers B.V.
over
in spite of the bulk of
importance
of approaches
in these catalysts,
anhydride
have made this process more
of the mechanism
a strong emphasis
present
0166-9834/83/$03.00
synthesis
based catalysts
A variety
production
developments
have seen an enormous
anhydride
vanadium
has emerged.
economic
In phase
for this reaction
232 [ 3-71 .
Some of these phases,
such as aVPO5 18, 101 (with principal
d spacings
in
at 3.57, 3.07 and 3.01), BVP05 [9, 101 (d = 3.48, 3.40 and 3.07) and (VO)2P2O7 [lOI
(d = 3.87, 3.14 and 2.99) have already
activity
has sometimes
a'VPO5 [lo]
been assigned
been fully determined,
to less well determined
(d = 3.10, 3.00 and 1.96), a phase simply
3.07 and 3.00) which appears
identical
but catalytic
phases
labelled
such as
X [61
(d = 3.57,
to nVPO5 [8] or a phase labelled
6 [3,4]
(d = 3.90, 3.13 and 2.99) which Trifiro
et al.have
the R phase [ll] structure
to it.
(VO)2P207
[ 101.
seems to contain a mixture of V+4 and V+5. +4 the V containing part of this B phase [3, 41 as
labelled
(d = 3.87, 3.14 and 2.98) and have assigned On the other hand, Bordes
for catalysts
poorly crystalline
material
The oxidation
heating
in air.
Some workers neous catalysts must become
calcined
at 773 K.
with principal
state of vanadium
involved
state [9] and the other such as (V0)2P207,with studies
has suggested
anhydride
have emphasized
determining
selectivity
selectivity
by stabilizing
a large concentration
the importance
is in its +5 oxidation
vanadium
in the +4 oxidation
indicated
that there is a good
the +4 oxidation
of V+4 favours
selectivity oxidation
for butene partial
process
Our approach catalysts
involved
solid state chemistry vanadium addition, measured
has been to prepare
with
vanadium
that Naka-
that the
phosphate
in the range 0.94 to 1.07.
known crysthllographic
states of vanadium.
in n-butane
but
devoid of Vt5 showed lower
the P/V ratio to a small rBnge we hoped to prepare
terised oxidation
It appears
process
oxidation.from which they concluded +5_v+4 redox couple.
to this problem
could readily be compared
activity
totally
oxidation
ratio in to enhance
the V
with P/V ratios which varied
to restrict
state of vanadium.
the selective
mura et al. [13] have shown that catalysts
interconvension
of the P/V atomic
High P/V ratios are reported
[13, 141.
that
is the interface
fit at the interface between these two phases thus facilitating +5_v+4 between the V redox couple. Some studies
on heteroge-
states of vanadium
Thus Bordes
to maleic
one such as gVPO5,in which vanadium
crystallographic
in
into @VP05 upon
oxidation
least two oxidation
in the process [7, 10, 131.
Detailed
it forms
6' [12].
have taken the view that since selective is a redox process,at
has been observed
In general
d values at 4.67, 4.07, 3.14 and
This phase will thus be labelled
two phases;
state [lo].
B phase (111 with
is +4 and it transforms
the "active phase" for l-butene oxidation between
the
In addition, another phase of V-P-O catalysts
in this laboratory
2.52.
has equated
a tripolyphosphate
oxidation
and the results
properties,
and the homogeneity
These catalysts
notably
were tested
are compared
phese composition,
by XPS, were also studied.
principally
catalysts
which
phases with well charac-
of the P/V ratio throughout
some surface properties,
based
By choosing
for catalytic
with some of their oxidation
the samples.
the surface
state of In
P/V ratio, as
233 EXPERIMENTAL Preparation
of catalysts
The catalysts
used in this work were prepared
150 grams of lactic acid in water and stirring
by adding
9.1 grams of V205 to
the resulting
suspension
at
reflux for 16 hours, at which stage a blue solution, characteristic of the for+4 complex, had developed. Thereafter the appropriate amount of 85% mation of V H3P04 in water was added and this solution The solvent was then
4 hours.
solid material
which
remained
were prepared
and the
about by the finely
divided
and sieved, with those particles
the range 0.035 to 0.5 mm being retained catalysts
stirring
at 773 K for 16 hours in air. In
drops brought
it was pellitized,broken
at reflux for a further
off with constant
was calcinated
order to avoid very high pressure solid obtained,
was stirred
evaporated
for catalytic
in this way with P/V atomic ratios
in
In all,five
testing.
in the range 0.94
to
1.07.
Characterization X-ray diffractograms
of fresh and worked
Philips
X-ray diffractometer
filtered
through
Surface
by double
areas were determined
oxidation
titration
by the BET method
using nitrogen
as adsorbate
state of vanadium
against
KMn04.
in 100 ml of 2M H2SO4 at 350 K.
to Vt4
of FeS04(NH4)2S04
(equation
(a t b t c) Vt5 An excess
2).
to ferric [15]. 3) gave a measure (a t b t c) Vt4 The average
using a radiation
About
with the aid of a SETARAM
(AV) in the catalysts
+
was cooled +
Thereafter
was the quantitative
a second titration
oxidation
(a t b t c)e-
+
of all the Vt5
to close to 273K in ice water.
t4 (a t b t c) V
of the total vanadium -
(1) reduction
t Fe
t2
was then added to the cool solution.
which occured
was dissolved
was thus carried out +4 in the of all Vt3 and V
was then added to achieve
(a t b t c)e-
was determined
100 mg of each catalyst
The first titration
The solution
of (NH4)2S208
the only reaction
using Cub
at 77 K.
(volume 1) which effectively involved the oxidation +5 solution to V i.e. +3 +5 * (a t b t c) Vt5 + b Vt4 + cv aV An excess
were recorded
counter
nickel.
MLB 10-8 microbalance The average
catalysts
with Geiger-MBller
in excess
(2)
In these conditions
oxidation
of ferrous
ions
(volume 2) with KMn04 (equation
content
of the solid.
(a t b t c) Vt5
state of vanadium
(3)
(AV) was calculated
after equation
4
t131.
A,, =
3a + 2b + C = at
btc
5
(2a t b) atbtc
=
5 _ Volume
1
Volume 2
(4)
234 XPS measurements a signal averager sided adhesive
were carried
out using a V.G. ESCA 3 apparatus
(TRACOR NORTHERN
tape.
Excitation
energies were referenced
TN 1710).
Samples
equipped
were supported
was with the AlKo line (1486.6 eV).
to the CIs line (B.E. 285 eV).
with
on double Binding
The spectra
of CIs,
were recorded in this sequence for each sample studied. 02s' P2p' "2s and c1s Tbe relative intensities,i.e. the P/V ratio,were taken as the simple relation between the areas under the P For the electron
microscopy
2P
with a KEVEX E.D.S. was used. (STEM) facilities analysis
provided
of thin electron
and the V2s peaks. study, a JEOL 100 CX TEMSCAN The Scanning
Transmission
a highly focussed transparent
electron
microscope
Electron
equipped
Microscope
probe which made possible
samples with a resolution
of ca. 20 nm.
In general, the local P/V ratios of areas of the catalysts of diameter 0.1 to 1 um were checked
by Electron
Probe Micro Analysis
(EPMA) at ca. 50 different
spots for each sample.
Catalytic
activity
: apparatus and measurement
procedures
RF
G.C. -a R
Apparatus
Figure 1 R:
M
reactor;
The apparatus of the various n-butane
ment
outlinedhereabove
vanadium
phosphate
flow reactor
the catalyst
(R).
was packed
of the temperature
catalyst
BI_7
was outgassed
: valves;
: rotaflowmeter
to maleic anhydride.
differential which
RF
within
;
: 6-way injection valves;
: gas chromatograph.
was used to measure catalysts
, 03 ‘& . : 8s .
tests.
VI-2
G.C.
86
B7 . .
used to carry out catalytic
: gas mixer;
: flowmeters; Fl-2
,
the catalytic
for the partial
A charge of 3 grams of catalyst This reactor and featured the catalyst
consisted
a thermowell bed.
activities
oxidation
of
was placed
of a Pyrex U-tube which allowed
In normal operation,
in situ for 16 hours at 723 K, cooled to the
in the into
measurethe
reaction
235 temperature
(673 K) and then sealed off from the remainder
means of the 3 way valves BI and B2.
of the system by
Feed gases for the reaction,
comprising
1.3 vol % n-butane in air,were composed as follows : a large flow of air (1500 -1 ml min ) was established via valve B4 and,with B7 closed,this flow was vented to the atmosphere
via B6.
value, the required measured
When this gas flow had stabilized
flow of n-butane
at the desired
(19.5 ml min-') was set via B3 and
with the aid of the calibrated
rotaflowmeter
(RF).
Finally,
any
desired
part of this gas mixture could be flowed through the reactor via B7. -1 A flowrate of 90 ml min , corresponding to a gas hourly space velocity (GHSV) of 4680 hr-', was used throughout be checked suitable
this study.
The composition
by means of the G.C. system prior to its exposure
manipulation
Analysis
products
using an INTERSMAT
rometer
detector
reactor
with the chromatograph
was carried
one of two 6-way valves.
gas.
of reaction
Gases were injected
via
The first of these led to a 0.5 m x 2 nnn stainless
components
Oil 500 on chromosorb
was separated
the
steel and this was heated
products.
and flowed
on which
from all other
n-butane
was separated
into one cell of the detectors.
The second 6-way valve led to a 2 m x 4 mm stainless 20% Silicon
gas
fitted with a kata-
The piping which connected
was of 4 mm stainless
packed with PORAPAK Q, 80-100 mesh,
from all other gaseous
out by means of on-line
IGC 1214 gas chromatograph
using helium as carrier
at 100°C to avoid condensation
steel column
by
of BI and B2.
of the reaction
chromatography
of the gas could to the catalyst
steel column
packed with
WHP, 80-100 mesh, on which maleic
reaction
products.
These
separations
anhydride were carried
out at 368 K. In what follows, Y
=
yield % (Y) in maleic
No of moles of product No of moles of reactant
Conversion c
=
=
is defined
as
x 100
introduced
% (C) as
N" of moles of reactant
consumed
N" of moles of reactant
introduced
and selectivity s
anhydride
formed
(Y/C)
% (S) in maleic
anhydride
x 100
as
x 100
RESULTS X-ray diffractograms measured
directly
of the catalysts
after calcination
values of AV and specific presented
in table
1.
surface
with P/V ratios
are presented areas, measured
before
These data show the influence
P/V ratio on the composition
of the final catalyst
of 0.97 and 1.07
in figure
2.
In addition,
catalytic
of slight
testing,are
changes
and on its textural
in the proper-
236 ties.
Thus it can be clearly
phosphorus
seen from figure 2 that a slight deficiency
from the stoichiometric
crystallised phosphorus
1:l ratio promoted
phase with AV of ca. +5. strongly
stabilized
Figure 2
TABLE
state of vanadium
of a material
in
of a well
On the other hand, a slight excess
the +4 oxidation
nation at 773 K and led to the formation diffraction
the formation
during
of calci-
with very broad X-ray
lines.
X-ray diffractograms
of catalysts
with P/V of 0.97 and 1.07
1
Measured
values
and phases
of AV, before and after catalytic
P/V ratio AV before
testing,
specific
surface
present
testing
AV after
testing
S ecific m 5 g-1
surface
Phases present testing
area
0.94
0.97
1.0
1.03
1.07
4.97
4.90
4.86
4.39
4.04
4.98
4.92
4.90
4.59
4.24
2.7
5.6
9.6
4.9
4.9
t3VP05
;v,o,
Bn BVP05
iVPO5
w
before BVPO5
W
area
237 The results Measurements recorded
of the catalytic
at 673 K are presented
rature were
subject
across
measurements
However
the whole temperature in selectivity
for the catalyst
here since measurements
the general
range.
and yield
in figure 3.
Only those data
made above this tempe-
of maleic
trends observed
anhydride
were
on the
identical
The data recorded at 673 K show that a
for maleic
with the highest
the lowest P/V ratio
are presented
range 663 to 703 K.
to errors due to decomposition
walls of the reactor.
maximum
activity
were made in the temperature
anhydride
formation
was observed
P/V ratio tested and that the catalyst
(0.94) exhibited
with
zero selectivity.
P/V RATIO
Figure 3
Influence
(S) for maleic
By contrast, products
in overall
for intermediate
in surface areas
some oxidation
lines from catalysts
favour of SVPO5.
testing occured
catalysts
during
in the relative
recorded
tures as high as 703 K.
changes
to move towards
small changes were observed
of n-butane
P/V ratios.
By contrast,
P/V ratios less than unity. changes,tending
conversion
after catalytic
The data reveal that no significant
ting theoccurrenceof
(Y) and selectivity
to all reaction
This maximum
coincided
with
(table 1).
The values of AV measured
signficant
(C), yield
formation.
the maximum
was observed
the maximum
of P/V ratio on conversion
anhydride
after testing
are presented
in table 1.
in AV for catalysts
having
with P/V > 1 exhibited
higher values
for AV,thereby
the testing. intensities
In addition,
indicasome
of X-ray diffraction
for catalytic
activity
to tempera-
In general these showed a loss of the 6' phase in
238 The data presented tivity
in maleic
diffractograms
in figure 4 represent
anhydride
formation
before testing
used because
it was thought
tions during
testing
tions observed
an attempt
with the phases observed
for catalytic
activity.
that these were more
probably
occured
the selec-
in the X-ray
These diffractograms
representative
at 673 K, since the small changes
after testing
to correlate
were
of the composi-
in AV and phase composi-
at the highest temperatures
used.
WV RATIO
Influence
Figure 4 @PO6
of P/V ratio on the relative
(0) and (upper traces) AV before
curve marked
S replots
the selectivity
amounts
(a) and after
of the 13" phase
(0) catalytic
data of figure
(O),
testing.
3 for comparison
The
(same
scale).
However
the general
recorded after
trend was not affected
catalytic
testing.
in the X-ray diffractograms amount of each phase
selectivity
could
and a maximum Electron catalytic revealed
were taken directly For comparison
present.
and after testing,are
activity
these curves with data
of figure 4, the peak heights
as a relative measure
of the
the values of AV, measured
before
Thus the maximum in on the same diagrams. 4+ oxidation state present V with a maximum in
also presented
be correlated
in the phase labelled
microscopic
by plotting
For the purpose
examination
confirmed
6" in figure
2.
of these materials
the findings
that as the P/V ratio increased,
before
testing
of the X-ray diffraction the crystallinity
for
study and
of the catalysts
239
Figure 5
Scanning
electron
micrograph
of the catalyst
with P/V = 0.94
Figure 6
Scanning
electron
micrograph
of the catalyst
with P/V = 0.97
240
Fiqure 7
Scanninq
electron
microqraph
of the catalyst
with P/V = 1.03
Fiqure 8
Scanning
electron
micrograph
of the catalyst
with P/V = 1.07
241 As shown in figure 5, the catalyst
decreased.
large particles
of a well crystallized
(figures 6 - 8), the amount extent
samples
material
were almost
Measurements
A summary presented
the different
of the ratio of intensities
in figure
these catalysts ;
below
9.
remained
relatively
presence
of any V2O5 in this catalyst.
layers,but
of the XPS study,the
at the extremes
It should
(greater than of
did not reveal the
be pointed
out here that for to cover the
the shape of the curve in figure 9. However i.e. those with P/V ratios of 0.9 and
activity.
a9
l.0
1
PNRATIO Influence
each catalyst
in the proportion
P/V ratio used was expanded
of the range,
1.1, were not tested for catalytic
increase
the X-ray diffractograms
range 0.9 to 1.1 in order to confirm
Figure 9
throughout
present.
of the PZp and the VZs XPS lines is
this value there was a drastic
06
that for all the
stable for high P/V ratios
in the surface
the samples
to such an
These data show that the P/V ratio at the surface of
vanadium
the purposes
increased
absent from the catalyst
by EPMA revealed
types of particles
of
but as the P/V ratio increased,
crystallized
particles
P/V ratio.
with P/V = 0.94 consisted
of the series the P/V ratio was homogeneous
and throughout
0.97)
of poorly
that well crystallized
with the highest
material
(BULK)
of the bulk P/V ratio on the ratio of the PZp to VZs XPS
peaks.
DISCUSSION Influence
of P/V ratio on phase composition
A striking
feature of the results
ratio was restricted catalysts
obtained
ratios favoured
presented
to a small range,its
and their catalytic
the formation
above is that,although
influence
activity
the P/V
on the nature of the final
was very pronounced.
of BVPO5 [9] with AV values
close to +5.
Low P/V On the
242 other hand, high P/V ratios favoured B"[ 12] and AV values close to +4. with P/V = 1.07 was composed Little
information
rial with a similar were not presented transforms strongly
XRD pattern
dependent
after calcination
influence
at 773 K[12j
The phase labelled
study confirmed
of calcination of reducing
mation or otherwise
agent,
B phase
13, 41&
In this
phase
The
of the SW phase as of this phase as
elsewhere
1121.
The
i.e. lactic acid, HCl or oxalic acid, on the for-
of the 0' phase is not yet fully understood.
The XPS data indicate
that some surface enrichment
samples with P/V ratios of less than about 0.97.
in vanadium
However
tion factors
( 17j , a surface P/V ratio of 2.4 was observed in the plateau Large errors
i.e. above 0.97.
vanadium
on the surface
ions on the surface,
in view of the uncertainties
are often associated
associated
between
Following
the arguments
outlined
position between
during
testing
selectivity
at 673 K.
for maleic
observed mostly
for catalysts
1181.
However
this aspect
activity presented
in figures
which did not change markedly
strong correlation
anhydride
phase and V+4 in these catalysts.
was
below.
above the results
A
this type
of individual
their selectivity
with these calculations,
P/V ratio and catalytic
and 4 can be taken to refer to catalysts
with
that phosphorus
to bring about isolation
thus increasing
of the results will not be pursued further
Relationship
cross section photoioniza-
but these data could be an indication
acting as a diluent
for
inten-
116 1 were calculated
of calculation
using the Scofield
occured
when absolute
sity values
region,
1111
work, only at 773 K.
of the evolution
will be presented
is
it is not observed
the poor crystallinity
conditions
and slowly
appearance
Its
after calcination
Full details
A mate-
but full details
precursor
.
in such circumstances.
by its XRD pattern.
a function
from an amorphous
of this phase were observed
microscopy
indicated
previously,
the P/V ratio, but in general,
above 873 K.
of the catalyst
of this material.
has been reported
calcination
[lo] is observed
trace amounts electron
upon
of a phase which we label
as to the nature of the 6' phase.
It originates
into 4VP05 during
or (VO)2P2O7
almost entirely
is available
[ 61 .
the formation
The X-ray diffractograms
formation
Conversely
was thus observed
and the presence
a minimum
3
in com-
of the BW
in selectivity
was
with P/V ratios less than 1, i.e. which were composed
of 6VPO6.
The very poor selectivity understood
of the catalyst
in terms of the XPS data.
point where a marked
drop in surface
much more pronounced
than the corresponding
surface enrichment selectivity
in vanadium
with P/V = 0.94 can be further
This composition
P/V ratio was observed. diminution
would be expected
since it is phosphorus
coincides
which
This drop was
in bulk P/V ratio. Any
to strongly
is believed
with the
decrease
the
to render these catalysts
243 selective 1191,
an opinion
which
is fully confirmed
by our data for catalysts
with P/V > 1. A feature most,
of these results
i.e. between
variant,
within
P/V = 0.97 to 1.07,the
experimental
ratio is a necessary phosphate
are apparent
that the oxidation
influenced
by excess
the V+4 [17,
condition
surface
contention
phosphorus
in-
plateau
for a selective
P/V
vanadium
i.e. since excess
ratio in the P/V range where
phosphorus
inhibits
inhibits
reoxidation
lysts and strongly Reports
in the patent is the B phase
that selective
maleic
literature
[ 3, 41.
anhydride
phosphorus
strongly.
energies
changed
formation
of the catalysts of excess
It has been shown else-
of the bulk of these cata-
of the bulk of reduced
catalysts [ 20] .
that the active phase in V-P-O
The results
presented
here would
from n-butane
to this phase since the 6' phase was also selective.
amorphous
phases
have been reported
indicate
is not a property
exclusive
of V-P-O catalysts
catalysts.
selectivity
of the influence
the reduction
This
for the V2s and V2p peaks calcined
of the system.
indicate
stabilizes
selectivity
with bigh P/V ratios must have been a consequence
that excess
but
it can be
an invariant
that the increased
on the solid state chemistry
at the surface Secondly,
P/V ratio indicated
in this P/V range for freshly indicated
composition.
at the surface was not strongly
surface
is borne out by the XPS binding
phosphorus
surface
become concentrated
state of vanadium
bulk phosphorus,
These consideraions
catalysts
changed
(XPS) remained
into the bulk of the catalyst.
191 state the invariant
which were unchanged
where
P/V ratio
as a result of the invariant
little of the excess
vi5/C4
surface
Thus it seems that a certain
but not sufficient
must have been incorporated argued
error.
selectivity
based catalyst.
Two factors Firstly,
is that in the range where
Indeed reduced
in the literature
[ 111 .
Thus what would or otherwise the surface indicating
seem important is not the exact phase involved but the presence +4 . However the arguments presented above would indicate that of V
layers of the catalysts that the direct
of the catalyst excess
are in a fairly oxidized condition thus +5 phase. interaction occured with a V The AV value
could be seen as a consequence
phosphorus
which controls
the mobility
of the stabilizing of oxygen
anions
effect
through
of the
lattice [ 20] . An interesting version
feature
of n-butane
correlated
was observed
with a maximum
and their reducibility determines
overall
lattice oxygen
of these results
in
for intermediate
specific
by hydrogen
activity
P/V ratios.
in overall
This finding
[20].
indicates
of the catalyst
con-
This maximum
surface area for these samples
is the ability
in a non-selective
is that the maximum
(table 1)
that what
to give up its bulk
way such as it does in reacting
with hydrogen.
In summary, the results of this study indicate that it is not only the B phase which can be selective
for maleic
anhydride
formation.
The Bw phase is
244 also selective. catalytic
However
conditions,
direct interaction with the hydrocarbon may occur, in +5 with a V phase on the surface of these catalysts. Thus
the AV values shown by the catalysts
are the result of the influence
phosphorus surface
on the solid state processes, i.e. reduction-oxidation. +5 +4 ratios were effected by changes P/V ratio nor the V /V
for the bulk of these catalysts Further
details
selectivity
in the range where selectivity
of the mode of action of excess
will be presented
phosphorus
of excess Neither
the
in the former
was changed
in determining
most. the
soon.
ACKNOWLEDGEMENTS One of us (B.K. HODNETT) Politique
Scientifique"
for running
the scanning
wishes
(Belgium) electron
to thank the "Service de Programmation for a fellowship. micrographs
We also thank Michel
de la Genet
and for help with the XPS measure-
ments.
REFERENCES 1 2 3 4 5 6 7 8 9 10 lla b 12 13 14 15 16 17 18 19 20
K. Wohlfahrt and G. Emig, Hydrocarbon Processing, (1980) June, 83 D.A. De Maio, Chemical Engineering, 87(10) (1980) 104 R.A. Mount and H. Rafelson, US Patent B 330.354 (1975) R.A. Schneider, US Patent 3.864.280 (1975) Chevron Research, Dutch Patent 7.308.517 (1973) Imperial Chemical Industries, Belgian Patent 867.189 (1978) E. Bordes and P. Courtine, J. Catal., 57 (1979) 236 B. Jordon and C. Calvo, Can. J. Chem., 51 (1973) 2621 R. Gopal and C. Calvo, J. Solid State Chem., 5 (1972) 432 E. Bordes, Thesis, Universite de Technologie de Compiegne (1979) G. Poli, I. Resta, 0. Ruggeri and F. Trifiro, Appl. Catal., 1 (1981) 395 G. Poli, 0. Ruggeri and F. Trifiro, 9th Intl Symp. Reactivity of Solids, Cracow (1980) 512 B.K. Hodnett and B. Delmon, unpublished results M. Nakamura, K. Kawai and Y. Fujirawa, J. Catal., 34 (1974) 345 G. Centi, F. Trifiro, A. Vaccari, G.M. Pajonk and S.J. Teichner, Bull. Sot. Chim. Fr., (1981) I-293 A.I. Vogel, Quantitative Inorganic Analysis, Longman (London) (1962) p. 646 J.C. Vedrine, Analusis, 9 (1981) 199 J.H. Scofield, J. of Electron Spectrosc. and Related Phenom., 8 (1976) 129 J.L. Callahan and R.K. Grasselli, A.I.Ch.E., 9 (1963) 755 M. Ai, Bull. Chem. Sot. Japan, 43 (1970) 3490 B.K. Hodnett and B. Delmon, submitted for publication