- Email: [email protected]
SMSI effect in the butadiene hydrogenation on Pd-Cu bimetallic catalysts
407
CatalysisToday, 16 (1993)407-415 Elsevier Science Publishers B.V., Amsterdam
SMSI effect in the butadiene bimetallic catalysts M.M.Pereira,
on Pd-Cu
hydrogenation
F. B. Noronha and M.Schmal*
COPPE/NUCAT,Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brasil, fax (55-2112906626.
C.P.
68502,
CEP 21945,
Abstract Niobia Pd-Cu supported bimetallic catalysts have been studied in the 1,3-butadiene hydrogenation. On catalysts reduced at 573K, the addition of copper to palladium decreased the hydrogen adsorption capacity and the These turnover frequency but increased the trans/cis 2-butene ratio. results are ascribed to a bimetallic formation. After reduction at 773K. the hydrogen chemisorption and turnover frequency are drastically reduced due to SMSI effect. The 1,3-butadiene hydrogenation seems to be a structure sensitive reaction.
1. INTRODUCTION Since
the term “strong
by Tauster
et
chemisorption (titania,
influenced influence structure behavior
[1,21 a
niobial,
has received catalytic
al on
metal-support
to
describe
group
after
VIII
high
much attention
activity by on
the
the
of
reactions of
the
was introduced
suppression on
reduction
In addition,
[3-81.
of
(HTR),
it
has been shown that
TiOz supported
metals
the
SMSI effect
but
only
14,121.
Haller
a group
oxide
the SMSI effect
reactions
adding
Hz and CO
reducible
a
In general,
sensitive
effect
strong supported
temperature
SMSI [9-111.
insensitive with
the
metal
and selectivity
structure
interaction”(SMSI1
et
a
al.
Ib metal
has
minor [41
to
be
a great
effect
compared
group
the
could
VIII
on this metal
catalysts. In reaction is
contrast [4,6],
to
controversial.
turnover
hydrocarbon
the effect
frequency
hydrogenolysis,
of particle al.
size [131
a
structure
observed
Boitiaux
et
(TOFl for
the 1,3-butadiene
a
marked
hydrogenation
sensitive
hydrogenation
on the butadiene
decrease
reaction
0920-5861/93/$6.00 0 1993Elsevier Science Publishers B.V. All rights reserved.
of when
408 the metallic dispersion of Pd/AlsOa catalyst was increased. On the other hand,
Borgna
et
al.
1141 did
not
verify
such correlation
between
the
particle size and the activity/selectivity for this reaction. The addition of
chromium
decreased
the
catalytic
activity
the
of
bimetallic
palladium-chromium catalyst. However, these results were interpreted by a modification of the metal-unsaturated hydrocarbon
interaction induced by
ligand-effect. The aim of this work was to study the behavior of palladium catalysts, modified both by the addition of copper and by the SMSI effect, on the 1,3-butadiene hydrogenation. Our results allow to elucidate the sensibility of this reaction.
2.EXPEHIMENTAL 2.1. Catalyst preparation The NbaOs support (BET area: 30 m2/gl was obtained by calcination of niobic acid (CBMM, AD 376) in air at 773K for
2 hours. The catalysts were
prepared by incipient wetness impregnation of the support with
an
aqueous
solution of palladium chloride and copper chloride 1151, followed by drying at 393K for 16h and calcination at 673K for 2h. The prepared catalysts and their metal contents measured by atomic absorption spectroscopy are given in table 1.
2.2. Hydrogen chemisorption The frontal technique has been used for the hydrogen chemisorption, following a methodology similar to that presented in 1151. After reduction, the
catalyst
was
flushed
with
an
argon
gas
temperature for 30 min. Then, the catalyst was
flow
at
the
reduction
cooled to 343K and the
irreversible amount of adsorbed hydrogen was measured by a frontal method 1161. This [171.
adsorption
temperature was
chosen
to avoid B-PdH
x
formation
409
TABLE 1 Catalysts metal contents (xPd-vCu:x/r represents the theorical atomic ratio between Pd and Cu), hydrogen chemisorption and ratio of hydrogen adsorption after reduction at 573 and 773K.
Catalyst
Composition
Hz Chemisorption
(wt.-%) Pd
RCb
(pmolsH /ingPdl
cu
573K"
773Ka
0
2.08
0.62
3.35
Pd/NbsOs
0.87
lPd-2WNbaOs
0.89
1
0.52
0.22
2.36
lPd-5Cu/NbaOs
0.83
2.8
0.43
0.24
1.79
a reduction temperatures b RC= ratio of hydrogen adsorption amounts, after reduction at 573 and 773K
2.3. Catalytic activity The hydrogenation of 1,3-butadiene was performed in a flow system at atmospheric
pressure and 343K. The
catalyst
(ca. 10 mg), mixed with a
silica diluent (catalyst/diluent ratio : l/30), were reduced "in situ" with a mixture of 1.5% hydrogen in nitrogen at 573 or 773K. The reaction mixture consisted of 1,3-butadiene/hydrogen/nitrogen (10:10:80) and the conditions were
established
in order
products were analysed by
to keep
conversions below
12%. The
reaction
on line gas chromatography (VARIAN 2400, with a
80/100 Carbopack C/ 0.19% picric acid column at 313Kl. It was verified that the reaction is not limited by a diffusion process. The activities expressed in turnover frequency (TOFU were calculated from
the hydrogen
hydrogenation
chemisorption
results. The
selectivities for partial
(Shpl, 1-butene (S1l and the trans/cis 2-butene ratio were
determined as described in [141. All selectivities were obtained at the same conversion and temperature (iso-conversion).
410
3.RESULTS
3.1. Hydrogen
chemisorption
The amount of Ha irreversibly adsorbed on the catalysts, reduced at 573 and 7733, are shown present
significant
in table 1. The supported copper catalyst did not
irreversible
chemisorption
of
hydrogen.
In
the
bimetallic catalyst, an increase in the copper content and in the reduction temperature caused a decrease in the amount of hydrogen chemisorbed.
3.2. Catalytic test The catalytic activity (TOF) and selectivities are presented in table 2.
The
turnover
frequencies
decrease with
both
copper
addition
(after
reduction at 573K) and reduction at high temperature (HTR). The supported copper catalyst was virtually inactive in the temperature studied. The
1-butene selectivity and trans/cis 2-butene ratio increase for
higher copper content reduction at high
(after reduction at 57331 but do not change with
temperature. No n-butane was found in all bimetallic
catalysts.
Table 2 Turnover frequency (TOF), selectivities for I-butene (S1l, partial hydrogenation(Shp) and the translcis
2-butene ratio for niobia supported catalysts
after reduction at 573 and 773K.
Catalyst
S1(%l
S&(%1
t/c
TOF(s-'1
573
773
573
773
Pd/NbsOs
55
55
96
88
5.8
4.7
5.97
0.23
lPd-2Cu/NbaOs
58
71
99
100
7.2
9.2
3.00
1.35
lPd-5Cu/NbaOs
66
67
100
100
8.4
8.1
1.32
0.08
573
773
573
773
411 4. Discussion
SMSI state The suppression of hydrogen adsorption on Pd/NbzOs catalyst (table 1) after
high
temperature
reduction
(773KI
is
the
main
feature
of
the
so-called SMSI effect [1,21 and is consistent with previous works [15,181. Hu et al [19] have also reported that the hydrogen chemisorption and the catalytic activity for ethane hydrogenolysis were strongly suppressed by HTR.
These
species
behavior
were
(NbOxI which
explained by
cover
the presence
the surface of
of
reduced
rhodium particle
niobia
(geometric
effect). According
to
the
decoration model
[4,11,19,201, the presence of
these species on the metal surface would physically block active sites, preferentially
affecting those reactions that require a large ensemble of
atoms as active sites. Hence, HTR leads to a strong activity suppression for structure sensitive reactions. The
literature
[13,211 presents contradictory interpretations about
the effect of particle size on the 1,3-butadiene hydrogenation. On alumina and silica supported catalysts, Boitiaux et al [131 found a great decrease in the turnover number for 1,3-butadiene hydrogenation, when the dispersion was increased. Tardy et al
1211 performed this reaction on Pd particles
evaporated on carbonaceous supports and observed that it appears to be very size sensitive. They also observed that the catalytic activity increases when the particle size increases. In
this
1,3-butadiene drastically
work,
we
observe
hydrogenation after
on
H'IR. Then,
that
the
Pd/NbzOs we
specific catalyst
postulate
activity (Table
that
the
(TOF)
21
for
decrease
1,3-butadiene
hydrogenation is a structure sensitive reaction. A geometric explanation of the SMSI effect is also reinforced by the selectivities results. After high temperature reduction, the trans/cis 2butene ratio and the 1-butene selectivity are approximately constant, which excludes
an
electronic
explanation. However,
influnce of localized electronic effects.
we
can
not
rule
out
the
412 Metal-metal interactions
For the bimetallic decreased
catalysts reduced at 573K, the Presence of copper
the amount of irreversibly chemisorbed hydrogen. These results
are a clear evidence of bimetallic particle formation 122-241 and confirms our previous between
work
group
[151. Many
VIII-group
authors
Ib metals
[22-251 explained
in bimetallic
the interaction
systems by
geometric
effects, i.e., dilution or blocking of a fraction of the palladium surface by copper. Recently,
Leon y Leon and Vannice [221 studied the adsorption
properties of Pd-Cu/SiOz systems and observed also that the addition of copper to Pd/SiOz decreased the hydrogen and carbon monoxide chemisorption. This behavior was ascribed to a palladium-copper interaction. The geometric dilution of the palladium surface by copper was also observed by Noronha et al monoxide
adsorption
[151, by the decrease of hydrogen and carbon as
capacities,
well
as
an
increase
in
the
ratio
linear/bridged adsorbed carbon monoxide species. The catalytic activity and the selectivities results also confirm the bimetallic formation. According to a
second
metal
decreases
the
Haller and Resasco [41, the addition of
catalytic
activity
(TOF)
of
structure
sensitive reactions. From table 2, the turnover frequencies decreased when the copper content increased, after reduction at 573K. These results lead us to postulate that 1,3-butadiene hydrogenation is a structure sensitive reaction and agree fairly well with the chemisorption results. On the other hand, a pure geometric effect cannot explain the increase of
the
selectivity
for
1-butene
and
the
trans/cis
ratio
with
copper
addition. A modification of the electronic structure of palladium is thus certainly involved. Examining
the
hydrogen
chemisorption
results
of
the
bimetallic
catalysts (after reduction at 573K), we observe that the dispersion of this catalysts is approximately constant. In spite of this, the distribution of butenes
is
strongly
different.
The
lPd-5Cu/Nb20s catalyst
presented
S1
selectivity and trans/cis ratio higher than in the lPd-2Cu/Nbz0s catalyst. Moreover, all the bimetallic catalysts were fully selective for the partial hydrogenation, whereas the Pd/Nbz05 catalyst was only 90% selective. Such a modification of selectivity induced by an electronic effect has been already reported by Borgna et al.[141. They investigated the effect of chromium on the reactivity of palladium in the 1,3-butadiene hydrogenation.
413 The
addition
of
hydrogenation
chromium
and
the
increased
trans/cis
both
the
2-butene
seletivity
ratio.
These
for
partial were
results
interpreted by a modification of the electronic structure of palladium. From EXAFS analysis they showed a transfer of charge to the Pd 4d band due to the presence of Cr atoms. This
increase of the electron density of
palladium would induce a change in seletivity, since the bond strength of the hydrocarbons are affected differently. Recently, Noronha et al.[lSI have also suggested a modification of the eletronic structure of palladium
in Pd-Cu/NbaOs catalysts. According to
this work, copper decreased the adsorption strength of carbon monoxide on palladium, probably induced by an electron enrichment of palladium in the presence of copper. These results could be
interpreted by an eletronic
modification of the active sites, that is, the electron densities of Pd metal are increased by the electron transfer from copper. The effect of copper addition on the bimetallic catalysts reduced at 773K can be well understood by the ratio of hydrogen adsorbed amounts after reduction at 573 and 773K. This ratio must be higher than one [151, as the suppressed.
hydrogen chemisorption after reduction at 773K is strongly
However, this ratio decreases when the copper content increases. Noronha et al.[lSI also observed similar behavior in Pd-Cu/NbaOs catalysts (2 wt.% of palladium) but this ratio decreased more drastically. They proposed that the addition possibility agreement
of of
with
copper
to Pd/NbaOs catalysts
SMSI
formation.
these
results.
The On
turnover
limits or frequencies
Pd/NbaOs catalyst,
suppresses are
the TOF
also
the in
decreases
drastically, after HTR, due to the SMSI effect. The presence of copper inhibits
the
possibility
of
SMSI
formation.
Therefore,
the
TOF
after
reduction at 573 and 773K were approximately the same for the lPd-2Cu/NbsOs catalyst. However, the strong decrease of TOF observed for lPd-5Cu/NbaOs catalyst suggests that addition of extra Cu could not only suppress the SMSI formation but also principaly block the active sites.
CONCLUSIONS
In
all
catalysts,
the
specific
activity
for
1,3
butadiene
hydrogenation decreased after HTR, which confirmed that this reaction is structure sensitive.
414 The the
addition
trans-cis
of
ratio.
copper
improved the
Moreover,
the
selectivity
bimetallic
for
catalysts
l-butene and were
fully
selective for the partial hydrogenation. SMSI effects were attributed to both eletronic and geometric effects. However, the presence of copper inhibits or supress the SMSI formation.
Ackowledgment
This work has been supported by PRONAC (Programa National de Catalisel and
FINEP
(Financiadora
de
Estudos
e
Projetosl.
MMP
thanks
FCC
for
financial support. We are grateful to CBMM for the niobia supply.
REFERENCES
l- S.J.Tauster and S.C.Fung, J. Catal., 55 (19781 29. 2- S.J.Tauster, S.C.Fung and R.L.Garten, J.Am.Chem.Soc., 100(l) (19781 170. 3- B.Imelik, C.Naccache, C.Coudurier, G.Prauliaud,P.Meriaudeau, P.Gallezot, G.A.Martin and J.C.Vendrine (Editors), Metal-Support and Metal-Additive Effects in Catalysis, Stud.Surf.Sci.Catal. vol 11, Elsevier, Amsterdam, (19821. 4- G.L.Haller and D.E.Resasco, Adv.Catal., 36 (19891 173. 5- S.J.Tauster, Acc.Chem.Res., 20(111 (19871 389. 6- G.C.Bond and R.Burch, Catalysis, 6 (1983) 27. 7- F.B.Noronha, A.Maia, M.Schmal, M.Primet and R.Frety, in Proceedings 12th Ibero American Congress on catalysis, IBP Pub., Rio de Janeiro, Vol.3, 1990 p.730. 8- K.J.Blankenburg and A.K.Datye, J. Catal., 128 (19911 186. 9- K.Kunimori, H.Abe, E.Yamaguchi, S.Matsui and T.Uchijima, in Proceedings 8th International Congress on Catalysis, Berlin, vol. 5, 1984 ~251. 10D.E.Resasco and G.L.Haller, Stud.Surf.Sci.Catal., 11 (19821 105. ll- P.Meriaudeau, J.F.Dutel, M.Dufaux and C.Naccache, Stud.Surf.Sci.Catal., 11 (19821 95. 12- K. Kunimori, Z.Hu, T.Uchijima, K. Asakura, Y.Iwasawa and M.Soma, Catal.Today, 8 (19901 85. 13- J.P.Boitiaux, J.Cosyns and S.Vasudevan, Appl.Catal., 6 (19831 41. 14- A. Borgna, B.Moraweck, J.Massardier and A.J.Renouprez, J.Catal. 128 (19911 99. 15- F.B.Noronha, M.Primet, R.Frety and M.Schmal, Appl.Catal.,78 (19911 125. 16- P.N.da Silva, M.Guenin, C.Leclercq and Roger Frety, Appl.Catal., 54 (19891 203. 17- P.C.Aben, J. Catal., 10 (1968) 224. 18- A.Maeda, F.Yamakawa, K.Kunimori and T.Uchijima, Catal.Letters, 4 (19901 102. 19- Z.Hu, K.Kunimori and T.Uchijima, Appl.Catal., 69 (19911 253.
415 20- J.Santos, J.Phillips and J.A.Dumesic, J.Catal. 81 (1983) 147. 21- B.Tardy, C.Noupa, C.Leclercq, J.C.Bertolini, A.Hoareau, Mtreilleux. J.P.Faure and G.Nihoul, J.Catal., 129 (1991) 1. 22- C.A.Leon y Leon and M.A. Vannice, Appl.Catal., 69 (1991) 291. Concepts and 23Catalysts: J.H.Sinfelt, Bimetallic Discoveries, Applications, John Wiley & Sons, New York, 1983, p. 24- W.M.H.Sachtler and R.A.Van Santen, Adv. Catal., 26 (1977) 69. 25- H.A.C.M.Hendrickx and V.Ponec, Surf. Sci., 192 (1987) 234.
CatalysisToday, 16 (1993)407-415 Elsevier Science Publishers B.V., Amsterdam
SMSI effect in the butadiene bimetallic catalysts M.M.Pereira,
on Pd-Cu
hydrogenation
F. B. Noronha and M.Schmal*
COPPE/NUCAT,Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brasil, fax (55-2112906626.
C.P.
68502,
CEP 21945,
Abstract Niobia Pd-Cu supported bimetallic catalysts have been studied in the 1,3-butadiene hydrogenation. On catalysts reduced at 573K, the addition of copper to palladium decreased the hydrogen adsorption capacity and the These turnover frequency but increased the trans/cis 2-butene ratio. results are ascribed to a bimetallic formation. After reduction at 773K. the hydrogen chemisorption and turnover frequency are drastically reduced due to SMSI effect. The 1,3-butadiene hydrogenation seems to be a structure sensitive reaction.
1. INTRODUCTION Since
the term “strong
by Tauster
et
chemisorption (titania,
influenced influence structure behavior
[1,21 a
niobial,
has received catalytic
al on
metal-support
to
describe
group
after
VIII
high
much attention
activity by on
the
the
of
reactions of
the
was introduced
suppression on
reduction
In addition,
[3-81.
of
(HTR),
it
has been shown that
TiOz supported
metals
the
SMSI effect
but
only
14,121.
Haller
a group
oxide
the SMSI effect
reactions
adding
Hz and CO
reducible
a
In general,
sensitive
effect
strong supported
temperature
SMSI [9-111.
insensitive with
the
metal
and selectivity
structure
interaction”(SMSI1
et
a
al.
Ib metal
has
minor [41
to
be
a great
effect
compared
group
the
could
VIII
on this metal
catalysts. In reaction is
contrast [4,6],
to
controversial.
turnover
hydrocarbon
the effect
frequency
hydrogenolysis,
of particle al.
size [131
a
structure
observed
Boitiaux
et
(TOFl for
the 1,3-butadiene
a
marked
hydrogenation
sensitive
hydrogenation
on the butadiene
decrease
reaction
0920-5861/93/$6.00 0 1993Elsevier Science Publishers B.V. All rights reserved.
of when
408 the metallic dispersion of Pd/AlsOa catalyst was increased. On the other hand,
Borgna
et
al.
1141 did
not
verify
such correlation
between
the
particle size and the activity/selectivity for this reaction. The addition of
chromium
decreased
the
catalytic
activity
the
of
bimetallic
palladium-chromium catalyst. However, these results were interpreted by a modification of the metal-unsaturated hydrocarbon
interaction induced by
ligand-effect. The aim of this work was to study the behavior of palladium catalysts, modified both by the addition of copper and by the SMSI effect, on the 1,3-butadiene hydrogenation. Our results allow to elucidate the sensibility of this reaction.
2.EXPEHIMENTAL 2.1. Catalyst preparation The NbaOs support (BET area: 30 m2/gl was obtained by calcination of niobic acid (CBMM, AD 376) in air at 773K for
2 hours. The catalysts were
prepared by incipient wetness impregnation of the support with
an
aqueous
solution of palladium chloride and copper chloride 1151, followed by drying at 393K for 16h and calcination at 673K for 2h. The prepared catalysts and their metal contents measured by atomic absorption spectroscopy are given in table 1.
2.2. Hydrogen chemisorption The frontal technique has been used for the hydrogen chemisorption, following a methodology similar to that presented in 1151. After reduction, the
catalyst
was
flushed
with
an
argon
gas
temperature for 30 min. Then, the catalyst was
flow
at
the
reduction
cooled to 343K and the
irreversible amount of adsorbed hydrogen was measured by a frontal method 1161. This [171.
adsorption
temperature was
chosen
to avoid B-PdH
x
formation
409
TABLE 1 Catalysts metal contents (xPd-vCu:x/r represents the theorical atomic ratio between Pd and Cu), hydrogen chemisorption and ratio of hydrogen adsorption after reduction at 573 and 773K.
Catalyst
Composition
Hz Chemisorption
(wt.-%) Pd
RCb
(pmolsH /ingPdl
cu
573K"
773Ka
0
2.08
0.62
3.35
Pd/NbsOs
0.87
lPd-2WNbaOs
0.89
1
0.52
0.22
2.36
lPd-5Cu/NbaOs
0.83
2.8
0.43
0.24
1.79
a reduction temperatures b RC= ratio of hydrogen adsorption amounts, after reduction at 573 and 773K
2.3. Catalytic activity The hydrogenation of 1,3-butadiene was performed in a flow system at atmospheric
pressure and 343K. The
catalyst
(ca. 10 mg), mixed with a
silica diluent (catalyst/diluent ratio : l/30), were reduced "in situ" with a mixture of 1.5% hydrogen in nitrogen at 573 or 773K. The reaction mixture consisted of 1,3-butadiene/hydrogen/nitrogen (10:10:80) and the conditions were
established
in order
products were analysed by
to keep
conversions below
12%. The
reaction
on line gas chromatography (VARIAN 2400, with a
80/100 Carbopack C/ 0.19% picric acid column at 313Kl. It was verified that the reaction is not limited by a diffusion process. The activities expressed in turnover frequency (TOFU were calculated from
the hydrogen
hydrogenation
chemisorption
results. The
selectivities for partial
(Shpl, 1-butene (S1l and the trans/cis 2-butene ratio were
determined as described in [141. All selectivities were obtained at the same conversion and temperature (iso-conversion).
410
3.RESULTS
3.1. Hydrogen
chemisorption
The amount of Ha irreversibly adsorbed on the catalysts, reduced at 573 and 7733, are shown present
significant
in table 1. The supported copper catalyst did not
irreversible
chemisorption
of
hydrogen.
In
the
bimetallic catalyst, an increase in the copper content and in the reduction temperature caused a decrease in the amount of hydrogen chemisorbed.
3.2. Catalytic test The catalytic activity (TOF) and selectivities are presented in table 2.
The
turnover
frequencies
decrease with
both
copper
addition
(after
reduction at 573K) and reduction at high temperature (HTR). The supported copper catalyst was virtually inactive in the temperature studied. The
1-butene selectivity and trans/cis 2-butene ratio increase for
higher copper content reduction at high
(after reduction at 57331 but do not change with
temperature. No n-butane was found in all bimetallic
catalysts.
Table 2 Turnover frequency (TOF), selectivities for I-butene (S1l, partial hydrogenation(Shp) and the translcis
2-butene ratio for niobia supported catalysts
after reduction at 573 and 773K.
Catalyst
S1(%l
S&(%1
t/c
TOF(s-'1
573
773
573
773
Pd/NbsOs
55
55
96
88
5.8
4.7
5.97
0.23
lPd-2Cu/NbaOs
58
71
99
100
7.2
9.2
3.00
1.35
lPd-5Cu/NbaOs
66
67
100
100
8.4
8.1
1.32
0.08
573
773
573
773
411 4. Discussion
SMSI state The suppression of hydrogen adsorption on Pd/NbzOs catalyst (table 1) after
high
temperature
reduction
(773KI
is
the
main
feature
of
the
so-called SMSI effect [1,21 and is consistent with previous works [15,181. Hu et al [19] have also reported that the hydrogen chemisorption and the catalytic activity for ethane hydrogenolysis were strongly suppressed by HTR.
These
species
behavior
were
(NbOxI which
explained by
cover
the presence
the surface of
of
reduced
rhodium particle
niobia
(geometric
effect). According
to
the
decoration model
[4,11,19,201, the presence of
these species on the metal surface would physically block active sites, preferentially
affecting those reactions that require a large ensemble of
atoms as active sites. Hence, HTR leads to a strong activity suppression for structure sensitive reactions. The
literature
[13,211 presents contradictory interpretations about
the effect of particle size on the 1,3-butadiene hydrogenation. On alumina and silica supported catalysts, Boitiaux et al [131 found a great decrease in the turnover number for 1,3-butadiene hydrogenation, when the dispersion was increased. Tardy et al
1211 performed this reaction on Pd particles
evaporated on carbonaceous supports and observed that it appears to be very size sensitive. They also observed that the catalytic activity increases when the particle size increases. In
this
1,3-butadiene drastically
work,
we
observe
hydrogenation after
on
H'IR. Then,
that
the
Pd/NbzOs we
specific catalyst
postulate
activity (Table
that
the
(TOF)
21
for
decrease
1,3-butadiene
hydrogenation is a structure sensitive reaction. A geometric explanation of the SMSI effect is also reinforced by the selectivities results. After high temperature reduction, the trans/cis 2butene ratio and the 1-butene selectivity are approximately constant, which excludes
an
electronic
explanation. However,
influnce of localized electronic effects.
we
can
not
rule
out
the
412 Metal-metal interactions
For the bimetallic decreased
catalysts reduced at 573K, the Presence of copper
the amount of irreversibly chemisorbed hydrogen. These results
are a clear evidence of bimetallic particle formation 122-241 and confirms our previous between
work
group
[151. Many
VIII-group
authors
Ib metals
[22-251 explained
in bimetallic
the interaction
systems by
geometric
effects, i.e., dilution or blocking of a fraction of the palladium surface by copper. Recently,
Leon y Leon and Vannice [221 studied the adsorption
properties of Pd-Cu/SiOz systems and observed also that the addition of copper to Pd/SiOz decreased the hydrogen and carbon monoxide chemisorption. This behavior was ascribed to a palladium-copper interaction. The geometric dilution of the palladium surface by copper was also observed by Noronha et al monoxide
adsorption
[151, by the decrease of hydrogen and carbon as
capacities,
well
as
an
increase
in
the
ratio
linear/bridged adsorbed carbon monoxide species. The catalytic activity and the selectivities results also confirm the bimetallic formation. According to a
second
metal
decreases
the
Haller and Resasco [41, the addition of
catalytic
activity
(TOF)
of
structure
sensitive reactions. From table 2, the turnover frequencies decreased when the copper content increased, after reduction at 573K. These results lead us to postulate that 1,3-butadiene hydrogenation is a structure sensitive reaction and agree fairly well with the chemisorption results. On the other hand, a pure geometric effect cannot explain the increase of
the
selectivity
for
1-butene
and
the
trans/cis
ratio
with
copper
addition. A modification of the electronic structure of palladium is thus certainly involved. Examining
the
hydrogen
chemisorption
results
of
the
bimetallic
catalysts (after reduction at 573K), we observe that the dispersion of this catalysts is approximately constant. In spite of this, the distribution of butenes
is
strongly
different.
The
lPd-5Cu/Nb20s catalyst
presented
S1
selectivity and trans/cis ratio higher than in the lPd-2Cu/Nbz0s catalyst. Moreover, all the bimetallic catalysts were fully selective for the partial hydrogenation, whereas the Pd/Nbz05 catalyst was only 90% selective. Such a modification of selectivity induced by an electronic effect has been already reported by Borgna et al.[141. They investigated the effect of chromium on the reactivity of palladium in the 1,3-butadiene hydrogenation.
413 The
addition
of
hydrogenation
chromium
and
the
increased
trans/cis
both
the
2-butene
seletivity
ratio.
These
for
partial were
results
interpreted by a modification of the electronic structure of palladium. From EXAFS analysis they showed a transfer of charge to the Pd 4d band due to the presence of Cr atoms. This
increase of the electron density of
palladium would induce a change in seletivity, since the bond strength of the hydrocarbons are affected differently. Recently, Noronha et al.[lSI have also suggested a modification of the eletronic structure of palladium
in Pd-Cu/NbaOs catalysts. According to
this work, copper decreased the adsorption strength of carbon monoxide on palladium, probably induced by an electron enrichment of palladium in the presence of copper. These results could be
interpreted by an eletronic
modification of the active sites, that is, the electron densities of Pd metal are increased by the electron transfer from copper. The effect of copper addition on the bimetallic catalysts reduced at 773K can be well understood by the ratio of hydrogen adsorbed amounts after reduction at 573 and 773K. This ratio must be higher than one [151, as the suppressed.
hydrogen chemisorption after reduction at 773K is strongly
However, this ratio decreases when the copper content increases. Noronha et al.[lSI also observed similar behavior in Pd-Cu/NbaOs catalysts (2 wt.% of palladium) but this ratio decreased more drastically. They proposed that the addition possibility agreement
of of
with
copper
to Pd/NbaOs catalysts
SMSI
formation.
these
results.
The On
turnover
limits or frequencies
Pd/NbaOs catalyst,
suppresses are
the TOF
also
the in
decreases
drastically, after HTR, due to the SMSI effect. The presence of copper inhibits
the
possibility
of
SMSI
formation.
Therefore,
the
TOF
after
reduction at 573 and 773K were approximately the same for the lPd-2Cu/NbsOs catalyst. However, the strong decrease of TOF observed for lPd-5Cu/NbaOs catalyst suggests that addition of extra Cu could not only suppress the SMSI formation but also principaly block the active sites.
CONCLUSIONS
In
all
catalysts,
the
specific
activity
for
1,3
butadiene
hydrogenation decreased after HTR, which confirmed that this reaction is structure sensitive.
414 The the
addition
trans-cis
of
ratio.
copper
improved the
Moreover,
the
selectivity
bimetallic
for
catalysts
l-butene and were
fully
selective for the partial hydrogenation. SMSI effects were attributed to both eletronic and geometric effects. However, the presence of copper inhibits or supress the SMSI formation.
Ackowledgment
This work has been supported by PRONAC (Programa National de Catalisel and
FINEP
(Financiadora
de
Estudos
e
Projetosl.
MMP
thanks
FCC
for
financial support. We are grateful to CBMM for the niobia supply.
REFERENCES
l- S.J.Tauster and S.C.Fung, J. Catal., 55 (19781 29. 2- S.J.Tauster, S.C.Fung and R.L.Garten, J.Am.Chem.Soc., 100(l) (19781 170. 3- B.Imelik, C.Naccache, C.Coudurier, G.Prauliaud,P.Meriaudeau, P.Gallezot, G.A.Martin and J.C.Vendrine (Editors), Metal-Support and Metal-Additive Effects in Catalysis, Stud.Surf.Sci.Catal. vol 11, Elsevier, Amsterdam, (19821. 4- G.L.Haller and D.E.Resasco, Adv.Catal., 36 (19891 173. 5- S.J.Tauster, Acc.Chem.Res., 20(111 (19871 389. 6- G.C.Bond and R.Burch, Catalysis, 6 (1983) 27. 7- F.B.Noronha, A.Maia, M.Schmal, M.Primet and R.Frety, in Proceedings 12th Ibero American Congress on catalysis, IBP Pub., Rio de Janeiro, Vol.3, 1990 p.730. 8- K.J.Blankenburg and A.K.Datye, J. Catal., 128 (19911 186. 9- K.Kunimori, H.Abe, E.Yamaguchi, S.Matsui and T.Uchijima, in Proceedings 8th International Congress on Catalysis, Berlin, vol. 5, 1984 ~251. 10D.E.Resasco and G.L.Haller, Stud.Surf.Sci.Catal., 11 (19821 105. ll- P.Meriaudeau, J.F.Dutel, M.Dufaux and C.Naccache, Stud.Surf.Sci.Catal., 11 (19821 95. 12- K. Kunimori, Z.Hu, T.Uchijima, K. Asakura, Y.Iwasawa and M.Soma, Catal.Today, 8 (19901 85. 13- J.P.Boitiaux, J.Cosyns and S.Vasudevan, Appl.Catal., 6 (19831 41. 14- A. Borgna, B.Moraweck, J.Massardier and A.J.Renouprez, J.Catal. 128 (19911 99. 15- F.B.Noronha, M.Primet, R.Frety and M.Schmal, Appl.Catal.,78 (19911 125. 16- P.N.da Silva, M.Guenin, C.Leclercq and Roger Frety, Appl.Catal., 54 (19891 203. 17- P.C.Aben, J. Catal., 10 (1968) 224. 18- A.Maeda, F.Yamakawa, K.Kunimori and T.Uchijima, Catal.Letters, 4 (19901 102. 19- Z.Hu, K.Kunimori and T.Uchijima, Appl.Catal., 69 (19911 253.
415 20- J.Santos, J.Phillips and J.A.Dumesic, J.Catal. 81 (1983) 147. 21- B.Tardy, C.Noupa, C.Leclercq, J.C.Bertolini, A.Hoareau, Mtreilleux. J.P.Faure and G.Nihoul, J.Catal., 129 (1991) 1. 22- C.A.Leon y Leon and M.A. Vannice, Appl.Catal., 69 (1991) 291. Concepts and 23Catalysts: J.H.Sinfelt, Bimetallic Discoveries, Applications, John Wiley & Sons, New York, 1983, p. 24- W.M.H.Sachtler and R.A.Van Santen, Adv. Catal., 26 (1977) 69. 25- H.A.C.M.Hendrickx and V.Ponec, Surf. Sci., 192 (1987) 234.