Surface chemistry and reactivity of well-defined multilayered supported M1Ox/M2Ox/SiO2 catalysts

Article abstract of DOI:10.1016/j.jcat.2008.06.002

A series of group 5-7 transition metal oxides (TMOs) were supported on SiO₂ and surface-modified SiO₂ containing surface AlO_x, ZrO_x, and TiO_x species. The surface reactivity of these silica supported oxides was chemically probed with CH₃OH-temperature-programmed surface reaction (TPSR) spectroscopy. The selectivity of the model supported MO_x catalytic active sites on SiO₂ generally reflect the same product distribution as their corresponding bulk MO_x counterparts toward dimethyl ether (DME), formaldehyde (HCHO) and CO₂ from surface acidic, redox, and basic sites, respectively. The reactivity of the surface MO_x sites generally was suppressed by anchoring of the surface MO_x species onto the SiO₂ support. The general surface chemistry trend followed the known inorganic chemistry of the corresponding bulk MO_x TMOs. For the multilayered supported M₁O_x/M₂O_x/SiO₂, with M₁ representing the group 5-7 TMOs and M₂ representing Al, Zr or Ti, the selectivity of the catalytic active sites was generally comparable to that for the model-supported M₁O_x/SiO₂ catalysts. The reactivity of the surface VO_x, MoO_x, and ReO_x redox sites increased by one to four orders of magnitude with the introduction of the surface modifiers; however, the reactivity of the surface WO_x acidic site was mildly suppressed by the presence of the surface modifiers. The reactivity of the basic CrO_x site was only mildly perturbed by the surface modifiers. The reactivity trend of the catalytic TMOs sites was related to the electronegativity properties of the anchoring substrate cations (Si > Al > Zr ～ Ti).

Full text of DOI:10.1016/j.jcat.2008.06.002

Journal of Catalysis 258 (2008) 103–110
Contents lists available at ScienceDirect
Journal of Catalysis
www.elsevier.com/locate/jcat
Surface chemistry and reactivity of well-defined multilayered supported
M₁O_x/M₂O_x/SiO₂ catalysts
∗
Edward L. Lee, Israel E. Wachs
Operando Molecular Spectroscopy and Catalysis Laboratory, Chemical Engineering Department, 111 Research Drive, Iacocca Hall, Lehigh University, Bethlehem, PA 18015, USA
a r t i c l e i n f o
a b s t r a c t
Article history:
A series of group 5–7 transition metal oxides (TMOs) were supported on SiO₂ and surface-modified SiO₂
containing surface AlO_x, ZrO_x, and TiO_x species. The surface reactivity of these silica supported oxides
was chemically probed with CH₃OH-temperature-programmed surface reaction (TPSR) spectroscopy. The
selectivity of the model supported MO_x catalytic active sites on SiO₂ generally reflect the same product
distribution as their corresponding bulk MO_x counterparts toward dimethyl ether (DME), formaldehyde
(HCHO) and CO₂ from surface acidic, redox, and basic sites, respectively. The reactivity of the surface
MO_x sites generally was suppressed by anchoring of the surface MO_x species onto the SiO₂ support.
The general surface chemistry trend followed the known inorganic chemistry of the corresponding bulk
MO_x TMOs. For the multilayered supported M₁O_x/M₂O_x/SiO₂, with M₁ representing the group 5–7 TMOs
and M₂ representing Al, Zr or Ti, the selectivity of the catalytic active sites was generally comparable
to that for the model-supported M₁O_x/SiO₂ catalysts. The reactivity of the surface VO_x, MoO_x, and ReO_x
redox sites increased by one to four orders of magnitude with the introduction of the surface modifiers;
however, the reactivity of the surface WO_x acidic site was mildly suppressed by the presence of the
surface modifiers. The reactivity of the basic CrO_x site was only mildly perturbed by the surface modifiers.
The reactivity trend of the catalytic TMOs sites was related to the electronegativity properties of the
anchoring substrate cations (Si > Al > Zr ∼ Ti).
Received 19 March 2008
Revised 30 May 2008
Accepted 3 June 2008
Available online 17 July 2008
Keywords:
Catalysts
Supported
SiO₂
Oxides
V₂O₅
CrO₃
MoO₃
WO₃
Re₂O₇
Reactivity
Kinetics
© 2008 Elsevier Inc. All rights reserved.
Temperature programmed surface reaction
TPSR
CH₃OH
HCHO
CH₃OCH₃
CO
CO₂
1. Introduction
metal oxide catalysts. The literature reports various industrial
applications for these supported catalysts, including ammoxida-
tion of 3-picoline (V₂O₅/Al₂O₃–SiO₂) [4], selective catalytic re-
duction (SCR) of nitrogen oxide with ammonia and NO reduc-
tion with CO (V₂O₅/TiO₂/SiO₂) [3,5–11], ethylene polymerization
(CrO₃/TiO₂–SiO₂) [12,13], denitrogenation of nitrogen containing
heteroaromatic compounds (Mo/Al₂O₃–SiO₂) [14,15], HDS of thio-
phene (Mo/ZrO₂–SiO₂ and MoO₃/TiO₂–SiO₂) [16–18], and alkene
metathesis and epoxidation with H₂O₂ (Re₂O₇/Al₂O₃–SiO₂) [19,20].
These promoted mixed-oxide support materials have been found
to have more favorable catalytic properties than the more conven-
tional supported MO_x/SiO₂ catalysts.
The molecular and electronic structures of the supported group
5–7 transition metal oxides on SiO₂ and surface modified SiO₂
(where surface modification is achieved with surface AlO_x, ZrO_x,
and TiO_x species) have been successfully determined [21–23].
The group 5 metal oxides maintain the monoxo surface structure
(M=O) for both the native SiO₂ and the surface modified SiO₂
supports. The surface monoxo (M=O)/dioxo (M(=O)₂) ratio of the
Various promoters or additives are generally added to the
supported MO_x/SiO₂ catalyst systems to enhance their catalytic
performance (e.g., enhanced activity, improved selectivity, ther-
mal stability). Some of the typical additives are oxides of AlO_x,
ZrO_x, and TiO_x. The interaction between Al₂O₃–SiO₂ generates
new Brønsted acidic sites at bridging Al–OH–Si bond [1]. The
ZrO₂–SiO₂ interaction also results in enhanced surface acid-
ity, as well as excellent chemical resistance to alkaline corro-
sion and low thermal expansion [2], and the interaction be-
tween TiO₂–SiO₂ also yields high thermal stability, excellent me-
chanical strength, and generation of new catalytic active acidic
sites [3]. These surface-modified SiO₂ mixed oxides are further
used as oxide supports for the supported group 5–7 transition
Corresponding author. Fax: +1 (610) 758 6555.
*
E-mail address: iew0@lehigh.edu (I.E. Wachs).
0021-9517/$ – see front matter © 2008 Elsevier Inc. All rights reserved.
doi:10.1016/j.jcat.2008.06.002

104
E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
group 6 metal oxides (CrO_x, MoO_x, and WO_x) is controlled by the
surface modifiers, however. The group 7 metal oxide of surface
ReO₄ maintains the trioxo structure (Re(=O)₃) in the presence and
absence of the surface modifiers. The promoters also have a sig-
nificant effect on the corresponding electronic structure and result
in a narrower distribution of isolated surface metal oxide species,
especially for the group 6 metal oxides. These structural changes
in the surface species also demonstrate that the surface group 5–7
transition metal oxides preferentially anchor to the surface modi-
fiers (AlO_x, ZrO_x, and TiO_x) over the exposed SiO₂ support sites.
The objective of this investigation was to determine the influ-
ence of the surface modifiers on the molecular/electronic structure-
activity/selectivity relationships for the multilayered SiO₂-sup-
ported group 5–7 metal oxide catalysts. Surface AlO_x, ZrO_x, and
TiO_x species were used as the surface modifiers in this study.
The surface chemistry and reactivity was chemically probed with
CH₃OH-temperature-programmed surface reaction (TPSR) spec-
troscopy. The CH₃OH-TPSR experiments provide information about
the nature of the catalytic active sites (redox, acidic, or basic)
and their specific surface reactivity (k_rds) toward methanol, in
which k_rds represents the first-order kinetic constant of the rate-
determining-step (RDS) [24–27]. The catalytic activities of the
model supported MO_x/SiO₂ catalyst systems were assessed and
used as benchmarks for the multilayered supported metal oxide
catalysts.
V₂O₅/SiO₂, in keeping with earlier studies), henceforth designated
MO_x/SiO₂.
The multilayered catalysts were synthesized similarly to the
model catalysts; however, the incipient wetness impregnation of
the group 5–7 transition metal oxide overlayer was added to an
existing calcined alumina-, titania-, and zirconia-surface modified
SiO₂ support. The calcination procedures followed that for the
model catalysts for the corresponding systems. The CrO₃, MoO₃,
WO₃, and Re₂O₇ on the surface modified SiO₂ supports were syn-
thesized at 3 wt% (with V₂O₅ synthesized at 5 wt%, in keeping
with earlier studies) unless specified otherwise and are designated
as M₁O_x/M₂O_x/SiO₂ (e.g., CrO₃/Al₂O₃/SiO₂).
2.2. CH₃OH-TPSR spectroscopy
The surface reactivity of the model supported MO_x/SiO₂ and
multilayered supported M₁O_x/M₂O_x/SiO₂ catalysts was determined
by CH₃OH-TPSR spectroscopy. CH₃OH is a “smart” chemical probe
molecule that distinguishes among surface acidic, redox, and ba-
sic sites [24]. The dissociative chemisorption of methanol forms
∗
surface methoxy (CH₃O ) intermediate species, the most abundant
reaction intermediate (MARI) [31,32]. The surface methoxy inter-
mediate undergoes different reaction pathways that depend the
nature of the catalytic active site: formaldehyde (HCHO) from re-
dox sites, dimethyl ether (CH₃OCH₃, DME) from acidic sites, and
CO/CO₂ from basic sites [24,33]. No additional reaction products,
such as methyl formate (MF) and dimethoxy methane (DMM),
were found in the present study. Formation of H₂O always accom-
panies the CH₃OH surface chemistry, but this was not evaluated in
the study because it does not provide any additional insight. In ad-
dition, the formation of CO was not explicitly investigated because
of its similarity to the CO₂ combustion product.
2. Experimental
2.1. Catalyst synthesis
The SiO₂-supported catalysts consist of highly dispersed metal
oxides (Al₂O₃, TiO₂, ZrO₂, V₂O₅, CrO₃, MoO₃, WO₃, and Re₂O₇) that
were successfully prepared by incipient wetness impregnation, as
described in detail elsewhere [21,28–30]. The SiO₂ support mate-
rial, amorphous SiO₂ (Cabot, Cab–O–Sil fumed silica EH-5, S.A. =
332 m²/g), was found to be more easily handled by an initial wa-
The CH₃OH-TPSR spectra were obtained with a commercial
TPSR system (Altamira Instruments, AMI-200) equipped with an
on-line quadrupole mass spectrometer (Ametek Dycor Dymaxion
with Dycor System 2000 software). The catalyst samples, typically
200–300 mg of loose powder, were placed in a quartz bubble U-
tube and held in place by glass wool. The U-tube was placed in a
◦
ter pretreatment and calcination at 500 C for 4 h with no change
in the material properties. The SiO₂ support was impregnated with
aqueous and nonaqueous (toluene) solutions of the corresponding
precursors: aluminum sec-butoxide (Al[O(CH₃)CH₂H₅]₃, Alfa Aesar,
95%), titanium isopropoxide (Ti[OCH(CH₃)₂]₄, Alfa-Aesar, 99.999%),
zirconium tert-butoxide (Zr[OC(CH₃)₃]₄, Alfa Aesar, 97%), vana-
dium triisopropoxide (VO[CHO(CH₃)₂]₃, Alfa Aesar, 97%), chromium
(III) nitrate (Cr(NO₃)₃·9H₂O, Alfa Aesar, 98.5%), ammonium hep-
tamolybdate ((NH₄)₆Mo₇O₂₄·4H₂O, Aldrich, 99.98%), ammonium
metatungstate ((NH₄)₆H₂W₁₂O₄₀·xH₂O, Pfaltz and Bauer, 99.5%),
or perrhenic acid (HReO₄, Alfa Aesar, 75–80%). The SiO₂ was ini-
◦
clamshell furnace capable of linear heating rates from 1-30 C/min
◦
up to 1200 C, with the temperatures measured by thermocouples
both at the top of the sample bed and at the center of the fur-
nace. The gas flow, accurately metered by mass flow controllers
(Brooks, model 5850E series), and the temperature setpoints were
fully computer-automated (controlled by a LabVIEW-based appli-
cation software). The exhaust line from the U-tube reactor to the
◦
mass spectrometer (MS) was maintained at ∼100 C to prevent
condensation of the methanol and reaction products. The typi-
cal protocol for obtaining the CH₃OH-TPSR spectra was as fol-
◦
tially dried for 2 h at 115 C for the nonaqueous preparations
◦
lows. The samples were first pretreated at 450 C under flow-
before synthesis inside a glove box (Vacuum Atmospheres, Omni-
Lab VAC 101965) under a nitrogen environment. After impregna-
tion, the samples were allowed to dry overnight under the nitro-
gen atmosphere. Calcination of the samples entailed ramping at
ing air (Airgas, Zero grade) for 1 h at 30 sccm, then cooled to
◦
110 C to prevent moisture condensation. The flowing gas was
switched to helium (Airgas, UHP) as the samples were allowed
◦
◦
◦
to cool further to 100 C for 30 min to remove any physically
1 C/min to 110 C and holding for 5 h under flowing N₂ (Air-
adsorbed oxygen. Then a CH₃OH/He (Airgas, Certified, 2000 ppm
CH₃OH/He) gas mixture was introduced and chemisorbed at 100 C
gas, ultra-high purity) in a programmable furnace (Thermolyne
◦
◦
model 48000), followed by another 1 C/min ramp under flow-
◦
◦
ing air (Airgas, Zero grade) to 500 C (with 450 C used for the
V₂O₅/SiO₂, in keeping with earlier studies) and holding for 6 h.
The procedure for the aqueous preparations was the same as for
the nonaqueous preparations, except that the drying and initial
calcination steps were performed in ambient air and under flow-
ing air (Airgas, zero grade), respectively. The surface modified SiO₂
supports, Al₂O₃/SiO₂, TiO₂/SiO₂, and ZrO₂/SiO₂, were synthesized
with 5 wt% metal oxide loadings on SiO₂. The model catalysts,
V₂O₅/SiO₂, CrO₃/SiO₂, MoO₃/SiO₂, WO₃/SiO₂, and Re₂O₇/SiO₂, were
synthesized with 3 wt% metal oxides on SiO₂ (with 5 wt% used for
(30 sccm) for 30–45 min, depending on the catalyst weight [24,
34]. A methanol breakthrough curve was obtained with the MS for
each run to ensure saturation of the catalyst surface. The catalyst
samples were purged with helium for 1 h to remove physically ad-
sorbed methanol, and then the sample temperature was ramped
◦
◦
at 10 C/min from room temperature to 500 C under either he-
lium or blended 1% O₂/He (Airgas, Certified, 9.735% O₂/He) gas.
The 1% O₂/He carrier flow was used for the easily reducible sup-
ported metal oxide systems because reduction produces a second,
high-temperature TPSR peak from the reduced sites, and the 1%

E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
105
Fig. 1. CH₃OH-TPSR relative selectivity of supported MO_x/SiO₂ (left) at maximum attainable surface metal oxide coverage, without the presence of crystalline MO_x NPs, and
their corresponding bulk MO_x (right). The volatile nature of bulk Re₂O₇ prevented the study of this unsupported MO_x.
O₂/He mixture prevents surface reduction and provides MS spectra
for the fully oxidized surface metal oxides.
3. Results
−
The m/e values used to detect the various TPSR products were
3.1. Model supported MO_x/SiO₂ catalysts
−
−
m/e = 30 (primary) and 29 (secondary) for HCHO, m/e = 45
(primary) and 46 (secondary) for CH₃OCH₃ (DME), m/e⁻ = 31 for
The CH₃OH-TPSR spectrum of the pure SiO₂ reflects the rela-
tively low reactivity of the native SiO₂ support and the absence
of any significant surface redox (HCHO formation), acidic (DME
formation), and basic (CO₂ formation) sites (see Supporting Infor-
mation, Fig. S1). The model SiO₂-supported metal oxide catalyst
samples used in the present study (AlO_x/SiO₂, TiO_x/SiO₂, ZrO_x/SiO₂,
VO_x/SiO₂, NbO_x/SiO₂, TaO_x/SiO₂, CrO_x/SiO₂, MoO_x/SiO₂, WO_x/SiO₂,
and ReO_x/SiO₂) were previously shown to be 100% dispersed as
surface oxides on the SiO₂ support by Raman, IR, UV–vis, XANES,
and solid-state ⁵¹V and ²⁷Al NMR spectroscopy [21–23,38–52]. The
CH₃OH-TPSR spectra of the model SiO₂ catalyst systems reveal
that adding the surface metal oxides introduced surface redox,
acidic, and basic catalytic active sites (see Supporting Information,
Figs. S2–S11). The peak temperature, T_p, and k_rds of the model sup-
ported MO_x/SiO₂ catalytic systems for the formation of DME (see
Table 1), HCHO, and CO₂ (see Table 2), along with the relative peak
area ratios of HCHO:DME:CO₂ (see Table 3) for each system, are
summarized below. The selectivity and k_rds information are plot-
ted in Figs. 1 and 2, to facilitate visual inspection of the data. The
corresponding E_act values are tabulated elsewhere (see Supporting
Information, Table S1). In general, the CH₃OH-TPSR spectral inten-
sity of the reaction products for each supported MO_x/SiO₂ system
increased with surface MO_x coverage and decreased slightly in T_p
with surface coverage. The increase in MS signal intensity (area
under the TPSR curve) was proportional to the number of catalytic
active sites, and the slight drop in T_p values was related to the
decreased concentration of the less reactive surface Si–OCH₃ inter-
mediates with increasing surface MO_x coverage. A decrease in the
−
−
CH₃OH, m/e = 28 for CO, and m/e = 44 for CO₂. In addition,
◦
reaction-limited CH₃OH also was formed at T_p ∼ 170–200 C from
∗
∗
the recombination of the surface CH₃O and H species. The low
T_p value indicates the ease at which the recombination occurred,
whereas previous transient kinetic isotopic studies with CH₃OH
and CD₃OD revealed the efficient formation of CH₃OD and CD₃OH
species [35]. The contribution of the HCHO cracking fraction of
CH₃OH was carefully subtracted out of the apparent HCHO MS sig-
nal when it overlapped with the true HCHO signal. The relative
selectivity toward each desorption product was determined from
the areas under the TPSR curves using a Lorentzian fit.
The surface kinetic parameters (E_act and k_rds) for the surface
methoxy reactions to HCHO, CH₃OCH₃, and CO/CO₂ were obtained
directly from the CH₃OH-TPSR spectra. The RDS for the unimolec-
∗
ular surface CH₃O dehydrogenation to HCHO involves breaking
the surface methoxy C–H bond [33]. The RDS for CH₃OCH₃ for-
mation involves unimolecular surface methoxy C–O bond scission
[26,36]. Formation of CO/CO₂ proceeds through conversion of the
∗
∗
surface CH₃O to surface formate (HCOO ), and the RDS involves
breaking either the surface formate C–H or C–O bond unimolecular
reactions [25]. The unimolecular aspect of the RDS for the differ-
ent reaction pathways allows application of the first-order Redhead
equation [37] to determine the E_act for the surface reactions,
ꢀ
ꢁ
ꢀ
ꢁ
E_act
RT_p²
ν
β
−E_act
=
exp
,
(1)
RT_p
in which T_p is the CH₃OH-TPSR peak temperature of the reaction
T_p corresponds to a decrease in E_act and an increase in k_rds
.
−1
product, R is the gas constant (1.987 cal/mol K), ν = 10¹³
s
for
Figs. 1 and 2 also compare the selectivity and activity from
the CH₃OH-TPSR studies of the model supported MO_x/SiO₂ cat-
alysts with those of their corresponding unsupported, bulk MO_x
catalysts. The selectivity patterns of the surface MO_x catalytic ac-
tive sites on SiO₂ were comparable to those of their corresponding
bulk MO_x oxides, with one exception: The supported TiO₂/SiO₂ cat-
alyst system exhibited significant redox character in addition to
DME formation, whereas the bulk TiO₂ system yielded DME ex-
clusively. With few exceptions, the bulk MO_x catalysts tended to
be more active than their corresponding SiO₂-supported surface
MO_x species. The difference reflects the changes associated with
◦
first-order kinetics [34], and β is the heating rate (10 C/min). The
RDS of the surface methoxy intermediate conversion to DME and
HCHO, k_rds, is a function of E_act (and hence T_p) and is determined
by
ꢀ
ꢁ
−E_act
k_rds = v exp
,
(2)
RT
in which T is a reference temperature used for the comparison of
k_rds values. In keeping with previous investigations, this study also
◦
used T = 230 C as the reference temperature.

106
E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
◦
Fig. 2. k_rds of HCHO, DME and CO₂ of MO_x/SiO₂ at 230 C for low and high (maximum dispersion) metal oxide coverage. The k_rds values of bulk oxides are shown for
reference with notation as stars [24–27].
anchoring the isolated surface MO_x species on the SiO₂ surface.
In general, the SiO₂-supported MO_x species had comparable selec-
tivity to and slightly lower surface reactivity than their bulk MO_x
counterparts.
Table 1
CH₃OH-TPSR surface kinetics (k_rds) of model supported MO_x/SiO₂ catalysts (M = Al,
Ti, Zr, V, Nb, Ta, Cr, Mo, W, and Re) for surface methoxy dehydration to DME
Wt T_p
k_rds (DME) T_p
k_rds (DME) T_p
k_rds (DME) T_p
k_rds (DME)
−1
◦
−1
◦
−1
◦
−1
◦
(%) ( C) (s
)
( C) (s
)
( C) (s
)
( C) (s
)
The k_rds (DME) trends for the model supported MO_x/SiO₂ metal
oxides at low and high maximum dispersion as a function of the
metal oxide oxidation state or group number also are shown in
Fig. 2. The supported Al₂O₃/SiO₂, CrO₃/SiO₂, and WO₃/SiO₂ sys-
tems had the fastest surface kinetics for DME formation and in-
cluded the most active surface acid sites. The supported TiO₂/SiO₂,
ZrO₂/SiO₂, and Re₂O₇/SiO₂ catalysts were two to four orders of
magnitude slower in k_rds for DME formation; therefore, the k_rds
values indicate the following periodic group trend of the metal
oxide cation oxidation state: (+3) > (+6) > (+5) > (+4) ∼ (+7).
Each group in this trend was approximately one order of magni-
tude greater than the next, starting with the fastest k_rds (DME) for
supported Al₂O₃/SiO₂. The k_rds values also were generally higher
at higher metal oxide loading, and the periodic group trend held
true for all loading coverages. The k_rds (DME) values for the bulk
oxides of Al₂O₃, TiO₂, ZrO₂, Nb₂O₅, Ta₂O₅, Cr₂O₃, and WO₃, indi-
cated by the star symbol in Fig. 2 were slightly greater (within one
order of magnitude) than their corresponding SiO₂-supported ox-
ides [24]. Only the bulk V₂O₅ and MoO₃ bulk metal oxides did not
exhibit activity for DME formation during CH₃OH-TPSR.
The k_rds trends for the formation of HCHO of the model
MO_x/SiO₂ systems also are shown in Fig. 2 for the same surface
metal oxide coverages. The supported CrO₃/SiO₂ system had the
most active surface redox catalytic sites, and its k_rds value was
approximately three orders of magnitude greater than those for
the supported V₂O₅/SiO₂, Re₂O₇/SiO₂, and MoO₃/SiO₂ systems. The
bulk oxides of ZrO₂, V₂O₅, Nb₂O₅, Ta₂O₅, Cr₂O₃, and MoO₃ and
their k_rds (HCHO) values, indicated by the star symbol in Fig. 2,
generally were several orders of magnitude greater than their cor-
responding SiO₂-supported oxide catalysts. Only the bulk Al₂O₃,
TiO₂, and WO₃ systems did not give rise to HCHO formation dur-
ing CH₃OH-TPSR. The least active redox catalytic sites were found
for the supported TiO₂/SiO₂, ZrO₂/SiO₂, and Nb₂O₅/SiO₂ catalysts,
which were another order of magnitude lower in k_rds (HCHO).
Only the supported V₂O₅/SiO₂, CrO₃/SiO₂, and Re₂O₇/SiO₂ cata-
lysts gave rise to CO₂ production (see Figs. 1 and 2). Although CO₂
formation is reflective of basic catalytic active sites, CO₂ formation
also can arise from decomposition of surface Si–OCH₃ interme-
Al₂O₃/SiO₂
1
3
5
270 6.82E−4
248 3.21E−3
241 5.26E−3
234 8.60E−3
10
TiO₂/SiO₂
V₂O₅/SiO₂
CrO₃/SiO₂
1
3
5
8
10
12
377 3.56E−7
340 4.88E−6
330 9.89E−6
278 3.88E−4
278 3.88E−4
372 5.07E−7
364 8.93E−7
310 4.06E−5
360 1.19E−6
ZrO₂/SiO₂
285 2.37E−4
Nb₂O₅/SiO₂
MoO₃/SiO₂
1
5
8
10
15
380 2.88E−7
378 3.31E−7
357 1.47E−6
360 1.19E−6
357 1.47E−6
328 1.14E−5
326 1.31E−5
324 1.51E−5
320 2.00E−5
–
–
–
–
Ta₂O₅/SiO₂
WO₃/SiO₂
Re₂O₇/SiO₂
1
3
5
6
8
330 9.89E−6
330 9.89E−6
308 4.68E−5
295 1.17E−4
300 8.23E−5
–
–
380 2.88E−7
330 9.89E−6
366 7.75E−7
324 1.51E−5
324 1.51E−5
10
diates and readsorption/oxidation of the HCHO reaction product.
Note that these supported catalysts also have active redox sites for
HCHO production. We do not discuss CO₂ formation further here,
because of the uncertain nature of the origin of CO₂ production.
3.2. Multilayered supported M₁O_x/M₂O_x/SiO₂ catalysts
The surface chemistry and kinetics of the group 5–7 surface
metal oxides (VO_x
titania-, and zirconia-surface modified SiO₂ supports were also
chemically probed with CH₃OH-TPSR. The resulting catalytic activ-
ity and selectivity patterns are shown in Figs. 3 and 4, respectively,
and the k_rds values are listed in Table 4 (also see Supporting Infor-
, CrO_x, MoO_x, WO_x, and ReO_x) on the alumina-,

E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
107
Fig. 3. k_rds of supported 3%M₁O_x/5%M₂O_x/SiO₂ (M₁ = V, Cr, Mo, W, and Re; M₂ = Al, Zr, and Ti, with exception of V₂O₅ at 5%) for surface methoxy decomposition to DME,
HCHO, and CO₂.
Table 2
CH₃OH-TPSR surface kinetics (k_rds) of model supported MO_x/SiO₂ catalysts (M = Al, Ti, Zr, V, Nb, Ta, Cr, Mo, W, and Re) for surface methoxy dehydrogenation to HCHO (left
columns) and formation of CO₂ (right column)
Wt
(%)
T_p
( C)
k_rds (HCHO)
−1
T_p
( C)
k_rds (HCHO)
−1
T_p
( C)
k_rds (HCHO)
−1
T_p
( C)
k_rds (HCHO)
−1
T_p
( C)
k_rds (CO₂)
−1
◦
◦
◦
◦
◦
(s
)
(s
)
(s
)
(s
)
(s
)
a
Al₂O₃/SiO₂
1
3
5
–
–
–
–
–
–
–
–
10
a
TiO₂/SiO₂
V₂O₅/SiO₂
345
CrO₃/SiO₂
V₂O₅/SiO₂
370
1
3
5
400
6.98E−8
3.42E−6
9.89E−6
200
183
9.38E−2
3.82E−1
5.84E−7
2.40E−6
418
386
1.95E−8
1.88E−7
330
350
8
10
12
305
292
5.78E−5
1.45E−4
346
344
3.19E−6
3.68E−6
386
1.88E−7
a
a
a
ZrO₂/SiO₂
Nb₂O₅/SiO₂
460
MoO₃/SiO₂
CrO₃/SiO₂
1
3
5
–
–
9.87E−10
333
350
8.00E−6
2.40E−6
274
280
5.15E−4
3.37E−4
367
356
370
370
7.22E−7
1.57E−6
5.84E−7
5.84E−7
455
445
425
1.41E−9
2.86E−9
1.18E−8
8
10
15
350
2.40E−6
a
a
Ta₂O₅/SiO₂
WO₃/SiO₂
Re₂O₇/SiO₂
Re₂O₇/SiO₂
1
3
5
8
10
–
–
–
–
–
–
–
–
–
–
330
355
338
9.89E−6
1.69E−6
5.62E−6
386
380
370
1.88E−7
2.88E−7
5.84E−7
338
340
5.62E−6
4.88E−6
a
◦
Denotes catalytic system with no formation of CO₂ product below 500 C.
mation Figs. S12–S16 for CH₃OH-TPSR spectra and T_p values and
Table S2 for E_act values). With the exception of the surface AlO_x
modifier, which dominates the acidic character of the catalysts, the
selectivity of the multilayered catalysts are mainly comparable to
the model supported MO_x/SiO₂ catalysts without the surface mod-
ifiers. The presence of the surface modifiers generally enhanced
the activity of the surface VO_x, MoO_x, and ReO_x redox sites and
depressed the activity of surface WO_x acid sites. The DME forma-
tion for multilayered catalysts with surface AlO_x modifiers was not
taken into consideration because of the significant contribution of
the surface AlO_x sites to DME production.
The HCHO formation k_rds values for the multilayered supported
catalysts, as shown in Fig. 3, exhibited significantly enhanced sur-
face reactivity compared with the model reference supported sys-
tems (represented by the black circles) for the redox supported
V₂O₅/SiO₂, MoO₃/SiO₂, and Re₂O₇/SiO₂ catalysts. The surface mod-
ifiers increased k_rds (HCHO) by one to three orders of magnitude,
with the exception of the supported chromia system, which was
not significantly affected and decreased slightly in activity. These
results agree well with findings from previous steady-state CH₃OH
oxidation studies in which the turnover frequency (TOF) [53] in-
creased by more than an order of magnitude with addition of
the surface modifiers for HCHO formation [1–3,54]. CH₃OH oxi-

108
E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
dation steady-state reaction studies for supported CrO₃/TiO_x/SiO₂
confirmed that the TOF and selectivity toward HCHO did not differ
appreciably from those for the model CrO₃/SiO₂ system [55]. The
enhanced redox activity did not originate from the less active sur-
face titania or zirconia sites, because these formed HCHO at higher
addition of the surface modifiers. The presence of the very active
surface AlO_x sites appeared to dominate the overall acidity; conse-
quently, the AlO_x-containing multilayered catalyst systems cannot
be considered in any analysis. In contrast, the supported ZrO_x and
TiO_x sites exhibited surface acidic sites that were relatively un-
reactive and produced DME only at elevated temperatures, above
those seen for the group 5–7 supported metal oxides. The surface
modifiers dramatically enhanced the DME formation kinetics of the
◦
temperatures (T_p > 350 C). The surface modifiers did not appre-
ciably affect the redox character of the supported tungsta systems,
because they generally did not yield HCHO, with the exception of
the supported WO₃/TiO_x/SiO₂ catalyst, which created weak redox
◦
◦
both surface VO_x (T_p from ∼330–340 C to ∼235–250 C with k_rds
◦
surface sites at a high T_p ∼ 436 C.
Table 3
The DME formation k_rds for the multilayered supported metal
HCHO:DME:CO₂ ratios for model supported MO_x/SiO₂ catalysts
oxide catalysts, as shown in Fig. 3, also were strongly influenced by
Wt (%)
HCHO:DME:CO₂ ratio (A_HCHO:A_DME:A_CO
)
2
Al₂O₃/SiO₂
1
3
5
0:1:0
0:1:0
0:1:0
0:1:0
10
TiO₂/SiO₂
4:1:0
V₂O₅/SiO₂
8:1:27
CrO₃/SiO₂
1
3
3:1:45
2:1:60
5
8
3:1:0
2:1:0
20:1:35
10
12
25:1:37
24:1:33
2:1:0
ZrO₂/SiO₂
0:1:0
Nb₂O₅/SiO₂
0.20:1:0
MoO₃/SiO₂
1
3
1:0:0
1:0:0
5
8
10
15
0.20:1:0
0.20:1:0
0.20:1:0
0.17:1:0
0.13:1:0
0.08:1:0
0.08:1:0
1:0:0
Ta₂O₅/SiO₂
0:1:0
WO₃/SiO₂
Re₂O₇/SiO₂
1
3
5
0:1:0
0:1:0
0:1:0
0:1:0
1:0:9
13:1:98
12:1:90
0:1:0
Fig. 4. CH₃OH-TPSR relative selectivity of supported 3%M₁O_x/5%M₂O_x/SiO₂ (except
V₂O₅ with 5%) for multilayered catalysts. M₁ represent the group 5–7 transition
metal oxides and M₂ represents surface AlO_x, TiO_x and ZrO_x. The column labeled
none indicates that no surface M₂O_x species have been added.
6
8
10
0.07:1:0
0.07:1:0
Table 4
CH₃OH-TPSR surface kinetics (k_rds) of supported 3%M₁O_x/5%M₂O_x/SiO₂ (M₁ = V, Cr, Mo, W, and Re; M₂ = Al, Zr, and Ti, with exception of V₂O₅ at 5%) for surface methoxy
decomposition to DME, HCHO, and CO₂. The peak area ratio of HCHO:DME for each system is also listed
M₁O_x/M₂O_x/SiO₂ multilayered catalyst systems
T_p
( C)
k_rds
(s
T_p
( C)
k_rds
(s
T_p
( C)
k_rds
(s
T_p
( C)
k_rds
(s
T_p
( C)
k_rds
◦
−1
◦
−1
◦
−1
◦
−1
◦
−1
(s )
)
)
)
)
M₂O_x
DME
M₁O_x = V₂O₅
CrO₃
MoO₃
WO₃
Re₂O₇
None
AlO_x
ZrO_x
TiO_x
340
240
250
246
4.88E−6
5.64E−3
2.79E−3
3.70E−3
278
270
280
277
3.88E−4
6.82E−4
3.37E−4
4.17E−4
–
–
308
236
315
347
4.68E−5
7.47E−3
2.85E−5
2.97E−6
380
240
242
312
2.88E−7
5.64E−3
4.90E−3
3.53E−5
246
300
320
3.70E−3
8.23E−5
2.00E−5
HCHO
None
AlO_x
ZrO_x
TiO_x
330
240
235
240
9.89E−6
5.64E−3
8.02E−3
5.64E−3
183
205
200
202
3.82E−1
6.60E−2
9.38E−2
8.15E−2
350
264
278
230
2.40E−6
1.04E−3
3.88E−4
1.14E−2
–
–
–
436
–
–
–
355
314
260
278
1.69E−6
3.06E−5
1.38E−3
3.88E−4
5.43E−9
CO₂
None
AlO_x
ZrO_x
TiO_x
350
280
262
262
2.40E−6
3.37E−4
1.20E−3
1.20E−3
280
270
287
280
3.37E−4
6.82E−4
2.06E−4
3.37E−4
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
380
334
286
308
2.88E−7
7.45E−6
2.21E−4
4.68E−5
HCHO:DME:CO₂ ratio (A_HCHO:A_DME:A_CO
)
2
None
AlO_x
ZrO_x
TiO_x
20:1:58
2:1:18
18:1:150
7:1:54
2:1:42
2:1:60
2:1:70
2:1:90
1:0:0
0.5:1:0
2:1:0
4:1:0
0:1:0
0:1:0
0:1:0
2:1:0
13:1:82
0.33:1:1
1:1:10
8:1:52

E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
109
−6
−3
increasing from ∼10
to ∼10
s
⁻¹) and surface ReO_x (T_p de-
bulk M₁O_x transition metal oxides. Although some contribution
may come from the different molecular structures of the silica-
supported M₁O_x species compared with their unsupported M₁O_x
counterparts, the major effect on the surface M₁O_x species ap-
pears to be their coordination to the silica support, which has a
high cation electronegativity [57].
◦
−7
creases from ∼380 to ∼240 C and k_rds increasing from ∼10
to
−3
∼10
s
⁻¹) species. For the supported MoO_x systems, the surface
modifiers created surface acidic character that were absent on the
model system, possibly originating from the surface ZrO_x and TiO_x
sites. The surface modifiers did not appear to appreciably affect
the acidic behavior of the supported chromia and tungsta systems.
CH₃OH oxidation steady-state reaction studies for CrO₃/TiO_x/SiO₂
confirmed that the TOF and selectivity toward DME were not ap-
preciably different from those for the model supported CrO₃/SiO₂
catalyst [55].
4.2. Multilayered supported M₁O_x/M₂O_x/SiO₂ catalysts
The addition of the surface modifiers in the multilayered sup-
ported metal oxide catalysts generally did not significantly al-
ter the CH₃OH-TPSR product selectivity (see Fig. 4). The acidic
supported WO₃/TiO₂/SiO₂ catalyst exhibited some redox charac-
ter with the addition of surface TiO_x, and the redox supported
MoO₃/ZrO₂/SiO₂ and MoO₃/TiO₂/SiO₂ catalyst systems exhibited
some acidic character with the addition of surface ZrO_x and TiO_x.
Consequently, the surface M₁O_x catalytic active sites in the multi-
layered supported M₁O_x/M₂O_x/SiO₂ catalysts were found to mostly
retain their intrinsic chemical properties, because the product se-
lectivity demonstrated no appreciable change from the introduc-
tion of the surface modifiers.
The introduction of surface AlO_x, TiO_x, and ZrO_x modifiers
onto the SiO₂-support dramatically enhanced the k_rds redox values
(by as much as a factor of ∼10⁴) of the supported M₁O_x cat-
alytic active sites. All of the multilayered supported VO_x/M₂O_x/SiO₂
and ReO_x/M₂O_x/SiO₂ catalyst systems contained the same sur-
face monoxo VO₄ and trioxo ReO₄ structures, respectively. Thus,
the enhanced redox reactivity cannot be related to local molec-
ular structural changes, but instead must be a consequence of
the ligand effect of the different substrate cations (Si, Al, Ti, and
Zr). We propose that the enhanced redox activity is related to
the lower electronegativity of substrate cations, Si > Al > Ti ∼ Zr,
which inversely affects the electron density on the bridging V–O-
support bond. Several recent theoretical DFT/ab initio calculations
have concluded that for supported vanadia catalytic systems, the
bridging V–O-support bond is the most energetically favorable
methanol chemisorption site on the surface VO_x structure [51,58–
60]. The inverse surface reactivity trend with cation electronegativ-
ity also was seen for the acidic sites of the multilayered supported
WO₃/M₂O_x/SiO₂ catalyst systems. For the acidic surface WO_x cat-
alytic active sites, the fewer the number of electronegative cations
introduced, the greater the resulting electron density on the bridg-
ing W–O-support bonds, which appeared to mildly suppress their
acidic activity rather than produce catalytic enhancement. Similarly
for the basic multilayered supported CrO₃/M₂O_x/SiO₂ catalysts, in-
troduction of the less electronegative surface Al, Zr, and Ti cations
had only a minor effect on the overall reactivity. Thus, the sur-
face AlO_x, ZrO_x, and TiO_x modifiers appear to have the most pro-
nounced catalytic enhancing effect on the surface redox catalytic
active sites on SiO₂.
4. Discussion
4.1. Model supported M₁O_x/SiO₂ catalysts
The selectivity pattern of the model silica-supported surface
M₁O_x catalytic active sites during CH₃OH-TPSR was similar to that
of the corresponding unsupported, bulk M₁O_x transition metal ox-
ides (see Fig. 1). This similarity indicates that the intrinsic redox,
acidic, and basic characteristics of each transition metal oxide were
retained when anchored onto the SiO₂ surface. One exception to
this trend is the supported TiO_x species, which exhibited signifi-
cant redox character compared with bulk TiO₂, dominated by its
acidic character. Additional characterization studies are needed to
fully understand the origin of the enhanced redox characteristics
of the surface TiO_x species on SiO₂.
The selectivity trend is related to the known inorganic chem-
istry properties of the bulk metal oxides [56]. First, the first-row
transition metal oxides (TMOs) were more easily reducible than
the second- and third-row TMOs [56], which qualitatively suggests
that the first-row transition metal oxides will be more active for
oxidation reactions. As demonstrated earlier, VO_x was more active
and more reducible than NbO_x and TaO_x, and CrO_x was more ac-
tive and reducible than both MoO_x and WO_x. Second, the redox
properties were enhanced with the transition metal oxide oxida-
tion state (+4 < +5 < +6 < +7) [56]. As shown in Fig. 2, the
redox k_rds values increased as Ti⁺⁴ < V⁺⁵ < Cr
for the first-row
+6
+4
+5
+6
TMOs, as Zr ∼ Nb < Mo
for the second-row TMOs, and as
+5
+6
+7
Ta < W < Re for the third-row TMOs. These redox reactiv-
ity values for the supported MO_x/SiO₂ catalysts correlate well with
the periodic trends from inorganic chemistry properties.
Combining the molecular structural information [21] with the
current CH₃OH-TPSR chemical probe study findings allows us to
examine possible structure–activity relationships for the model
group 4–7 supported MO_x/SiO₂ catalysts. It does not appear
that the local molecular structure of the surface MO_x species
on SiO₂ was the dominant factor in determining the surface re-
dox, acidic, and basic characteristics. For example, although the
group 5 supported metal oxide catalysts (V₂O₅/SiO₂, Nb₂O₅/SiO₂,
Ta₂O₅/SiO₂) exhibited the same surface molecular structure, an
isolated monoxo O=M(–O–Si)₃ structure, the surface VO_x was
dominated by redox characteristics, whereas the surface NbO_x and
TaO_x were primarily acidic sites. Similarly, although the group 6
supported metal oxide catalysts (CrO₃/SiO₂, MoO₃/SiO₂, and WO₃/
SiO₂) had the same surface molecular structures of predominantly
isolated dioxo (O=)₂M(–O–Si)₂ species, the three systems exhib-
ited different reactivity characteristics. Therefore, the local struc-
ture of the dehydrated surface MO_x species on SiO₂ does not
appear to determine the surface reactivity of the catalytic active
sites.
5. Conclusion
In this work, the surface reactivity of model supported M₁O_x/
SiO₂ and multilayered supported M₁O_x/M₂O_x/SiO₂ catalysts (where
M₁ represents the group 5–7 transition metal oxides and M₂
represents Al, Zr, or Ti) were chemically probed by CH₃OH-TPSR
spectroscopy. For the model supported M₁O_x/SiO₂ catalysts, the
k_rds activity trend was seen to follow the periodic trends for in-
organic chemistry properties; the first-row transition metal ox-
ides were more easily reducible than the second- and third-row
metal oxides, and redox activity increased with oxidation state
(+4 < +5 < +6 < +7). The inverse trend was found to hold for
the acidic activity of the model supported MO_x/SiO₂ catalysts. For
the multilayered supported M₁O_x/M₂O_x/SiO₂ catalytic systems, the
surface M₂O_x modifiers had no significant effect on the selectivity
However, the surface reactivity of the model silica-supported
M₁O_x catalytic active sites, as chemically probed by CH₃OH-TPSR,
was affected by anchoring of the M₁O_x transition metal oxides to
the SiO₂ support. The activity of the surface M₁O_x catalytic active
sites on SiO₂ was generally lower than that of their unsupported,

110
E.L. Lee, I.E. Wachs / Journal of Catalysis 258 (2008) 103–110
of the surface M₁O_x catalytic active sites, but the surface modi-
fiers did have a significant effect on the catalytic activity of the
SiO₂-supported metal oxide catalysts. The k_rds activity of the re-
dox surface vanadia, molybdena, and rhenia catalytic active sites
was enhanced by ∼10¹–10⁴. The presence of the surface modi-
fiers only mildly perturbed the reactivity of the basic surface CrO_x
sites, but suppressed the reactivity of the acidic surface WO_x cat-
alytic actives sites. In general, the selectivity was controlled by the
intrinsic properties of each surface M₁O_x site, and the surface re-
activity was significantly influenced by the anchoring surface M₂O_x
ligands. Thus, the catalytic activity was controlled by the M₂O_x
ligand according to the electronic requirements of the different re-
action pathways and the electronegativity (Si > Al > Ti ∼ Zr) of the
anchoring sites or ligands.
[17] S. Damyanova, M.A. Centeno, L. Petrov, P. Grange, Spectrochim. Acta
(2001) 2495.
[18] B.M. Reddy, B. Chowdhury, P.G. Smirniotis, Appl. Catal. A 211 (2001) 19.
[19] J.A. Moulijn, J.C. Mol, J. Mol. Catal. 46 (1988) 1.
[20] D. Mandelli, M.C.A. van Vliet, U. Arnold, R.A. Sheldon, U. Schuchardt, J. Mol.
Catal. A 168 (2001) 165.
[21] E.L. Lee, I.E. Wachs, J. Phys. Chem. C 111 (2007) 14410.
[22] E.L. Lee, I.E. Wachs, J. Phys. Chem. C 112 (2008) 6487.
[23] E.L. Lee, I.E. Wachs, J. Phys. Chem. C, submitted for publication.
[24] M. Badlani, I.E. Wachs, Catal. Lett. 75 (2001) 137.
[25] X. Wang, I.E. Wachs, Catal. Today 96 (2004) 211.
[26] T. Kim, A. Burrows, C.J. Kiely, I.E. Wachs, J. Catal. 246 (2007) 370.
[27] I.E. Wachs, J.-M. Jehng, W. Ueda, J. Phys. Chem. B 109 (2005) 2275.
[28] X. Gao, S.R. Bare, J.L.G. Fierro, M.A. Banares, I.E. Wachs, J. Phys. Chem. B 102
(1998) 5653.
A 57
[29] X. Gao, S.R. Bare, B.M. Weckhuysen, I.E. Wachs, J. Phys. Chem. B 102 (1998)
10842.
[30] J.M. Jehng, I.E. Wachs, J. Phys. Chem. 95 (1991) 7373.
[31] L.J. Burcham, L.E. Briand, I.E. Wachs, Langmuir 17 (2001) 6164.
[32] L.J. Burcham, G. Deo, X. Gao, I.E. Wachs, Top. Catal. 11/12 (2000) 85.
[33] J.M. Tatibouet, Appl. Catal. A 148 (1997) 213.
[34] L.E. Briand, W.E. Farneth, I.E. Wachs, J. Catal. 208 (2002) 301.
[35] J.M. Tatibouet, H. Lauron-Pernot, J. Mol. Catal. A 171 (2001) 205.
[36] I.E. Wachs, T. Kim, E.I. Ross, Catal. Today 116 (2006) 162.
[37] P.A. Redhead, Vacuum 12 (1962) 213.
Acknowledgments
Funding for this study was provided by the U.S. Department of
Energy, Basic Energy Sciences (grant DE-FG02-93ER14350).
Supplementary material
[38] J.-M. Jehng, W.-C. Tung, C.-H. Huang, I.E. Wachs, Microporous Mesoporous
Mater. 99 (2007) 299.
The online version of this article contains additional supple-
mentary material: Tables S1–S2 and Figs. S1–S16.
Please visit DOI: 10.1016/j.jcat.2008.06.002.
[39] T. Tanaka, H. Nojima, T. Yamamoto, S. Takenaka, T. Funabiki, S. Yoshida, Phys.
Chem. Chem. Phys. 1 (1999) 5235.
[40] M. Cornac, A. Janin, J.C. Lavalley, Polyhedron 5 (1986) 183.
[41] C.C. Williams, J.G. Ekerdt, J.-M. Jehng, F.D. Hardcastle, A.M. Turek, I.E. Wachs, J.
Phys. Chem. 95 (1991) 8781.
References
[42] H. Hu, S.R. Bare, I.E. Wachs, J. Phys. Chem. 99 (1995) 10897.
[43] M.A. Banares, H. Hu, I.E. Wachs, J. Catal. 150 (1994) 407.
[44] W. Zhang, A. Desikan, S.T. Oyama, J. Phys. Chem. 99 (1995) 14468.
[45] N. Ohler, A.T. Bell, J. Phys. Chem. B 109 (2005) 23419.
[46] N. Das, H. Eckert, H. Hu, I.E. Wachs, J.F. Walzer, F.J. Feher, J. Phys. Chem. 97
(1993) 8240.
[47] H. Eckert, I.E. Wachs, J. Phys. Chem. 93 (1989) 6796.
[48] M. Baltes, A. Kytokivi, B.M. Weckhuysen, R.A. Schoonheydt, P. van der Voort,
E.F. Vansant, J. Phys. Chem. B 105 (2001) 6211.
[1] X. Gao, I.E. Wachs, J. Catal. 192 (2000) 18.
[2] X. Gao, J.L.G. Fierro, I.E. Wachs, Langmuir 15 (1999) 3169.
[3] X. Gao, S.R. Bare, J.L.G. Fierro, I.E. Wachs, J. Phys. Chem. B 103 (1999) 618.
[4] B.N. Reddy, M. Subrahmanyam, Langmuir 8 (1992) 2072.
[5] R. Mariscal, M. Galan-Fereres, J.A. Anderson, L.J. Alemany, J.M. Palacios, J.L.G.
Fierro, in: G. Centi, C. Cristiani, P. Forzatti, S. Perathoner (Eds.), Environmental
Catalysis, SCI, Rome, 1995, p. 223.
[49] M.A. Vuurman, I.E. Wachs, D.J. Stufkens, A. Oskam, J. Mol. Catal. 80 (1993) 209.
[50] M.A. Vuurman, D.J. Stufkens, A. Oskam, J. Mol. Catal. 76 (1992) 263.
[51] R.Z. Khaliullin, A.T. Bell, J. Phys. Chem. B 106 (2002) 7832.
[52] B.M. Weckhuysen, I.E. Wachs, R.A. Schoonheydt, Chem. Rev. 96 (1996) 3327.
[53] M. Boudart, Chem. Rev. 95 (1995) 661.
[54] J.-M. Jehng, I.E. Wachs, Catal. Lett. 13 (1992) 9.
[55] J.-M. Jehng, I.E. Wachs, B.M. Weckhuysen, R.A. Schoonheydt, J. Chem. Soc. Fara-
day Trans. 91 (1995) 953.
[56] N.N. Greenwood, A. Earnshaw, Chemistry of the Elements, Pergamon Press,
Elmsford, NY, 1989.
[57] R.T. Sanderson, J. Chem. Educ. 65 (1988) 112.
[58] J.L.Bronkema, A.T. Bell, J. Phys. Chem. C 111 (2007) 420.
[59] J. Dobler, M. Pritzsche, J. Sauer, J. Am. Chem. Soc. 127 (2005) 10861.
[60] N. Magg, B. Immaraporn, J.B. Giorgi, T. Schroeder, M. Baumer, J. Dobler, Z.
Wu, E. Kondratenko, M. Cherian, M. Baerns, P.C. Stair, J. Sauer, H.J. Freund, J.
Catal. 226 (2004) 88.
[6] M.D. Amiridis, J.P. Solar, Ind. Eng. Chem. Res. 35 (1996) 978.
[7] R.A. Rajadhyaksha, G. Hausinger, H. Zeilinger, A. Ramstetter, H. Schmeiz, H.
Knözinger, Appl. Catal. 51 (1989) 67.
[8] R.A. Rajadhyaksha, H. Knözinger, Appl. Catal. 51 (1989) 81.
[9] P. Wauthoz, T. Machej, P. Grange, Appl. Catal. 69 (1991) 149.
[10] E.T.C. Vogt, A. Boot, A.J. van Dillen, J.W. Geus, F.J.J.G. Janssen, F.M.G. van den
Kerkhof, J. Catal. 114 (1988) 313.
[11] M. Galan-Fereres, R. Mariscal, L.J. Alemany, J.L.G. Fierro, J. Chem. Soc. Faraday
Trans. 90 (1994) 3711.
[12] M.P. McDaniel, M.B. Welsh, M.J. Dreiling, J. Catal. 82 (1983) 98.
[13] S.J. Conway, J.W. Falconer, C.H. Rochester, J. Chem. Soc. Faraday Trans. 85 (1989)
71.
[14] S. Rajagopal, T.L. Grimm, D.J. Collins, R. Miranda, J. Catal. 137 (1992) 453.
[15] M. Henker, K.P. Wendlandt, J. Valyon, P. Bornmann, Appl. Catal. 69 (1991) 205.
[16] S. Damyanova, A. Docteva, C. Vladov, L. Petrov, P. Grange, B. Delmon, Belg.
Chem. Commun. 30 (1999) 306.