The selective hydrogenation
of acetylene has been studied over
AgPd and CuPd catalysts. Controlled surface reactions were used to
synthesize these bimetallic nanoparticles on both TiO2 and
SiO2 supports. Chemisorption measurements of the bimetallic
catalysts indicate that Pd prefers to be on the nanoparticle surface
with a Cu parent catalyst, while Pd prefers to be subsurface with
a Ag parent catalyst. From energy-dispersive X-ray spectroscopy analysis,
the composition of the nanoparticles is determined to be more uniform
on the SiO2 support compared to that on the TiO2 support. X-ray absorption spectroscopy results indicate that, after
reduction, the CuPd bimetallic catalysts have some Pd–Pd bonds,
but the average number of Pd–Pd bonds decreases after reaction.
Infrared spectra of the adsorbed CO show that an increased fraction
of isolated Pd species are present on the bimetallic catalysts compared
to those on the monometallic catalysts. Adsorption of acetylene and
ethylene, however, indicates adsorbed surface species that require
contiguous Pd ensembles. These results suggest that the surface structure
of the catalyst is highly dynamic and influenced by the gas environment,
as well as the support. The catalysts are active for the selective
hydrogenation of acetylene in an ethylene-rich environment under mild
conditions. Over all catalysts, the ethylene selectivity is greater
than 92%; however, improved selectivity is observed over the bimetallic
catalysts compared to that over the monometallic Pd catalysts. An
ethylene selectivity of 100% is observed over the CuPd0.08/TiO2 catalyst. The highest acetylene conversion rate
per gram of Pd is observed over the CuPd0.02/TiO2 catalyst, while the highest turnover frequency is found over the
AgPd0.64/TiO2 catalyst. The bimetallic SiO2-supported catalysts have lower rates than Pd/SiO2 but still show improved selectivity. The combined characterization
measurements and reaction kinetics studies indicate that the performance
improvements of the bimetallic catalysts may be attributed to both
electronic and geometric modifications of Pd by the parent Cu or Ag
metal.
Pt
and PtSn catalysts supported on SiO2 and H-ZSM-5
were studied for methane conversion under nonoxidative conditions.
Addition of Sn to Pt/SiO2 increased the turnover frequency
for production of ethylene by a factor of 3, and pretreatment of the
catalyst at 1123 K reduced the extent of coke formation. Pt and PtSn
catalysts supported on H-ZSM-5 zeolite were prepared to improve the
activity and selectivity to non-coke products. Ethylene formation
rates were 20 times faster over a PtSn(1:3)/H-ZSM-5 catalyst with
SiO2:Al2O3 = 280 in comparison to
those over PtSn(3:1)/SiO2. H-ZSM-5-supported catalysts
were also active for the formation of aromatics, and the rates of
benzene and naphthalene formation were increased by using more acidic
H-ZSM-5 supports. These catalysts operate through a bifunctional mechanism,
in which ethylene is first produced on highly dispersed PtSn nanoparticles
and then is subsequently converted to benzene and naphthalene on Brønsted
acid sites within the zeolite support. The most active and stable
PtSn catalyst forms carbon products at a rate, 2.5 mmol of C/((mol
of Pt) s), which is comparable to that of state-of-the-art Mo/H-ZSM-5
catalysts with same metal loading operated under similar conditions
(1.8 mmol of C/((mol of Mo) s)). Scanning transmission electron microscopy
measurements suggest the presence of smaller Pt nanoparticles on H-ZSM-5-supported
catalysts, in comparison to SiO2-supported catalysts, as
a possible source of their high activity. A microkinetic model of
methane conversion on Pt and PtSn surfaces, built using results from
density functional theory calculations, predicts higher coupling rates
on bimetallic and stepped surfaces, supporting the experimental observations
that relate the high catalytic activity to small PtSn particles.
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