In
connection with an initiative to enhance heat recovery from
the large-scale operation of a heterogeneously catalyzed nitrobenzene
hydrogenation process to produce aniline, it is necessary to operate
the process at elevated temperatures (>100 °C), a condition
that
can compromise aniline selectivity. Alumina-supported palladium catalysts
are selected as candidate materials that can provide sustained aniline
yields at elevated temperatures. Two Pd/Al
2
O
3
catalysts are examined that possess comparable mean Pd particle
sizes (∼5 nm) for different Pd loading: 5 wt % Pd/Al
2
O
3
and 0.3 wt % Pd/Al
2
O
3
. The higher
Pd loading sample represents a reference catalyst for which the Pd
crystallite morphology has previously been established. The lower
Pd loading technical catalyst more closely corresponds to industrial
specifications. The morphology of the Pd crystallites of the 0.3 wt
% Pd/Al
2
O
3
sample is explored by means of temperature-programmed
infrared spectroscopy of chemisorbed CO. Reaction testing over the
range of 60–180 °C shows effectively complete nitrobenzene
conversion for both catalysts but with distinction in their selectivity
profiles. The low loading catalyst is favored as it maximizes aniline
selectivity and avoids the formation of overhydrogenated products.
A plot of aniline yield as a function of WHSV for the 0.3 wt % Pd/Al
2
O
3
catalyst at 100 °C yields a “volcano”
like curve, indicating aniline selectivity to be sensitive to residence
time. These observations are brought together to provide an indication
of an aniline synthesis catalyst specification suited to a unit operation
equipped for enhanced heat transfer.
Structure/function relationships in heterogeneous catalysis play an important role in catalyst design strategies. The combination of chemisorption of suitable probe molecules alongside application of infrared spectroscopy is an established technique for providing information on the metal crystallite morphology of supported metal catalysts. Following a review of key literature on this topic, a variety of experimental arrangements that may be adopted for this task are examined. Specifically, the adsorption of CO over a 5wt% Pd/Al2O3 catalyst is investigated using transmission and diffuse reflectance sampling options and two research grade spectrometers. Although comparable spectra are obtained on all the platforms examined, differences are noted. In particular, temperature-programmed IR spectroscopy on one platform enables resolution of two features assigned to linear CO bound to the Pd particles. The relevance of this sub-division of terminal sites with respect to selective hydrogenation reactions is briefly considered.
Two Pd/γ-Al2O3 catalysts
are examined
for the vapor phase hydrogenation of nitrobenzene over the temperature
range of 60–200 °C. A 1 wt % catalyst is selected as a
reference material that is diluted with γ-alumina to produce
a 0.3 wt % sample, which is representative of a metal loading linked
to a candidate industrial specification aniline synthesis catalyst.
Cyclohexanone oxime is identified as a by-product that is associated
with reagent transformation. Temperature-programed infrared spectroscopy
and temperature-programed desorption measurements of chemisorbed CO
provide information on the morphology of the crystallites of the higher
Pd loading catalyst. The lower Pd loading sample exhibits a higher
aniline selectivity by virtue of minimization of product overhydrogenation.
Reaction testing measurements that were undertaken employing elevated
hydrogen flow rates lead to the proposition of separate reagent and
product-derived by-product formation pathways, each of which occurs
in a consecutive manner. A global reaction scheme is proposed that
defines the by-product distribution accessible by the grades of catalyst
examined. This information is helpful in defining product purification
procedures that would be required in certain heat recovery scenarios
connected with large-scale aniline production.
A 1 % w/w alumina-supported gold catalyst is described that is prepared from the impregnation of alumina with a solution of ammonium tetraazidoaurate(III), NH 4 [Au(N 3 ) 4 ]. Decomposition of the azide precursor leads to a residue-free catalyst comprised of well-dispersed gold particles. This novel material is tested for propyne hydrogenation using pulse-flow techniques and displays 100 % selectivity to the par-* Dr. D. Lennon E-Mail: David.Lennon@glasgow.ac.uk [a]
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