(127g) Tuning the Interfacial Property of Copper-Ceria Catalyst By Indium for Low Temperature CO Oxidation

The
development of novel catalysts for low-temperature CO elimination attracts a
lot of attention not only in academic research but also in practical
application, such as purifying automobile emission and preferential oxidation
(PROX) in the proton exchange membrane fuel cell. Supported noble metal
catalysts (Au, Pt, Rh, Pd),
which show an excellent catalytic performance, have been widely investigated
for CO oxidation. However, due to the high cost of the noble metals and
remarkable progresses in oxide syntheses, catalytic oxidation of carbon
monoxide over base metal oxide catalysts such as Mn₂O₃,
Co₃O₄ and CuO has becoming a
promising alternative for noble metals.

Among
the metal oxide catalysts, CuO-CeO₂ catalyst has been paid much more
attention due to their low cost and comparable catalytic activity to the noble
metal catalysts in low temperature CO oxidation. It is generally accepted that
the high performance for CuO-CeO₂ catalysts is dependent on the
synergetic redox property between copper and ceria at the interfacial sites,
which is considered as the active sites in CO oxidation reaction.

Up
to now, based on the understanding of structure of the active component, two
strategies should be employed for the improvement of the catalytic performance
of copper-ceria catalysts for CO oxidation. Firstly, the facility for achieving
the entities of the Cu⁺ species at the Cu-Ce
interface, which is favored by an increase in the dispersion and decrease in
the particle size. Secondly, the redox properties of the interface sites
between partially reduced copper species and the support, this may be the most
important factor in determining the catalytic activities when the nature of the
ceria-based support is varied.

Therefore,
in the present study, the geometry and electronic structure at the interfacial
sites were tuned by adding In into the catalyst to
enhance the catalytic performance. The structure-performance relationship was
thoroughly studied to support fundamental understanding on CO oxidation over
CuO-CeO₂ catalyst.

Fig. 1.
Temperature-dependent CO oxidation over (¨‹) 5Cu/CeO₂,
(¡ö) 0.5In5Cu/CeO₂, (◄) 1In5Cu/CeO₂, (¡ñ) 1.25In5Cu/CeO₂,
(¡ø) 2In5Cu/CeO₂, (♦) 3In5Cu/CeO₂ and (insert) T₁₀₀
of various In-Cu/CeO₂ catalysts.

Fig. 2.
Binding energy of In 3d_5/2 and Cu 2p_3/2, I_sat/I_pp,
Cu⁺(%) and Ce³⁺(%) as a function
of In content in the Cu-In/CeO₂ catalysts.

In
this work, In-promoted Cu/CeO₂ catalyst exhibits remarkable
catalytic performance for low temperature CO oxidation. A volcano-shape curve
is observed for reaction rate vs. In content, in which
the 1.25In5Cu/CeO₂ catalyst possesses the lowest temperature of
complete conversion (T₁₀₀ = 100 ^oC).
The highest reaction rate (5.93¡Á10^-6mol g_cat^-1s^-1)
over 1.25In5Cu/CeO₂ at 80 ^oC is
obtained. HAADF-STEM images and in situ DRIFTS have proved that an addition of In into the catalysts leads to a decrease in particle size
of copper. Copper atoms are diluted by indium atoms indicating that more
low-coordination copper sites are exposed and more metal-support interfaces are
created, which are considered to be the active sites for this reaction. The
adsorption strength of CO on copper is weakened after doping indium, which is
assumed to be more favorable for reacting with the adjacent lattice oxygen,
preventing the accumulation of surface carbonate-containing products and
enhancing the stability and the resistance for CO₂. The electronic
structure of the surface copper atoms is changed by accepting electron through
the redox equilibrium between copper and indium, which could facilitate the
stabilization of Cu⁺ sites at the interface. Tuning the interfacial
property of Cu/CeO₂ catalyst by indium sheds deep insight for the
rational design and controllable synthesis of copper-ceria based catalysts with
high catalytic performance.