3.5. Influence of coexisting gases3

3.5. Influence of coexisting gases
3.5.1. Effect of SO2
Exhaust gases usually contain SO2 that is poisonous to catalysts,
although the sulfur contents in automotive fuels have recently been
severely restricted in many countries. Therefore, reaction inhibition and catalyst poisoning by coexisting SO2have been extensively
studied for the SCR reactions. In many cases, coexisting SO2causes
either irreversible or reversible deactivation of HC-SCR catalysts.
On the other hand, it is of interest that the H2-SCR and CO-SCR
reactions on Ir catalyst are not severely inhibited by coexisting
SO2. Ogura et al. [49] reported that the catalytic activity of 0.02%
Ir/silicalite catalyst for CO-SCR is not influenced by coexisting
150 ppm SO2(Fig. 6). Shimokawabe et al. [80,81] showed that the
presence of 100 ppm SO2causes a significant deactivation of Ir/WO3
for the CO-SCR, but its negative effect is completely removed by
coexisting O2, indicating that the coexistence of O2and SO2does
not inhibit the CO-SCR reaction. Furthermore, it should be noted
that the presence of both O2and SO2is essential for the H2-SCR and
CO-SCR reactions on Ir catalysts to occur as already described in this
review. The H2-SCR and CO-SCR reactions over Ir/SiO2[43,44,50,51]
and promoted Ir/SiO2such as Ba/Ir/SiO2[87] and Li/Ir/SiO2[46] do
not take place in the absence of SO2, whereas their catalytic activity
was significantly enhanced by the addition of 1–20 ppm SO2into
the reaction gas. It is also noteworthy that the NO reduction activity
is not influenced by changing the SO2concentration range from 1
to 150 ppm.
Interested in the role of SO2in the H2-SCR and CO-SCR reactions over supported-Ir catalysts, Fujitani et al. [94] investigated the
adsorption and reactivity of SO2on the Ir (1 1 1) surfaces by surface
science techniques. X-ray photoelectron spectroscopy (XPS) measurements showed that SO2is molecularly adsorbed on the Ir (1 1 1)
surface at −73
◦
C. Then, the adsorbed SO2on the Ir (1 1 1) surface
undergoes disproportionation to atomic sulfur and SO3 at 27
◦
C,
followed by SO3desorption: 3SO2(a) → 2SO3(a) + S(a). The remaining atomic sulfur reacts with surface oxygen on Ir to be removed
from the surface: S(a) + 2O(a) → 2SO2(g). The Ir surface, thus,
reverts to its initial metallic state.
Haneda et al. [51] investigated the valence state of the Ir surface
by FT-IR using CO as a probe molecule. Fig. 10 shows FT-IR spectra
of CO species adsorbed onto Ir/SiO2recorded in different compositions of flowing gas at 250
◦
C. When 0.6% CO/He was exposed to
Ir/SiO2, a strong IR band at 2079 cm
−1
assignable to linearly bonded
CO onto Ir
0
sites was observed (Fig. 10A(a)). The exposure of CO in
the presence of O2to Ir/SiO2caused a shift of IR band to 2107 cm
−1
indicating the adsorption of CO onto Ir
ı+
sites (Fig. 10A(b)). The
surface of Ir seems to be easily oxidized in the presence of O2. On
the other hand, when CO was exposed to Ir/SiO2in the presence of
O2and SO2, two distinct IR bands assignable to Ir
0–CO and Ir
ı+–CO
were observed at 2074 and 2107 cm
−1
, respectively (Fig. 10A(c)).
This clearly indicates that coexisting SO2participates in the stabilization of Ir
0
sites on which NO reduction with CO proceeds. It is of
interest that the introduction of SO2into the CO–O2/He flowing gas
caused the appearance of an IR band at 2074 cm
−1
due to Ir
0
–CO,
and its band intensity increased over time on stream (Fig. 10B). In
conclusion, the role of coexisting SO2 is not only to stabilize but also
to create Ir
0
sites, which is the catalytically active species for the SCR
as described in Section 3.3., in oxidizing atmospheres. This finding
is in good agreement with the findings obtained on single-crystal
model catalysts by Fujitani et al. [94].