Mo的引入方式对CeO2脱硝性能的影响

固定源排放的氮氧化物(NOx)导致了严重的环境污染问题,NH3选择性催化还原(NH3-SCR)被认为是目前控制NOx排放的最有效技术,已广泛应用于电力行业的烟气排放治理.然而,我国非电行业的NOx减排仍然面临着重大挑战,因为其排放的废气温度通常低于300oC,且含有一定量的SO2,传统的钒基SCR催化剂因活性温度(30...

Effects of different methods of introducing Mo on denitration performance and anti-SO2 poisoning performance of CeO2

Cerium-based catalysts are very attractive for the catalytic abatement of nitrogen oxides (NOx) emitted from stationary sources. However, the main challenge is still achieving satisfactory catalytic activity in the low-temperature range and tolerance to SO2 poisoning. In the present work, two series of Mo-modified CeO2 catalysts were respectively obtained through a wet impregnation method (Mo-CeO2) and a co-precipitation method (MoCe-cp), and the roles of the Mo species were systematically investigated. Activity tests showed that the Mo-CeO2 catalyst displayed much higher NO conversion at low temperature and anti-SO2 ability than MoCe-cp. The optimal Mo-CeO2 catalyst displayed over 80％ NO elimination efficiency even at 150 °C and remarkable SO2 resistance at 250 °C (nearly no activity loss after 40 h test). The characterization results indicated that the introduced Mo species were highly dispersed on the Mo-CeO2 catalyst surface, thereby providing more Br?nsted acid sites and inhibiting the formation of stable adsorbed NOx species. These factors syn-ergistically promote the selective catalytic reduction (SCR) reaction in accordance with the Eley-Rideal (E-R) reaction path on the Mo-CeO2 catalyst. Additionally, the molybdenum surface could protect CeO2 from SO2 poisoning; thus, the reducibility of the Mo-CeO2 catalyst declined slightly to an adequate level after sulfation. The results in this work indicate that surface modifica-tion with Mo species may be a simple method of developing highly efficient cerium-based SCR cata-lysts with superior SO2 durability.