Adsorptive purification of NOx by HZSM-5 zeolites: Effects of Si/Al ratio, temperature, humidity, and gas composition

Adsorption is a promising technology for capturing nitrogen oxides (NOx) from humid flue gases, for which as the preferred NOx adsorbent, zeolite with an appropriate silica to alumina (Si/Al) ratio provides the key step for success in practical applications. In this work, the effects of Si/Al ratio, temperature, relative humidity (RH), and feed gas (NOx-H2O(g)-CO2-O2-N2) compositions on NOx sorption behavior on HZSM-5 zeolites were systemat-ically investigated, based on a series of characterizations, fixed-bed adsorption and temperature programmed desorption (TPD) tests. The low-silica HZSM-5(25) showed the best performance (326.6 mu mol/g and 39.2 mu mol/g at dry and 90%RH) as compared to others with higher Si/Al ratios at each RH, in which the roll-up effect was positively correlated with the Si/Al ratios and humidity. O2 enhanced NOx adsorption and reached an optimal adsorption capacity at the concentration of 14%, while CO2 had little effect on NOx adsorption. The decrease in temperature increased NOx adsorption capacity on HZSM-5(25), benefitting from NO2 physisorption as well as satisfactory NO oxidation within the active adsorbent structure. The facile thermal desorption of NOx and sig-nificant NO-NO2 conversion on HZSM-5(25) was exhibited by bimodal TPD peaks at 343-353K and 533-543K respective for NO and NO2, in contrast to those on Silicalite-1. A potential water-resistant strategy via the enhancement of NOx adsorption competitiveness was revealed, providing a theoretical guideline for NOx adsorbent screening in industrial applications.

Automated summary

In this study, the effects of Si/Al ratio, temperature, relative humidity, and feed gas compositions on NOx sorption behavior on HZSM-5 zeolites were investigated. The results showed that HZSM-5(25) with low silica exhibited the best performance in NOx adsorption. Oxygen enhanced NOx adsorption, while carbon dioxide had little effect. Lower temperature increased NOx adsorption capacity on HZSM-5(25) due to NO2 physisorption and satisfactory NO oxidation. The study also revealed a potential water-resistant strategy for NOx adsorbents.