Understanding the roles of Brønsted/Lewis acid sites on manganese oxide-zeolite hybrid catalysts for low-temperature NH3-SCR

doi:10.1016/S1872-2067(24)60112-9

Abstract

Abstract:

Although metal oxide-zeolite hybrid materials have long been known to achieve enhanced catalytic activity and selectivity in NO_x removal reactions through the inter-particle diffusion of intermediate species, their subsequent reaction mechanism on acid sites is still unclear and requires investigation. In this study, the distribution of Brønsted/Lewis acid sites in the hybrid materials was precisely adjusted by introducing potassium ions, which not only selectively bind to Brønsted acid sites but also potentially affect the formation and diffusion of activated NO species. Systematic in situ diffuse reflectance infrared Fourier transform spectroscopy analyses coupled with selective catalytic reduction of NO_x with NH₃ (NH₃-SCR) reaction demonstrate that the Lewis acid sites over MnO_x are more active for NO reduction but have lower selectivity to N₂ than Brønsted acids sites. Brønsted acid sites primarily produce N₂, whereas Lewis acid sites primarily produce N₂O, contributing to unfavorable N₂ selectivity. The Brønsted acid sites present in Y zeolite, which are stronger than those on MnO_x, accelerate the NH₃-SCR reaction in which the nitrite/nitrate species diffused from the MnO_x particles rapidly convert into the N₂. Therefore, it is important to design the catalyst so that the activated NO species formed in MnO_x diffuse to and are selectively decomposed on the Brønsted acid sites of H-Y zeolite rather than that of MnO_x particle. For the physically mixed H-MnO_x+H-Y sample, the abundant Brønsted/Lewis acid sites in H-MnO_x give rise to significant consumption of activated NO species before their inter-particle diffusion, thereby hindering the enhancement of the synergistic effects. Furthermore, we found that the intercalated K⁺ in K-MnO_x has an unexpected favorable role in the NO reduction rate, probably owing to faster diffusion of the activated NO species on K-MnO_x than H-MnO_x. This study will help to design promising metal oxide-zeolite hybrid catalysts by identifying the role of the acid sites in two different constituents.

Key words: Hybrid metal oxide-zeolite, The role of acid sites, Manganese oxides, Physical mixing, Selective catalytic reduction of NO_x with NH₃

Hyun Sub Kim, Hwangho Lee, Hongbeom Park, Inhak Song, Do Heui Kim. Understanding the roles of Brønsted/Lewis acid sites on manganese oxide-zeolite hybrid catalysts for low-temperature NH₃-SCR[J]. Chinese Journal of Catalysis, 2024, 65: 79-88.

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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(24)60112-9

https://www.cjcatal.com/EN/Y2024/V65/I10/79

Figures/Tables 7

Fig. 1. (a) XRD patterns of as-synthesized K-MnOx and H-MnOx. (b) XRD peak shift after removal of K+ in K-MnOx sample via HNO3 treatment. N2 adsorption-desorption isotherms (c), and DRIFTS spectra (d) of K-MnOx and H-MnOx samples after 500 ppm NH3 + 5% O2 adsorption at 100 °C for 30 min.

Fig. 2. NOx conversion (a) and N2 selectivity (b) over MnOx and physically mixed MnOx+Y samples in NH3-SCR reaction at low temperatures with the following reaction conditions: [NO] = [NH3] = 500 ppm, [O2] = 5 vol%, N2 balance, and GHSV = 120000 mL h?1 g?1 based on MnOx amount.

Fig. 3. N2O concentration of K-MnOx, H-MnOx, and K-MnOx+K-Y in NH3-SCR reaction at 200 and 250 °C with the following reaction conditions: [NO] = [NH3] = 500 ppm, [O2] = 5 vol%, N2 balance, and GHSV = 120000 mL h?1 g?1 based on MnOx amount.

Fig. 4. In situ DRIFT spectra of K-MnOx (a,b) and H-MnOx (c,d) after exposure to 500 ppm NH3 + 5% O2 followed by 500 ppm NO + 5% O2 at 100 °C. (e) The reactivity of adsorbed NH3 species towards activated NO species over H-MnOx plotted as a normalized intensity.

Fig. 6. The reactivity of adsorbed NH3 species towards activated NO species over H-MnOx+H-Y and K-MnOx+H-Y, plotted as a normalized intensity.

Fig. 5. In situ DRIFT spectra of H-Y zeolite (a,b), H-MnOx+H-Y (c,d), and H-MnOx+H-Y (e,f) after exposure to 500 ppm NH3 + 5% O2 followed by 500 ppm NO + 5% O2 at 100 °C.

Scheme 1. The plausible reaction scheme over the physically mixed MnOx and zeolite hybrid catalyst in low-temperature NH3-SCR reaction.

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Understanding the roles of Brønsted/Lewis acid sites on manganese oxide-zeolite hybrid catalysts for low-temperature NH₃-SCR

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