Abstract
Energy consumption steadily increases and energy production is associated with many environmental risks, e.g., generating the largest share of greenhouse gas emissions. The primary gas pollution concern is CO2, CH4, and nitrogen oxides (NOx). Environmental catalysis plays a pivotal role in NOx mitigation (DeNOx). This study investigated, for the first time, a collection of ceramic foams as potential catalyst support for selective catalytic NOx reduction (SCR). Ceramic foams could be an attractive support option for NOx removal. However, we should functionalize the surface of raw foams for such applications. A library of ceramic SiC, Al2O3, and ZrO2 foams ornamented with nanorod ZnO and TiO2 as W and V oxide support was obtained for the first time. We characterized the surface layer coating structure using the XPS, XRF and SEM, and TEM microscopy to optimize the W to V molar ratio and examine NO2 mitigation as the SCR model, which was tested only very rarely. Comparing TiO2 and ZnO systems reveals that the SCR conversion on ZnO appeared superior vs. the conversion on TiO2, while the SiC-supported catalysts were less efficient than Al2O3 and ZrO2-supported catalysts. The energy bands in optical spectra correlate with the observed activity rank.
Highlights
IntroductionThe production of energy is, associated with many environmental risks
Energy demand growth is a fundamental problem of civilization in the Anthropocene.The production of energy is, associated with many environmental risks
This study investigated a collection of ceramic foams as potential catalysts for selective catalytic nitrogen oxides (NOx) reduction (SCR) reactions
Summary
The production of energy is, associated with many environmental risks. NOx formation is a consequence of energy production. One of the targets of environmental catalysis is the mitigation of NOx from the air. The design and development of porous functional materials is an essential environmental catalysis domain [1]. Porous ceramics are essential catalyst supports in this area [2]. Ceramic foams are monolithic threedimensional structures with an 80–90% void spaces fraction. These materials were developed initially to filter out molten metal impurities [3], which means that their surface area is generally too low for catalytic applications. The advantages of the innovatively structured foam catalysts involve fluid dynamics and heat transfer phenomena, which can positively influence catalyst performance
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