Abstract
It is pertinent to assess the performance of a sustainable system that can treat nitrogen oxides (NO x) emissions from combusting biomass waste. Low-temperature selective catalytic reduction is attractive due to the longer catalyst lifetime and the possibility to use carbon-based catalysts. Hence, this study explores this system with the utilization of: (i) a cost-effective catalyst support, i.e. activated carbon derived from abundant biomass waste; (ii) a renewable reductant, i.e. hydrogen; and (iii) Earth-abundant metal catalysts, i.e. copper and iron. The catalyst was prepared by impregnating metal oxides (Cu and Fe) over palm kernel shell activated carbon (PKS). The catalyst was characterised by hydrogen-temperature programmed reduction (H 2-TPR) and nitric oxide-temperature programmed desorption (NO-TPD). H 2-TPR revealed an increase in the reducibility, attributed to the synergistic effects between Cu and Fe. However, these catalyst sites favour nitrous oxide (N 2O) formation as shown via NO-TPD. Meanwhile, the catalyst activity has also been investigated in a fixed-bed reactor. It showed that the 100% conversion can be achieved at 200°C, but the selectivity towards nitrogen formation is as low as 40%. Therefore, investigating the optimum design of PKSCuFe catalyst is justifiable to improve the performance of low-temperature selective catalytic reduction.
Highlights
In developing countries, decomposable organic waste, mainly from agricultural activities, dominates the total solid waste produced (4.5 times more than the generation of municipal solid waste) [1]
Copper-iron catalyst (PKSCuFe) was prepared under mild conditions using active carbon prepared from palm kernel shell (PKS) as the support via incipient wetness
In order to investigate the role of Cu-Fe in a hydrogen-selective catalytic reduction (H2-SCR), monometallic catalysts of copper (PKSCu) and iron (PKSFe) were synthesized using the same carbon support
Summary
Decomposable organic waste, mainly from agricultural activities, dominates the total solid waste produced (4.5 times more than the generation of municipal solid waste) [1]. Typical final disposal methods are open dumping, landfilling and incineration. The development of methods for the sustainable utilization of solid waste is becoming more prominent [2]. One sustainable alternative in utilizing agro-waste is its conversion to either energy or other useful products, such as composites and activated carbon which have shown successful application in industry. Activated carbon has been utilized widely in wastewater treatment and gas purification processes because it has high adsorption capacity. The synthesis and application of carbonaceous catalysts from biomass has recently been reviewed [3]. Yang et al (2011) have reviewed the application of various
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