Abstract
Composites of Laponite and Cu–Mn hopcalite-related mixed oxides, prepared from hydrotalcite-like (Htlc) precursors obtained in inverse microemulsions, were synthesized and characterized with XRF, XRD, SEM, TEM, H2 temperature-programmed reduction (TPR), and N2 adsorption/desorption at −196 °C. The Htlc precursors were precipitated either with NaOH or tetrabutylammonium hydroxide (TBAOH). Al was used as an element facilitating Htlc structure formation, and Ce and/or Zr were added as promoters. The composites calcined at 600 °C are mesoporous structures with similar textural characteristics. The copper–manganite spinel phases formed from the TBAOH-precipitated precursors are less crystalline and more susceptible to reduction than the counterparts obtained from the precursors synthesized with NaOH. The Cu–Mn-based composites are active in the combustion of toluene, and their performance improves further upon the addition of promoters in the following order: Ce < Zr < Zr + Ce. The composites whose active phases are prepared with TBAOH are more active than their counterparts obtained with the use of the precursors precipitated with NaOH, due to the better reducibility of the less crystalline mixed oxide active phase.
Highlights
The emission of volatile organic compounds (VOCs), stemming mainly from industrial processes and automobile exhausts, represents a serious environmental hazard, in developed countries
The results showed that the synthetic procedure with the use of the microemulsion method for the active phase generation provided materials with better developed textural properties, more suitable for catalytic applications
The results showed that the use of the tetrabutylammonium hydroxide as an unconventional precipitant of the active phase within the inverse micellar system led to composite catalysts of improved combustion activity
Summary
The emission of volatile organic compounds (VOCs), stemming mainly from industrial processes and automobile exhausts, represents a serious environmental hazard, in developed countries. Catalytic combustion is considered a attractive clean-up technology for VOC mitigation. The catalysts for this process are based either on noble metals or on transition metal oxides [1,2,3,4,5]. During World War I, the search for an efficient CO absorbent to be used in military gas masks resulted in the development of hopcalite catalysts—based on mixtures of Cu and Mn oxides—which
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