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Mordenite-Supported Ag + -Cu 2+ -Zn 2+ Trimetallic System: A Variety of Nanospecies Obtained via Thermal Reduction in Hydrogen Followed by Cooling in an Air or Hydrogen Atmosphere.

Inocente Rodríguez-IznagaVitalii PetranovskiiFelipe F Castillón-BarrazaSergio Fuentes-MoyadoFernando Chávez-RivasAlexey N Pestryakov
Published in: Materials (Basel, Switzerland) (2022)
Multimetallic systems, instead of monometallic systems, have been used to develop materials with diverse supported species to improve their catalytic, antimicrobial activity, etc., properties. The changes in the types of nanospecies obtained through the thermal reduction of ternary Ag + -Cu 2+ -Zn 2+ /mordenite systems in hydrogen, followed by their cooling in an air or hydrogen atmosphere, were studied. Such combinations of trimetallic systems with different metal content, variable ratios (between them), and alternating atmosphere types (during the cooling after reducing the samples in hydrogen at 350 °C) lead to diversity in the obtained copper and silver nanospecies. No reduction of Zn 2+ was evidenced. A low silver content leads to the formation of reduced silver clusters, while the formation of nanoparticles of a bigger size takes place in the trimetallic samples with high silver content. The cooling of the reduced trimetallic samples in the air causes the oxidation of the obtained metallic clusters and silver and copper nanoparticles. In the case of copper, such conditions lead to the formation of mainly copper (II) oxide, while the silver nanospecies are converted mainly into clusters and nanoparticles. The zinc cations provoked changes in the mordenite matrix, which was associated with the formation of point oxygen defects in the mordenite structure and the formation of surface zinc oxide sub-nanoparticles in the samples cooled in the air.
Keyphrases
  • gold nanoparticles
  • oxide nanoparticles
  • visible light
  • silver nanoparticles
  • heavy metals
  • reduced graphene oxide
  • walled carbon nanotubes
  • ionic liquid
  • hydrogen peroxide
  • nitric oxide
  • risk assessment