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Małgorzata Rutkowska

Uniwersytet Jagielloński in Kraków

Contact malgorzata.rutkowska@uj.edu.pl
Research Areas
  • Catalytic conversion of air pollutants:  NOx reduction (DeNOx process, NH3-SCR),  NH3 oxidation (NH3-SCO),  N2O decomposition,  incineration of volatile organic compounds (VOCs),  incineration carbon soots,   

  • Catalytic synthesis of green fuel dimethyl ether (bioDME),   

  • Catalytic decomposition of NH3 to hydrogen (sustainable, clean energy source),   

  • Catalytic and adsorption methods for elimination of organic and inorganic pollutants from wastewater,  

  • Catalytic “green” oxidative desulfurisation (ODS),  

  • Synthesis and functionalization of high surface area silica and aluminosilica materials with uniform porous structure (e.g. 2D zeolites, zeolites with hierarchical porous structure, PILCs, PCHs, MCM-41, MCM-48, SBA-15, MCF, MSU) for catalytic and adsorption applications,   

  • Synthesis of other high surface area materials like hydrotalcite-originated mixed metal oxides for catalytic applications. 

Examples of master's project topics

  • ‘Verification of the catalytic activity of heteroatomic Ti-MCM-22 zeolites modified with transition metal cations in the nitrogen oxide conversion process’.   
  • ‘Cobalt-nickel catalysts on oxide-graphene supports for the ammonia decomposition process’.  
  •  ‘An influence of the layered zeolites modification with iron on their catalytic activity in the N2O decomposition process’ .  
  •  ‘Zeolite catalysts with a spherical structure for the synthesis of dimethyl ether’    
  • ‘Nickel catalysts on carbon oxide for the decomposition of ammonia into hydrogen’. 
  •  ‘Mitigation of contamination with pharmaceuticals in water and wastewater using novel 2D inorganic photocatalysts ‘. 
  •  ‘Zeolites with MWW topology modified with selected metal cations as catalysts in the oxidation process of diphenyl sulfide’. 
  •  ‘The role of EDTA in the process of iron deposition on the surface of mesoporous silica types MCM-41 and MCM-48 in terms of controlling its form and degree of dispersion’. 

Further Information

https://zchts.chemia.uj.edu.pl/en_GB/