Project Department of nanochemistry

• Formation of cyclodextrin complexes with astaxanthin detail
• Cyclodextrin-based nanomaterials for PFAS passive sampler construction detail
• Design and synthesis of functionalized magnetic nanoparticles for effective removal of novel per- and polyfluorinated compounds (PFAS) from water detail
• Development and characterization of efficient sorbents for the uptake of challenging PFAS in water and soil detail
• Water and Ammonia electrooxidation using Ruthenium based complexes and hybrid organosilica nanomaterials as an effective heterogeneous molecular anode detail
• Water electrooxidation using ruthenium based complexes and hybrid organosilica nanomaterials as an effective heterogeneous molecular anode detail
• Elucidating PFAS bioaccumulation mechanisms in fish for developing a novel biomimicking approach detail
• Hybrid organosilica nanomaterials for heterogeneous catalysis of enantioselective reactions detail
• Interaction of perfluoroalkylated compounds with cyclodextrin matrices: a probe of sorption mechanisms using NMR spectroscopy (SORPFAS) detail
• Laser synthesis of cyclodextrin functionalised nanoalloys for applications in catalysis detail
• Method for evaluation of the fibrous material-cell interaction based on live cell imaging detail
• Nanofibrous mats capable of naked-eye detection of hazards during filtration detail
• New types of hybrid organosilane fibrous scaffolds prepared via electrospinning and 3D printing technologies focused on applications in the field of regenerative medicine detail
• Sustainability of biodiesel production with decreasing quality of input fats detail
• Upgrade and modernization of larfe research infrastructure "Nanomaterials and nanotechnologies for protection of the environment and sustainable future". detail
• The use of enhanced methods in the development of an innovated interdental brush detail
• Development of new types of fully biocompatible scaffolds with organosilane fibres intended for peripheral nerve repair detail
• Development of new types of fully biocompatible conductive organosilane fibrous scaffolds intended for soft and neural tissues regeneration detail