In this study, zeolite micro-particles were embedded on electrospun
nanofibers to enhance the efficiency of zeolite particles by
increasing the active surface area. Metal catalysts were coated on
the nanofiber mat to perform the zeolite recycle process, which can
replace the conventional chemical process. The electrospinning
technique was utilized to fabricate a membrane with high surface
area, porosity, and provide a substrate for the uniform distribution
of zeolite particles (zeolite membrane). Catalyst metal nanoparticles
In this study, zeolite micro-particles were embedded on electrospun
nanofibers to enhance the efficiency of zeolite particles by
increasing the active surface area. Metal catalysts were coated on
the nanofiber mat to perform the zeolite recycle process, which can
replace the conventional chemical process. The electrospinning
technique was utilized to fabricate a membrane with high surface
area, porosity, and provide a substrate for the uniform distribution
of zeolite particles (zeolite membrane). Catalyst metal nanoparticles
were synthesized on the surface of the nanofibers to
recycle zeolite by an in-situ chemical reduction process (Electroless
Plating, EP). The NH3eN removal process applied in the fabrication
of zeolite/palladium membrane (Ze/Pd membrane) consisted of the
following steps.
were synthesized on the surface of the nanofibers to
recycle zeolite by an in-situ chemical reduction process (Electroless
Plating, EP). The NH3eN removal process applied in the fabrication
of zeolite/palladium membrane (Ze/Pd membrane) consisted of the
following steps.