Membrane technology is applied in several industries due to the advantages of being environmentally friendly and energy efficient. An in-depth examination on the impact of membrane Polyetheretherketone/Polyvinylalcohol (PEEK/PVA) composite modified with nanoparticle zinc oxide (ZnO) on particle size, mechanical, and morphological properties. Scanning electron microscopy (SEM) was applied for studying the dispersion of ZnO particles in PEEK/PVA composite. The characterization of the obtained hybrids was done using Fourier transform infrared spectroscopy (FT-IR), and X-ray diffraction (XRD) with an increase in the solubility of the gas molecules within the polymer matrix, an increase in the CO2 permeability is observed. The outcomes of the N2 permeability confirmed that the permeability of this agent undergo reduction with increasing pressure. Separation process at high pressures was proven since the selectivity of CO2/N2 boosted from 93.8 at 1 bar pressure to 43.6 at 8 bar pressure, with increasing feed pressure. The careful and detailed examination of the permeability and selectivity of CO2/N2 for membrane PEEK/PVA/ZnO nanoparticle modified with PEEK/PVA composite was performed. An increase in the CO2 permeability to the membrane PEEK/PVA from 19.6 to 87.7 upon modifying the surface area of the membrane PEEK/PVA/m-ZnO NPs (1.0 wt%, 2.0 wt% and 3.0 wt%), and increasing the percentage of this additive in the polymer matrix. Increase was due to the presence of cavities developed in the process of surface modification, and the increased of free volume and solubility of CO2/N2 inside the polymer membrane. Manuscript profile

The characterization of morphological, particle size, mechanical, and thermal on the impactof membrane Polyetheretherketon/Polyvinylalcohol (PEEK/PVA) composite was modified with zinc oxide nanoparticles for Permeability and Selectivity of CO2 properties. Separation process was done at high pressures since the selectivity of CO2 boosted from 94.0 at 1 bar with increasing feed pressure. Also, the permeability of CO2 for membrane PEEK/PVA/ZnO nanoparticle modified with PEEK/PVA composite was performed. The increase in CO2 permeability to the membrane PEEK/PVA from 26.4 to 82.6 occurred upon modifying the surface area of the membrane PEEK/PVA/m-ZnONPs (1.0 wt%, 2.0 wt%, and 3.0 wt%), and increasing the percentage of this additive in the polymer matrix. The increase was due to the presence of cavities developed in the process of surface modification, and the increased of free volume and solubility of CO2 inside the polymer membrane. Manuscript profile