Synthesis and characterization of chitosan/polyvinyl alcohol immersed in sodium hydroxide thin film as a heterogeneous catalyst in biodiesel production.

Biodiesel is a potential renewable energy source that can be used to replace fossil fuels because of its low toxicity, biodegradability, and renewability. However, biodiesel production requires long reaction times. Hence, a catalyst is needed to speed up the reaction and optimize production conditions. CS/PVA thin film catalyst immersed in NaOH has intriguing catalytic properties that can improve biodiesel conversion efficiency. In this paper, a series of chitosan/polyvinyl alcohol­sodium hydroxide (CS/PVA-NaOH) thin films have been prepared as heterogeneous catalysts in biodiesel production. According to the FTIR spectra data, It shows that the vibrational frequency of the hydroxyl group (-OH) shifted from 3271 cm-1 to 3290 cm-1, indicating the hydrogen bond interaction between chitosan and PVA. Water uptake (45.42-218.64 %), swelling (120.63-142.99 %), porosity (62.67-243.43 %), and the durability of the thin film at pH conditions of 5-11 have been found to be the physicochemical characteristics of blended Chitosan/PVA (4/1; 3/2; 2.5/2.5; 2/3; 1/4 (v/v)). The optimal conditions for producing biodiesel were found to be around 65 °C for 90 min with an oil: methanol molar ratio of 1:7. By using a heterogeneous catalyst of CS/PVA-NaOH, the conversion efficiency from oil to biodiesel was achieved at around 95.39-99.52 %.

Permeability improvement of polyethersulfone-polietylene glycol (PEG-PES) flat sheet type membranes by tripolyphosphate-crosslinked chitosan (TPP-CS) coating.

In this study, improvement of urea and creatinine permeability of polyethersulfone (PES) membrane by coating with synthesized tripolyphosphate-crosslinked chitosan (TPP-CS) has been conducted. Original and modified membranes, e.g. pristine PES, polyethersulfone-polyethylene glycol (PES-PEG) and PES-PEG/TPP-CS membranes were characterized using FTIR, DTG, SEM, AFM, water uptake, contact angles, porosity measurement, tensile strength test and permeation tests against urea and creatinine. The results show that the PES modification by TPP-CS coating has been successfully carried out. The water uptake ability, hydrophilicity and porosity of the modified membranes increase significantly to a greater degree. All modified membranes have good thermal stability and tensile strength and their permeation ability towards urea and creatinine increase with the increasing concentration of TPP-CS. PES membrane has urea clearance ability of 7.36 mg/dL and creatinine of 0.014 mg/dL; membrane PES-PEG shows urea clearance of 11.87 mg/dL and creatinine of 0.32 mg/dL; while PES-PEG/TPP-CS membrane gives urea clearance of 20.87-36.40 mg/dL and creatinine in the range of 0.52-0.78 mg/dL. These results suggest that the PES-PEG membrane coated with TPP-CS is superior and can be used as potential material for hemodialysis membrane.