Synthesis, characterization, hydrolytic, and thermal stability of urea-formaldehyde composites based on modified montmorillonite K10

In this study, the thermal and hydrolytic properties of composite systems based on the urea-formaldehyde resin (UF) and eco-friendly montmorillonite (K10) as formaldehyde (FA) scavenger were examined. UF resin with molar ratio FA:U = 0.8 was synthesized in situ with inactivated, and activated K10. K10 was activated by sulfuric acid (H2SO4) with and without magnetic stirring. The samples are marked with K10((H2SO4)), K10 ((H2SO4)) ST, UF/K10((H2SO4)), and UF/K10((H2SO4)ST), respectively. X-ray diffraction analysis and non-isothermal thermogravimetric analysis, supported by data from Fourier transform infrared spectroscopy and scanning electron microscopy were used to characterize the samples. Based on the measurement of specific surface area (SSA), the degree of activation was determined. Measurement of the SSA shows that higher values were obtained for modified K10 compared to inactive K10. The amount of free and liberated FA was 0.06% and 4.6% for UF/K10((H2SO4)) and 0.12% and 4% for UF/K10((H2SO4)ST). This research showed that the UF/K10((H2SO4)) composite has a lesser amount of free FA (0.06%) in comparison to the UF/K10((H2SO4)ST) composite (0.12%). The UF/K10 ((H2SO4)ST) composite has a higher resistance to acidic hydrolysis. The modified UF/K10((H2SO4)) composite is more thermally stable than UF/K10((H2SO4)ST) composite.

Automated summary

This study examines the thermal and hydrolytic properties of composite systems based on urea-formaldehyde resin and eco-friendly montmorillonite. Experimental results show that the activation of montmorillonite can increase the specific surface area and reduce the amount of free formaldehyde, improving the performance of the composite system.