Abstract
Polyethylene glycol (PEG) is commonly used to prevent particle aggregation of nanotitanium dioxide (nano-TiO(2)) through steric hindrance. The particle aggregation of microcrystalline cellulose@nano-TiO(2) core-shell sunscreen composite (MCC@nano-TiO(2)) makes the powder difficult to grind and also boosts the probability of nano-TiO(2) peeling off during grinding. It is essential to inhibit agglomeration by surface treatment to avoid adverse effects in cosmetic applications. First, the structural and UV protection capability of the composite was investigated before and after the complete coverage of MCC by nano-TiO(2). Then, different amounts of PEG were added in the later stages of composite preparation to fix PEG onto the particle surfaces. Systematic examinations were then conducted to investigate the effects of PEG modification on structure and properties. Results reveal that at an MCC:nano-TiO(2) mass ratio of 60:40, a 6% PEG modification significantly enhances the dispersibility and UV protection by altering the nano-TiO(2) shell structure. Notably, PEG is exposed on the particle surface, which markedly increases UV reflection and scattering, thereby extending the UVA protection range. The critical absorption wavelength (λ(c)) was 376 nm. PEG modification also minimizes agglomeration and potential release of nano-TiO(2) particles. This study lays a foundation for the industrialization of MCC@nano-TiO(2) and provides new ideas for the surface modification of core-shell nano-TiO(2) materials.