Abstract
The inherent properties of TiO(2), including a wide band gap and restricted spectral response range, hinder its commercial application and its ability to harness only 2-3% of solar energy. To address these challenges and unlock TiO(2)'s full potential in photocatalysis, C(60)- and CdS-co-modified nano-titanium dioxide has been adopted in this work to reduce the band gap, extend the absorption wavelength, and control photogenerated carrier recombination, thereby enhancing TiO(2)'s light-energy-harnessing capabilities and hydrogen evolution capacity. Using the sol-gel method, we successfully synthesized CdS-C(60)/TiO(2) composite nanomaterials, harnessing the unique strengths of CdS and C(60). The results showed a remarkable average yield of 34.025 μmol/h for TiO(2) co-modified with CdS and C(60), representing a substantial 17-fold increase compared to pure CdS. Simultaneously, the average hydrogen generation of C(60)-modified CdS surged to 5.648 μmol/h, a notable two-fold improvement over pure CdS. This work opens up a new avenue for the substantial improvement of both the photocatalytic degradation efficiency and hydrogen evolution capacity, offering promise of a brighter future in photocatalysis research.