ZnTiO₃ nanoparticles (NPS), synthesized using a sol-gel process from zinc acetate dihydrate and titanium tetrabutanolate, were incorporated into aluminum borosilicate glasses to enhance their effectiveness in water purification. Integrating ZnTiO₃-NPS at the expense of SiO₂ causes significant alterations by converting [BO₃] to [BO₄], modifying the Si-O bonds with other metal oxides, and creating a denser structure with more bridging oxygens. The structural improvement is indicated by higher ultrasonic velocities and elastic moduli, demonstrating a stronger and more unified glass framework. The study investigates how different concentrations of ZnTiO₃-NPS affect the glasses' structure and mechanical and optical properties, specifically observing changes in light transmission, such as a blueshift in the absorption edge towards longer wavelengths. This blueshift due to ZnTiO₃-NPS was assured by the observed decrease in the optical band gap (E_g) values and the increase in the mean oscillator position (λ_o) values. Furthermore, the real () and imaginary () parts of the optical conductivity, nonlinear optical parameters viz. first (χ⁽¹⁾) and third (χ⁽³⁾) orders subsatellites, and nonlinear index of refraction (n₂) have been estimated based on the values of the linear index of refraction (n) and the extinction coefficient (k). The optical modifications impact the refractive index, suggesting various potential technological applications based on the ZnTiO₃ levels.