**Ruby Mejía-de Gutiérrez 1,\*, Mónica Villaquirán-Caicedo 1, Sandra Ramírez-Benavides 1, Myriam Astudillo <sup>2</sup> and Daniel Mejía <sup>2</sup>**

	- Colombia; myriam.astudillo@correounivalle.edu.co (M.A.); daniel.mejia@correounivalle.edu.co (D.M.)

Received: 29 December 2019; Accepted: 6 February 2020; Published: 9 February 2020

**Abstract:** Metakaolin-based geopolymer cements were produced by alkaline activation with a potassium hydroxide and potassium silicate solution. To produce the geopolymer composites, 10 wt.% titanium oxide (TiO2) and 5 wt.% copper oxide (CuO) nanoparticles were used. The geopolymer mortar was prepared using glass waste as fine aggregate. The raw materials and materials produced were characterized by X-ray diffraction, electron microscopy, and Fourier-transform infrared spectroscopy techniques. Likewise, the geopolymer samples were characterized to determine their physical properties, including their density, porosity, and absorption. The photocatalytic activity of the materials was evaluated by activating the nanoparticles in a chamber with UV–Vis light during 24 h; then, different tests were performed to determine the growth inhibition of *Staphylococcus aureus*, *Escherichia coli*, and *Pseudomonas aeruginosa* bacteria in nutrient agar for times of up to 24 h. The study results showed that a geopolymer mortar containing glass waste as fine aggregate (GP-G) exhibited a water absorption 56.73% lower than that of the reference geopolymer paste without glass (GP). Likewise, glass particles allowed the material to have a smoother and more homogeneous surface. The pore volume and density of the GP-G were 37.97% lower and 40.36% higher, respectively, than those of the GP. The study with bacteria showed that, after 24 h in the culture media, the GP-G mortars exhibited a high inhibition capacity for the growth of *P. aeruginosa* from solutions of 10−<sup>4</sup> mL and in solutions of 10−<sup>6</sup> mL for *E. coli* and *S. aureus.* These results indicate the possibility of generating antibacterial surfaces by applying geopolymer composite.

**Keywords:** geopolymer; glass waste; titanium oxide; copper oxide; antibacterial surfaces
