Degradación fotocatalítica de tetraciclina-antibiótico bajo irradiación de luz ultravioleta mediante nanoarquitectura jerárquica de TiO2 soportada

Juan José Hinostroza Mojarro; Francisco Javier  García Picazo; Mirza Mariela  Ruiz Ramirez; Karen Melisa  Luque López; Balter  Trujillo Navarrete

doi:10.37636/recit.v44274286

Autores/as

Juan José Hinostroza Mojarro Tecnológico Nacional de México/IT de Tijuana/ Tecnológico de Tijuana, Blvd. Alberto Limón Padilla s/n Col. Otay Tecnológico, Tijuana, B.C. 22510, México.
Francisco Javier García Picazo Tecnológico Nacional de México/IT de Tijuana/ Tecnológico de Tijuana, Blvd. Alberto Limón Padilla s/n Col. Otay Tecnológico, Tijuana, B.C. 22510, México.
Mirza Mariela Ruiz Ramirez Tecnológico Nacional de México/IT de Tijuana/ Tecnológico de Tijuana, Blvd. Alberto Limón Padilla s/n Col. Otay Tecnológico, Tijuana, B.C. 22510, México.
Karen Melisa Luque López Tecnológico Nacional de México/IT de Tijuana/ Tecnológico de Tijuana, Blvd. Alberto Limón Padilla s/n Col. Otay Tecnológico, Tijuana, B.C. 22510, México.
Balter Trujillo Navarrete Tecnológico Nacional de México/IT de Tijuana/ Tecnológico de Tijuana, Blvd. Alberto Limón Padilla s/n Col. Otay Tecnológico, Tijuana, B.C. 22510, México.

DOI:

https://doi.org/10.37636/recit.v44274286

Palabras clave:

Fotocatálisis, TiO2, Tetraciclina, Radiación UV, Reactor tipo Bach

Resumen

Se sintetizaron nanoflores de óxido de titanio (TiO₂) fase rutilo similares a crisantemo sobre la superficie de anillos de borosilicato Raschig (BRRs). La nanoarquitectura jerárquica se investigó usando varias técnicas fisicoquímicas: microscopía electrónica de barrido (MEB), espectroscopia de energía dispersiva (EED), difracción de rayos-X (DRX), espectroscopia infrarroja por transformada de Fourier (IR-TR), espectroscopia de reflectancia difusa (ERD), potencial zeta (ζ). Los TiO₂-BRR fueron usados como columna empacada en un reactor fotocatalítico, y evaluada su actividad catalítica en la degradación de un antibiótico bacteriostático: tetraciclina (C₂2H₂₄N₂O₈). El fotocatalizador eliminó el 91% del contaminante emergente logrando una eficiencia energética del 68% con una carga optimizada de 75 TiO₂-BRR y un pH de 4 a 25 °C; sin variación significativa en al menos tres ciclos de fotodegradación. Esta información se puede utilizar para el desarrollo de fotocatalizadores soportados de TiO₂ dirigidos a eliminar contaminantes emergentes, ofreciendo una alternativa viable.

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