Comparative Kinetic Analysis of Triclosan Degradation under UV-C and Simulated Solar Irradiation
Metadatos
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González Fernández, Lázaro Adrián; Chems, Myriam; Medellín Castillo, Nahum Andrés; Castillo Ramos, Ventura; Sánchez Polo, Manuel; Vilasó Cadre, Javier E.; Ocampo-Pérez, RaúlEditorial
MDPI
Materia
Triclosan degradation UV-C irradiation Simulated solar irradiation
Fecha
2024-04-25Referencia bibliográfica
González-Fernández, L.A.; Chems, M.; Medellín-Castillo, N.A.; Castillo-Ramos, V.; Sánchez-Polo, M.; Vilasó-Cadre, J.E.; Ocampo-Pérez, R. Comparative Kinetic Analysis of Triclosan Degradation under UV-C and Simulated Solar Irradiation. Separations 2024, 11, 131. https://doi.org/10.3390/separations11050131
Patrocinador
PhD thesis work in Chemistry at the University of Granada and PhD in Environmental Sciences at the Autonomous University of San Luis PotosiResumen
This research delves deeply into the intricate degradation kinetics of triclosan, employing
two distinct methodologies: UV and simulated solar irradiation. Through a comprehensive comparative
analysis, the study endeavors to elucidate the efficacy of these techniques, aiming to shed
light on their respective methodological strengths and limitations. The study compares the efficacy
of UV and simulated solar irradiation techniques for triclosan degradation, revealing that both
methods exhibit effectiveness in degrading triclosan, with variations observed in degradation rates
and byproduct formation. Through a detailed examination of the kinetics of triclosan degradation,
the study reveals the intricate pathways and mechanisms involved in the photodegradation process.
Results highlight the influence of irradiance levels and residence times on degradation efficiency.
The research identifies optimal conditions for triclosan degradation, emphasizing the importance
of residence time and irradiance levels. Results show that a residence time of 4 h and an irradiance
level of 450W m−2 maximize degradation efficiency. Analysis of degradation byproducts provides
insights into the transformation pathways of triclosan under UV and simulated solar irradiation,
indicating the formation of 2,4-dichlorophenol, quinone, and hydroquinone as primary byproducts.