A nationwide monitoring of atmospheric microplastic deposition

Plastic production continues to increase every year, yet it is widely acknowledged that a significant portion of this material ends up in ecosystems as microplastics (MPs). Among all the environmental compartments affected by MPs, the atmosphere remains the least well-known. Here, we conducted a one...

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Detalles Bibliográficos
Autores: Edo Cuesta, Carlos|||0000-0003-0340-7327, Fernández Piñas, Francisca, Leganés Nieto, Francisco, Gómez, May, Martínez, Ico, Hernández Sánchez, Cintia, González Sálamo, Javier, Hernández Borges, Javier, López Castellanos, Joaquín, Bayo, Javier, Romera Castillo, Cristina, Elustondo, David, Santamaría, Carolina, Alonso, Rocío, García Gómez, Héctor, González Cascón, María Rosario, Martínez Hernández, María de las Virtudes, Ladanburu Aguirre, Junkal, Incera, Mónica, Gago, Jesús, Noya, Beatriz, Beiras, Ricardo, Muniategui Lorenzo, Soledad, Rosal García, Roberto|||0000-0003-0816-8775, González Pleiter, Miguel|||0000-0002-7674-4167
Tipo de recurso: artículo
Fecha de publicación:2023
País:España
Institución:Universidad de Alcalá (UAH)
Repositorio:e_Buah Biblioteca Digital Universidad de Alcalá
Idioma:inglés
OAI Identifier:oai:ebuah.uah.es:10017/62304
Acceso en línea:http://hdl.handle.net/10017/62304
https://dx.doi.org/10.1016/j.scitotenv.2023.166923
Access Level:acceso abierto
Palabra clave:Atmosphere
Atmospheric deposition
Airborne microplastics
Sampling methodology
Outdoor fallout
Urban areas
Química
Chemistry
Descripción
Sumario:Plastic production continues to increase every year, yet it is widely acknowledged that a significant portion of this material ends up in ecosystems as microplastics (MPs). Among all the environmental compartments affected by MPs, the atmosphere remains the least well-known. Here, we conducted a one-year simultaneous monitoring of atmospheric MPs deposition in ten urban areas, each with different population sizes, economic activities, and climates. The objective was to assess the role of the atmosphere in the fate of MPs by conducting a nationwide quantification of atmospheric MP deposition. To achieve this, we deployed collectors in ten different urban areas across continental Spain and the Canary Islands. We implemented a systematic sampling methodology with rigorous quality control/quality assurance, along with particle-oriented identification and quantification of anthropogenic particle deposition, which included MPs and industrially processed natural fibres. Among the sampled MPs, polyester fibres were the most abundant, followed by acrylic polymers, polypropylene, and alkyd resins. Their equivalent sizes ranged from 22 ?m to 398 ?m, with a median value of 71 ?m. The particle size distribution of MPs showed fewer large particles than expected from a three-dimensional fractal fragmentation pattern, which was attributed to the higher mobility of small particles, especially fibres. The atmospheric deposition rate of MPs ranged from 5.6 to 78.6 MPs m?2 day?1, with the higher values observed in densely populated areas such as Barcelona and Madrid. Additionally, we detected natural polymers, mostly cellulosic fibres with evidence of industrial processing, with a deposition rate ranging from 6.4 to 58.6 particles m?2 day?1. There was a positive correlation was found between the population of the study area and the median of atmospheric MP deposition, supporting the hypothesis that urban areas act as sources of atmospheric MPs. Our study presents a systematic methodology for monitoring atmospheric MP deposition.