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Polyester microfibers delay growth of cherry tomato (Solanum lycopersicum var. cerasiforme) throughout the lifecycle
Summary
A lifecycle greenhouse experiment found that polyester microfibers — a common contaminant in soils amended with biosolids — slowed the growth of cherry tomatoes at multiple life stages, and that these effects were caused primarily by the physical properties of the fibers rather than any leached chemicals. Even at a relatively low concentration of 0.5% by soil weight, microfibers measurably impaired plant development. This is significant because polyester microfibers are one of the most prevalent microplastic types in agricultural soils, and their effects on crop productivity could have food security implications.
Agroecosystems are increasingly recognized as major basins for terrestrial microplastics. Many agricultural practices have led to high loading of plastic mulch films, synthetic microfibers, and other microplastics onto fields. There is demonstrated ability for microplastics to influence soil properties and plant productivity, but these effects are highly variable by species, soil, and life stage. Here, we conduct a lifecycle assessment of how polyester microfibers, a dominant biosolid contaminant, affect the development of cherry tomato (Solanum lycopersicum var. cerasiforme) in peaty growing medium. We distinguish the importance of physical and chemical characteristics of microfibers by comparing plants in soil containing microfibers at 0.5% soil weight, or soil watered with leachate isolated from microfibers. We find that polyester microfibers reduce emergence success by 11%, delay flowering and ripening time by several days, and lead to a reduction in biomass in adult plants. However, we observe no effect of chemical additives from microfibers on plant development. We also note a decrease in soil water holding capacity from microfibers. Overall, we conclude that physical microfiber properties or physical/chemical interactions are the likely drivers of biological effects. These findings emphasize that microfibers have impacts beyond mineral soils, and consequences at every stage of plant development.
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