RESUMEN
The ubiquity of plastics in modern life has made them a significant environmental concern and a marker of the Anthropocene era. The degradation of plastics results in the formation of microplastics (MPs), which measure 5 mm or less. The coexistence of MPs with other pollutants found in sludge, water treatment plant effluents, surface water, and groundwater, shapes the environmental landscape together. Despite extensive investigation, the long-term implications of MPs in soils remain uncertain, underscoring the importance of delving into their transportation and interactions with soil biota and other contaminants. The present article provides a comprehensive overview of MPs contamination in soil, encompassing its sources, prevalence, features, and interactions with soil flora and fauna, heavy metals, and organic compounds. The sources of MPs in soil agroecosystems are mulching, composting, littering, sewage sludge, irrigation water, and fertilizer application. The concentration of MPs reported in plastic mulch, littering, and sewage sludge is 503 ± 2760 items per kg-1, 4483 ± 2315 MPs/kg, and 11,100 ± 570 per/kg. The transport of MPs in soil agroecosystems is due to their horizontal and vertical migration including biotic and abiotic mobility. The article also highlighted the analytical process, which includes sampling planning, collection, purification, extraction, and identification techniques of MPs in soil agroecosystems. The mechanism in the interaction of MPs and organic pollutants includes surface adsorption or adhesion cation bridging, hydrogen bonding, charge transfer, ligand exchange, van der Waals interactions, and ion exchange.
RESUMEN
Currently, around 400 million tonnes of synthetic polymers are being dumped as waste annually and by this rate by 2050 the ocean would contain more such waste compared to the total weight of fish. As recycling could solve part of this problem, recently such waste is being reused for various purposes like composite preparation, oil production and various other use such as production of foams, sponges, and aerogels. However, there is a relatively limited literature available on the utilization of polyethylene polymer (like LDPE). The study presented in this article indicated that LDPE-based polymers could be reused (after modification) for preparation of hydrophobic, lightweight, and porous aerogels that have oil-spills and organic solvent adsorption capacity. The aerogels showed contact angle of 121.9o, bulk density below 0.25 g/cm3, and were found to be semi-crystalline. The aerogels showed oil and solvent adsorption more than that for their untreated counterparts. Also, the aerogels were found to be recycled for more than five cycles with very minimum loss of efficacy. This area of producing oil sorbents from single used plastic wastes is still very open for further research and seems to be a promising route for both waste reduction, and the synthesis of value-added products. This could be one of the most sustainable approaches for efficient single-used plastic wase management and environment clean-up.