We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Heterogeneous Nucleation of Supersaturated Water Vapor onto Sub-10 nm Nanoplastic Particles
Summary
Researchers conducted the first experiments on heterogeneous nucleation of water vapor onto sub-10 nm PET nanoplastic seeds, finding that nanoplastics activate water droplet formation at lower supersaturation than silver particles, with strong effects from plastic additives and temperature — suggesting atmospheric nanoplastics may influence cloud formation.
Nanoplastic pollution by atmospheric transport processes is a recently discovered environmental problem on a global scale that is attributed to the dispersion of aerosolized nanoplastics. However, knowledge about the basic physicochemical properties of aerosol nanoplastic particles is scarce. Here, we present experiments on the heterogeneous nucleation of supersaturated water vapor onto sub-10 nm polyethylene terephthalate (PET) seeds. We determined onset saturation ratios for the activation of PET seeds in comparison to the well-documented reference system of silver particles, resulting in lower onset saturation ratios of the PET seeds compared to silver seeds. By using different PET bulk materials for the generation of nanoparticles, we report a strong material dependence of the onset saturation ratios, pointing to a strong effect of additives from commodity plastics in heterogeneous nucleation. Moreover, our results show a strong dependence on nucleation temperature that might be of immediate atmospheric relevance. Our work can be considered as an initial step in airborne nanoplastic detection by condensation techniques, and we anticipate our study to serve as a basis for further research that will eventually allow assessing the impact of nanoplastic dispersion on atmospheric processes.
Sign in to start a discussion.
More Papers Like This
Potential impacts of atmospheric microplastics and nanoplastics on cloud formation processes
Researchers investigated how atmospheric microplastics and nanoplastics could act as cloud condensation nuclei or ice nucleating particles, potentially affecting cloud formation, precipitation patterns, and Earth's radiation balance at sufficient concentrations.
Potential Influence of Microplastics on Cloud Formation through Heterogeneous Ice Nucleation
Researchers tested whether microplastic particles can act as ice-nucleating agents and influence cloud ice formation through heterogeneous ice nucleation in laboratory experiments. Multiple polymer types triggered ice nucleation at temperatures relevant to cloud formation, suggesting that airborne microplastics could influence precipitation processes and atmospheric chemistry.
Adsorption-Driven Cloud Droplet Activation of Fresh and Aged Polypropylene Particles
Scientists found that tiny plastic particles in the air can help form clouds and potentially affect weather patterns. When these plastic particles get weathered by sunlight and air pollution, they become much better at attracting water droplets to form clouds compared to fresh plastic particles. This matters because microplastics are now everywhere in our atmosphere, and understanding how they change weather and climate could help us better predict environmental changes that affect human health and agriculture.
Heterogeneous Ice Nucleation of Microplastics before and after Oxidation
Researchers investigated heterogeneous ice nucleation induced by seven morphologies of polypropylene, polyethylene, and polyethylene terephthalate microplastics in immersion freezing mode, and examined how atmospheric oxidation affects their ice-nucleating efficiency and potential influence on cloud formation.
Ice nucleation onto model nanoplastics in the cirrus cloud regime
Laboratory experiments showed that model polystyrene nanoplastics can act as ice-nucleating particles in the cirrus cloud temperature regime, suggesting that atmospheric nanoplastics transported to high altitudes could influence cloud formation and Earth's radiative budget.