A new study sheds light on the quantity and type of microplastics present in clouds. It offers insight into how these airborne particles influence cloud formation and their negative impact on the climate.
The researchers analyzed cloud water samples from high-altitude mountains in Japan to ascertain the amount of microplastics in them.
While most studies on microplastics have focused on aquatic ecosystems, few have looked at their impact on cloud formation and climate change.
Led by Hiroshi Okochi, Professor at Waseda University, the study appears in a recent issue of the journal Environmental Chemistry Letters. Contributors include co-authors Yize Wang from Waseda University and Yasuhiro Niida from PerkinElmer Japan Co. Ltd.
“Microplastics in the free troposphere are transported and contribute to global pollution,” said Okochi. “If the issue of ‘plastic air pollution’ is not addressed proactively, climate change and ecological risks may become a reality, causing irreversible and serious environmental damage in the future,”
To investigate the role of these tiny plastic particles in the troposphere and the atmospheric boundary layer, the team collected cloud water from the summit of Mount (Mt.) Fuji, south-eastern foothills of Mt. Fuji (Tarobo), and the summit of Mt. Oyama – regions at altitudes ranging between 1300-3776 meters. Using advanced imaging techniques like attenuated total reflection imaging and micro-Fourier transform infrared spectroscopy (µFTIR ATR imaging), the researchers determined the presence of microplastics in the cloud water, and examined their physical and chemical properties.
They identified nine different types of polymers and one type of rubber in the AMPs detected. Notably, most of the polypropylene that was detected in the samples was degraded and had carbonyl (C=O) and/or hydroxyl (OH) groups. The Feret diameters of these AMPs ranged between 7.1 – 94.6 µm, the smallest seen in the free troposphere. Moreover, the presence of hydrophilic (water loving) polymers in the cloud water was abundant, suggesting that they were removed as “cloud condensation nuclei.” These findings confirm that AMPs play a key role in rapid cloud formation, which may eventually affect the overall climate.
Accumulation of AMPs in the atmosphere, especially in the polar regions, could lead to significant changes in the ecological balance of the planet, leading to severe loss of biodiversity. Okochi concludes by saying “AMPs are degraded much faster in the upper atmosphere than on the ground due to strong ultraviolet radiation, and this degradation releases greenhouse gases and contributes to global warming. As a result, the findings of this study can be used to account for the effects of AMPs in future global warming projections.”