Plastic rain in protected areas of the United States

Here, there, and everywhere

No place is safe from plastic pollution. Brahney et al. show that even the most isolated areas in the United States—national parks and national wilderness areas—accumulate microplastic particles after they are transported there by wind and rain (see the Perspective by Rochman and Hoellein). They estimate that more than 1000 metric tons per year fall within south and central western U.S. protected areas. Most of these plastic particles are synthetic microfibers used for making clothing. These findings should underline the importance of reducing pollution from such materials.

Science, this issue p. 1257; see also p. 1184

Abstract

Eleven billion metric tons of plastic are projected to accumulate in the environment by 2025. Because plastics are persistent, they fragment into pieces that are susceptible to wind entrainment. Using high-resolution spatial and temporal data, we tested whether plastics deposited in wet versus dry conditions have distinct atmospheric life histories. Further, we report on the rates and sources of deposition to remote U.S. conservation areas. We show that urban centers and resuspension from soils or water are principal sources for wet-deposited plastics. By contrast, plastics deposited under dry conditions were smaller in size, and the rates of deposition were related to indices that suggest longer-range or global transport. Deposition rates averaged 132 plastics per square meter per day, which amounts to >1000 metric tons of plastic deposition to western U.S. protected lands annually.

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Supplementary Material

Summary

Materials and Methods

Figs. S1 to S5

Table S1

References (25–29)

Data S1 to S4

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References and Notes

R. Geyer, J. R. Jambeck, K. L. Law, Production, use, and fate of all plastics ever made. Sci. Adv. 3, e1700782 (2017).

C. M. Rochman, Microplastics research—from sink to source. Science 360, 28–29 (2018).

S. Allen, D. Allen, V. R. Phoenix, G. Le Roux, P. Durántez Jiménez, A. Simonneau, S. Binet, D. Galop, Atmospheric transport and deposition of microplastics in a remote mountain catchment. Nat. Geosci. 12, 339–344 (2019).

M. Bergmann, S. Mützel, S. Primpke, M. B. Tekman, J. Trachsel, G. Gerdts, White and wonderful? Microplastics prevail in snow from the Alps to the Arctic. Sci. Adv. 5, eaax1157 (2019).

N. Mahowald, S. Albani, J. F. Kok, S. Engelstaeder, R. Scanza, D. S. Ward, M. G. Flanner, The size distribution of desert dust aerosols and its impact on the Earth system. Aeolian Res. 15, 53–71 (2014).

P. R. Betzer, K. L. Carder, R. A. Duce, J. T. Merrill, N. W. Tindale, M. Uematsu, D. K. Costello, R. W. Young, R. A. Feely, J. A. Breland, R. E. Bernstein, A. M. Greco, Long–range transport of giant mineral aerosol particles. Nature 336, 568–571 (1988).

C. R. Lawrence, J. Neff, The contemporary physical and chemical flux of Aeolian dust: A synthesis of direct measurements of dust deposition. Chem. Geol. 267, 46–63 (2009).

N. C. Brady, R. R. Weil, The Nature and Properties of Soils (Prentice Hall, 2008).

E. L. Morley, D. Robert, Electric fields elicit ballooning in spiders. Curr. Biol. 28, 2324–2330.e2 (2018).

A. F. Stein, R. R. Draxler, G. D. Rolph, B. J. B. Stunder, M. D. Cohen, F. Ngan, NOAA’s HYSPLIT atmospheric transport and dispersion modeling system. Bull. Am. Meteorol. Soc. 96, 2059–2077 (2015).

G. Rolph, A. Stein, B. Stunder, Real-time environmental applications and display sYstem: READY. Environ. Model. Softw. 95, 210–228 (2017).

S. A. Carr, Sources and dispersive modes of micro-fibers in the environment. Integr. Environ. Assess. Manag. 13, 466–469 (2017).

U. Pirc, M. Vidmar, A. Mozer, A. Kržan, Emissions of microplastic fibers from microfiber fleece during domestic washing. Environ. Sci. Pollut. Res. Int. 23, 22206–22211 (2016).

K. Duis, A. Coors, Microplastics in the aquatic and terrestrial environment: Sources (with a specific focus on personal care products), fate and effects. Environ. Sci. Eur. 28, 2 (2016).

S. V. M. Tesson, C. A. Skjøth, T. Šantl-Temkiv, J. Löndahl, Airborne microalgae: Insights, opportunities, and challenges. Appl. Environ. Microbiol. 82, 1978–1991 (2016).

M. C. Rillig, Microplastic in terrestrial ecosystems and the soil? Environ. Sci. Technol. 46, 6453–6454 (2012).

M. Cole, P. Lindeque, E. Fileman, C. Halsband, R. Goodhead, J. Moger, T. S. Galloway, Microplastic ingestion by zooplankton. Environ. Sci. Technol. 47, 6646–6655 (2013).

S. Oberbeckmann, M. G. J. Loeder, G. Gerdts, A. M. Osborn, Spatial and seasonal variation in diversity and structure of microbial biofilms on marine plastics in Northern European waters. FEMS Microbiol. Ecol. 90, 478–492 (2014).

H. S. Carson, S. L. Colbert, M. J. Kaylor, K. J. McDermid, Small plastic debris changes water movement and heat transfer through beach sediments. Mar. Pollut. Bull. 62, 1708–1713 (2011).

K. A. Moser, J. S. Baron, J. Brahney, I. A. Oleksy, J. E. Saros, E. J. Hundey, S. A. Sadro, J. Kopáček, R. Sommaruga, M. J. Kainz, A. L. Strecker, S. Chandra, D. M. Walters, D. L. Preston, N. Michelutti, F. Lepori, S. A. Spaulding, K. R. Christianson, J. M. Melack, J. P. Smol, Mountain lakes: Eyes on global environmental change. Glob. Planet. Change 178, 77–95 (2019).

M. Beniston, Mountain Environments in Changing Climates (Routledge, 2002).

R. Dris, J. Gasperi, C. Mirande, C. Mandin, M. Guerrouache, V. Langlois, B. Tassin, A first overview of textile fibers, including microplastics, in indoor and outdoor environments. Environ. Pollut. 221, 453–458 (2017).

J. Brahney, G. Wetherbee, G. A. Sexstone, C. Youngbull, P. Strong, R. C. Heindel, A new sampler for the collection and retrieval of dry dust deposition. Aeolian Res. 45, 100600 (2020).

K. Munno, H. De Frond, B. O’Donnell, C. M. Rochman, Increasing the accessibility for characterizing microplastics: Introducing new application-based and spectral libraries of plastic particles (SLoPP and SLoPP-E). Anal. Chem. 92, 2443–2451 (2020).

S. Primpke, M. Wirth, C. Lorenz, G. Gerdts, Reference database design for the automated analysis of microplastic samples based on Fourier transform infrared (FTIR) spectroscopy. Anal. Bioanal. Chem. 410, 5131–5141 (2018).

Center for International Earth Science Information Network, Columbia University, Gridded Population of the World, Version 4 (GPWv4): Population Density Adjusted to Match 2015 Revision UN WPP Country Totals, Revision 11 (NASA Socioeconomic Data and Applications Center, 2018); .