Microplastics in Southern Ocean sea ice: a pan-Antarctic perspective

Anna Kelly; Thomas Rodemann; Klaus M. Meiners; Heidi J. Auman; Sebastien Moreau; Francois Fripiat; Bruno Dellile; Delphine Lannuzel

doi:10.20517/wecn.2024.66

Emerging Contaminants and Environmental Health ›› 2024, Vol. 3 ›› Issue (4) :26 DOI: 10.20517/wecn.2024.66

Research Article

Microplastics in Southern Ocean sea ice: a pan-Antarctic perspective

Author information +

¹Institute for Marine and Antarctic Studies, University of Tasmania, Hobart 7001, Tasmania, Australia.

²Central Science Laboratory, University of Tasmania, Hobart 7001, Tasmania, Australia.

³Australian Antarctic Division, Department of Climate Change, Energy, the Environment and Water, Kingston 7050, Tasmania, Australia.

⁴Australian Antarctic Program Partnership, University of Tasmania, Hobart 7001, Tasmania, Australia.

⁵Australian Centre for Excellence in Antarctic Science, Institute for Marine and Antarctic Studies, University of Tasmania, Hobart 7004, Tasmania, Australia.

⁶Norwegian Polar Institute, Fram Centre, Tromsø 9007, Norway.

⁷Laboratoire de Glaciologie, Université Libre des Bruxelles, Brussels 1050, Belgium.

⁸Chemical Oceanography Unit, Freshwater and Oceanic Sciences Unit of Research, University of Liège, Liège 4000, Belgium.

Correspondence to: Anna Kelly, Institute for Marine and Antarctic Studies, University of Tasmania, Private Bag 129, Hobart 7001, Tasmania, Australia. E-mail: anna.kelly@utas.edu.au

Show less

History +

PDF

Abstract

Microplastic (MP; plastic particles < 5 mm) pollution is pervasive in the marine environment, including remote polar environments. This study provides the first pan-Antarctic survey of MP pollution in Southern Ocean sea ice by analyzing sea ice cores from several diverse Antarctic regions. Abundance, chemical composition, and particle size data were obtained from 19 archived ice core samples. The cores were melted, filtered, and chemically analyzed using Fourier-transform infrared spectroscopy and 4,090 MP particles were identified. Nineteen polymer types were found across all samples, with an average concentration of 44.8 (± 50.9) particles·L^-1. Abundance and composition varied with ice type and geographical location. Pack ice exhibited significantly higher particle concentrations than landfast ice, suggesting open ocean sources of pollution. Winter sea ice cores had significantly more MPs than spring and summer-drilled cores, suggesting ice formation processes play a role in particle incorporation. Smaller particles dominated across samples. Polyethylene (PE) and polypropylene (PP) were the most common polymers, mirroring those most identified across marine habitats. Higher average MP concentrations in developing sea ice during autumn and winter, contrasting lower levels observed in spring and summer, suggest turbulent conditions and faster growth rates are likely responsible for the increased incorporation of particles. Southern Ocean MP contamination likely stems from both local and distant sources. However, the circulation of deep waters and long-range transport likely contribute to the accumulation of MPs in regional gyres, coastlines, and their eventual incorporation into sea ice. Additionally, seasonal sea ice variations likely influence regional polymer compositions, reflecting the MP composition of the underlying waters.

Keywords

Microplastic / marine debris / sea ice / plastic pollution / Antarctica / Southern Ocean

Cite this article

Download citation ▾

Anna Kelly, Thomas Rodemann, Klaus M. Meiners, Heidi J. Auman, Sebastien Moreau, Francois Fripiat, Bruno Dellile, Delphine Lannuzel. Microplastics in Southern Ocean sea ice: a pan-Antarctic perspective. Emerging Contaminants and Environmental Health, 2024, 3(4): 26 DOI:10.20517/wecn.2024.66

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Kanhai DK,Krumpen T,O’Connor I.Microplastics in sea ice and seawater beneath ice floes from the Arctic Ocean.Sci Rep2020;10:5004 PMCID:PMC7081216

[2]	Bergmann M,Primpke S,Trachsel J.White and wonderful? Microplastics prevail in snow from the Alps to the Arctic.Sci Adv2019;5:eaax1157 PMCID:PMC6693909

[3]	Obbard RW,Wong YQ,Baker I.Global warming releases microplastic legacy frozen in Arctic Sea ice.Earth’s Future2014;2:315-20

[4]	Peeken I,Beyer B.Arctic sea ice is an important temporal sink and means of transport for microplastic.Nat Commun2018;9:1505 PMCID:PMC5915590

[5]	Fraser CI,Plessis MD.Breaking down the barrier: dispersal across the Antarctic Polar Front.Ecography2017;40:235-7

[6]	Mountford AS.Modeling the accumulation and transport of microplastics by sea ice.JGR Oceans2021;126:e2020JC016826

[7]	Suaria G,Lee JR,Aliani S.Floating macro- and microplastics around the Southern Ocean: results from the Antarctic circumnavigation expedition.Environ Int2020;136:105494

[8]	De-la-Torre GE,Dioses-Salinas DC.Assessing the current state of plastic pollution research in Antarctica: knowledge gaps and recommendations.Chemosphere2024;355:141870

[9]	da Silva JRMC, Bergami E, Gomes V, Corsi I. Occurrence and distribution of legacy and emerging pollutants including plastic debris in Antarctica: sources, distribution and impact on marine biodiversity.Mar Pollut Bull2023;186:114353

[10]	Tirelli V,Lusher AL.Microplastics in polar samples. In: Rocha-Santos T, Costa MF, Mouneyrac C, editors. Handbook of microplastics in the environment. Cham: Springer International Publishing; 2022. pp. 281-322.

[11]	Fraser CI,Hogg AM.Antarctica’s ecological isolation will be broken by storm-driven dispersal and warming.Nature Clim Change2018;8:704-8

[12]	Isobe A,Uchida K.Microplastics in the Southern Ocean.Mar Pollut Bull2017;114:623-6

[13]	Waller CL,Waluda CM.Microplastics in the Antarctic marine system: an emerging area of research.Sci Total Environ2017;598:220-7

[14]	Kelly A,Rodemann T,Auman HJ.Microplastic contamination in east Antarctic sea ice.Mar Pollut Bull2020;154:111130

[15]	Materić D,Vallelonga P,Röckmann T.Nanoplastics measurements in Northern and Southern polar ice.Environ Res2022;208:112741

[16]	Aves AR,Gaw S.First evidence of microplastics in Antarctic snow.The Cryosphere2022;16:2127-45

[17]	Cunningham EM,Dick JTA.High abundances of microplastic pollution in deep-sea sediments: evidence from Antarctica and the Southern Ocean.Environ Sci Technol2020;54:13661-71

[18]	Cunningham EM,Altieri KE.The transport and fate of microplastic fibres in the Antarctic: the role of multiple global processes.Front Mar Sci2022;9:1056081

[19]	Lacerda ALDF,van Sebille E.Plastics in sea surface waters around the Antarctic Peninsula.Sci Rep2019;9:3977 PMCID:PMC6408452

[20]	Zhang Y,Kang S.Importance of atmospheric transport for microplastics deposited in remote areas.Environ Pollut2019;254:112953

[21]	Nowlin WD.The physics of the Antarctic circumpolar current.Rev Geophys1986;24:469-91

[22]	Ryan S,Huhn O.On the warm inflow at the eastern boundary of the Weddell Gyre.Deep Sea Res Pt I2016;107:70-81

[23]	Tamsitt V,Morrison AK.Spiraling pathways of global deep waters to the surface of the Southern Ocean.Nat Commun2017;8:172 PMCID:PMC5541074

[24]	Pennel R.On the factors controlling the eddy-induced transport in the Antarctic circumpolar current.J Phys Oceanogr2014;44:2127-38

[25]	Rintoul SR.Dynamics of the Southern Ocean circulation. Ocean circulation and climate - a 21st century perspective. Elsevier; 2013. pp. 471-92.

[26]	National Snow and Ice Data Center. NOAA/NSIDC climate data record of passive microwave sea ice concentration, version 4. Available from: https://nsidc.org/data/g02202/versions/4. [Last accessed on 23 Dec 2024]

[27]	Geilfus NX,Sousa J.Distribution and impacts of microplastic incorporation within sea ice.Mar Pollut Bull2019;145:463-73

[28]	Spindler M.Notes on the biology of sea ice in the Arctic and Antarctic.Polar Biol1994;14:BF00238447

[29]	Leventer A.Particulate flux from sea ice in polar waters. In: Thomas DN, Dieckmann GS, editors. Sea ice. Wiley; 2003. pp. 303-32.

[30]	Jeffries MO,Hurst-Cushing B.Snow-ice accretion and snow-cover depletion on Antarctic first-year sea-ice floes.Ann Glaciol2001;33:51-60

[31]	Lannuzel D,Schoemann V,Tison J.Development of a sampling and flow injection analysis technique for iron determination in the sea ice environment.Anal Chim Acta2006;556:476-83

[32]	Witzig CS,Wörle K.When good intentions go bad-false positive microplastic detection caused by disposable gloves.Environ Sci Technol2020;54:12164-72

[33]	Quinn B,Ewins C.Validation of density separation for the rapid recovery of microplastics from sediment.Anal Methods2017;9:1491-8

[34]	López-Rosales A,Grueiro-Noche G,López-Mahía P.Development of a fast and efficient method to analyze microplastics in planktonic samples.Mar Pollut Bull2021;168:112379

[35]	Thomas DN. Sea ice - an introduction to its physics, chemistry, biology and geology. London: Wiley Blackwell; 2003. Available from: https://www.wiley.com/en-us/Sea+Ice%3A+An+Introduction+to+its+Physics%2C+Chemistry%2C+Biology+and+Geology-p-9780632058082. [Last accessed on 23 Dec 2024]

[36]	Barrette PD.Understanding frazil ice: the contribution of laboratory studies.Cold Reg Sci Technol2021;189:103334

[37]	Ito M,Fukamachi Y,Kusumoto Y.Observations of frazil ice formation and upward sediment transport in the Sea of Okhotsk: a possible mechanism of iron supply to sea ice: frazil ice and upward sediment transport.J Geophys Res Oceans2017;122:788-802

[38]	Dieckmann GS,Ackley SF.The nutrient status in sea ice of the Weddell Sea during winter: effects of sea ice texture and algae.Polar Biol1991;11:449-56

[39]	Lannuzel D,de Jong J.Distribution of dissolved iron in Antarctic sea ice: spatial, seasonal, and inter‐annual variability.J Geophys Res2010;115:2009JG001031

[40]	Garrison DL,Buck KR.A physical mechanism for establishing algal populations in frazil ice.Nature1983;306:363-5

[41]	Spindler M.Distribution and abundance of the planktic foraminifer Neogloboquadrina pachyderma in sea ice of the Weddell Sea (Antarctica).Polar Biol1986;5:185-91

[42]	Weeks WF.The growth, structure, and properties of sea ice. In: Untersteiner N, editor. The geophysics of sea ice. Boston: Springer US; 1986. pp. 9-164.

[43]	Garrison D,Reimnitz E.Algae concentrated by frazil ice: evidence from laboratory experiments and field measurements.Antartic Sci1989;1:313-6

[44]	Weissenberger J.Experimental formation of sea ice: importance of water circulation and wave action for incorporation of phytoplankton and bacteria.Polar Biol1998;20:178-88

[45]	Fraser AD,Langhorne PJ.Antarctic landfast sea ice: a review of its physics, biogeochemistry and ecology.Rev Geophys2023;61:e2022RG000770

[46]	Roukaerts A,Van der Linden F.The biogeochemical role of a microbial biofilm in sea ice.Elem Sci Anth2021;9:00134

[47]	van der Merwe P,Nichols CM.Biogeochemical observations during the winter–spring transition in East Antarctic sea ice: evidence of iron and exopolysaccharide controls.Mar Chem2009;115:163-75

[48]	de Jong J,Maricq N.Iron in land-fast sea ice of McMurdo Sound derived from sediment resuspension and wind-blown dust attributes to primary productivity in the Ross Sea, Antarctica.Mar Chem2013;157:24-40

[49]	Meiners K,Fehling J,Spindler M.Vertical distribution of exopolymer particles in sea ice of the Fram Strait (Arctic) during autumn.Mar Ecol Prog Ser2023;248:1-13Available from: http://www.int-res.com/articles/meps2003/248/m248p001.pdf. [Last accessed on 24 Dec 2024]

[50]	Hoppmann M,Smith IJ.Platelet ice, the Southern Ocean’s hidden ice: a review.Ann Glaciol2020;61:341-68

[51]	Fripiat F,Vancoppenolle M.Macro-nutrient concentrations in Antarctic pack ice: overall patterns and overlooked processes.Elementa Sci Anthrop2017;5:13

[52]	Lannuzel D,van der Merwe PC.Iron biogeochemistry in Antarctic pack ice during SIPEX-2.Deep Sea Res Pt II2016;131:111-22

[53]	Meiners KM.Dynamics of nutrients, dissolved organic matter and exopolymers in sea ice. In: Thomas DN, editor. Sea ice. Wiley; 2017. pp. 415-32.

[54]	Chen Z,An C.Entrainment and enrichment of microplastics in ice formation processes: implications for the transport of microplastics in cold regions.Environ Sci Technol2023;57:3176-86

[55]	Tison J,Delille B.Temporal evolution of decaying summer first-year sea ice in the Western Weddell Sea, Antarctica.Deep Sea Res Pt II2008;55:975-87

[56]	Corkill M,Janssens J.Physical and biogeochemical properties of rotten East Antarctic summer sea ice.JGR Oceans2023;128:e2022JC018875

[57]	Reisser J,Noble K.The vertical distribution of buoyant plastics at sea: an observational study in the North Atlantic Gyre.Biogeosciences2015;12:1249-56

[58]	Marshall J.Closure of the meridional overturning circulation through Southern Ocean upwelling.Nature Geosci2012;5:171-80

[59]	Obbard RW.Microplastics in polar regions: the role of long range transport.Curr Opin Environ Sci Health2018;1:24-9

[60]	Zhang S,Ju M.Distribution characteristics of microplastics in surface and subsurface Antarctic seawater.Sci Total Environ2022;838:156051

[61]	Chen Q,Revell LE.Long-range atmospheric transport of microplastics across the southern hemisphere.Nat Commun2023;14:7898 PMCID:PMC10689495

[62]	Bullard JE,O’brien P.Preferential transport of microplastics by wind.Atmos Environ2021;245:118038

[63]	Dawson AL,King CK.Turning microplastics into nanoplastics through digestive fragmentation by Antarctic krill.Nat Commun2018;9:1001 PMCID:PMC5843626

[64]	Andrady AL.Microplastics in the marine environment.Mar Pollut Bull2011;62:1596-605

[65]	Choy CA,Gagne TO.The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column.Sci Rep2019;9:7843 PMCID:PMC6554305

[66]	Leistenschneider C,Primpke S,Burkhardt-Holm P.Unveiling high concentrations of small microplastics (11-500 μm) in surface water samples from the southern Weddell Sea off Antarctica.Sci Total Environ2024;927:172124

[67]	Tison J,Fraser AD.Physical and biological properties of early winter Antarctic sea ice in the Ross Sea.Ann Glaciol2020;61:241-59

[68]	Tison J,Dieckmann G.Biogeochemical impact of snow cover and cyclonic intrusions on the winter Weddell Sea ice pack.JGR Oceans2017;122:9548-71

[69]	Lewis M,Weissling B.Sea ice and snow cover characteristics during the winter–spring transition in the Bellingshausen Sea: an overview of SIMBA 2007.Deep Sea Res Pt II2011;58:1019-38

[70]	Leistenschneider C,Mani T,Taubner H.Microplastics in the Weddell Sea (Antarctica): a forensic approach for discrimination between environmental and vessel-induced microplastics.Environ Sci Technol2021;55:15900-11

[71]	Pakhomova S,Lusher AL.Microplastic variability in subsurface water from the Arctic to Antarctica.Environ Pollut2022;298:118808

[72]	Cincinelli A,Chelazzi D.Microplastic in the surface waters of the Ross Sea (Antarctica): occurrence, distribution and characterization by FTIR.Chemosphere2017;175:391-400

[73]	Kuklinski P,Koper M.Offshore surface waters of Antarctica are free of microplastics, as revealed by a circum-Antarctic study.Mar Pollut Bull2019;149:110573

[74]	Munari C,Scoponi M,Corinaldesi C.Microplastics in the sediments of Terra Nova Bay (Ross Sea, Antarctica).Mar Pollut Bull2017;122:161-5

[75]	Allen S,Moss K,Phoenix VR.Examination of the ocean as a source for atmospheric microplastics.PLoS One2020;15:e0232746 PMCID:PMC7217454

[76]	Almroth B, Eggert H. Marine plastic pollution: sources, impacts, and policy issues.Rev Env Econ Policy2019;13:317-26

[77]	Geyer R,Law KL.Production, use, and fate of all plastics ever made.Sci Adv2017;3:e1700782 PMCID:PMC5517107

[78]	Bråte IL,Allan I. Report made for the Norwegian Environment Agency: microplastics in marine environments; occurrence, distribution and effects. Available from: http://www.miljodirektoratet.no/Documents/publikasjoner/M319/M319.pdf. [Last accessed on 24 Dec 2024]

[79]	Erni-Cassola G,Gibson MI.Distribution of plastic polymer types in the marine environment; a meta-analysis.J Hazard Mater2019;369:691-8

[80]	Illuminati S,Tinari C.Microplastics in bulk atmospheric deposition along the coastal region of Victoria Land, Antarctica.Sci Total Environ2024;949:175221

[81]	Henry B,Klepp IG. Microplastic pollution from textiles: a literature review. 2018. Available from: https://hdl.handle.net/20.500.12199/5360. [Last accessed on 24 Dec 2024]

[82]	Šaravanja A,Dekanić T.Microplastics in wastewater by washing polyester fabrics.Materials2022;15:2683 PMCID:PMC9000408

[83]	Yuan Z,Cummins E.Ranking of potential hazards from microplastics polymers in the marine environment.J Hazard Mater2022;429:128399

[84]	Barboza LGA,Booth AM.Microplastics pollution in the marine environment. World seas: an environmental evaluation. Elsevier; 2019. pp. 329-51.

[85]	Dethleff D.Langmuir circulation driving sediment entrainment into newly formed ice: tank experiment results with application to nature (Lake Hattie, United States; Kara Sea, Siberia).J Geophys Res2007;112:2005JC003259