PDF
(1137KB)
Abstract
• Reclamation projects are important disturbances on microplastic risk in coasts.
• Tidal-flat reclamation area is a large storage medium for sedimentary microplastics.
• Aging and distribution features of soil microplastics show spatial heterogeneity.
• Coastal weathered engineering geotextiles are a significant threat to marine health.
Coastal tidal flats have received considerable attention in recent years, as they provide a direct channel for the discharge of terrestrial microplastics into the ocean. Land reclamation is occurring increasingly frequently in coastal tidal-flats; however, the environmental impacts of these activities remain unclear. Therefore, this pioneering study assessed the microplastic emission characteristics of reclamation geotextiles and performed a risk assessment accordingly. Morphological characterization of geotextile samples collected from five sites in Dongtai, China, provided evidence of sedimentary weathering. Based on several assumptions, the average abundance of microplastics in soil covered by geotextiles was estimated to reach 349±137 particles/kg dry weight, with the total microplastic load in the reclaimed area estimated to be 20.67±8.06 t. Compared with previous studies, this research demonstrates that coastal reclamation areas store a high concentration of microplastics, aggravating marine microplastic pollution. Moreover, conditional fragmentation model results revealed that the weathering and distribution characteristics of soil microplastics in coastal tidal-flat areas exhibit spatial heterogeneity, being more easily affected by natural factors (such as tides) than those in inland areas. As a result of tides, the annual discharge of geotextile-originating microplastics from the studied areas into the ocean was approximately 2465.52±960.77 t. These findings prove that the risks posed by engineering-microplastics are significant, indicating that further investigations are required on the precise laws of transfer and migration, as well as the toxicity mechanisms, in order to improve analytical techniques and policies in this field.
Graphical abstract
Keywords
Coastal reclamation
/
Engineering geotextiles
/
Soil microplastics
/
Weathering simulation
/
Marine emission
Cite this article
Download citation ▾
Xue Bai, Chang Li, Lingyu Ma, Pei Xin, Fengjie Li, Zhenjia Xu.
Quantitative analysis of microplastics in coastal tidal-flat reclamation in Dongtai, China.
Front. Environ. Sci. Eng., 2022, 16(8): 107 DOI:10.1007/s11783-022-1528-5
| [1] |
Brahney J, Hallerud M, Heim E, Hahnenberger M, Sukumaran S (2020). Plastic rain in protected areas of the United States. Science, 368(6496): 1257–1260
|
| [2] |
Carneiro J R, Morais M, Lopes M D (2018). Degradation of polypropylene geotextiles with different chemical stabilisations in marine environments. Construction & Building Materials, 165: 877–886
|
| [3] |
Danopoulos E, Jenner L C, Twiddy M, Rotchell J M (2020). Microplastic contamination of seafood intended for human consumption: A systematic review and meta-analysis. Environental Health Perspectives, 128(12): 126002
|
| [4] |
Dris R, Gasperi J, Tassin B (2018). Sources and fate of microplastics in urban areas: A focus on Paris megacity. In: Wagner M, Lambert S, eds. Freshwater Microplastics. Cham: Springer International Publishing, 58: 69–83
|
| [5] |
Du J, Zhao H X, Liu S S, Xie H J, Wang Y, Chen J W (2017). Antibiotics in the coastal water of the South Yellow Sea in China: Occurrence, distribution and ecological risks. Science of the Total Environment, 595: 521–527
|
| [6] |
Eo S, Hong S H, Song Y K, Han G M, Shim W J (2019). Spatiotemporal distribution and annual load of microplastics in the Nakdong River, Korea. Water Research, 160: 228–237
|
| [7] |
Guo B Y, Meng J, Wang X Y, Yin C N, Hao W Y, Ma B W, Tao Z (2020). Quantification of pesticide residues on plastic mulching films in typical farmlands of the North China. Frontiers of Environmental Science & Engineering, 14(1): 2
|
| [8] |
Hidalgo-Ruz V, Honorato-Zimmer D, Gatta-Rosemary M, Nunez P, Hinojosa I A, Thiel M (2018). Spatio-temporal variation of anthropogenic marine debris on Chilean beaches. Marine Pollution Bulletin, 126: 516–524
|
| [9] |
Hitchcock J N (2020). Storm events as key moments of microplastic contamination in aquatic ecosystems. Science of the Total Environment, 734: 139436
|
| [10] |
Jambeck J R, Geyer R, Wilcox C, Siegler T R, Perryman M, Andrady A, Narayan R, Law K L (2015). Plastic waste inputs from land into the ocean. Science, 347(6223): 768–771
|
| [11] |
Kiessling T, Knickmeier K, Kruse K, Brennecke D, Nauendorf A, Thiel M (2019). Plastic Pirates sample litter at rivers in Germany: Riverside litter and litter sources estimated by schoolchildren. Environmental Pollution, 245: 545–557
|
| [12] |
Kim I S, Chae D H, Kim S K, Choi S, Woo S B (2015). Factors influencing the spatial variation of microplastics on high-tidal coastal beaches in Korea. Archives of Environmental Contamination and Toxicology, 69(3): 299–309
|
| [13] |
Kukulka T, Jenkins R L III, Kirby J T, Shi F Y, Scarborough R W (2017). Surface wave dynamics in Delaware Bay and its adjacent coastal shelf. Journal of Geophysical Research. Oceans, 122(11): 8683–8706
|
| [14] |
Lawson C R (2008). Geotextile containment for hydraulic and environmental engineering. Geosynthetics International, 15(6): 384–427
|
| [15] |
Lebreton L C M, Van der Zwet J, Damsteeg J W, Slat B, Andrady A, Reisser J (2017). River plastic emissions to the world’s oceans. Nature Communications, 8: 15611
|
| [16] |
Liu G, Jiang R F, You J, Muir D C G, Zeng E T (2020). Microplastic impacts on microalgae growth: Effects of size and humic acid. Environmental Science & Technology, 54(3): 1782–1789
|
| [17] |
Liu X S, Wang J M (2020). Algae (Raphidocelis subcapitata) mitigate combined toxicity of microplastic and lead on Ceriodaphnia dubia. Frontiers of Environmental Science & Engineering, 14(6): 97
|
| [18] |
Liu Z Q, Chen M H, Li Y M, Huang Y H, Fan B, Lv W W, Yu P, Wu D L, Zhao Y L (2018). Different effects of reclamation methods on macrobenthos community structure in the Yangtze Estuary, China. Marine Pollution Bulletin, 127: 429–436
|
| [19] |
Mai L, Sun X F, Xia L L, Bao L J, Liu L Y, Zeng E Y (2020). Global riverine plastic outflows. Environmental Science & Technology, 54(16): 10049–10056
|
| [20] |
Mohamed Nor N H, Obbard J P (2014). Microplastics in Singapore’s coastal mangrove ecosystems. Marine Pollution Bulletin, 79(1–2): 278–283
|
| [21] |
Prambauer M, Wendeler C, Weitzenbock J, Burgstaller C (2019). Biodegradable geotextiles: An overview of existing and potential materials. Geotextiles and Geomembranes, 47(1): 48–59
|
| [22] |
Sarker A, Deepo D M, Nandi R, Rana J, Islam S, Rahman S, Hossain M N, Islam M S, Baroi A, Kim J E (2020). A review of microplastics pollution in the soil and terrestrial ecosystems: A global and Bangladesh perspective. Science of the Total Environment, 733: 139296
|
| [23] |
Schwab F, Rothen-Rutishauser B, Petri-Fink A (2020). When plants and plastic interact. Nature Nanotechnology, 15(9): 729–730
|
| [24] |
Song Y K, Hong S H, Eo S, Jang M, Han G M, Isobe A, Shim W J (2018). Horizontal and vertical distribution of microplastics in korean coastal waters. Environmental Science & Technology, 52(21): 12188–12197
|
| [25] |
Song Y K, Hong S H, Jang M, Han G M, Jung S W, Shim W J (2017). Combined effects of UV exposure duration and mechanical abrasion on microplastic fragmentation by polymer type. Environmental Science & Technology, 51(8): 4368–4376
|
| [26] |
Sun Q H, Li J, Wang C, Chen A Q, You Y L, Yang S P, Liu H H, Jiang G B, Wu Y N, Li Y S (2022). Research progress on distribution, sources, identification, toxicity, and biodegradation of microplastics in the ocean, freshwater, and soil environment. Frontiers of Environmental Science & Engineering, 16(1): 1
|
| [27] |
Szewc K, Graca B, Dolega A (2021). Atmospheric deposition of microplastics in the coastal zone: Characteristics and relationship with meteorological factors. Science of the Total Environment, 761: 143272
|
| [28] |
Tan W B, Cui D Y, Xi B D (2021). Moving policy and regulation forward for single-use plastic alternatives. Frontiers of Environmental Science & Engineering, 15(3): 50
|
| [29] |
Van Cauwenberghe L, Claessens M, Vandegehuchte M B, Mees J, Janssen C R (2013). Assessment of marine debris on the Belgian Continental Shelf. Marine Pollution Bulletin, 73(1): 161–169
|
| [30] |
Wang L W, Li P F, Zhang Q, Wu W M, Luo J, Hou D Y (2021). Modeling the conditional fragmentation-induced microplastic distribution. Environmental Science & Technology, 55(9): 6012–6021
|
| [31] |
Wang Z, Huo J Z, Duan Y R (2020). The impact of government incentives and penalties on willingness to recycle plastic waste: An evolutionary game theory perspective. Frontiers of Environmental Science & Engineering, 14(2): 29
|
| [32] |
Wang T, Zou X Q, Li B J, Yao Y L, Zang Z, Li Y L, Yu W W, Wang W Z (2019). Preliminary study of the source apportionment and diversity of microplastics: Taking floating microplastics in the South China Sea as an example. Environmental Pollution, 245: 965–974
|
| [33] |
Wang Y P, Zhang R S, Gao S (1999). Geomorphic and hydrodynamic responses in salt marsh-tidal creek systems, Jiangsu, China. Chinese Science Bulletin, 44(6): 544–549
|
| [34] |
Wu N, Zhang Y, Zhang X H, Zhao Z, He J H, Li W P, Ma Y Z, Niu Z (2019). Occurrence and distribution of microplastics in the surface water and sediment of two typical estuaries in Bohai Bay, China. Environental Science-Processes & Impacts, 21(7): 1143–1152
|
| [35] |
Xue B M, Zhang L L, Li R L, Wang Y H, Guo J, Yu K F, Wang S P (2020). Underestimated microplastic pollution derived from fishery activities and “hidden” in deep sediment. Environmental Science & Technology, 54(4): 2210–2217
|
RIGHTS & PERMISSIONS
Higher Education Press
