Polypropylene microplastics alter the cadmium adsorption capacity on different soil solid fractions

Xianying Ma , Xinhui Zhou , Mengjie Zhao , Wenzhuo Deng , Yanxiao Cao , Junfeng Wu , Jingcheng Zhou

Front. Environ. Sci. Eng. ›› 2022, Vol. 16 ›› Issue (1) : 3

PDF (1754KB)
Front. Environ. Sci. Eng. ›› 2022, Vol. 16 ›› Issue (1) : 3 DOI: 10.1007/s11783-021-1437-z
RESEARCH ARTICLE
RESEARCH ARTICLE

Polypropylene microplastics alter the cadmium adsorption capacity on different soil solid fractions

Author information +
History +
PDF (1754KB)

Abstract

• PP-MPs reduced the adsorption capacity of the bulk soil for Cd in aqueous medium.

• The responses of the POM, OMC and mineral fractions to PP-MPs were different.

• PP-MPs reduced the adsorption of POM and OMC fractions to Cd.

• PP-MPs increased the adsorption of mineral fraction to Cd.

• Effect of MPs on soil may be controlled by proportion of POM, OMC and mineral fractions.

Microplastics (MPs) are widely present in a variety of environmental media and have attracted more and more attention worldwide. However, the effect of MPs on the the interaction between heavy metals and soil, especially in soil fraction level, is not well understood. In this study, batch experiments were performed to investigate the adsorption characteristics of Cd in bulk soil and three soil fractions (i.e. particulate organic matter (POM), organic-mineral compounds (OMC), and mineral) with or without polypropylene (PP) MPs. The results showed that the addition of PP-MPs reduced the Cd adsorption capacity of the bulk soil in aqueous solution, and the effects varied with PP-MPs dose and aging degree. Whereas, the responses of the three fractions to PP-MPs were different. In presence of PP-MPs, the POM and OMC fractions showed negative adsorption effects, while the mineral fraction showed positive adsorption. For the bulk soil, POM and OMC fractions, the adsorption isotherm fitted to the Langmuir model better than the Freundlich model, whereas, the Freundlich isotherm model is more fitted for the mineral fraction. Combined with the comprehensive analysis of the partitioning coefficients, XRD and FTIR results, it was found that OMC fraction extremely likely play a leading role in the bulk soil adsorption of Cd in this study. Overall, the effect of MPs on adsorption capacity of the bulk soil for Cd may be determined by the proportion of POM, OMC, and mineral fractions in the soil, but further confirmation is needed.

Graphical abstract

Keywords

Polypropylene microplastics / Cadmium / Adsorption / POM / OMC / Mineral

Cite this article

Download citation ▾
Xianying Ma, Xinhui Zhou, Mengjie Zhao, Wenzhuo Deng, Yanxiao Cao, Junfeng Wu, Jingcheng Zhou. Polypropylene microplastics alter the cadmium adsorption capacity on different soil solid fractions. Front. Environ. Sci. Eng., 2022, 16(1): 3 DOI:10.1007/s11783-021-1437-z

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]

Altunay N, Hazer B, Tuzen M, Elik A (2021). A new analytical approach for preconcentration, separation and determination of Pb(II) and Cd(II) in real samples using a new adsorbent: Synthesis, characterization and application. Food Chemistry, 359: 129923
[2]

Awual M R, Hasan M M, Islam A, Rahman M M, Asiri A M, Khaleque M A, Sheikh M C (2019a). Introducing an amine functionalized novel conjugate material for toxic nitrite detection and adsorption from wastewater. Journal of Cleaner Production, 228: 778–785
[3]

Awual M R, Hasan M M, Islam A, Rahman M M, Asiri A M, Khaleque M A, Sheikh M C (2019b). Offering an innovative composited material for effective lead(II) monitoring and removal from polluted water. Journal of Cleaner Production, 231: 214–223
[4]

Balabane M, van Oort F (2002). Metal enrichment of particulate organic matter in arable soils with low metal contamination. Soil Biology and Biochemistry, 34(10): 1513–1516
[5]

Besnard E, Chenu C, Balesdent J, Puget P, Arrouays D (1996). Fate of particulate organic matter in soil aggregates during cultivation. European Journal of Soil Science, 47(4): 495–503
[6]

Bolan N, Kunhikrishnan A, Thangarajan R, Kumpiene J, Park J, Makino T, Kirkham M B, Scheckel K (2014). Remediation of heavy metal(loid)s contaminated soils--to mobilize or to immobilize? Journal of Hazardous Materials, 266: 141–166
[7]

Boots B, Russell C W, Green D S (2019). Effects of microplastics in soil ecosystems: Above and below ground. Environmental Science & Technology, 53(19): 11496–11506
[8]

Bradl H B (2004). Adsorption of heavy metal ions on soils and soils constituents. Journal of Colloid and Interface Science, 277(1): 1–18
[9]

Brennecke D, Duarte B, Paiva F, Caçador I, Canning-Clode J (2016). Microplastics as vector for heavy metal contamination from the marine environment. Estuarine, Coastal and Shelf Science, 178: 189–195
[10]

Cabrera C, Ortega E, Lorenzo M L, López M C (1998). Cadmium contamination of vegetable crops, farmlands, and irrigation waters. Reviews of Environmental Contamination and Toxicology, 154: 55–81
[11]

Chen X, Xu M, Yuan L M, Huang G Z, Chen X J, Shi W (2021). Degradation degree analysis of environmental microplastics by micro FT-IR imaging technology. Chemosphere, 274(1): 1297
[12]

de Souza Machado A A, Lau C W, Till J, Kloas W, Lehmann A, Becker R, Rillig M C (2018). Impacts of microplastics on the soil biophysical environment. Environmental Science & Technology, 52(17): 9656–9665
[13]

de Souza Machado A A, Lau C W, Kloas W, Bergmann J, Bachelier J B, Faltin E, Becker R, Görlich A S, Rillig M C (2019). Microplastics can change soil properties and affect plant performance. Environmental Science & Technology, 53(10): 6044–6052
[14]

Deng J, Guo P, Zhang X, Su H, Zhang Y, Wu Y, Li Y (2020). Microplastics and accumulated heavy metals in restored mangrove wetland surface sediments at Jinjiang Estuary (Fujian, China). Marine Pollution Bulletin, 159: 111482
[15]

Dobaradaran S, Schmidt T C, Nabipour I, Khajeahmadi N, Tajbakhsh S, Saeedi R, Javad Mohammadi M, Keshtkar M, Khorsand M, Faraji Ghasemi F (2018). Characterization of plastic debris and association of metals with microplastics in coastline sediment along the Persian Gulf. Waste Management (New York, N.Y.), 78: 649–658
[16]

Fu D D, Zhang Q J, Fan Z Q, Qi H Y, Wang Z Z, Peng L C (2019). Adsorption characteristics of copper ions on polystyrene microplastics. Environmental Science, 39(11): 4769–4775 (in Chinese)
[17]

Gewert B, Plassmann M M, MacLeod M (2015). Pathways for degradation of plastic polymers floating in the marine environment. Environmental Science. Processes & Impacts, 17(9): 1513–1521
[18]

Geyer R, Jambeck J R, Law K L (2017). Production, use, and fate of all plastics ever made. Science Advances, 3(7): e1700782
[19]

Guo X, Wang J (2021). Projecting the sorption capacity of heavy metal ions onto microplastics in global aquatic environments using artificial neural networks. Journal of Hazardous Materials, 402(1): 123709
[20]

Guo X, Zhang S, Shan X Q, Luo L E, Pei Z, Zhu Y G, Liu T, Xie Y N, Gault A (2006). Characterization of Pb, Cu, and Cd adsorption on particulate organic matter in soil. Environmental Toxicology and Chemistry, 25(9): 2366–2373
[21]

Hartmann N B, Hüffer T, Thompson R C, Hassellöv M, Verschoor A, Daugaard A E, Rist S, Karlsson T, Brennholt N, Cole M, Herrling M P, Hess M C, Ivleva N P, Lusher A L, Wagner M (2019). Are we speaking the same language? recommendations for a definition and categorization framework for plastic debris. Environmental Science & Technology, 53(3): 1039–1047
[22]

Hodson M E, Duffus-Hodson C A, Clark A, Prendergast-Miller M T, Thorpe K L (2017). Plastic bag derived-microplastics as a vector for metal exposure in terrestrial invertebrates. Environmental Science & Technology, 51(8): 4714–4721
[23]

Holmes L A, Turner A, Thompson R C (2012). Adsorption of trace metals to plastic resin pellets in the marine environment. Environmental Pollution, 160(1): 42–48
[24]

Holmes L A, Turner A, Thompson R C (2014). Interactions between trace metals and plastic production pellets under estuarine conditions. Marine Chemistry, 167: 25–32
[25]

Huang W, Song B, Liang J, Niu Q, Zeng G, Shen M, Deng J, Luo Y, Wen X, Zhang Y (2021). Microplastics and associated contaminants in the aquatic environment: A review on their ecotoxicological effects, trophic transfer, and potential impacts to human health. Journal of Hazardous Materials, 405: 124187
[26]

Huerta Lwanga E, Mendoza Vega J, Ku Quej V, Chi J L A, Sanchez Del Cid L, Chi C, Escalona Segura G, Gertsen H, Salánki T, van der Ploeg M, Koelmans A A, Geissen V (2017). Field evidence for transfer of plastic debris along a terrestrial food chain. Scientific Reports, 7(1): 14071
[27]

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
[28]

Kabir A H M E, Sekine M, Imai T, Yamamoto K, Kanno A, Higuchi T (2021). Assessing small-scale freshwater microplastics pollution, land-use, source-to-sink conduits, and pollution risks: Perspectives from Japanese rivers polluted with microplastics. Science of the Total Environment, 768(10): 144655
[29]

Khalid N, Aqeel M, Noman A (2020). Microplastics could be a threat to plants in terrestrial systems directly or indirectly. Environmental Pollution, 267: 115653
[30]

Komy Z R, Shaker A M, Heggy S E M, El-Sayed M E (2014). Kinetic study for copper adsorption onto soil minerals in the absence and presence of humic acid. Chemosphere, 99: 117–124
[31]

Labanowski J, Sebastia J, Foy E, Jongmans T, Lamy I, van Oort F (2007). Fate of metal-associated POM in a soil under arable land use contaminated by metallurgical fallout in northern France. Environmental Pollution, 149(1): 59–69
[32]

Lair G J, Gerzabek M H, Haberhauer G (2007). Retention of copper, cadmium and zinc in soil and its textual fractions influenced by long-term field management. European Journal of Soil Science, 58(5): 1145–1154
[33]

Li G X, Cao S K, Zheng S J, Wang W J, Cao Y X, Wang J W (2015). Crystallization, melting behavior, and crystal structure of reactive, intumescent, flame-retardant polypropylene. Journal of Applied Polymer Science, 132(5): 41374
[34]

Li M, Liu Y, Xu G, Wang Y, Yu Y (2021). Impacts of polyethylene microplastics on bioavailability and toxicity of metals in soil. Science of the Total Environment, 760: 144037
[35]

Li X, Mei Q, Chen L, Zhang H, Dong B, Dai X, He C, Zhou J (2019). Enhancement in adsorption potential of microplastics in sewage sludge for metal pollutants after the wastewater treatment process. Water Research, 157: 228–237
[36]

Liu M, Lu S, Song Y, Lei L, Hu J, Lv W, Zhou W, Cao C, Shi H, Yang X, He D (2018). Microplastic and mesoplastic pollution in farmland soils in suburbs of Shanghai, China. Environmental Pollution, 242(Pt A): 855–862
[37]

Luo Y, Wu Y, Shu J, Wu Z (2019). Effect of particulate organic matter fractions on the distribution of heavy metals with aided phytostabilization at a zinc smelting waste slag site. Environmental Pollution, 253: 330–341
[38]

Mao R F, Lang M F, Yu X Q, Wu R R, Yang X M, Guo X T (2020). Aging mechanism of microplastics with UV irradiation and its effects on the adsorption of heavy metals. Journal of Hazardous Materials, 393: 122515
[39]

Mbachu O, Jenkins G, Kaparaju P, Pratt C (2021). The rise of artificial soil carbon inputs: Reviewing microplastic pollution effects in the soil environment. Science of the Total Environment, 780: 146569
[40]

Park J H, Lamb D, Paneerselvam P, Choppala G, Bolan N, Chung J W (2011). Role of organic amendments on enhanced bioremediation of heavy metal(loid) contaminated soils. Journal of Hazardous Materials, 185(2–3): 549–574
[41]

Qi Y, Ossowicki A, Yang X, Huerta Lwanga E, Dini-Andreote F, Geissen V, Garbeva P (2020). Effects of plastic mulch film residues on wheat rhizosphere and soil properties. Journal of Hazardous Materials, 387: 121711
[42]

Qu C, Chen W, Hu X, Cai P, Chen C, Yu X Y, Huang Q (2019). Heavy metal behaviour at mineral-organo interfaces: Mechanisms, modelling and influence factors. Environment International, 131(6): 104995
[43]

Quan G, Fan Q, Sun J, Cui L, Wang H, Gao B, Yan J (2020). Characteristics of organo-mineral complexes in contaminated soils with long-term biochar application. Journal of Hazardous Materials, 384: 121265
[44]

Rillig M C (2018). Microplastic disguising as soil carbon storage. Environmental Science & Technology, 52(11): 6079–6080
[45]

Rios L M, Moore C, Jones P R (2007). Persistent organic pollutants carried by synthetic polymers in the ocean environment. Marine Pollution Bulletin, 54(8): 1230–1237
[46]

Samiey B, Cheng C H, Wu J (2014). Organic-inorganic hybrid polymers as adsorbents for removal of heavy metal ions from solutions: A review. Materials (Basel), 7(2): 673–726
[47]

Sari A, Tuzen M (2014). Cd(II) adsorption from aqueous solution by raw and modified kaolinite. Applied Clay Science, 88–89: 63–72
[48]

Scudo A, Liebmann B, Corden C, Tyrer D, Kreissig J, Warwick O (2017). Intentionally added microplastics in products- Final report of the study on behalf of the European Commission. Available online at the website of accessed April 26, 2021)
[49]

Sebastia J,van Oort F, Lamy I (2008). Buffer capacity and Cu affinity of soil particulate organic matter (POM) size fractions. European Journal of Soil Science, 59(2): 304–314
[50]

Shang E P, Xu E Q, Zhang H Q, Huang C H (2018). Spatial-temporal trends and pollution source analysis for heavy metal contamination of cultivated soils in five major grain producing regions of China. Environmental Science, 39(10): 4670–4683 (in Chinese)
[51]

Shi J, Wu Q, Zheng C, Yang J (2018). The interaction between particulate organic matter and copper, zinc in paddy soil. Environmental Pollution, 243(Pt B): 1394–1402
[52]

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
[53]

Tian Y, Yang J J, Hussain S (2021). Molecular mechanism of Cu(II) adsorption by organo-mineral complexes of red soil. Acta Pedologica Sinica, 58(3): 722–731 (in Chinese)
[54]

Wan Y, Wu C, Xue Q, Hui X (2019). Effects of plastic contamination on water evaporation and desiccation cracking in soil. Science of the Total Environment, 654: 576–582
[55]

Wang F, Yang W, Cheng P, Zhang S, Zhang S, Jiao W, Sun Y (2019). Adsorption characteristics of cadmium onto microplastics from aqueous solutions. Chemosphere, 235: 1073–1080
[56]

Wang J, Peng J, Tan Z, Gao Y, Zhan Z, Chen Q, Cai L (2017). Microplastics in the surface sediments from the Beijiang River littoral zone: Composition, abundance, surface textures and interaction with heavy metals. Chemosphere, 171: 248–258
[57]

Wen Y, Liu W, Deng W, He X, Yu G (2019). Impact of agricultural fertilization practices on organo-mineral associations in four long-term field experiments: Implications for soil C sequestration. Science of the Total Environment, 651(Pt 1): 591–600
[58]

Wu Y H, Zhou D M, Gao J, Si Y B (2015). Adsorption of three phthalic Acid esters on different clay minerals. Journal of Agro-Environment Science, 34(06): 1107–1114 (in Chinese)
[59]

Yan X, Yang X, Tang Z, Fu J, Chen F, Zhao Y, Ruan L, Yang Y (2020). Downward transport of naturally-aged light microplastics in natural loamy sand and the implication to the dissemination of antibiotic resistance genes. Environmental Pollution, 262: 114270
[60]

Yang J, Wang J Y, Qiao P W, Zheng Y M, Yang J X, Chen T B, Lei M, Wan X M, Zhou X Y (2020). Identifying factors that influence soil heavy metals by using categorical regression analysis: A case study in Beijing, China. Frontiers of Environmental Science & Engineering, 14(3): 37
[61]

Yang L, Zhang Y, Kang S, Wang Z, Wu C (2021). Microplastics in soil: A review on methods, occurrence, sources, and potential risk. Science of the Total Environment, 780(1): 146546
[62]

Yang X, Bento C P M, Chen H, Zhang H, Xue S, Lwanga E H, Zomer P, Ritsema C J, Geissen V (2018). Influence of microplastic addition on glyphosate decay and soil microbial activities in Chinese loess soil. Environmental Pollution, 242(Pt A): 338–347
[63]

Yu H, Hou J, Dang Q, Cui D, Xi B, Tan W (2020). Decrease in bioavailability of soil heavy metals caused by the presence of microplastics varies across aggregate levels. Journal of Hazardous Materials, 395(2): 122690
[64]

Zhang G S, Liu Y F (2018). The distribution of microplastics in soil aggregate fractions in southwestern China. Science of the Total Environment, 642(15): 12–20
[65]

Zhang M K (2006). Distribution of organic carbon, nutrients and heavy metals in different size fractions in sandy soil. Acta Pedologica Sinica, 43(4): 584–591 (in Chinese)
[66]

Zhang M K, Ke Z X (2004). Copper and zinc enrichment in different size fractions of organic matter from polluted soils. Pedosphere, 14(1): 27–36
[67]

Zhang S, Han B, Sun Y, Wang F (2020). Microplastics influence the adsorption and desorption characteristics of Cd in an agricultural soil. Journal of Hazardous Materials, 388: 121775
[68]

Zhang Z Q, Zhang Y P, Zhu Z H (2000). Study on the characteristics of kinetic of cadmium retention on soils. Journal of Environmental Sciences, 20(3): 370–375 (in Chinese)
[69]

Zhou J, Wen Y, Marshall M R, Zhao J, Gui H, Yang Y D, Zeng Z H, Jones D L, Zang H D (2021). Microplastics as an emerging threat to plant and soil health in agroecosystems. Science of the Total Environment, 787: 147444
[70]

Zhou T, Wu L, Luo Y, Christie P (2018). Effects of organic matter fraction and compositional changes on distribution of cadmium and zinc in long-term polluted paddy soils. Environmental Pollution, 232: 514–522
[71]

Zhou Y, Liu X, Wang J (2019). Characterization of microplastics and the association of heavy metals with microplastics in suburban soil of central China. Science of the Total Environment, 694(7): 133798
[72]

Zhuang G T (2015). Current situation of national soil pollution and strategies on prevention and control. Bulletin of the Chinese Academy of Sciences, 30(04): 477–483 (in Chinese)

RIGHTS & PERMISSIONS

Higher Education Press

AI Summary AI Mindmap
PDF (1754KB)

5874

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/