Abstract
Purpose
Heavy metal fractionation varies according to land uses. To understand the behavior of heavy metals in wetland soils under long-term agricultural cultivation, we examined the distribution, source, and associated environmental risk of heavy metals in different types of wetland soils.
Materials and methods
Soils were collected in cultivated lands, artificial ditches, and riparian zones from a reclaimed wetland in the Sanjiang Plain, Northeast China. They were analyzed for total concentrations and chemical fractions of Pb, Cd, Cu, Zn, Cr, and Ni, as well as pH, soil organic matter, total phosphorus, and particle size distribution.
Results and discussion
Heavy metal concentrations were significantly lower in cultivated wetland than in ditch and riparian wetlands. Riparian wetland was found to exhibit the highest metal concentrations. When compared with other two wetland types, the cultivated wetland showed much higher partitioning levels of heavy metals in the acid-soluble fraction and lower partitioning levels in the oxidizable fraction. Although Cr, Cu, and Ni in ditch and riparian wetlands were identified as the metal pollutants of primary concern, they had a low or no risk of further dispersion to other environmental components. Weathering of parent materials was the main source of Cr and Cu, Pb, Cd, and Zn originated mainly from agricultural practices, and Ni emanated from a mixture of sources.
Conclusions
Long-term agricultural cultivation can lead to significant heavy metal loss in cultivated wetland but enrich heavy metal concentrations in ditch and riparian wetlands. Periodic ditch dredging is considered an effective measure for decreasing heavy metal input into the fluvial system and thereby reducing the dispersion to the regional water environment.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Acevedo-Figueroa D, Jimenez BD, Rodriguez-Sierra CJ (2006) Trace metals in sediments of two estuarine lagoons from Puerto Rico. Environ Pollut 141(2):336–342
Akkajit P, DeSutter T, Tongcumpou C (2013) Fractionation of Cd and Zn in Cd-contaminated soils amended by sugarcane waste products from an ethanol production plant. J Soils Sediments 13(6):1057–1068
Bai JH, Xiao R, Cui BS, Zhang KJ, Wang QG, Liu XH, Gao HF, Huang LB (2011) Assessment of heavy metal pollution in wetland soils from the young and old reclaimed regions in the Pearl River Estuary, South China. Environ Pollut 159(3):817–824
Bendor E, Banin A (1989) Determination of organic-matter content in arid-zone soils using a simple loss-on-ignition method. Commun Soil Sci Plan Anal 20(15–16):1675–1695
Chapman PM, Allard PJ, Vigers GA (1999) Development of sediment quality values for Hong Kong Special Administrative Region: a possible model for other jurisdictions. Mar Pollut Bull 38(3):161–169
Cheng SP (2003) Heavy metal pollution in China: origin, pattern and control. Environ Sci Pollut Res Int 10(3):192–198
Cheng ZQ, Lee L, Dayan S, Grinshtein M, Shaw R (2011) Speciation of heavy metals in garden soils: evidences from selective and sequential chemical leaching. J Soils Sediments 11(4):628–638
Du Laing G, Rinklebe J, Vandecasteele B, Meers E, Tack FMG (2009) Trace metal behaviour in estuarine and riverine floodplain soils and sediments: a review. Sci Total Environ 407(13):3972–3985
Ghrefat HA, Yusuf N, Jamarh A, Nazzal J (2012) Fractionation and risk assessment of heavy metals in soil samples collected along Zerqa River, Jordan. Environ Earth Sci 66(1):199–208
Giani L, Ahrens V, Duntze O, Irmer SK (2003) Geo-pedogenesis of salic fluvisols on the North Sea island of Spiekeroog. J Plant Nutr Soil Sci 166(3):370–378
IUSS, ISRIC, FAO (2006) World reference base for soil resources. World Soil Resources Reports No. 103. Food and Agriculture Organization of the United Nations (FAO), Rome
Jalali M, Khanlari ZV (2008) Effect of aging process on the fractionation of heavy metals in some calcareous soils of Iran. Geoderma 143(1–2):26–40
Keller C, Hammer D (2004) Metal availability and soil toxicity after repeated croppings of Thlaspi caerulescens in metal contaminated soils. Environ Pollut 131(2):243–254
Lambert R, Grant C, Sauve S (2007) Cadmium and zinc in soil solution extracts following the application of phosphate fertilizers. Sci Total Environ 378(3):293–305
Marchand L, Mench M, Jacob DL, Otte ML (2010) Metal and metalloid removal in constructed wetlands, with emphasis on the importance of plants and standardized measurements: a review. Environ Pollut 158(12):3447–3461
Mico C, Recatala L, Peris M, Sanchez J (2006) Assessing heavy metal sources in agricultural soils of an European Mediterranean area by multivariate analysis. Chemosphere 65(5):863–872
Mitsch WJ (1995) Restoration of our lakes and rivers with wetlands—an important application of ecological engineering. Water Sci Technol 31(8):167–177
Mohamed I, Ahamadou B, Li M, Gong CX, Cai P, Liang W, Huang QY (2010) Fractionation of copper and cadmium and their binding with soil organic matter in a contaminated soil amended with organic materials. J Soils Sediments 10(6):973–982
Montagne D, Cornu S, Bourennane H, Baize D, Ratie C, King D (2007) Effect of agricultural practices on trace-element distribution in soil. Commun Soil Sci Plan Anal 38(3–4):473–491
Nriagu JO, Pacyna JM (1988) Quantitative assessment of worldwide contamination of air, water and soils by trace-metals. Nature 333(6169):134–139
Ontario Ministry of the Environment (MOE) (1993) Guidelines for the protection and management of aquatic sediment quality in Ontario. Queen’s Printer for Ontario, Ontario
Ouyang W, Huang HB, Hao FH, Shan YS, Guo BB (2012) Evaluating spatial interaction of soil property with non-point source pollution at watershed scale: the phosphorus indicator in Northeast China. Sci Total Environ 432:412–421
Ouyang W, Xu YM, Hao FH, Wang XL, Chen SY, Lin CY (2013) Effect of long-term agricultural cultivation and land use conversion on soil nutrient contents in the Sanjiang Plain. Catena 104:243–250
Overesch M, Rinklebe J, Broll G, Neue HU (2007) Metals and arsenic in soils and corresponding vegetation at Central Elbe river floodplains (Germany). Environ Pollut 145(3):800–812
Pan XF, Yan BX, Muneoki Y (2011) Effects of land use and changes in cover on the transformation and transportation of iron: a case study of the Sanjiang Plain, Northeast China. Sci China Earth Sci 54(5):686–693
Pekey H, Karakas D, Ayberk S, Tolun L, Bakoglu M (2004) Ecological risk assessment using trace elements from surface sediments of Izmit Bay (Northeastern Marmara Sea) Turkey. Mar Pollut Bull 48(9–10):946–953
Perkins SM, Filippelli GM, Souch CJ (2000) Airborne trace metal contamination of wetland sediments at Indiana Dunes National Lakeshore. Water Air Soil Pollut 122(1–2):231–260
Qian J, Shana XQ, Wang ZJ, Tu Q (1996) Distribution and plant availability of heavy metals in different particle-size fractions of soil. Sci Total Environ 187(2):131–141
Quinton JN, Catt JA (2007) Enrichment of heavy metals in sediment resulting from erosion on agricultural fields. Environ Sci Technol 41(10):3495–3500
Rauret G, Lopez-Sanchez JF, Sahuquillo A, Barahona E, Lachica M, Ure AM, Davidson CM, Gomez A, Luck D, Bacon J, Yli-Halla M, Muntau H, Quevauviller P (2000) Application of a modified BCR sequential extraction (three-step) procedure for the determination of extractable trace metal contents in a sewage sludge amended soil reference material (CRM 483), complemented by a three-year stability study of acetic acid and EDTA extractable metal content. J Environ Monitor 2(3):228–233
Reicosky DC, Lindstrom MJ (1993) Fall tillage method-effect on short-term carbon dioxide flux from soil. Agron J 85(6):1237–1243
Rodriguez L, Ruiz E, Alonso-Azcarate J, Rincon J (2009) Heavy metal distribution and chemical speciation in tailings and soils around a Pb-Zn mine in Spain. J Environ Manag 90(2):1106–1116
Shan YS, Tysklind M, Hao FH, Ouyang W, Chen SY, Lin CY (2013) Identification of sources of heavy metals in agricultural soils using multivariate analysis and GIS. J Soils Sediments 13(4):720–729
Sheoran AS, Sheoran V (2006) Heavy metal removal mechanism of acid mine drainage in wetlands: a critical review. Miner Eng 19(2):105–116
Singh KP, Mohan D, Singh VK, Malik A (2005) Studies on distribution and fractionation of heavy metals in Gomti river sediments—a tributary of the Ganges, India. J Hydrol 312(1–4):14–27
State Environmental Protection Administration (SEPA) (1995) Chinese environmental quality standard for soils. State Environmental Protection Administration of China, Beijing (in Chinese)
Tang WZ, Shan BQ, Zhang H, Mao ZP (2010) Heavy metal sources and associated risk in response to agricultural intensification in the estuarine sediments of Chaohu Lake Valley, East China. J Hazard Mater 176:945–951
Wang LL, Song CC, Song YY, Guo YD, Wang XW, Sun XX (2010) Effects of reclamation of natural wetlands to a rice paddy on dissolved carbon dynamics in the Sanjiang Plain, Northeastern China. Ecol Eng 36(10):1417–1423
Yang XM, Zhang XP, Deng W, Fang HJ (2003) Black soil degradation by rainfall erosion in Jilin, China. Land Degrad Dev 14(4):409–420
Zhang GL (2010) Changes of soil labile organic carbon in different land uses in Sanjiang Plain, Heilongjiang Province. Chin Geogr Sci 20(2):139–143
Zhang HG, Cui BS, Zhang KJ (2012) Surficial and vertical distribution of heavy metals in different estuary wetlands in the Pearl River, South China. Clean Soil Air Water 40(10):1174–1184
Acknowledgments
This work was financially supported by the National Natural Science Foundation of China (Grant No. 41271463, 40930740), the Supporting Program of the “Twelfth Five-year Plan” for Science & Technology Research of China (2012BAD15B05), and the National Science Foundation for Innovative Research Group (No. 51121003).
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible editor: Jaco Vangronsveld
Rights and permissions
About this article
Cite this article
Jiao, W., Ouyang, W., Hao, F. et al. Long-term cultivation impact on the heavy metal behavior in a reclaimed wetland, Northeast China. J Soils Sediments 14, 567–576 (2014). https://doi.org/10.1007/s11368-013-0812-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11368-013-0812-1