Abstract
Purpose
High water-level fluctuations (WLFs) usually lead to the periodic drying and rewetting of littoral sediment, proven to influence the transformation of various sediment contaminants. However, details regarding metal bioavailability variations remain unclear. In this study, oxidation–reduction status transition, metal fraction transformation, and the development of the acid volatile sulfide (AVS) and the simultaneously extracted metals (SEM) were investigated to assess the variations of metal bioavailability in the littoral anoxic sediment during the drying–rewetting process.
Methods
A series of sediment cores were collected from the littoral area near the mouth of Nanfei River in Lake Chaohu, China, with half of them exposed to dark conditions with an overlying water cover (the control treatment). The other half was dried through the removal of overlying water and then exposed to air and sunlight (the drying treatment). Every 5 days, three of the dried sediment cores were rewetted for 3 days with lake water collected in situ. Various characteristics were analyzed for both the control and drying sediment cores. The drying and rewetting experiment was carried out for 30 days, and the bioavailability of metals was then evaluated thoroughly through data analyses.
Results and discussion
The periodic drying and rewetting process led to the oxidation of the anoxic sediment with a pronounced increase in oxygen penetration depth and redox potential, and a decrease in AVS concentrations in the drying treatment after 15 days of experimentation. Significant increases in the values of the ratio of SEM and AVS, the difference between SEM and AVS, and the organic carbon normalized difference between ΣSEM and AVS were retrieved for the drying treatment after process completion. The increase of metal bioavailability to aquatic organisms was consequently predicted, with the most significant concerns noted regarding Cd and Pb due to their transformation to less firmly bound fractions.
Conclusions
The periodic drying and rewetting process could increase the bioavailability of metals in littoral anoxic sediment. Therefore, this process should be given more attention during future management of water level and remediation of littoral sediment in similar areas.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Atkinson CA, Jolley DF, Simpson SL (2007) Effect of overlying water pH, dissolved oxygen, salinity and sediment disturbances on metal release and sequestration from metal contaminated marine sediments. Chemosphere 69:1428–1437
Baldwin DS (1996) Effects of exposure to air and subsequent drying on the phosphate sorption characteristics of sediments from a eutrophic reservoir. Limnol Oceanogr 41:1725–1732
Baldwin DS, Mitchell A (2000) The effects of drying and re-flooding on the sediment and soil nutrient dynamics of lowland river–floodplain systems: a synthesis. Regul Rivers Res Manag 16:457–467
Baldwin DS, Mitchell A, Rees G (2000) The effects of in situ drying on sediment–phosphate interactions in sediments from an old wetland. Hydrobiologia 431:3–12
Birch H (1964) Mineralisation of plant nitrogen following alternate wet and dry conditions. Plant Soil 20:43–49
Burton GA, Nguyen LT, Janssen C, Baudo R, McWilliam R, Bossuyt B, Beltrami M, Green A (2005) Field validation of sediment zinc toxicity. Environ Toxicol Chem 24:541–553
Campana O, Blasco JN, Simpson SL (2013) Demonstrating the appropriateness of developing sediment quality guidelines based on sediment geochemical properties. Environ Sci Technol 47:7483–7489
Campanha MB, Moreira AB, Bisinoti MC (2012) Metal fluxes at the sediment–water interface in rivers in the Turvo/Grande drainage basin, São Paulo State, Brazil. J Soils Sediments 12:1508–1516
Chapman PM, Wang F, Janssen C, Persoone G, Allen HE (1998) Ecotoxicology of metals in aquatic sediments: binding and release, bioavailability, risk assessment, and remediation. Can J Fish Aquat Sci 55:2221–2243
Chinese-EPA (2002) Methods for the examination of water and wastewater 4th edition. China Environmental Science Press, Beijing, China
Clark MW, McConchie D, Lewis DW, Saenger P (1998) Redox stratification and heavy metal partitioning in Avicennia-dominated mangrove sediments: a geochemical model. Chem Geol 149:147–171
Clausen J, Johnson G (1990) Lake level influences on sediment and nutrient retention in a lakeside wetland. J Environ Qual 19:83–88
Cline JD (1969) Spectrophotometric determination of hydrogen sulfide in natural waters. Limnol Oceanogr 14:454–458
Das S, Liu C-C, Jean J-S, Lee C-C, Yang H-J (2016) Effects of microbially induced transformations and shift in bacterial community on arsenic mobility in arsenic-rich deep aquifer sediments. J Hazard Mater 310:11–19
De Jonge M, Teuchies J, Meire P, Blust R, Bervoets L (2012) The impact of increased oxygen conditions on metal-contaminated sediments part I: effects on redox status, sediment geochemistry and metal bioavailability. Water Res 46:2205–2214
Di Toro DM, Mahony JD, Hansen DJ, Scott KJ, Hicks MB, Mayr SM, Redmond MS (1990) Toxicity of cadmium in sediments: the role of acid volatile sulfide. Environ Toxicol Chem 9:487–1502
Equeenuddin SM, Tripathy S, Sahoo P, Panigrahi M (2013) Metal behavior in sediment associated with acid mine drainage stream: role of pH. J Geochem Explor 124:230–237
Farrah H, Pickering WF (1993) Factors influencing the potential mobility and bioavailability of metals in dried lake sediments. Cheml Speciation Bioavail: 81-96
Furey P, Nordin R, Mazumder A (2004) Water level drawdown affects physical and biogeochemical properties of littoral sediments of a reservoir and a natural lake. Lake Reserv Manage 20:280–295
Gilmour CC, Riedel GS, Riedel G, Kwon S, Landis R, Brown SS, Menzie CA, Ghosh U (2013) Activated carbon mitigates mercury and methylmercury bioavailability in contaminated sediments. Environ Sci Technol 47:13001–13010
Håkanson L (1980) An ecological risk index for aquatic pollution control. A sedimentological approach. Water Res 14:975–1001
Hsieh Y, Yang C (1989) Diffusion methods for the determination of reduced inorganic sulfur species in sediments. Limnol Oceanogr 34:1126–1130
Javed MB, Shotyk W (2018) Estimating bioaccessibility of trace elements in particles suspended in the Athabasca River using sequential extraction. Environ Pollut 240:466–474
Kashem M, Singh B (2001) Metal availability in contaminated soils: I. Effects of floodingand organic matter on changes in Eh, pH and solubility of Cd, Ni and Zn. Nutr Cycl Agroecosyst 61:247–255
Lécrivain N, Frossard V, Clément B (2019) Changes in mobility of trace metals at the sediment-water-biota interfaces following laboratory drying and reimmersion of a lacustrine sediment. Environ Sci Pollut Res
Lee B-G, Griscom SB, Lee J-S, Choi HJ, Koh C-H, Luoma SN, Fisher NS (2000) Influences of dietary uptake and reactive sulfides on metal bioavailability from aquatic sediments. Science 287:282–284
Leira M, Cantonati M (2008) Effects of water-level fluctuations on lakes: an annotated bibliography, Ecological effects of water-level fluctuations in lakes. Springer, pp. 171-184
Liu C, Fan C, Shen Q, Shao S, Zhang L, Zhou Q (2016) Effects of riverine suspended particulate matter on post-dredging metal re-contamination across the sediment–water interface. Chemosphere 144:2329–2335
Liu C, Zhang L, Fan C, Xu F, Chen K, Gu X (2017) Temporal occurrence and sources of persistent organic pollutants in suspended particulate matter from the most heavily polluted river mouth of Lake Chaohu, China. Chemosphere 174:39–45
Liu C, Gu X, Chen K, Fan C, Zhang L, Huang W (2018) Nitrogen and phosphorus exchanges across the sediment-water interface in a bay of Lake Chaohu. Water Environ Res 90:1956–1963
Liu C, Du Y, Chen K, Ma S, Chen B, Lan Y (2019a) Contrasting exchanges of nitrogen and phosphorus across the sediment–water interface during the drying and re-inundation of littoral eutrophic sediment. Environ Pollut 255:113356
Liu C, Shao S, Zhang L, Du Y, Chen K, Fan C, Yu Y (2019b) Sulfur development in the water-sediment system of the algae accumulation embay area in Lake Taihu. Water 11:1817
Long ER, MacDonald DD, Smith SL, Calder FD (1995) Incidence of adverse biological effects within ranges of chemical concentrations in marine and estuarine sediments. Environ Manag 19:81–97
Luoma SN (1983) Bioavailability of trace metals to aquatic organisms — a review. Sci Total Environ 28:1–22
Machado W, Villar LS, Monteiro FF, Viana LCA, Santelli RE (2010) Relation of acid-volatile sulfides (AVS) with metals in sediments from eutrophicated estuaries: is it limited by metal-to-AVS ratios? J Soils Sediments 10:1606–1610
Martins VV, Zanetti MOB, Pitondo-Silva A, Stehling EG (2014) Aquatic environments polluted with antibiotics and heavy metals: a human health hazard. Environ Sci Pollut Res 21:5873–5878
Mossop KF, Davidson CM (2003) Comparison of original and modified BCR sequential extraction procedures for the fractionation of copper, iron, lead, manganese and zinc in soils and sediments. Anal Chim Acta 478:111–118
Müller A (2002) Pyritization of iron and trace metals in anoxic fjord sediments (Nordåsvannet fjord, western Norway). Appl Geochem 17:923–933
Mulligan CN, Yong RN, Gibbs BF (2001) An evaluation of technologies for the heavy metal remediation of dredged sediments. J Hazard Mater 85:145–163
Orekhova NA, Konovalov SK (2018) Oxygen and sulfides in bottom sediments of the Coastal Sevastopol Region of Crimea. Oceanol 58:679–688
Penttinen O-P, Kilpi-Koski J, Jokela M, Toivainen K, Väisänen A (2008) Importance of dose metrics for lethal and sublethal sediment metal toxicity in the oligochaete worm Lumbriculus variegatus. J Soils Sediments 8:59–66
Qi C, Zhang L, Fang J, Lei B, Tang X, Huang H, Wang Z, Si Z, Wang G (2019) Benthic cyanobacterial detritus mats in lacustrine sediment: characterization and odorant producing potential. Environ Pollut:113453
Rabalais NN, Turner RE, Wiseman WJ Jr (2002) Gulf of Mexico hypoxia, AKA “the dead zone”. Annu Rev Ecol Syst 33:235–263
Remaili TM, Yin N, Bennett WW, Simpson SL, Jolley DF, Welsh DT (2018) Contrasting effects of bioturbation on metal toxicity of contaminated sediments results in misleading interpretation of the AVS–SEM metal-sulfide paradigm. Environ Sci Process Impacts 20:1285–1296
Saeedi M, Daneshvar S, Karbassi AR (2004) Role of riverine sediment and particulate matter in adsorption of heavy metals. Int J Environ Sci Technol 1:135–140
Saeki K, Okazaki M, Matsumoto S (1993) The chemical phase changes in heavy metals with drying and oxidation of the lake sediments. Water Res 27:1243–1251
Saup CM, Williams KH, Rodríguez-Freire L, Cerrato JM, Johnston MD, Wilkins MJ (2017) Anoxia stimulates microbially catalyzed metal release from Animas River sediments. Environ Sci Process Impacts 19:578–585
Shao S, Xue L, Liu C, Shang J, Wang Z, He X, Fan C (2016) Assessment of heavy metals in sediment in a heavily polluted urban river in the Chaohu Basin,China Chin J Oceanol Limnol 34:526–538
Steinman AD, Ogdahl ME, Weinert M, Thompson K, Cooper MJ, Uzarski DG (2012) Water level fluctuation and sediment–water nutrient exchange in Great Lakes coastal wetlands. J Great Lakes Res 38:766–775
Steinman AD, Ogdahl ME, Weinert M, Uzarski DG (2014) Influence of water-level fluctuation duration and magnitude on sediment–water nutrient exchange in coastal wetlands. Aquat Ecol 48:143–159
Stephens SR, Alloway BJ, Parker A, Carter JE, Hodson ME (2001) Changes in the leachability of metals from dredged canal sediments during drying and oxidation. Environ Pollut 114:407–413
Strom D, Simpson SL, Batley GE, Jolley DF (2011) The influence of sediment particle size and organic carbon on toxicity of copper to benthic invertebrates in oxic/suboxic surface sediments. Environ Toxicol Chem 30:1599–1610
Tack FM, Callewaert OWJJ, Verloo MG (1996) Metal solubility as a function of pH in a contaminated, dredged sediment affected by oxidation. Environ Pollut 91:199–208
Ure A, Quevauviller P, Muntau H, Griepink B (1993) Speciation of heavy metals in soils and sediments. An account of the improvement and harmonization of extraction techniques undertaken under the auspices of the BCR of the Commission of the European Communities. Int J Environ Anal Chem 51:135–151
USEPA (2004) The incidence and severity of sediment contamination in surface waters of the United States: National Sediment Quality Survey (second edition), EPA-823-R-04-007. Environmental Protection Agency, Office of Water, Washington, DC, USA
USEPA (2008) Methods for determination of inorganic analytes: inductively coupled plasma-mass spectrometry (method 6020A). In: USEPA (Hrsg.), Washington, DC, USA
Villalobos-Castañeda B, Alfaro-Cuevas R, Cortés-Martínez R, Martínez-Miranda V, Márquez-Benavides L (2010) Distribution and partitioning of iron, zinc, and arsenic in surface sediments in the Grande River mouth to Cuitzeo Lake, Mexico. Environ Monit Assess 166:331–346
Wang L, Yuan X, Zhong H, Wang H, Wu Z, Chen X, Zeng G (2014) Release behavior of heavy metals during treatment of dredged sediment by microwave-assisted hydrogen peroxide oxidation. Chem Eng J 258:334–340
Wegener J-WM, van den Berg GA, Stroomberg GJ, van Velzen MJM (2002) The role of sediment-feeding oligochaeteTubifex on the availability of trace metals in sediment pore waters as determined by diffusive gradients in thin films (DGT). J Soils Sediments 2:71–76
Wei F, Chen J, Wu Y (1990) Background value of soil elements in China. China Environmental Science Press, Beijing, China
Yin H, Deng J, Shao S, Gao F, Gao J, Fan C (2011a) Distribution characteristics and toxicity assessment of heavy metals in the sediments of Lake Chaohu, China. Environ Monit Assess 179:431–442
Yin HB, Gao YN, Fan CX (2011b) Distribution, sources and ecological risk assessment of heavy metals in surface sediments from Lake Taihu, China Environ Res Lett 6
Zhang X, Liu X, Wang H (2014) Developing water level regulation strategies for macrophytes restoration of a large river-disconnected lake, China. Ecol Eng 68:25–31
Zhang L, Liao Q, Shao S, Zhang N, Shen Q, Liu C (2015) Heavy metal pollution, fractionation, and potential ecological risks in sediments from Lake Chaohu (Eastern China) and the surrounding rivers. Int J Environ Res Public Health 12:14115–14131
Funding
This study was supported by the National Natural Science Foundation of China (No. 41703078, 41771122, and 41673123), the Natural Science Foundation of Jiangsu Province (No. BK20171101), and the State Major Project for Water Pollution Control and Management (2018ZX07208-004).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Research involving human participants and/or animals
None.
Additional information
Responsible editor: Shiming Ding
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
ESM 1
(PDF 674 kb)
Rights and permissions
About this article
Cite this article
Liu, C., Kong, M., Zhang, L. et al. Metal bioavailability during the periodic drying and rewetting process of littoral anoxic sediment. J Soils Sediments 20, 2949–2959 (2020). https://doi.org/10.1007/s11368-020-02634-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11368-020-02634-y