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Environmental Science and Pollution Research

, Volume 25, Issue 21, pp 21086–21096 | Cite as

Total and methyl-mercury seasonal particulate fluxes in the water column of a large lake (Lake Geneva, Switzerland)

  • Elena Gascón Díez
  • Neil D. Graham
  • Jean-Luc Loizeau
Research Article

Abstract

Concentrations and fluxes of total and methylmercury were determined in surface sediments and associated with settling particles at two sites in Lake Geneva to evaluate the sources and dynamics of this toxic contaminant. Total mercury concentrations measured in settling particles were different throughout the seasons and were greatly influenced by the Rhone River particulate inputs. Total mercury concentrations closer to shore (NG2) ranged between 0.073 ± 0.001 and 0.27 ± 0.01 μg/g, and between 0.038 ± 0.001 and 0.214 ± 0.008 μg/g at a site deeper in the lake (NG3). Total mercury fluxes ranged between 0.144 ± 0.002 and 3.0 ± 0.1 μg/m2/day at NG2, and between 0.102 ± 0.008 and 1.32 ± 0.08 μg/m2/day at NG3. Combined results of concentrations and fluxes showed that total mercury concentrations in settling particles are related to the season and particle inputs from the Rhone River. Despite an observed decrease in total mercury fluxes from the coastal zone towards the open lake, NG3 (~ 3 km from the shoreline) was still affected by the coastal boundary, as compared to distal sites at the center of the lake. Thus, sediment focusing is not efficient enough to redistribute contaminant inputs originating from the coastal zones, to the lake center. Methylmercury concentrations in settling particles largely exceeded the concentrations found in sediments, and their fluxes did not show significant differences with relation to the distance from shore. The methylmercury found associated with settling particles would be related to the lake’s internal production rather than the effect of transport from sediment resuspension.

Keywords

Mercury fluxes Mercury transport Settling particles Methylmercury Lake Geneva Freshwater pollution Sediment traps 

Notes

Acknowledgements

We would like to thank Philippe Arpagaus for his help during the sampling campaigns, in addition to “La Direction Générale de l’Environnement DGE–Inspection de la pêche” and “Canton de Vaud” for allowing us to deploy the sediment traps in Lake Geneva. The work was partially funded by SNF research grant PDFMP2-123034.

Supplementary material

11356_2018_2252_MOESM1_ESM.pdf (192 kb)
ESM 1 (PDF 192 kb)

References

  1. Baskaran M, Miller CJ, Kumar A, Andersen E, Hui J, Selegeanc JP, Creech CT, Barkach J (2015) Sediment accumulation rates and sediment dynamics using five different methods in a well-constrained impoundment: case study from union Lake, Michigan. J Great Lakes Res 41:607–617CrossRefGoogle Scholar
  2. Bengtsson G, Picado F (2008) Mercury sorption to sediments: dependence on grain size, dissolved organic carbon, and suspended bacteria. Chemosphere 73:526–531CrossRefGoogle Scholar
  3. Benoit JM, Gilmour CC, Mason RP, Riedel GS, Riedel GF (1998) Behavior of mercury in the Patuxent River estuary. Biogeochemistry 40:249–265CrossRefGoogle Scholar
  4. Blais JM, Kalff J (1995) The influence of lake morphometry on sediment focusing. Limnol Oceanogr 40:582–588CrossRefGoogle Scholar
  5. Bloesch J, Uehlinger U (1986) Horizontal sedimentation differences in a eutrophic Swiss Lake. Limnol Oceanogr 31:1094–1109CrossRefGoogle Scholar
  6. Bloom N (1989) Determination of Picogram levels of methylmercury by aqueous phase Ethylation, followed by cryogenic gas-chromatography with cold vapor atomic fluorescence detection. Can J Fish Aquat Sci 46:1131–1140CrossRefGoogle Scholar
  7. Bloom NS, Gill GA, Cappellino S, Dobbs C, Mcshea L, Driscoll C, Mason R, Rudd J (1999) Speciation and cycling of mercury in Lavaca Bay, Texas, sediments. Environ Sci Technol 33:7–13CrossRefGoogle Scholar
  8. Bravo AG, Bouchet S, Amouroux D, Poté J, Dominik J (2011) Distribution of mercury and organic matter in particle-size classes in sediments contaminated by a waste water treatment plant: Vidy Bay, Lake Geneva, Switzerland. J Environ Monit 13:974–982CrossRefGoogle Scholar
  9. Burnier G, Jaquerod CA, Poget E, Vioget P (2011) Bilans 2011 de l’épuration vaudoise. Rapport du service des eaux, sols et assaisnissement, Etat de Vaud, 27 ppGoogle Scholar
  10. Compeau G, Bartha R (1984) Methylation and demethylation of mercury under controlled redox, Ph, and salinity conditions. Appl Environ Microbiol 48:1203–1207Google Scholar
  11. Dean WE (1974) Determination of carbonate and organic matter in calcareous sediments and sedimentary rocks by loss on ignition; comparison with other methods. J Sediment Res 44:242–248Google Scholar
  12. Dominik J, Burrus D, Vernet J-P (1987) Transport of the environmental radionuclides in an alpine watershed. Earth Planet Sci Lett 84:165–180CrossRefGoogle Scholar
  13. Dominik J, Dulinski M, Span D, Hofmann A, Favarger P-Y, Vernet J-P (1993) Transfert de matière et de radio-isotopes entre l'eau et les sédiments dans le Léman. Rapp Comm int prot eaux Léman contre pollut Campagne 1992:163–188Google Scholar
  14. Drevnik PE, Shinneman ALC, Lamborg CH, Engstrom DR, Bother MH, Oris JT (2010) Mercury fluxes to sediments of Lake Tahoe, California-Nevada. Watet Air Soil Pollut 210:399–407CrossRefGoogle Scholar
  15. Ethier ALM, Atkinson JF, DePinto JV, Lean DRS (2012) Estimating mercury concentrations and fluxes in the water column and sediment of Lake Ontario with HERMES model. Environ Pollut 161:335–342CrossRefGoogle Scholar
  16. Evans RD (1994) Empirical-evidence of the importance of sediment resuspension in lakes. Hydrobiologia 284:5–12CrossRefGoogle Scholar
  17. Feyte S, Gobeil C, Tessier A, Cossa D (2012) Mercury dynamics in lake sediments. Geochim Cosmochim Acta 82:92–112CrossRefGoogle Scholar
  18. Fuchs A, Selmeczy GB, Kasprzak P, Padisák J, Casper P (2016) Coincidence of sedimentation peaks with diatom blooms, wind, and calcite precipitation measured in high resolution by a multi-trap. Hydrobiologia 763:329–344CrossRefGoogle Scholar
  19. Gagnon C, Pelletier E, Mucci A (1997) Behaviour of anthropogenic mercury in coastal marine sediments. Mar Chem 59:159–176CrossRefGoogle Scholar
  20. Gandais V (1989) Origines et variations spatio-temporelles des flux de matière particulaire au centre du Léman. Dissertation, University of GenevaGoogle Scholar
  21. Gascón Díez E, Bravo AG, Porta AN, Masson M, Graham ND, Stoll S, Akhtman Y, Amouroux D, Loizeau J-L (2013) Influence of a wastewater treatment plant on mercury contamination and sediment characteristics in Vidy Bay (Lake Geneva, Switzerland). Aquat Sci 76:S21–S32Google Scholar
  22. Gascón Díez E, Loizeau J-L, Cosio C, Bouchet S, Adatte T, Amouroux D, Bravo AG (2016) Role of settling particles on mercury methylation in the oxic water column of freshwater systems. Environ Sci Technol 50:11672–11679CrossRefGoogle Scholar
  23. Gascón Díez E, Corella JP, Adatte T, Thevenon F, Loizeau J-L (2017) High-resolution reconstruction of the 20th century history of trace metals, major elements, and organic matter in sediments in a contaminated area of Lake Geneva, Switzerland. Appl Geochem 78:1–11CrossRefGoogle Scholar
  24. Gilmour CC, Podar M, Bullock AL, Graham AM, Brown SD, Somenahally AC, Johs A, Hurt RA, Bailey KL, Elias DA (2013) Mercury methylation by novel microorganisms from new environments. Environ Sci Technol 47:11810–11820CrossRefGoogle Scholar
  25. Graham ND (2015) The fate of sediment-bound contaminants: a case study of Vidy Bay (Lake Geneva, Switzerland. Dissertation, University of GenevaGoogle Scholar
  26. Graham ND, Bouffard D, Loizeau J-L (2016) The influence of bottom boundary layer hydrodynamics on sediment focusing in a contaminated bay. Environ Sci Pollut Res 23:25412–25426CrossRefGoogle Scholar
  27. Håkanson L (1977) The influence of wind, fetch, and water depth on the distribution of sediments in Lake Vänern, Sweden. Can J Earth Sci 14:397–412CrossRefGoogle Scholar
  28. Håkanson L, Jansson M (1983) Principles of lake sedimentology. Springer-Verlag, BerlinCrossRefGoogle Scholar
  29. Heimburger LE, Cossa D, Marty JC, Migon C, Averty B, Dufour A, Ras J (2010) Methyl mercury distributions in relation to the presence of nano- and picophytoplankton in an oceanic water column (Ligurian Sea, North-Western Mediterranean). Geochim Cosmochim Acta 74:5549–5559CrossRefGoogle Scholar
  30. Hurley JP, Watras CJ, Bloom NS (1991) Mercury cycling in a northern Wisconsin seepage lake: the role of particulate matter in vertical transport. Water Air Soil Pollut 56:543–551CrossRefGoogle Scholar
  31. Kim EH, Mason RP, Porter ET, Soulen HL (2006) The impact of resuspension on sediment mercury dynamics, and methylmercury production and fate: a mesocosm study. Mar Chem 102:300–315CrossRefGoogle Scholar
  32. Kocman D, Wilson SJ, Amos HM, Telmer KH, Steenhuisen F, Sunderland EM, Mason RP, Outridge P, Horvat M (2017) Toward an assessment of the global inventory of present-day mercury releases to freshwater environments. Int J Environ Res Public Health 14:138CrossRefGoogle Scholar
  33. Korthals ET, Winfrey MR (1987) Seasonal and spatial variations in mercury methylation and demethylation in an oligotrophic Lake. Appl Environ Microbiol 53:2397–2404Google Scholar
  34. Liu B, Yan HY, Wang CP, Li QH, Guedron S, Spangenberg JE, Feng XB, Dominik J (2012) Insights into low fish mercury bioaccumulation in a mercury-contaminated reservoir, Guizhou, China. Environ Pollut 160:109–117CrossRefGoogle Scholar
  35. Loizeau J-L, Arbouille D, Santiago S, Vernet J-P (1994) Evaluation of a wide-range laser diffraction grain-size analyzer for use with sediments. Sedimentology 41:353–361CrossRefGoogle Scholar
  36. Loizeau J-L, Girardclos S, Dominik J (2012) Taux d'accumulation de sédiments récents et bilan de la matière particulaire dans le Léman (Suisse - France). Arch Sci 65:81–92Google Scholar
  37. Loizeau J-L, Makri S, Arpagaus P, Ferrari B, Casado-Martinez C, Benejam T, Marchand P (2017) Micropolluants métalliques et organiques dans les sédiments superficiels du Léman. Rapp Comm int prot eaux Léman contre pollut Campagne 2016:143–198Google Scholar
  38. Marvin C, Charlton M, Milne J, Thiessen L, Schachtschneider G, Sverko E (2007) Metals associated with suspended sediments in lakes Erie and Ontario, 2000-2002. Environ Monit Assess 130:149–161CrossRefGoogle Scholar
  39. Mason RP, Kim EH, Cornwell J, Heyes D (2006) An examination of the factors influencing the flux of mercury, methylmercury and other constituents from estuarine sediment. Mar Chem 102:96–110CrossRefGoogle Scholar
  40. Mason RP, Choi AL, Fitzgerald WF, Hammerschmidt CR, Lamborg CH, Soerensen AL, Sunderland EM (2012) Mercury biogeochemical cycling in the ocean and policy implications. Environ Res 119:101–117CrossRefGoogle Scholar
  41. OFEV (Editor) (2016) Annuaire hydrologique de la Suisse 2010. Office fédéral de l’environnement, Berne. Etat de l’environnement n° 1631: 627Google Scholar
  42. Pardos M, Benninghoff C, De Alencastro LF, Wildi W (2004) The impact of a sewage treatment plant’s effluent on sediment quality in a small bay in Lake Geneva (Switzerland–France). Part 1: spatial distribution of contaminants and the potential for biological impacts. Lakes Reserv Res Manag 9:41–52CrossRefGoogle Scholar
  43. Parks JM, Johs A, Podar M, Bridou R, Hurt RA, Smith SD, Tomanicek SJ, Qian Y, Brown SD, Brandt CC, Palumbo AV, Smith JC, Wall JD, Elias DA, Liang LY (2013) The genetic basis for bacterial mercury methylation. Science 339:1332–1335CrossRefGoogle Scholar
  44. Podar M, Gilmour CC, Brandt CC, Soren A, Brown SD, Crable BR, Palumbo AV, Somenahally AC, Elias DA (2015) Global prevalence and distribution of genes and microorganisms involved in mercury methylation. Sci Adv 1(9):e1500675CrossRefGoogle Scholar
  45. Poté J, Haller L, Loizeau J-L, Bravo AG, Sastre V, Wildi W (2008) Effects of a sewage treatment plant outlet pipe extension on the distribution of contaminants in the sediments of the bay of Vidy, Lake Geneva, Switzerland. Bioresour Technol 99:7122–7131CrossRefGoogle Scholar
  46. Razmi AM, Barry DA, Bakhtyar R, Le Dantec N, Dastgheib A, Lemin U, Wüest A (2013) Current variability in a wide and open lacustrine embayment in Lake Geneva (Switzerland). J Great Lakes Res 39:455–465CrossRefGoogle Scholar
  47. Rigaud S, Radakovitch O, Couture RM, Deflandre B, Cossa D, Garnier C, Garnier JM (2013) Mobility and fluxes of trace elements and nutrients at the sediment-water interface of a lagoon under contrasting water column oxygenation conditions. Appl Geochem 31:35–51CrossRefGoogle Scholar
  48. Rolfhus KR, Sakamoto HE, Cleckner LB, Stoor RW, Babiarz CL, Back RC, Manolopoulos H, Hurley JP (2003) Distribution and fluxes of total and methylmercury in Lake superior. Environ Sci Technol 37:865–872CrossRefGoogle Scholar
  49. Roos-Barraclough F, Shotyk W (2003) Millennial-scale records of atmospheric mercury deposition obtained from ombrotrophic and minerotrophic peatlands in the Swiss Jura Mountains. Environ Sci Technol 37:235–244CrossRefGoogle Scholar
  50. Roos-Barraclough F, Givelet N, Martinez-Cortizas A, Goodsite ME, Biester H, Shotyk W (2002) An analytical protocol for the determination of total mercury concentrations in solid peat samples. Sci Total Environ 292:129–139CrossRefGoogle Scholar
  51. Savoye L, Quetin P, Klein A (2015) Physico-chemical changes in the waters of Lake Geneva. Meteorological datas Contributions from the tributaries of Lake Geneva and from the Rhone below Geneva. Rapp Comm int prot eaux Léman contre pollut Campagne 2014:19–67Google Scholar
  52. Schartup AT, Ndu U, Balcom PH, Mason RP, Sunderland EM (2015) Contrasting effects of marine and terrestrially derived dissolved organic matter on mercury speciation and bioavailability in seawater. Environ Sci Technol 49:5965–5972CrossRefGoogle Scholar
  53. Taylor SE, Birch GF (2000) Contaminant dynamics in offchannel embayments of port Jackson, new South Wales. AGSO 5-6:233–237Google Scholar
  54. Thevenon F, Graham ND, Chiaradia M, Arpagaus P, Wildi W, Poté J (2011) Local to regional scale industrial heavy metal pollution recorded in sediments of large freshwater lakes in Central Europe (lakes Geneva and Lucerne) over the last centuries. Sci Total Environ 412:239–247CrossRefGoogle Scholar
  55. Van Metre PC (2011) Increased atmospheric deposition of mercury in reference lakes near major urban areas. Environ Pollut 162:209–215CrossRefGoogle Scholar
  56. Wang WX, Stupakoff I, Gagnon C, Fisher NS (1998) Bioavailability of inorganic and methylmercury to a marine deposit feeding polychaete. Environ Sci Technol 32:2564–2571CrossRefGoogle Scholar
  57. Wiklund JA, Kirk JL, Muir DCG, Evans M, Yang F, Keating J, Parsons MT (2017) Anthropogenic mercury deposition in Flin Flon Manitoba and the Experimental Lakes area Ontario (Canada): a multi-lake sediment core reconstruction. Sci Total Environ 586:685–695CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Department F.-A. Forel for Environmental and Aquatic Sciences, and Institute for Environmental SciencesUniversity of GenevaGeneva 4Switzerland
  2. 2.Soil and Water InfrastructureBiology Centre CASČeské BudějoviceCzech Republic

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