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RESEARCH ARTICLE
Contents Vol 60(7)

Mercury concentration and solid phase speciation changes in the course of early diagenesis in marine coastal sediments (Southern Baltic Sea)

Jacek Beldowski A B and Janusz Pempkowiak A
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- Author Affiliations

A Department of Marine Chemistry and Biochemistry, Institute of Oceanology, Polish Academy of Sciences, ul. Powstańców Warszawy 55, 81-712 Sopot, Poland.

B Corresponding author. Email: hyron@iopan.gda.pl

Marine and Freshwater Research 60(7) 745-757 https://doi.org/10.1071/MF08060
Submitted: 29 February 2008  Accepted: 11 February 2009   Published: 28 July 2009

Abstract

On reaching the sea, mercury discharged into the environment is deposited on and buried in marine sediments. Diagenetic processes in sediments lead to changes in both mercury concentration and speciation; they may enhance mercury bioavailability and/or lead to mercury remobilisation. Total concentrations and speciation of mercury were measured in dated sediment samples from sites covering a range of different environmental conditions and mercury concentrations. In the course of ~200 year-long diagenetic processes, the dominant changes in mercury speciation have involved diffusion of labile mercury to the overlying water, transformation of organic-bound mercury to HgS under anoxic conditions or to insoluble humin-bound Hg under oxic conditions, and dismutation of HgS into soluble polysulfides under hyperanoxic conditions. Rate constants of labile-to-stable mercury species transformations and the return flux of mercury were calculated on the basis of sediment core geochronology obtained by the 210Pb method. Although the study was performed in a specific area, we believe that the observed processes are valid for other shallow, coastal seas and that the results enable mercury stability in sediments to be assessed in similar areas worldwide.

Additional keywords: budget, kinetics, labile, rate constants, remobilisation, species, stable, transformation processes.


Acknowledgement

The study was carried out as part of the statutory activities of the Institute of Oceanology, Sopot, grant No. II.2.04. Authors would like to express their gratitude to the guest editor and anonymous reviewers, for thorough comments which have greatly improved the quality of this manuscript.


References

Bełdowski, J. , and Pempkowiak, J. (2003). Horizontal and vertical variabilities of mercury concentration and speciation in sediments of the Gdansk Basin, Southern Baltic Sea. Chemosphere 52, 645–654.
Crossref | GoogleScholarGoogle Scholar | PubMed | Boudreau B. P. (1996). ‘Diagenetic Models and Their Implementation: Modelling Transport and Reactions in Aquatic Sediments.’ 1st edn. (Springer–Verlag: Heidelberg.)

Bowen H. J. M. (1966). ‘Trace Elements in Biochemistry.’ 1st edn. (Academic Press: London.)

Christiansen, C. , Edelvang, K. , Emeis, K. , Graf, G. , and Jahmlich, S. , et al. (2002). Material transport from the near shore to the basinal environment in the Southern Baltic Sea: I. Processes and mass estimates. Journal of Marine Systems 35, 133–150.
Crossref | GoogleScholarGoogle Scholar | Emelyanov E. (1995). ‘Baltic Sea: Geology, Geochemistry, Paleoceanography, Pollution.’ (P.P. Shirshov Institute of Oceanology RAS: Kaliningrad.)

Forstner U., and Wittmann G. (1981). ‘Metal Pollution in the Aquatic Environment.’ 1st edn. (Springer: Berlin.)

Gingele, F. X. , and Leipe, T. (1998). Distribution and enrichment of redox-sensitive metals in Baltic Sea sediments. Baltica 11, 5–16.
HELCOM (2004). The fourth Baltic Sea pollution load compilation (PLC-4). Baltic Sea Environment Proceedings 93, Helsinki.

Horvat, M. , Covelli, S. , Faganeli, J. , Logar, M. , and Mandic, V. , et al. (1999). Mercury in contaminated coastal environment; a case study: the Gulf of Trieste. The Science of the Total Environment 237–238, 43–56.
Crossref | GoogleScholarGoogle Scholar | Jackson T. A. (1998). Mercury in aquatic ecosystem. In ‘Metal Metabolism in Aquatic Environments’. (Eds J. Langston and M. J. Bebiano.) pp. 178–249. (Chapman & Hall: London.)

Jeglinski W., Kotulska B., and Kramarska R. (2007). ‘Mapa geologiczna dna Bałtyku – opracowanie komputerowe.’ (Polish Geological Survey, Digital Maps: Gdansk.)

Laurier, F. J. G. , Cossa, D. , Gonzalez, J. L. , Breviere, E. , and Sarazin, G. (2003). Mercury transformations and exchanges in a high turbidity estuary: the role of organic matter and amorphous oxyhydroxides. Geochimica et Cosmochimica Acta 67, 3329–3345.
Crossref | GoogleScholarGoogle Scholar | CAS | Leivuori M. (2002). Sediments reflect the state of the Baltic Sea. Finnish Institute of Marine Research, Publication 642, Helsinki.

Leśniak T. (2002). ‘Materiały pomocnicze do terenowych zajęć geologicznych w rejonie nadmorskim.’ (AGH Uczelniane wydawnictwa naukowo-dydaktyczne: Kraków.)

Pempkowiak, J. (1991). Enrichment factors of heavy metals in surface dated with 210Pb and 137Cs. Environment International 11, 137–145.
Pempkowiak J. (1994). Zmiany potencjału oksydacyjno – redukcyjnego, pH oraz stężenia węgla organicznego w osadach wewnętrznej Zatoki Puckiej, lipiec – październik 1988 rok. In ‘Zatoka Pucka. Możliwości Rewaloryzacji’. (Eds L. Kruk Dowgiałło and P. Ciszewski.) pp. 53–64. (Instytut Ochrony Środowiska: Warsaw.)

Pempkowiak, J. , Cossa, D. , Sikora, A. , and Sanjuan, J. (1998). Mercury in water and sediments of the southern Baltic Sea. The Science of the Total Environment 213, 185–192.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | Robbins J. A. (1978). Geochemical and geophysical application of radioactive lead. In ‘The Biogeochemistry of Lead in the Environment’. (Ed. J. O. Nriagu.) pp. 285–393. (Elsevier: Amsterdam.)

Sarmiento J., and Gruber N. (2006). Diagenesis. In ‘Ocean Biogeochemical Dynamics’. pp. 227–260. (Princeton University Press: Princeton, NJ.)

Vallius, H. , and Kunzendorf, H. (2001). Sediment surface geochemistry of three Baltic Sea deep basins. Ambio 30, 135–141.
CAS | PubMed |

Wallschlager, D. , Desai, M. V. M. , and Wilken, R.-D. (1996). The role of humic substances in the aqueous mobilisation of mercury from contaminated floodplain soils and sediments along a contaminated river transect. Water, Air, and Soil Pollution 90, 507–520.
Crossref | GoogleScholarGoogle Scholar |

Wallschlager, D. , Desai, M. V. M. , Spengler, M. , and Wilken, R.-D. (1998a). Mercury speciation in floodplain soils and sediments along a contaminated river transect. Journal of Environmental Quality 27, 1034–1044.
CAS |

Wallschlager, D. , Desai, M. V. M. , Spengler, M. , Windmäller, C. C. , and Wilken, R. D. (1998b). How humic substances dominate mercury geochemistry in contaminated floodplains and sediments. Journal of Environmental Quality 27, 1044–1054.
CAS |