Long-term scenarios of mercury budgeting and exports for a Mediterranean hot spot (Marano-Grado Lagoon, Adriatic Sea)

Canu, Donata Melaku; Rosati, Ginevra

doi:10.1016/j.ecss.2016.12.005

Cited by 12 publications

(17 citation statements)

References 43 publications

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“…The WASP7 Hg model/MERC7 submodel (Wool et al, 2001) is a dynamic process-based model designed to simulate the Hg cycle within a system of well-mixed discrete spatial units (layers) of water and sediment as well as the exchanges of the system with its boundaries. This model has been already adapted and successfully applied to a shallow environment in a 2D configuration (Canu & Rosati, 2017;Melaku Canu et al, 2015), and is here used in a 1D configuration to explore Hg dynamics along an extended redox gradient. Figure 3 shows the conceptual model of the processes that affect the evolution of the state variables (Table S2).…”

Section: Model Structurementioning

confidence: 99%

“…Global Biogeochemical Cycles 10.1002/2017GB005700 WASP7 Hg model /MERC7 sub-model (Wool et al, 2001) and already succefully applied in shallow waters (Canu & Rosati 2017;Melaku Canu et al, 2015). One-dimensional (1-D) modeling has widely been used to investigate the biogeochemical and ecological features of the basin (Grégoire & Soetaert, 2010;Konovalov et al, 2004;Lamborg et al, 2008;Oguz et al, 2000;Yakushev et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Mercury in the Black Sea: New Insights From Measurements and Numerical Modeling

Rosati

Heimbürger

Canu

et al. 2018

Global Biogeochemical Cycles

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Redox conditions and organic matter control marine methylmercury (MeHg) production. The Black Sea is the world's largest and deepest anoxic basin and is thus ideal to study Hg species along the extended redox gradient. Here we present new dissolved Hg and MeHg data from the 2013 GEOTRACES MEDBlack cruise (GN04_leg2) that we integrated into a numerical 1‐D model, to track the fate and dynamics of Hg and MeHg. Contrary to a previous study, our new data show highest MeHg concentrations in the permanently anoxic waters. Observed MeHg/Hg percentage (range 9–57%) in the anoxic waters is comparable to other subsurface maxima in oxic open‐ocean waters. With the modeling we tested for various Hg methylation and demethylation scenarios along the redox gradient. The results show that Hg methylation must occur in the anoxic waters. The model was then used to simulate the time evolution (1850–2050) of Hg species in the Black Sea. Our findings quantify (1) inputs and outputs of Hg T (~31 and ~28 kmol yr −1 ) and MeHg T (~5 and ~4 kmol yr −1 ) to the basin, (2) the extent of net demethylation occurring in oxic (~1 kmol yr −1 ) and suboxic water (~6 kmol yr −1 ), (3) and the net Hg methylation in the anoxic waters of the Black Sea (~11 kmol yr −1 ). The model was also used to estimate the amount of anthropogenic Hg (85–93%) in the Black Sea.

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Section: Model Structurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mercury in the Black Sea: New Insights From Measurements and Numerical Modeling

Rosati

Heimbürger

Canu

et al. 2018

Global Biogeochemical Cycles

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“…In addition, the contribution of organic matter and nutrient deposition to estuarine sediment via urban run-off during the monsoon season, resulted in a two-fold and five-fold increase in methanogenesis and denitrification respectively, increasing the production of the greenhouse gases nitrous oxide (N2O) and methane (CH4). Canu and Rosati (2016) modelled the long-term (100 yrs) dynamics of the mercury cycle in the Marano-Grado Lagoon (a Mediterranean mercury hotspot), and showed that a sea level rise (of 0.315 m) and temperature rise (+2.5°C) may increase sediment methylmercury (MeHg) by up to 87% and 95% of current levels. Mercury bioaccumulation in biota was projected to increase accordingly.…”

Section: Pollution and Contaminationmentioning

confidence: 99%

Unbounded boundaries and shifting baselines: Estuaries and coastal seas in a rapidly changing world

Little

Spencer

Schuttelaars

et al. 2017

Estuarine, Coastal and Shelf Science

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This Special Issue of Estuarine, Coastal and Shelf Science presents contributions from ECSA 55; an international symposium organised by the Estuarine and Coastal Sciences Association (ECSA) and Elsevier on the broad theme of estuaries and coastal seas in times of intense change. The objectives of the SI are to synthesise, hypothesise and illustrate the impacts of global change on estuaries and coastal seas through learning lessons from the past, discussing the current and forecasting for the of combining cross-disciplinary palaeo, contemporary and future modelling studies and; (4) the importance of shifting baselines on ecosystem functioning and the future provision of ecosystem services.

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“…The investigation of the biogeochemical dynamics of Hg species in the marine environment addresses the need to accurately model sources and pathways of this priority contaminant within and among the different abiotic and biotic compartments of the aquatic ecosystem (Driscoll et al, 2013;Batrakova et al, 2014). Over the last few years some theo-retical studies have offered innovative tools to reproduce the mass balance and the dynamics of [Hg] in the marine environment by means of biogeochemical models based on interconnected zero-dimensional boxes representing water or sediment compartments: among these are the River MERLIN-Expo model (Ciffroy, 2015) and the WASP (Water Analysis Simulation Program) model (Melaku Canu et al, 2015;Canu and Rosati, 2017;Rosati et al, 2018). In particular, the River MERLIN-Expo model (Ciffroy, 2015) has been used to reproduce the spatiotemporal distribution of inorganic and organic contaminants in the 1D domain of rivers and to calculate the mass balance for each of them.…”

Section: Introductionmentioning

confidence: 99%

“…Over the last few years some theo-retical studies have offered innovative tools to reproduce the mass balance and the dynamics of [Hg] in the marine environment by means of biogeochemical models based on interconnected zero-dimensional boxes representing water or sediment compartments: among these are the River MERLIN-Expo model (Ciffroy, 2015) and the WASP (Water Analysis Simulation Program) model (Melaku Canu et al, 2015;Canu and Rosati, 2017;Rosati et al, 2018). In particular, the River MERLIN-Expo model (Ciffroy, 2015) has been used to reproduce the spatiotemporal distribution of inorganic and organic contaminants in the 1D domain of rivers and to calculate the mass balance for each of them. Although the model is able to describe many of the physical and chemical processes involved in fresh water and sediment, it specifically targets environments characterized by (i) nearly homogeneous water bodies and (ii) limited variations in landscape geometry.…”

Section: Introductionmentioning

confidence: 99%

HR3DHG version 1: modeling the spatiotemporal dynamics of mercury in the Augusta Bay (southern Italy)

et al. 2020

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Abstract. The biogeochemical dynamics of Hg, and specifically of its three species Hg0, HgII, and MeHg (elemental, inorganic, and organic, respectively), in the marine coastal area of Augusta Bay (southern Italy) have been explored by the high-resolution 3D Hg (HR3DHG) model, namely an advection–diffusion–reaction model for dissolved mercury in the seawater compartment coupled with a diffusion–reaction model for dissolved mercury in the pore water of sediments in which the desorption process for the sediment total mercury is taken into account. The spatiotemporal variability of the mercury concentration in both seawater ([HgD]) and the first layers of bottom sediments ([HgDsed] and [HgTsed]), as well as the Hg fluxes at the boundaries of the 3D model domain, have been theoretically reproduced, showing acceptable agreement with the experimental data collected in multiple field observations during six different oceanographic cruises. Also, the spatiotemporal dynamics of the total mercury concentration in seawater have been obtained by using both model results and field observations. The mass balance of the total Hg species in seawater has been calculated for the Augusta Harbour, improving previous estimations. The HR3DHG model could be used as an effective tool to predict the spatiotemporal distributions of dissolved and total mercury concentrations, while contributing to better assessing hazards for the environment and therefore for human health in highly polluted areas.

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Long-term scenarios of mercury budgeting and exports for a Mediterranean hot spot (Marano-Grado Lagoon, Adriatic Sea)

Cited by 12 publications

References 43 publications

Mercury in the Black Sea: New Insights From Measurements and Numerical Modeling

Mercury in the Black Sea: New Insights From Measurements and Numerical Modeling

Unbounded boundaries and shifting baselines: Estuaries and coastal seas in a rapidly changing world

HR3DHG version 1: modeling the spatiotemporal dynamics of mercury in the Augusta Bay (southern Italy)

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