Assessing the spatial and temporal variability of methylmercury biogeochemistry and bioaccumulation in the Mediterranean Sea with a coupled 3D model

Rosati, Ginevra; Canu, Donata Melaku; Lazzari, Paolo; Solidoro, Cosimo

doi:10.5194/bg-19-3663-2022

Cited by 9 publications

(12 citation statements)

References 111 publications

(179 reference statements)

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“…In recent years, more comprehensive 3D ocean Hg models including MeHg chemistry have been developed. Currently, four marine Hg models based on numerical 3D hydrodynamic modeling are in active use Kawai et al, 2020;Rosati et al, 2022;Bieser et al, 2023 excluding models that are no longer actively being updated). Table F2 gives an overview of published 3D ocean Hg models.…”

Section: Ocean Modelsmentioning

confidence: 99%

“…Table F2 gives an overview of published 3D ocean Hg models. While all these models contain a complete marine Hg chemistry including MeHg, only , Rosati et al, (2022), and Bieser et al, (2023) consider uptake to and release from marine biota. This makes these three models the first hydrodynamic 3D Hg model to include the marine ecosystem.…”

Section: Ocean Modelsmentioning

confidence: 99%

“…There are few marine Hg model studies evaluating individual models against observations (Zhang et al, 2019c;Kawai et al, 2020;Rosati et al, 2022;Bieser et al, 2023), and so far, no ensemble studies have been performed. Here, we propose a framework for the first marine Hg model ensemble study.…”

Section: Ocean Modelsmentioning

confidence: 99%

“…Combined with projections of future anthropogenic Hg emission scenarios, Giang and Selin (2016) used Amos et al, (2013) and Schartup et al, (2022) used Soerensen et al, (2016a) to assess future changes in Hg levels. Threedimensional biogeochemical models including ecosystem interactions are increasingly applied to simulate the spatiotemporal dynamics of Hg species in the ocean including bioaccumulation in the marine food web Rosati et al, 2022;Bieser et al, 2023;Zhu et al, 2023).…”

Section: Temporal Trendsmentioning

confidence: 99%

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The Multi-Compartment Hg Modeling and Analysis Project (MCHgMAP): Mercury modeling to support international environmental policy

Dastoor,

Angot,

Bieser

et al. 2024

Preprint

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Abstract. The Multi-Compartment Hg (mercury) Modeling and Analysis Project (MCHgMAP) is an international multi-model research initiative intended to simulate and analyze the geospatial distributions and temporal trends of environmental Hg to inform the effectiveness evaluations of two multilateral environmental agreements (MEAs): the Minamata Convention on Mercury (MC) and Convention on Long-Range Transboundary Air Pollution (LRTAP). This MCHgMAP overview paper presents its science objectives, background and rationale, experimental design (multi-model ensemble (MME) architecture, inputs and evaluation data, simulations and reporting framework), and methodologies for the evaluation and analysis of simulated environmental Hg levels. The primary goals of the project are to facilitate detection and attribution of recent (observed) and future (projected) spatial patterns and temporal trends of global environmental Hg levels, and identification of key knowledge gaps in Hg science and modeling to improve future effectiveness evaluation cycles of the MEAs. The current advances and challenges of Hg models, emission inventories, and observational data are examined, and an optimized multi-model experimental design is introduced for addressing the key policy questions of the MEAs. A common set of emissions, environmental conditions, and observation datasets are proposed (where possible) to enhance the MME comparability. A novel harmonized simulation approach between atmospheric, land, oceanic and multi-media models is developed to account for the short- and long-term changes in secondary Hg exchanges and to achieve mechanistic consistency of Hg levels across environmental matrices. A comprehensive set of model experiments is developed and prioritized to ensure a systematic analysis and participation of a variety of models from the scientific community.

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Section: Ocean Modelsmentioning

confidence: 99%

Section: Ocean Modelsmentioning

confidence: 99%

Section: Ocean Modelsmentioning

confidence: 99%

Section: Temporal Trendsmentioning

confidence: 99%

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The Multi-Compartment Hg Modeling and Analysis Project (MCHgMAP): Mercury modeling to support international environmental policy

Dastoor,

Angot,

Bieser

et al. 2024

Preprint

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“…Later models were developed with improved ocean biogeochemistry. For example, Zhang et al (2020) and Rosati et al (2022) coupled Hg cycling with a biogeochemical and ecological model, considering the uptake to and release of Hg from marine biota. The lasted developed biogeochemical multi-compartment model for Hg cycling MERCY v2.0, developed by Bieser et al (2023), includes all currently known processes controlling marine Hg cycling.…”

Section: Introductionmentioning

confidence: 99%

A high-resolution marine mercury model MITgcm-ECCO2-Hg with online biogeochemistry

Zhu

Zhang

et al. 2023

Preprint

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Abstract. Mercury (Hg) is a global persistent contaminant. Modeling studies are useful means of synthesizing a current understanding of the Hg cycle. Previous studies mainly use coarse-resolution models, which makes it impossible to analyze the role of turbulence in the Hg cycle and inaccurately describes the transport of kinetic energy. Furthermore, all of them are coupled with offline biogeochemistry, so they cannot respond to short-term variability in oceanic Hg concentration. Here we use a high-resolution (horizontal resolution is 1/5°) ocean model (MITgcm-ECCO2, high-resolution-MITgcm) coupled with the online biogeochemistry of Darwin project to simulate the global Hg cycle. The finer portrayal of surface Hg concentrations in estuarine and coastal areas, strong western boundary flow and upwelling areas, and concentration diffusion as vortex shapes demonstrate the effects of turbulence that are neglected in previous models. Ecological events such as algal blooms can cause a sudden enhancement of phytoplankton biomass and chlorophyll concentrations, which can also result in a dramatic change in particle-bound mercury sinking flux at the same time in our simulation. In the global estuary region, the inclusion of riverine Hg input in the high-resolution model allows us to reveal the outward spread of Hg in an eddy shape driven by fine-scale ocean currents. With faster current velocities and diffusion rates, our model captures the transport and mixing of Hg from river discharge in a more accurate and detailed way and improves our understanding of Hg cycle in the ocean.

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Bioconcentration, bioaccumulation and biomagnification of mercury in plankton of the Mediterranean Sea

Tesán-Onrubia,

Heimbürger-Boavida,

Dufour

et al. 2023

Marine Pollution Bulletin

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Assessing the spatial and temporal variability of methylmercury biogeochemistry and bioaccumulation in the Mediterranean Sea with a coupled 3D model

Cited by 9 publications

References 111 publications

The Multi-Compartment Hg Modeling and Analysis Project (MCHgMAP): Mercury modeling to support international environmental policy

The Multi-Compartment Hg Modeling and Analysis Project (MCHgMAP): Mercury modeling to support international environmental policy

A high-resolution marine mercury model MITgcm-ECCO2-Hg with online biogeochemistry

Bioconcentration, bioaccumulation and biomagnification of mercury in plankton of the Mediterranean Sea

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