Methylmercury cycling in sediments on the continental shelf of southern New England

Hammerschmidt, Chad R.; Fitzgerald, William F.

doi:10.1016/j.gca.2005.10.020

Cited by 167 publications

(141 citation statements)

References 56 publications

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“…In the far-stream reaches, percent LOI alone explained 49 percent of the variability in sediment THg concentration. A positive relation between THg and percent LOI has been observed in a number of other studies (Hammerschmidt and Fitzgerald, 2006;Han and others, 2007;Marvin-DiPasquale and others, 2009a, b). In the higher gradient near-stream reaches, sediment BD became an important explanatory variable in addition to percent LOI, alluding to the nature of the particles that are likely to be deposited in the high-gradient environment.…”

Section: Controls On Mercury Distributionsupporting

confidence: 60%

Characterization of mercury contamination in the Androscoggin River, Coos County, New Hampshire

Chalmers¹,

Marvin-DiPasquale²,

Degnan³

et al. 2013

Open-File Report

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For more information on the USGS-the Federal source for science about the Earth, its natural and living resources, natural hazards, and the environment, visit http://www.usgs.gov or call 1-888-ASK-USGS.For an overview of USGS information products, including maps, imagery, and publications, visit http://www.usgs.gov/pubprodTo order this and other USGS information products, visit http://store.usgs.gov Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.Although this information product, for the most part, is in the public domain, it also may contain copyrighted materials as noted in the text. Permission to reproduce copyrighted items must be secured from the copyright owner. Thor Smith of the U.S. Geological Survey (USGS) assisted with surface-water, pore-water, and invertebrate sampling. Marc Zimmerman, Jon Denner, and Jamie Shanley of the USGS assisted with pore-water sample collection, and Evangelos Kakouros, Le Kieu, and Michelle Beyer of the USGS analyzed pore-water and sediment samples. Jeffrey Deacon of the USGS and Cornell Rosiu of the USEPA were instrumental in the study planning and design. The authors would also like to thank Chuck Dobroski and Jamie Shanley for their thoughtful technical reviews. In this report, the words right and left refer to directions that would be reported by an observer facing downstream.Vertical coordinate information is referenced to the North American Vertical Datum of 1988 (NAVD 88).Horizontal coordinate information is referenced to the North American Datum of 1983 (NAD 83).Altitude, as used in this report, refers to distance above the vertical datum. Concentrations AbstractThe former chloralkali facility in Berlin, New

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Section: Controls On Mercury Distributionsupporting

confidence: 60%

Characterization of mercury contamination in the Androscoggin River, Coos County, New Hampshire

Chalmers¹,

Marvin-DiPasquale²,

Degnan³

et al. 2013

Open-File Report

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“…Assuming that MeHg comprises no more than 25% of total Hg in bacteria, phytoplankton and zooplankton, [90] and 100% in marine mammals and fish, [91] the MeHg mass in marine biota is therefore ∼4.5 t. We conservatively estimate that 47 t of abiotic MeHg (∼5% of the total Hg pool) is present in the upper Ocean, and ∼450 t in the whole Ocean, based on a dissolved MeHg concentration of 0.03 ng L −1 measured in North Atlantic continental shelf waters. [92] Thus, bioaccumulated MeHg represents <10% of the dissolved MeHg pool in the upper Ocean alone, and <1% of whole Ocean MeHg. If the extant pool of bioavailable MeHg is already >10-fold larger than that that has been bioaccumulated, then the effect of further additions to that pool must be limited proportionately.…”

Section: Lessons About the Fulcrums Controlling Biological Hg Trendsmentioning

confidence: 99%

“…[36] In temperate estuarine sediments, cycling of Hg by biotic methylation-demethylation was rapid with a turn-over time for MeHg of the order of days. [92] Photodemethylation was a potent process in an Alaskan lake, accounting for ∼80% of annual sedimentary MeHg production, even though it was limited to the 100-day ice-free season. [122] In essence, photodemethylation competed with freshwater biota for MeHg, thereby possibly inhibiting its uptake by the lake's food-web.…”

Section: Uncertainties and Future Research Prioritiesmentioning

confidence: 99%

A mass balance inventory of mercury in the Arctic Ocean

et al. 2008

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Environmental context. Mercury (Hg) occurs at high concentrations in Arctic marine wildlife, posing a possible health risk to northern peoples who use these animals for food. We find that although the dramatic Hg increases in Arctic Ocean animals since pre-industrial times can be explained by sustained small annual inputs, recent rapid increases probably cannot because of the existing large oceanic Hg reservoir (the 'flywheel' effect). Climate change is a possible alternative force underpinning recent trends.Abstract. The present mercury (Hg) mass balance was developed to gain insights into the sources, sinks and processes regulating biological Hg trends in the Arctic Ocean. Annual total Hg inputs (mainly wet deposition, coastal erosion, seawater import, and 'excess' deposition due to atmospheric Hg depletion events) are nearly in balance with outputs (mainly shelf sedimentation and seawater export), with a net 0.3% year −1 increase in total mass. Marine biota represent a small fraction of the ocean's existing total Hg and methyl-Hg (MeHg) inventories. The inertia associated with these large non-biological reservoirs means that 'bottom-up' processes (control of bioavailable Hg concentrations by mass inputs or Hg speciation) are probably incapable of explaining recent biotic Hg trends, contrary to prevailing opinion. Instead, varying rates of bioaccumulation and trophic transfer from the abiotic MeHg reservoir may be key, and are susceptible to ecological, climatic and biogeochemical influences. Deep and sustained cuts to global anthropogenic Hg emissions are required to return biotic Hg levels to their natural state. However, because of mass inertia and the less dominant role of atmospheric inputs, the decline of seawater and biotic Hg concentrations in the Arctic Ocean will be more gradual than the rate of emission reduction and slower than in other oceans and freshwaters. Climate warming has likely already influenced Arctic Hg dynamics, with shrinking sea-ice cover one of the defining variables. Future warming will probably force more Hg out of the ocean's euphotic zone through greater evasion to air and faster Hg sedimentation driven by higher primary productivity; these losses will be countered by enhanced inputs from coastal erosion and rivers.

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“…Sulfate-reducing bacteria convert inorganic Hg in marine sediments to methylmercury (MeHg) [12], which can accumulate in food chains when it is absorbed by primary producers, resulting in fish being exposed to MeHg primarily through the diet [13]. Prey preferences, ontogenetic shifts in habitat, migration, and seasonal movements are factors that complicate the determination of Hg bioaccumulation in marine fish.…”

Section: Introductionmentioning

confidence: 99%

Regional variation in mercury and stable isotopes of red snapper (Lutjanus campechanus) in the northern gulf of Mexico, USA

Sluis

Boswell

Chumchal

et al. 2012

Enviro Toxic and Chemistry

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Methylmercury cycling in sediments on the continental shelf of southern New England

Cited by 167 publications

References 56 publications

Characterization of mercury contamination in the Androscoggin River, Coos County, New Hampshire

Characterization of mercury contamination in the Androscoggin River, Coos County, New Hampshire

A mass balance inventory of mercury in the Arctic Ocean

Regional variation in mercury and stable isotopes of red snapper (Lutjanus campechanus) in the northern gulf of Mexico, USA

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