Boreal Forests Sequester Large Amounts of Mercury over Millennial Time Scales in the Absence of Wildfire

Giesler, Reiner; Clemmensen, Karina E.; Wardle, David A.; Klaminder, Jonatan; Bindler, Richard

doi:10.1021/acs.est.6b06369

Cited by 13 publications

(14 citation statements)

References 57 publications

(154 reference statements)

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“…Hg has four release pathways: (1) evasion into the atmosphere after microbial decay 11 , (2) leaf stomata transpiration 14 , (3) fire 11 , and (4) leaching into groundwater followed by eventual export by rivers into the oceans 16 . Microbial decay frees Hg from organic matter, but plants and soil organic matter reabsorb 11 most of this liberated Hg. Whether leaves represent an Hg source or sink depends on the concentration gradient between the stomata and the atmosphere 14 .…”

Section: Introductionmentioning

confidence: 99%

“…Whether leaves represent an Hg source or sink depends on the concentration gradient between the stomata and the atmosphere 14 . Fire consumes soil organic matter, emitting carbon dioxide and Hg into the atmosphere 11 . Once leached into water, bound to Dissolved Organic Carbon (DOC) and Particulate Organic Carbon (POC), Hg can methylate, entering the food chain and accumulating in various species, particularly fish 8 .…”

Section: Introductionmentioning

confidence: 99%

“…Because Hg bonds to organic matter, the terrestrial carbon cycle modulates the terrestrial Hg cycle. Hg has three uptake pathways: (1) bonding to soil organic matter 8,10,11 , (2) stomatal leaf uptake 12,13 , and (3) root absorption 12,14 . Once absorbed by plants, translocation by phloem assimilates Hg into leaves and wood 12,13 .…”

mentioning

confidence: 99%

“…Once absorbed by plants, translocation by phloem assimilates Hg into leaves and wood 12,13 . The deposition of dead leaves, roots, and stems transfers additional Hg to the soil 11,15 .…”

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confidence: 99%

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Potential impacts of mercury released from thawing permafrost

et al. 2020

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Mercury (Hg) is a naturally occurring element that bonds with organic matter and, when converted to methylmercury, is a potent neurotoxicant. Here we estimate potential future releases of Hg from thawing permafrost for low and high greenhouse gas emissions scenarios using a mechanistic model. By 2200, the high emissions scenario shows annual permafrost Hg emissions to the atmosphere comparable to current global anthropogenic emissions. By 2100, simulated Hg concentrations in the Yukon River increase by 14% for the low emissions scenario, but double for the high emissions scenario. Fish Hg concentrations do not exceed United States Environmental Protection Agency guidelines for the low emissions scenario by 2300, but for the high emissions scenario, fish in the Yukon River exceed EPA guidelines by 2050. Our results indicate minimal impacts to Hg concentrations in water and fish for the low emissions scenario and high impacts for the high emissions scenario.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

“…Once absorbed by plants, translocation by phloem assimilates Hg into leaves and wood 12,13 . The deposition of dead leaves, roots, and stems transfers additional Hg to the soil 11,15 .…”

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Potential impacts of mercury released from thawing permafrost

et al. 2020

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“…As a result of these environmental changes, it is predicted that wildfires will become increasingly frequent and severe in the near future, including in the Arctic (Hu et al, 2015; Teufel & Sushama, 2019; Wang et al, 2015; Wotton et al, 2017). These new fire regimes may alter freshwater ecosystems by rapidly liberating metal(loid) contaminants slowly accumulated in soils and biomass over centuries or millennia (Abraham et al, 2017; Giesler et al, 2017). Burned catchments result in elevated loading of sediment, organic matter, nutrients, major ions, and metal(loid)s to connected streams and lakes for decades following wildfires because catchment erosion is facilitated by fire (Dunnette et al, 2014; Ice et al, 2004; Jensen et al, 2017; Nelson et al, 2007; Rothenberg et al, 2010; Stein et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Paleolimnological Assessment of Wildfire‐Derived Atmospheric Deposition of Trace Metal(loid)s and Major Ions to Subarctic Lakes (Northwest Territories, Canada)

et al. 2020

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Wildfires release terrestrial elements to the atmosphere as aerosols, and these events are becoming more frequent and intense in the Arctic boreal forest as the climate is warming. We quantified the impact of atmospheric deposition of aerosols from local wildfires on metal(loid) fluxes using macroscopic charcoal accumulation rates, historical fire mapping, and element concentrations in 210Pb‐dated lake sediment from five subarctic lakes with small catchments. Lake sediments showed small but significant increases in fluxes (median = 5–10%) for 22 trace metals, metalloids, or major ions following fire events. The impact of wildfire aerosols on element fluxes was mostly due to short‐term (≤2 years) increasing sedimentation rate (6 ± 41% increase), whereas sediment element concentrations were not strongly impacted. Wildfire‐associated deposition to lake sediments was mainly composed of Ca, Al, Fe, Mg, K, Mn, and Na, which are major constituents of ash from burned biomass, but changes in sediment flux were greatest for Sb, As, Ni, Ba, Mn, Mo, and Sr compared to pre‐disturbance conditions. Compared to anthropogenic sources of pollution, wildfire‐associated atmospheric fluxes of metal contaminants to the lakes (e.g., Hg, Pb, As, Sb, and Cd) were low. This study provides quantitative estimates of wildfire impacts on atmospheric geochemical fluxes to subarctic lakes, which can be used for modeling larger‐scale impacts under changing fire regimes.

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