Mercury isotopes in a forested ecosystem: Implications for air-surface exchange dynamics and the global mercury cycle

Mercury isotopes in a forested ecosystem: Implications for air-surface exchange dynamics and the global mercury cycle

Forests mediate the biogeochemical cycling of mercury (Hg) between the atmosphere and terrestrial ecosystems; however, there remain many gaps in our understanding of these processes. Our objectives in this study were to characterize Hg isotopic composition within forests, and use natural abundance s...

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Veröffentlicht in:Global biogeochemical cycles 2013-03, Vol.27 (1), p.222-238
Hauptverfasser: Demers, Jason D., Blum, Joel D., Zak, Donald R.
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Air-Surface Exchange
Animal and plant ecology
Animal, plant and microbial ecology
Atmosphere
Biogeochemical cycles
Biological and medical sciences
Carbon dioxide
Earth sciences
Earth, ocean, space
Ecosystems
Emissions
Exact sciences and technology
Foliage
Forest ecosystems
Forest floor
Forest soils
Forested Ecosystems
Forests
Fundamental and applied biological sciences. Psychology
General aspects
Geochemistry
Isotopes
Leaves
Mercury
Mercury Biogeochemistry
Mercury Stable Isotopes
Soil environment
Synecology
Terrestrial ecosystems
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description Forests mediate the biogeochemical cycling of mercury (Hg) between the atmosphere and terrestrial ecosystems; however, there remain many gaps in our understanding of these processes. Our objectives in this study were to characterize Hg isotopic composition within forests, and use natural abundance stable Hg isotopes to track sources and reveal mechanisms underlying the cycling of Hg. We quantified the stable Hg isotopic composition of foliage, forest floor, mineral soil, precipitation, and total gaseous mercury (THg(g)) in the atmosphere and in evasion from soil, in 10‐year‐old aspen forests at the Rhinelander FACE experiment in northeastern Wisconsin, USA. The effect of increased atmospheric CO2 and O3 concentrations on Hg isotopic composition was small relative to differences among forest ecosystem components. Precipitation samples had δ202Hg values of −0.74 to 0.06‰ and ∆199Hg values of 0.16 to 0.82‰. Atmospheric THg(g) had δ202Hg values of 0.48 to 0.93‰ and ∆199Hg values of −0.21 to −0.15‰. Uptake of THg(g) by foliage resulted in a large (−2.89‰) shift in δ202Hg values; foliage displayed δ202Hg values of −2.53 to −1.89‰ and ∆199Hg values of −0.37 to −0.23‰. Forest floor samples had δ202Hg values of −1.88 to −1.22‰ and ∆199Hg values of −0.22 to −0.14‰. Mercury isotopes distinguished geogenic sources of Hg and atmospheric derived sources of Hg in soil, and showed that precipitation Hg only accounted for ~16% of atmospheric Hg inputs. The isotopic composition of Hg evasion from the forest floor was similar to atmospheric THg(g); however, there were systematic differences in δ202Hg values and MIF of even isotopes (∆200Hg and ∆204Hg). Mercury evasion from the forest floor may have arisen from air‐surface exchange of atmospheric THg(g), but was not the emission of legacy Hg from soils, nor re‐emission of wet‐deposition. This implies that there was net atmospheric THg(g) deposition to the forest soils. Furthermore, MDF of Hg isotopes during foliar uptake and air‐surface exchange of atmospheric THg(g) resulted in the release of Hg with very positive δ202Hg values to the atmosphere, which is key information for modeling the isotopic balance of the global mercury cycle, and may indicate a shorter residence time than previously recognized for the atmospheric mercury pool. Key pointsAtmospheric Hg was fractionated during uptake by foliage (‐2.89 permil δ202Hg)Hg evading from soil was from atmospheric Hg interaction with soil environmentAir‐surface exchange of Hg r
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Our objectives in this study were to characterize Hg isotopic composition within forests, and use natural abundance stable Hg isotopes to track sources and reveal mechanisms underlying the cycling of Hg. We quantified the stable Hg isotopic composition of foliage, forest floor, mineral soil, precipitation, and total gaseous mercury (THg(g)) in the atmosphere and in evasion from soil, in 10‐year‐old aspen forests at the Rhinelander FACE experiment in northeastern Wisconsin, USA. The effect of increased atmospheric CO2 and O3 concentrations on Hg isotopic composition was small relative to differences among forest ecosystem components. Precipitation samples had δ202Hg values of −0.74 to 0.06‰ and ∆199Hg values of 0.16 to 0.82‰. Atmospheric THg(g) had δ202Hg values of 0.48 to 0.93‰ and ∆199Hg values of −0.21 to −0.15‰. Uptake of THg(g) by foliage resulted in a large (−2.89‰) shift in δ202Hg values; foliage displayed δ202Hg values of −2.53 to −1.89‰ and ∆199Hg values of −0.37 to −0.23‰. Forest floor samples had δ202Hg values of −1.88 to −1.22‰ and ∆199Hg values of −0.22 to −0.14‰. Mercury isotopes distinguished geogenic sources of Hg and atmospheric derived sources of Hg in soil, and showed that precipitation Hg only accounted for ~16% of atmospheric Hg inputs. The isotopic composition of Hg evasion from the forest floor was similar to atmospheric THg(g); however, there were systematic differences in δ202Hg values and MIF of even isotopes (∆200Hg and ∆204Hg). Mercury evasion from the forest floor may have arisen from air‐surface exchange of atmospheric THg(g), but was not the emission of legacy Hg from soils, nor re‐emission of wet‐deposition. This implies that there was net atmospheric THg(g) deposition to the forest soils. 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Cycles</addtitle><description>Forests mediate the biogeochemical cycling of mercury (Hg) between the atmosphere and terrestrial ecosystems; however, there remain many gaps in our understanding of these processes. Our objectives in this study were to characterize Hg isotopic composition within forests, and use natural abundance stable Hg isotopes to track sources and reveal mechanisms underlying the cycling of Hg. We quantified the stable Hg isotopic composition of foliage, forest floor, mineral soil, precipitation, and total gaseous mercury (THg(g)) in the atmosphere and in evasion from soil, in 10‐year‐old aspen forests at the Rhinelander FACE experiment in northeastern Wisconsin, USA. The effect of increased atmospheric CO2 and O3 concentrations on Hg isotopic composition was small relative to differences among forest ecosystem components. Precipitation samples had δ202Hg values of −0.74 to 0.06‰ and ∆199Hg values of 0.16 to 0.82‰. Atmospheric THg(g) had δ202Hg values of 0.48 to 0.93‰ and ∆199Hg values of −0.21 to −0.15‰. Uptake of THg(g) by foliage resulted in a large (−2.89‰) shift in δ202Hg values; foliage displayed δ202Hg values of −2.53 to −1.89‰ and ∆199Hg values of −0.37 to −0.23‰. Forest floor samples had δ202Hg values of −1.88 to −1.22‰ and ∆199Hg values of −0.22 to −0.14‰. Mercury isotopes distinguished geogenic sources of Hg and atmospheric derived sources of Hg in soil, and showed that precipitation Hg only accounted for ~16% of atmospheric Hg inputs. The isotopic composition of Hg evasion from the forest floor was similar to atmospheric THg(g); however, there were systematic differences in δ202Hg values and MIF of even isotopes (∆200Hg and ∆204Hg). Mercury evasion from the forest floor may have arisen from air‐surface exchange of atmospheric THg(g), but was not the emission of legacy Hg from soils, nor re‐emission of wet‐deposition. This implies that there was net atmospheric THg(g) deposition to the forest soils. Furthermore, MDF of Hg isotopes during foliar uptake and air‐surface exchange of atmospheric THg(g) resulted in the release of Hg with very positive δ202Hg values to the atmosphere, which is key information for modeling the isotopic balance of the global mercury cycle, and may indicate a shorter residence time than previously recognized for the atmospheric mercury pool. 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Psychology</subject><subject>General aspects</subject><subject>Geochemistry</subject><subject>Isotopes</subject><subject>Leaves</subject><subject>Mercury</subject><subject>Mercury Biogeochemistry</subject><subject>Mercury Stable Isotopes</subject><subject>Soil environment</subject><subject>Synecology</subject><subject>Terrestrial ecosystems</subject><issn>0886-6236</issn><issn>1944-9224</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><recordid>eNp1kU9v1DAQxSMEEkvhwDewhJDoIa3_2-EGq7KtVMqBVkhcrIkz2bok8WJvRPPtm-0uPSBxmnf4vTczekXxltETRik_Xdf-hM-CPSsWrJKyrDiXz4sFtVaXmgv9sniV8x2lTCpVLYrxKyY_pomEHLdxg5mEgQBpY8K8xYagj3maVf-RXPSbLnjYhjjkHUAgpDKPqQWPBO_9LQxrJM00QB98JjA0ZHuLZN3FGjrSH_b4yXf4unjRQpfxzWEeFTdfzq6X5-Xlt9XF8tNlCYpzVra6tqLmvKoQQWqqvZSAlfCe8tpYKU0NKBrgCpUHy2rLRGM0a9uqMbQ14qj4sM_dpPh7nD9yfcgeuw4GjGN2THEqTGXVDn33D3oXxzTM1zmmheVKiUrM1PGe8inmnLB1mxR6SJNj1O0KcHMB7rGAmX1_SITsoWsTDD7kJwM3khtqd5tP99yf0OH0_0C3-rz8m1zuHWFu5v7JAemX00YY5X5crdzyp2Xn2l657-IBirmj4w</recordid><startdate>201303</startdate><enddate>201303</enddate><creator>Demers, Jason D.</creator><creator>Blum, Joel D.</creator><creator>Zak, Donald R.</creator><general>Blackwell Publishing Ltd</general><general>American Geophysical Union</general><scope>BSCLL</scope><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SN</scope><scope>7TG</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>KL.</scope><scope>L.G</scope><scope>7UA</scope></search><sort><creationdate>201303</creationdate><title>Mercury isotopes in a forested ecosystem: Implications for air-surface exchange dynamics and the global mercury cycle</title><author>Demers, Jason D. ; Blum, Joel D. ; Zak, Donald R.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a5221-f6b83b2299eea4606c44ae93cc02b78447bae3da25e5ca81b813d761ff9d70f73</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>Air-Surface Exchange</topic><topic>Animal and plant ecology</topic><topic>Animal, plant and microbial ecology</topic><topic>Atmosphere</topic><topic>Biogeochemical cycles</topic><topic>Biological and medical sciences</topic><topic>Carbon dioxide</topic><topic>Earth sciences</topic><topic>Earth, ocean, space</topic><topic>Ecosystems</topic><topic>Emissions</topic><topic>Exact sciences and technology</topic><topic>Foliage</topic><topic>Forest ecosystems</topic><topic>Forest floor</topic><topic>Forest soils</topic><topic>Forested Ecosystems</topic><topic>Forests</topic><topic>Fundamental and applied biological sciences. 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Cycles</addtitle><date>2013-03</date><risdate>2013</risdate><volume>27</volume><issue>1</issue><spage>222</spage><epage>238</epage><pages>222-238</pages><issn>0886-6236</issn><eissn>1944-9224</eissn><coden>GBCYEP</coden><abstract>Forests mediate the biogeochemical cycling of mercury (Hg) between the atmosphere and terrestrial ecosystems; however, there remain many gaps in our understanding of these processes. Our objectives in this study were to characterize Hg isotopic composition within forests, and use natural abundance stable Hg isotopes to track sources and reveal mechanisms underlying the cycling of Hg. We quantified the stable Hg isotopic composition of foliage, forest floor, mineral soil, precipitation, and total gaseous mercury (THg(g)) in the atmosphere and in evasion from soil, in 10‐year‐old aspen forests at the Rhinelander FACE experiment in northeastern Wisconsin, USA. The effect of increased atmospheric CO2 and O3 concentrations on Hg isotopic composition was small relative to differences among forest ecosystem components. Precipitation samples had δ202Hg values of −0.74 to 0.06‰ and ∆199Hg values of 0.16 to 0.82‰. Atmospheric THg(g) had δ202Hg values of 0.48 to 0.93‰ and ∆199Hg values of −0.21 to −0.15‰. Uptake of THg(g) by foliage resulted in a large (−2.89‰) shift in δ202Hg values; foliage displayed δ202Hg values of −2.53 to −1.89‰ and ∆199Hg values of −0.37 to −0.23‰. Forest floor samples had δ202Hg values of −1.88 to −1.22‰ and ∆199Hg values of −0.22 to −0.14‰. Mercury isotopes distinguished geogenic sources of Hg and atmospheric derived sources of Hg in soil, and showed that precipitation Hg only accounted for ~16% of atmospheric Hg inputs. The isotopic composition of Hg evasion from the forest floor was similar to atmospheric THg(g); however, there were systematic differences in δ202Hg values and MIF of even isotopes (∆200Hg and ∆204Hg). Mercury evasion from the forest floor may have arisen from air‐surface exchange of atmospheric THg(g), but was not the emission of legacy Hg from soils, nor re‐emission of wet‐deposition. This implies that there was net atmospheric THg(g) deposition to the forest soils. Furthermore, MDF of Hg isotopes during foliar uptake and air‐surface exchange of atmospheric THg(g) resulted in the release of Hg with very positive δ202Hg values to the atmosphere, which is key information for modeling the isotopic balance of the global mercury cycle, and may indicate a shorter residence time than previously recognized for the atmospheric mercury pool. Key pointsAtmospheric Hg was fractionated during uptake by foliage (‐2.89 permil δ202Hg)Hg evading from soil was from atmospheric Hg interaction with soil environmentAir‐surface exchange of Hg releases Hg with positive δ202Hg to global reservoir</abstract><cop>Washington, DC</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1002/gbc.20021</doi><tpages>17</tpages><oa>free_for_read</oa></addata></record>
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source Wiley Free Content; Wiley-Blackwell AGU Digital Library; EZB-FREE-00999 freely available EZB journals; Wiley Online Library All Journals
subjects Air-Surface Exchange
Animal and plant ecology
Animal, plant and microbial ecology
Atmosphere
Biogeochemical cycles
Biological and medical sciences
Carbon dioxide
Earth sciences
Earth, ocean, space
Ecosystems
Emissions
Exact sciences and technology
Foliage
Forest ecosystems
Forest floor
Forest soils
Forested Ecosystems
Forests
Fundamental and applied biological sciences. Psychology
General aspects
Geochemistry
Isotopes
Leaves
Mercury
Mercury Biogeochemistry
Mercury Stable Isotopes
Soil environment
Synecology
Terrestrial ecosystems
title Mercury isotopes in a forested ecosystem: Implications for air-surface exchange dynamics and the global mercury cycle
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