A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants
Human activities have released large quantities of neutral persistent organic pollutants (POPs) that may be biomagnified in food webs and pose health risks to wildlife, particularly top predators. Here we develop a global 3â€D ocean simulation for four polychlorinated biphenyls (PCBs) spanning a ran...
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University of Rhode Island: DigitalCommons@URI |
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ftunivrhodeislan |
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unknown |
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Human activities have released large quantities of neutral persistent organic pollutants (POPs) that may be biomagnified in food webs and pose health risks to wildlife, particularly top predators. Here we develop a global 3â€D ocean simulation for four polychlorinated biphenyls (PCBs) spanning a range of molecular weights and volatilities to better understand effects of climateâ€driven changes in ocean biogeochemistry on the lifetime and distribution of POPs. Observations are most abundant in the Arctic Ocean. There, model results reproduce spatial patterns and magnitudes of measured PCB concentrations. Sorption of PCBs to suspended particles and subsequent burial in benthic marine sediment is the dominant oceanic loss process globally. Results suggest benthic sediment burial has removed 75% of cumulative PCB releases since the onset of production in 1930. Wind speed, light penetration, and ocean circulation exert a stronger and more variable influence on volatile PCB congeners with lower particle affinity such as chlorinated biphenylâ€28 and chlorinated biphenylâ€101. In the Arctic Ocean between 1992 and 2015, modeled evasion (losses) of the more volatile PCB congeners from the surface ocean increased due to declines in sea ice and changes in ocean circulation. By contrast, net deposition increased slightly for higher molecular weight congeners with stronger partitioning to particles. Our results suggest future climate changes will have the greatest impacts on the chemical lifetimes and distributions of volatile POPs with lower molecular weights. |
| format |
Text |
| author |
Wagner, Charlotte C. Amos, Helen N. Thackray, Colin P. Zhang, Yanxu Lundgren, Elizabeth W. Forget, Gael Friedman, Carey L. Selin, Noelle E. Lohmann, Rainer Sunderland, Elise M. |
| spellingShingle |
Wagner, Charlotte C. Amos, Helen N. Thackray, Colin P. Zhang, Yanxu Lundgren, Elizabeth W. Forget, Gael Friedman, Carey L. Selin, Noelle E. Lohmann, Rainer Sunderland, Elise M. A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| author_facet |
Wagner, Charlotte C. Amos, Helen N. Thackray, Colin P. Zhang, Yanxu Lundgren, Elizabeth W. Forget, Gael Friedman, Carey L. Selin, Noelle E. Lohmann, Rainer Sunderland, Elise M. |
| author_sort |
Wagner, Charlotte C. |
| title |
A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| title_short |
A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| title_full |
A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| title_fullStr |
A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| title_full_unstemmed |
A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants |
| title_sort |
global 3â€d ocean model for pcbs: benchmark compounds for understanding the impacts of global change on neutral persistent organic pollutants |
| publisher |
DigitalCommons@URI |
| publishDate |
2019 |
| url |
https://digitalcommons.uri.edu/gsofacpubs/657 https://doi.org/10.1029/2018GB006018 https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/viewcontent/auto_convert.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/0/type/additional/viewcontent/Lohmann_Global3D_2019_SI.docx https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/1/type/additional/viewcontent/Lohmann_Global3D_2019_Fig1.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/2/type/additional/viewcontent/Lohmann_Global3D_2019_fig2.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/3/type/additional/viewcontent/Lohmann_Global3D_2019_fig3.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/4/type/additional/viewcontent/Lohmann_Global3D_2019_fig4.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/5/type/additional/viewcontent/Lohmann_Global3D_2019_fig5.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/6/type/additional/viewcontent/Lohmann_Global3D_2019_fig6.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/7/type/additional/viewcontent/Lohmann_Global3D_2019_fig7.pdf |
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Arctic Ocean Sea ice |
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Arctic Ocean Sea ice |
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Graduate School of Oceanography Faculty Publications |
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https://digitalcommons.uri.edu/gsofacpubs/657 doi:10.1029/2018GB006018 https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/viewcontent/auto_convert.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/0/type/additional/viewcontent/Lohmann_Global3D_2019_SI.docx https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/1/type/additional/viewcontent/Lohmann_Global3D_2019_Fig1.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/2/type/additional/viewcontent/Lohmann_Global3D_2019_fig2.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/3/type/additional/viewcontent/Lohmann_Global3D_2019_fig3.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/4/type/additional/viewcontent/Lohmann_Global3D_2019_fig4.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/5/type/additional/viewcontent/Lohmann_Global3D_2019_fig5.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/6/type/additional/viewcontent/Lohmann_Global3D_2019_fig6.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/7/type/additional/viewcontent/Lohmann_Global3D_2019_fig7.pdf |
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https://doi.org/10.1029/2018GB006018 |
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Global Biogeochemical Cycles |
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33 |
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3 |
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469 |
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481 |
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ftunivrhodeislan:oai:digitalcommons.uri.edu:gsofacpubs-1635 2024-09-15T17:53:30+00:00 A Global 3â€D Ocean Model for PCBs: Benchmark Compounds for Understanding the Impacts of Global Change on Neutral Persistent Organic Pollutants Wagner, Charlotte C. Amos, Helen N. Thackray, Colin P. Zhang, Yanxu Lundgren, Elizabeth W. Forget, Gael Friedman, Carey L. Selin, Noelle E. Lohmann, Rainer Sunderland, Elise M. 2019-01-01T08:00:00Z application/pdf https://digitalcommons.uri.edu/gsofacpubs/657 https://doi.org/10.1029/2018GB006018 https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/viewcontent/auto_convert.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/0/type/additional/viewcontent/Lohmann_Global3D_2019_SI.docx https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/1/type/additional/viewcontent/Lohmann_Global3D_2019_Fig1.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/2/type/additional/viewcontent/Lohmann_Global3D_2019_fig2.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/3/type/additional/viewcontent/Lohmann_Global3D_2019_fig3.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/4/type/additional/viewcontent/Lohmann_Global3D_2019_fig4.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/5/type/additional/viewcontent/Lohmann_Global3D_2019_fig5.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/6/type/additional/viewcontent/Lohmann_Global3D_2019_fig6.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/7/type/additional/viewcontent/Lohmann_Global3D_2019_fig7.pdf unknown DigitalCommons@URI https://digitalcommons.uri.edu/gsofacpubs/657 doi:10.1029/2018GB006018 https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/viewcontent/auto_convert.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/0/type/additional/viewcontent/Lohmann_Global3D_2019_SI.docx https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/1/type/additional/viewcontent/Lohmann_Global3D_2019_Fig1.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/2/type/additional/viewcontent/Lohmann_Global3D_2019_fig2.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/3/type/additional/viewcontent/Lohmann_Global3D_2019_fig3.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/4/type/additional/viewcontent/Lohmann_Global3D_2019_fig4.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/5/type/additional/viewcontent/Lohmann_Global3D_2019_fig5.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/6/type/additional/viewcontent/Lohmann_Global3D_2019_fig6.pdf https://digitalcommons.uri.edu/context/gsofacpubs/article/1635/filename/7/type/additional/viewcontent/Lohmann_Global3D_2019_fig7.pdf Graduate School of Oceanography Faculty Publications text 2019 ftunivrhodeislan https://doi.org/10.1029/2018GB006018 2024-08-21T00:09:33Z Human activities have released large quantities of neutral persistent organic pollutants (POPs) that may be biomagnified in food webs and pose health risks to wildlife, particularly top predators. Here we develop a global 3â€D ocean simulation for four polychlorinated biphenyls (PCBs) spanning a range of molecular weights and volatilities to better understand effects of climateâ€driven changes in ocean biogeochemistry on the lifetime and distribution of POPs. Observations are most abundant in the Arctic Ocean. There, model results reproduce spatial patterns and magnitudes of measured PCB concentrations. Sorption of PCBs to suspended particles and subsequent burial in benthic marine sediment is the dominant oceanic loss process globally. Results suggest benthic sediment burial has removed 75% of cumulative PCB releases since the onset of production in 1930. Wind speed, light penetration, and ocean circulation exert a stronger and more variable influence on volatile PCB congeners with lower particle affinity such as chlorinated biphenylâ€28 and chlorinated biphenylâ€101. In the Arctic Ocean between 1992 and 2015, modeled evasion (losses) of the more volatile PCB congeners from the surface ocean increased due to declines in sea ice and changes in ocean circulation. By contrast, net deposition increased slightly for higher molecular weight congeners with stronger partitioning to particles. Our results suggest future climate changes will have the greatest impacts on the chemical lifetimes and distributions of volatile POPs with lower molecular weights. Text Arctic Ocean Sea ice University of Rhode Island: DigitalCommons@URI Global Biogeochemical Cycles 33 3 469 481 |