Runsheng Yin David P. Krabbenhoft Jacob M. Ogorek John F. DeWild Thomas M. Holsen James P. Hurley Ryan F. Lepak 2015 <p><span>Sources of mercury (Hg) in Great Lakes sediments were assessed with stable Hg isotope ratios using multicollector inductively coupled plasma mass spectrometry. An isotopic mixing model based on mass-dependent (MDF) and mass-independent fractionation (MIF) (&delta;</span>^{<span>202</span>}<span>Hg and &Delta;</span>^{<span>199</span>}<span>Hg) identified three primary Hg sources for sediments: atmospheric, industrial, and watershed-derived. Results indicate atmospheric sources dominate in Lakes Huron, Superior, and Michigan sediments while watershed-derived and industrial sources dominate in Lakes Erie and Ontario sediments. Anomalous &Delta;</span>^{<span>200</span>}<span>Hg signatures, also apparent in sediments, provided independent validation of the model. Comparison of &Delta;</span>^{<span>200</span>}<span>Hg signatures in predatory fish from three lakes reveals that bioaccumulated Hg is more isotopically similar to atmospherically derived Hg than a lake&rsquo;s sediment. Previous research suggests &Delta;</span>^{<span>200</span>}<span>Hg is conserved during biogeochemical processing and odd mass-independent fractionation (MIF) is conserved during metabolic processing, so it is suspected even is similarly conserved. Given these assumptions, our data suggest that in some cases, atmospherically derived Hg may be a more important source of MeHg to higher trophic levels than legacy sediments in the Great Lakes.</span></p> application/pdf 10.1021/acs.estlett.5b00277 en American Chemical Society Use of stable isotope signatures to determine mercury sources in the Great Lakes article