Sulfur isotope homogeneity of oceanic DMSP and DMS

Amrani, Alon; Said–Ahmad, Ward; Shaked, Yeala; Kiene, Ronald P.

doi:10.1073/pnas.1312956110

Cited by 82 publications

(93 citation statements)

References 30 publications

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“…Indeed, the existing data sets include one from the South Pole covering approximately the past 50 years [ Patris et al ., ], the Camp Maudheimvidda (CM) and Camp Victoria (CV) ice cores from Dronning Maud Land (spanning the present to 1100 years ago) [ Jonsell et al ., ], and the Dome C shallow core [ Baroni et al ., ] (Figure ). These East Antarctic sites have δ 34 S values ranging from 13.9 to 18.1‰, similar to biogenic sulfur [ Amrani et al ., ; Calhoun et al ., ; Oduro et al ., ], suggesting that marine biogenic activity has a strong influence in East Antarctica. The contributions of other sources to the total sulfate are estimated to be minor: Volcanic degassing is estimated to contribute 10–20% based on a δ 34 S value from CV [ Jonsell et al ., ], and stratospheric sulfate is estimated to contribute approximately 5% based on aerosol chemistry observations at Neumayer Station [ Minikin et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Sulfur isotopic composition of surface snow along a latitudinal transect in East Antarctica

Uemura

Masaka

Fukui

et al. 2016

Geophysical Research Letters

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The sulfur stable isotopic values (δ34S) of sulfate aerosols can be used to assess oxidation pathways and contributions from various sources, such as marine biogenic sulfur, volcanoes, and sea salt. However, because of a lack of observations, the spatial distribution of δ34S values in Antarctic sulfate aerosols remains unclear. Here we present the first sulfur isotopic values from surface snow samples along a latitudinal transect in eastern Dronning Maud Land, East Antarctica. The δ34S values of sulfate showed remarkably uniform values, in the range of 14.8–16.9‰, and no significant decrease toward the inland part of the transect was noted. These results suggest that net isotopic fractionation during long‐range transport is insignificant. Thus, the δ34S values can be used to infer source contributions. The δ34S values suggest that marine biogenic sulfur is the dominant source of sulfate aerosols, with a fractional contribution of 84 ± 16%.

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Section: Introductionmentioning

confidence: 99%

Sulfur isotopic composition of surface snow along a latitudinal transect in East Antarctica

Uemura

Masaka

Fukui

et al. 2016

Geophysical Research Letters

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“…To the best of our knowledge, this is the first report containing S isotopic information on Indian aerosols. Nonetheless, from available literature containing S isotopic composition data from other regions and oceanic realms (Norman et al, 1999;Oduro et al, 2012;Amrani et al, 2013), we showed typical end member values in the Fig. 6 and attempted to provide interpretation for observed δ 34 S values of bulk aerosols over Goa.…”

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confidence: 94%

“…As Goa is a typical costal locale experiencing strong biogeochemical in the coastal waters just before arrival of monsoon, enhancement of δ 34 S shows most likely tracks changes in the sulfur inventory. Recently Amrani et al (2013) and Oduro et al (2012) have shown oceanic emissions of volatile dimethyl sulfide (DMS) and its precursor, dimethylsulfoniopropionate (DMSP) represent the largest natural source of biogenic sulfur to the global atmosphere, where it mediates aerosol dynamics and may, in turn, affect climate. Amrani et al (2013) reported δ 34 S of DMS and DMSP ranging between +18.9 and +20.3‰, remarkable consistent across the globe.…”

mentioning

confidence: 99%

“…Recently Amrani et al (2013) and Oduro et al (2012) have shown oceanic emissions of volatile dimethyl sulfide (DMS) and its precursor, dimethylsulfoniopropionate (DMSP) represent the largest natural source of biogenic sulfur to the global atmosphere, where it mediates aerosol dynamics and may, in turn, affect climate. Amrani et al (2013) reported δ 34 S of DMS and DMSP ranging between +18.9 and +20.3‰, remarkable consistent across the globe. Earlier δ 34 S values of SO 4 -2 have been reported between +15 and +19‰; marine biogenic ~+17.5‰ and sea salt SO 4 -2 as +21‰ (Normal et al, 1999;Fig.…”

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confidence: 99%

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Stable Isotopic and Chemical Characteristics of Bulk Aerosols during Winter and Summer Seasons at a Station in Western Coast of India (Goa)

Agnihotri

Karapurkar

Sarma

et al. 2015

Aerosol Air Qual. Res.

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We measured stable isotopic and chemical characteristics of bulk aerosols collected at a coastal station in western India (Goa) between December 2009 and January 2011, to characterize lower tropospheric atmospheric conditions and their influence on particle chemistry during winter and summer seasons. Marked differences were observed in terms of sources and chemical compositions of bulk aerosols. The δ 15 N TN values of winter aerosols (10.8 ± 2.2‰, n = 10) indicate biomass burning contributions in the carbonaceous fraction, while significantly depleted δ 15 N TN values of summer aerosols (6.2 ± 2.3‰, n = 12) hints incorporation of marine N species. The δ 34 S TS showed depleted values during winter (5.0 ± 1.0‰, n = 10), which closely matched with those of typical urban polluted environments, while summer aerosols showed a systematic enrichment of δ 34 S TS (up to ~14‰ with average value 9.0 ± 2.8‰, n = 13); possibly due to incorporation of volatile dimethyl sulfide (DMS) and its precursor dimethylsulfoniopropionate (DMSP) emitted from the adjacent Arabian Sea. Likewise, δ 13 C TOC values showed ~2‰ enrichment in winter aerosols (-24.8 ± 0.4‰, n = 10) with respect to those of summer values, indicating presence of bio-fuel and coal burning contributions in carbonaceous fraction of winter aerosols. We also measured major ions (Na + , K + , Mg ++ , Ca ++ , NH 4 + , Cl -, Br -, NO 3 -, SO 4 -2 ) in water soluble fraction of aerosols to understand winter/summer changes in the atmospheric chemistry over this coastal area. This is the first ever dataset on triple isotopic characteristics of bulk aerosols at a coastal location of India showing signatures of continental bio-mass/biofuel burning influences during winter, whereas marine inventories (e.g., sea salt, DMS and mineral dust) appear to dominate chemical composition of summer aerosols.

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“…Increased continental biogenic emissions would tend to decrease the δ 34 S‐SO 4 2− values of summer rain, which is opposite to the trend observed in this study. However, sulfate derived from marine biogenic emissions (mainly dimethyl sulfide (DMS)) are substantial (~19% of annual global S emissions), with more positive δ 34 S‐SO 4 2− values (+18.9 to +20.3‰) [ Amrani et al, ; Seguin et al, ] relative to this study. Primary productivity from phytoplankton and algae that produce DMS is elevated in the summer [e.g., Li et al, ; Norman et al, ].…”

Section: Discussionmentioning

confidence: 90%

Background atmospheric sulfate deposition at a remote alpine site in the Southern Canadian Rocky Mountains

et al. 2015

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We report observations of stable isotope ratios and ion concentrations from seasonal snowpack and summer bulk precipitation from remote alpine sites in the Southern Canadian Rocky Mountains. Spatial deposition patterns for sulfur (S) and δ34S‐SO42− values indicate dominantly distant sources with little impact from local to regional pollution. Comparable S loads and total snowpack δ34S‐SO42− values for glacier snowpack indicates S emissions were well mixed prior to dry deposition or incorporation into snowfall. A uniform S load and similar δ34S‐SO42− values in a detailed study of summer bulk precipitation implies well‐mixed distant emissions. We interpret the deposited 0.9 kg S ha−1yr−1 as atmospheric background deposition in midlatitude Western Canada. This study will improve calculations for sites impacted by point source emissions and provide a baseline for attributing changes associated with climate change, industrialization, and urban growth. Field evidence from this study supports theoretical and laboratory research on the relative importance of oxidation pathways on atmospheric δ34S‐SO42− values for long‐range transported sulfate. δ34S‐SO42− of the dominant S source in summer bulk precipitation (~ +2‰) versus snowpack (≥ +9‰) cannot be explained by seasonal emission sources, temperature effects on fractionation, or Rayleigh distillation. The study supports a seasonal difference in the relative importance of the different SO2 to SO42− oxidation pathways with homogeneous oxidation by OH and heterogeneous oxidation by H2O2 most important in summer, and O2 catalyzed by transition metal ions in a radical chain reaction pathway more significant in winter.

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Sulfur isotope homogeneity of oceanic DMSP and DMS

Cited by 82 publications

References 30 publications

Sulfur isotopic composition of surface snow along a latitudinal transect in East Antarctica

Sulfur isotopic composition of surface snow along a latitudinal transect in East Antarctica

Stable Isotopic and Chemical Characteristics of Bulk Aerosols during Winter and Summer Seasons at a Station in Western Coast of India (Goa)

Background atmospheric sulfate deposition at a remote alpine site in the Southern Canadian Rocky Mountains

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