Sulfur isotopes quantify the impact of anthropogenic activities on industrial-era Arctic sulfate in a Greenland ice core

Jongebloed, U. A.; Schauer, Andrew J.; Hattori, Shohei; Cole‐Dai, Jihong; Larrick, C. G.; Salimi, S.; Edouard, S. R.; Geng, Lei; Alexander, Becky

doi:10.1088/1748-9326/acdc3d

Cited by 6 publications

(7 citation statements)

References 44 publications

(70 reference statements)

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“…δ 34 S emission is assumed to be the same as primary sulfate (δ 34 S primary = +4.7(±0.6)‰) since sulfur isotope fractionation of fuel oil during high-temperature combustion is expected to be minimal . This is consistent with previous studies that assume primary sulfate from combustion retains the δ 34 S(SO 4 2– ) signature of the sulfur source. − We assume that Fairbanks is a closed system, where long-range transport of biogenic and volcanic sulfur can be neglected. This assumption is further supported by prior literature showing that the pollution layer is often confined lower than 20 meters in Fairbanks with the highest PM 2.5 concentrations below 3 meters. ,,, On-road mobile sampling performed by Robinson et al (2023) found the lowest PM 2.5 concentrations at the top of hills and asserted that residential neighborhoods were unequivocally the dominant PM source. δ 34 S false( normalSO 4 2 − false) false( ‰ false) = f primary × δ 34 S primary + false( 1 − normalf normalprimary false) × false( δ 34 normalS normalemission − ( f H 2 O 2 · ε H 2 O 2 + f O 3 · ε …”

Section: Methodsmentioning

confidence: 54%

Primary Sulfate Is the Dominant Source of Particulate Sulfate during Winter in Fairbanks, Alaska

Moon,

Jongebloed,

Dingilian

et al. 2023

ACS EST Air

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Within and surrounding high-latitude cities, poor air quality disturbs Arctic ecosystems, influences the climate, and harms human health. The Fairbanks North Star Borough has wintertime particulate matter (PM) concentrations that exceed the Environmental Protection Agency's (EPA) threshold for public health. Particulate sulfate (SO 4 2− ) is the most abundant inorganic species and contributes approximately 20% of the total PM mass in Fairbanks, but air quality models underestimate observed sulfate concentrations. Here we quantify sulfate sources using sizeresolved δ 34 S(SO 4 2− ), δ 18 O(SO 4 2− ), and Δ 17 O(SO 4 2−) of particulate sulfate in Fairbanks from January 18th to February 25th, 2022 using a Bayesian isotope mixing model. Primary sulfate contributes 62 ± 12% of the total sulfate mass on average. Most primary sulfate is found in the size bin with a particle diameter < 0.7 μm, which contains 90 ±5% of total sulfate mass and poses the greatest risk to human health. Oxidation by all secondary formation pathways combined contributes 38 ± 12% of total sulfate mass on average, indicating that secondary sulfate formation is inefficient in this cold, dark environment. On average, the dominant secondary sulfate formation pathways are oxidation by H 2 O 2 (13 ± 6%), O 3 (8 ± 4%), and NO 2 (8 ± 3%). These findings will inform mitigation strategies to improve air quality and public health in Fairbanks and possibly other high-latitude urban areas during winter.

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Section: Methodsmentioning

confidence: 54%

Primary Sulfate Is the Dominant Source of Particulate Sulfate during Winter in Fairbanks, Alaska

Moon,

Jongebloed,

Dingilian

et al. 2023

ACS EST Air

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“…We measure concentrations of MSA and sulfate (SO 4 2– ) and sulfur isotopes (δ 34 S) of sulfate in ice core samples from 1200 to 2006 CE ( Materials and Methods ). Sulfur isotopes are used to estimate the relative contribution from each of the main sources of Arctic sulfate: DMS, volcanic, and anthropogenic emissions ( 30 – 35 ). The influence of sea salt is subtracted from the sulfate concentration and sulfur isotope measurements ( Materials and Methods ).…”

Section: Resultsmentioning

confidence: 99%

“…where f anthro is the fraction of anthropogenic sulfate in the sample and δ 34 S anthro is the anthropogenic sulfur isotopic source signature, which is estimated to be +2.9 ± 0.3‰ [ SI Appendix, Supplementary Text S3 , ( 35 )]. We assume that source signatures (δ 34 S bio , δ 34 S volc , and δ 34 S anthro ) are relatively constant over time ( SI Appendix, Supplementary Text S3 ).…”

Section: Resultsmentioning

confidence: 99%

“…The isotopic source signatures of volcanic, DMS-derived biogenic, and anthropogenic sulfur are determined via two methods described in detail in Jongebloed et al ( 34 , 35 ) and SI Appendix, Supplementary Text S3 . The first method is a Keeling Plot, which is the regression of δ 34 S(nssSO 4 2– ) measurements against the reciprocal of the concentration measurements (1/[nssSO 4 2– ]) ( 36 – 38 ) and is used to determine δ 34 S volc and δ 34 S anthro ( SI Appendix , Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Other sulfate sources to the Arctic and global atmosphere include volcanic degassing, sea salt, and anthropogenic sources, including fossil fuel combustion and metal smelting ( 29 ). Here, we leverage the distinct isotopic composition of DMS-derived biogenic sulfur compared to that of other sources ( 30 – 35 ) to quantify the contribution of DMS to total sulfate in a central Greenland ice core covering 1200 to 2006 CE. We compare this DMS-derived biogenic sulfate to measurements of MSA from the same ice core samples to assess MSA’s utility as a proxy for DMS emissions and to examine trends in DMS-derived biogenic sulfur aerosol over this time period.…”

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confidence: 99%

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Industrial-era decline in Arctic methanesulfonic acid is offset by increased biogenic sulfate aerosol

Jongebloed,

Schauer,

Cole-Dai

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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Marine phytoplankton are primary producers in ocean ecosystems and emit dimethyl sulfide (DMS) into the atmosphere. DMS emissions are the largest biological source of atmospheric sulfur and are one of the largest uncertainties in global climate modeling. DMS is oxidized to methanesulfonic acid (MSA), sulfur dioxide, and hydroperoxymethyl thioformate, all of which can be oxidized to sulfate. Ice core records of MSA are used to investigate past DMS emissions but rely on the implicit assumption that the relative yield of oxidation products from DMS remains constant. However, this assumption is uncertain because there are no long-term records that compare MSA to other DMS oxidation products. Here, we share the first long-term record of both MSA and DMS-derived biogenic sulfate concentration in Greenland ice core samples from 1200 to 2006 CE. While MSA declines on average by 0.2 µg S kg –1 over the industrial era, biogenic sulfate from DMS increases by 0.8 µg S kg –1 . This increasing biogenic sulfate contradicts previous assertions of declining North Atlantic primary productivity inferred from decreasing MSA concentrations in Greenland ice cores over the industrial era. The changing ratio of MSA to biogenic sulfate suggests that trends in MSA could be caused by time-varying atmospheric chemistry and that MSA concentrations alone should not be used to infer past primary productivity.

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Latitudinal difference in sulfate formation from methanesulfonate oxidation in Antarctic snow imprinted on 17O-excess signature

Hattori,

Ishino,

Suzuki

et al. 2024

Applied Geochemistry

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Sulfur isotopes quantify the impact of anthropogenic activities on industrial-era Arctic sulfate in a Greenland ice core

Cited by 6 publications

References 44 publications

Primary Sulfate Is the Dominant Source of Particulate Sulfate during Winter in Fairbanks, Alaska

Primary Sulfate Is the Dominant Source of Particulate Sulfate during Winter in Fairbanks, Alaska

Industrial-era decline in Arctic methanesulfonic acid is offset by increased biogenic sulfate aerosol

Latitudinal difference in sulfate formation from methanesulfonate oxidation in Antarctic snow imprinted on 17O-excess signature

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