Deposition, recycling and archival of nitrate stable isotopes between the air-snow  interface: comparison between Dronning Maud Land and Dome C, Antarctica

Winton, V. Holly L.; Ming, Alison; Caillon, Nicolas; Hauge, Lisa Lolk; Jones, A. E.; Savarino, Joël; Yang, Xin; Frey, M. M.

doi:10.5194/acp-2019-669

Cited by 9 publications

(54 citation statements)

References 62 publications

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“…We do not see this positive correlation in the background variability in the ISOL‐ICE ice core (Figures 4c and 4e; R 2 =0.04, p <10 −3 with data from 5 years either side of the volcanic eruptions is not used). The

δ^{15} normalN false({NO}_{3}^{-} false)

is weakly anticorrelated to the accumulation rate (Figure 4d and 4e); R 2 =0.2, p <10 −4 again with 5 years either side of the volcanic eruptions removed) as would be expected from spatial transects across Antarctica (Erbland et al, 2015, 2013; Noro et al, 2018; Shi et al, 2018), and sensitivity tests of variable accumulation rate on the

δ^{15} normalN false({NO}_{3}^{-} false)

signal at the DML site (Winton, Ming et al, 2019).…”

Section: Resultsmentioning

confidence: 59%

“…The accumulation rate is variable at the DML site (2.5 to 11 cm year −1 water equivalent) (Oerter et al, 2000; Sommer et al, 2000) and there is no trend over the last 1,000 years. We speculate that changes in the accumulation rate will lead to changes in e ‐folding depth over time which can account for part of the variability of the

δ^{15} normalN false({NO}_{3}^{-} false)

signal (Winton, Ming et al, 2019), with a smaller contribution from extreme precipitation events (Turner et al, 2019). The e ‐folding depth of the local snowpack depends on snow physical properties and contributes to the

δ^{15} normalN false({NO}_{3}^{-} false)

signal eventually preserved in local firn and ice (Winton, Ming et al, 2019).…”

Section: Resultsmentioning

confidence: 99%

“…We speculate that changes in the accumulation rate will lead to changes in e ‐folding depth over time which can account for part of the variability of the

δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

signal eventually preserved in local firn and ice (Winton, Ming et al, 2019). Unfortunately, the variability of e ‐folding depth in the past is not known and may be a source of additional noise in the

δ^{15} normalN false({NO}_{3}^{-} false)

signal.…”

Section: Resultsmentioning

confidence: 99%

“…Winton, Ming et al (2019) carried out a comprehensive field and modeling study of the air‐snow transfer of

{NO}_{3}^{-}

at the low snowfall accumulation site at Kohnnen Station in Dronning Maud Land (DML), East Antarctica as part of the ISOL‐ICE (ISotopic constraints of past Ozone Layer in polar ICE) project. At the DML site,

{NO}_{3}^{-}

is recycled 3 times before it is archived in the snowpack below a depth of 15 cm and within 0.75 year.…”

Section: Introductionmentioning

confidence: 99%

“…Sensitivity analysis with a 1‐D air‐snow model, TRANSITS (TRansfer of Atmospheric Nitrate Stable Isotopes To the Snow) (Erbland et al, 2015), of

δ^{15} normalN false({NO}_{3}^{-} false)

at DML showed that the dominant factors controlling the archived

δ^{15} normalN false({NO}_{3}^{-} false)

signature are the snow accumulation rate and e ‐folding depth of the surface snowpack for incident UV, with a smaller role from changes in the snowfall timing and TCO. The Winton, Ming et al (2019) study sets the framework for the interpretation of a

δ^{15} normalN false({NO}_{3}^{-} false)

record from the new ISOL‐ICE ice core drilled in January 2017 at Kohnen Station in DML, henceforth referred to as the DML site, following the terminology in Winton, Ming et al (2019). The DML region experiences low annual accumulation rates (<10 g cm −2 year −1 ) but ice cores from the area still record seasonal‐, centennial‐, and millennial‐scale variability in glaciochemistry (Göktas et al, 2002; Oerter et al, 2000; Sommer et al, 2000), as well as highly resolved tropical volcanic eruptions (Hofstede et al, 2004; Severi et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

et al. 2020

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Major tropical volcanic eruptions have emitted large quantities of stratospheric sulfate and are potential sources of stratospheric chlorine although this is less well constrained by observations. This study combines model and ice core analysis to investigate past changes in total column ozone. Historic eruptions are good analogs for future eruptions as stratospheric chlorine levels have been decreasing since the year 2000. We perturb the preindustrial atmosphere of a chemistry‐climate model with high and low emissions of sulfate and chlorine. The sign of the resulting Antarctic ozone change is highly sensitive to the background stratospheric chlorine loading. In the first year, the response is dynamical, with ozone increases over Antarctica. In the high HCl (2 Tg emission) experiment, the injected chlorine is slowly transported to the polar regions with subsequent chemical ozone depletion. These model results are then compared to measurements of the stable nitrogen isotopic ratio, δ15normalNfalse(NO3−false), from a low snow accumulation Antarctic ice core from Dronning Maud Land (recovered in 2016–2017). We expect ozone depletion to lead to increased surface ultraviolet (UV) radiation, enhanced air‐snow nitrate photochemistry and enrichment in δ15normalNfalse(NO3−false) in the ice core. We focus on the possible ozone depletion event that followed the largest volcanic eruption in the past 1,000 years, Samalas in 1257. The characteristic sulfate signal from this volcano is present in the ice core but the variability in δ15normalNfalse(NO3−false) dominates any signal arising from changes in ultraviolet from ozone depletion. Prolonged complete ozone removal following this eruption is unlikely to have occurred over Antarctica.

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δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

signal at the DML site (Winton, Ming et al, 2019).…”

Section: Resultsmentioning

confidence: 59%

δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

signal eventually preserved in local firn and ice (Winton, Ming et al, 2019).…”

Section: Resultsmentioning

confidence: 99%

“…We speculate that changes in the accumulation rate will lead to changes in e ‐folding depth over time which can account for part of the variability of the

δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

signal.…”

Section: Resultsmentioning

confidence: 99%

“…Winton, Ming et al (2019) carried out a comprehensive field and modeling study of the air‐snow transfer of

{NO}_{3}^{-}

{NO}_{3}^{-}

is recycled 3 times before it is archived in the snowpack below a depth of 15 cm and within 0.75 year.…”

Section: Introductionmentioning

confidence: 99%

“…Sensitivity analysis with a 1‐D air‐snow model, TRANSITS (TRansfer of Atmospheric Nitrate Stable Isotopes To the Snow) (Erbland et al, 2015), of

δ^{15} normalN false({NO}_{3}^{-} false)

at DML showed that the dominant factors controlling the archived

δ^{15} normalN false({NO}_{3}^{-} false)

δ^{15} normalN false({NO}_{3}^{-} false)

Section: Introductionmentioning

confidence: 99%

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Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

et al. 2020

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Increasing Accumulation of Perfluorocarboxylate Contaminants Revealed in an Antarctic Firn Core (1958–2017)

Garnett

Halsall

Winton

et al. 2022

Environ. Sci. Technol.

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Perfluoroalkyl acids (PFAAs) are synthetic chemicals with a variety of industrial and consumer applications that are now widely distributed in the global environment. Here, we report the measurement of six perfluorocarboxylates (PFCA, C 4 –C 9 ) in a firn (granular compressed snow) core collected from a non-coastal, high-altitude site in Dronning Maud Land in Eastern Antarctica. Snow accumulation of the extracted core dated from 1958 to 2017, a period coinciding with the advent, use, and geographical shift in the global industrial production of poly/perfluoroalkylated substances, including PFAA. We observed increasing PFCA accumulation in snow over this time period, with chemical fluxes peaking in 2009–2013 for perfluorooctanoate (PFOA, C 8 ) and nonanoate (PFNA, C 9 ) with little evidence of a decline in these chemicals despite supposed recent global curtailments in their production. In contrast, the levels of perfluorobutanoate (PFBA, C 4 ) increased markedly since 2000, with the highest fluxes in the uppermost snow layers. These findings are consistent with those previously made in the Arctic and can be attributed to chlorofluorocarbon replacements (e.g., hydrofluoroethers) as an inadvertent consequence of global regulation.

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New Estimation of the NO_x Snow‐Source on the Antarctic Plateau

et al. 2021

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To fully decipher the role of nitrate photolysis on the atmospheric oxidative capacity in snow‐covered regions, NOx flux must be determined with more precision than existing estimates. Here, we introduce a method based on dynamic flux chamber measurements for evaluating the NOx production by photolysis of snowpack nitrate in Antarctica. Flux chamber experiments were conducted for the first time in Antarctica, at the French‐Italian station Concordia, Dome C (75°06'S, 123°20’E, 3233 m a.s.l) during the 2019–2020 summer campaign. Measurements were gathered with several snow samples of different ages ranging from newly formed drifted snow to 6‐year‐old firn. Contrary to existing literature expectations, the daily average photolysis rate coefficient, JNO3¯, did not significantly vary between differently aged snow samples, suggesting that the photolabile nitrate in snow behaves as a single‐family source with common photochemical properties, where a JNO3¯ = (2.37 ± 0.35) × 10−8 s−1 (1σ) has been calculated from December 10th 2019 to January 7th 2020. At Dome C summer daily average NOx flux, FNOx, based on measured NOx production rates was estimated to be (4.3 ± 1.2) × 108 molecules cm−2 s−1, which is 1.5–7 times less than the net NOx flux observed previously above snow at Dome C using the gradient flux method. Using these results, we extrapolated an annual continental snow sourced NOx budget of 0.017 ± 0.003 Tg·N y−1, ∼2 times the nitrogen budget, (N‐budget), of the stratospheric denitrification previously estimated for Antarctica. These quantifications of nitrate photolysis using flux chamber experiments provide a road‐map toward a new parameterization of the σNO3−(λ,0.25emT)ϕ(T,0.25empH) product that can improve future global and regional models of atmospheric chemistry.

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Deposition, recycling and archival of nitrate stable isotopes between the air-snow interface: comparison between Dronning Maud Land and Dome C, Antarctica

Cited by 9 publications

References 62 publications

Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

Increasing Accumulation of Perfluorocarboxylate Contaminants Revealed in an Antarctic Firn Core (1958–2017)

New Estimation of the NO_x Snow‐Source on the Antarctic Plateau

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Deposition, recycling and archival of nitrate stable isotopes between the air-snow interface: comparison between Dronning Maud Land and Dome C, Antarctica

Cited by 9 publications

References 62 publications

Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

Stratospheric Ozone Changes From Explosive Tropical Volcanoes: Modeling and Ice Core Constraints

Increasing Accumulation of Perfluorocarboxylate Contaminants Revealed in an Antarctic Firn Core (1958–2017)

New Estimation of the NOx Snow‐Source on the Antarctic Plateau

Contact Info

Product

Resources

About

New Estimation of the NO_x Snow‐Source on the Antarctic Plateau