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Global impacts of tropospheric halogens (Cl, Br, I) on oxidants and composition in GEOS-Chem

Sherwen, Tomás ; Schmidt, Johan A. ; Evans, Mat J. ; [weitere]

Copernicus GmbH ; 2016

In: Atmospheric Chemistry and Physics Vol. 16, No. 18 ( 2016-09-29), p. 12239-12271

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 16, No. 18 ( 2016-09-29), p. 12239-12271

Kurzfassung: Abstract. We present a simulation of the global present-day composition of the troposphere which includes the chemistry of halogens (Cl, Br, I). Building on previous work within the GEOS-Chem model we include emissions of inorganic iodine from the oceans, anthropogenic and biogenic sources of halogenated gases, gas phase chemistry, and a parameterised approach to heterogeneous halogen chemistry. Consistent with Schmidt et al. (2016) we do not include sea-salt debromination. Observations of halogen radicals (BrO, IO) are sparse but the model has some skill in reproducing these. Modelled IO shows both high and low biases when compared to different datasets, but BrO concentrations appear to be modelled low. Comparisons to the very sparse observations dataset of reactive Cl species suggest the model represents a lower limit of the impacts of these species, likely due to underestimates in emissions and therefore burdens. Inclusion of Cl, Br, and I results in a general improvement in simulation of ozone (O3) concentrations, except in polar regions where the model now underestimates O3 concentrations. Halogen chemistry reduces the global tropospheric O3 burden by 18.6 %, with the O3 lifetime reducing from 26 to 22 days. Global mean OH concentrations of 1.28  ×  106 molecules cm−3 are 8.2 % lower than in a simulation without halogens, leading to an increase in the CH4 lifetime (10.8 %) due to OH oxidation from 7.47 to 8.28 years. Oxidation of CH4 by Cl is small (∼  2 %) but Cl oxidation of other VOCs (ethane, acetone, and propane) can be significant (∼  15–27 %). Oxidation of VOCs by Br is smaller, representing 3.9 % of the loss of acetaldehyde and 0.9 % of the loss of formaldehyde.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-16-12239-2016

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2016

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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Global inorganic nitrate production mechanisms: comparison of a global model with nitrate isotope observations

Alexander, Becky ; Sherwen, Tomás ; Holmes, Christopher D. ; [weitere]

Copernicus GmbH ; 2020

In: Atmospheric Chemistry and Physics Vol. 20, No. 6 ( 2020-03-31), p. 3859-3877

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 20, No. 6 ( 2020-03-31), p. 3859-3877

Kurzfassung: Abstract. The formation of inorganic nitrate is the main sink for nitrogen oxides (NOx = NO + NO2). Due to the importance of NOx for the formation of tropospheric oxidants such as the hydroxyl radical (OH) and ozone, understanding the mechanisms and rates of nitrate formation is paramount for our ability to predict the atmospheric lifetimes of most reduced trace gases in the atmosphere. The oxygen isotopic composition of nitrate (Δ17O(nitrate)) is determined by the relative importance of NOx sinks and thus can provide an observational constraint for NOx chemistry. Until recently, the ability to utilize Δ17O(nitrate) observations for this purpose was hindered by our lack of knowledge about the oxygen isotopic composition of ozone (Δ17O(O3)). Recent and spatially widespread observations of Δ17O(O3) motivate an updated comparison of modeled and observed Δ17O(nitrate) and a reassessment of modeled nitrate formation pathways. Model updates based on recent laboratory studies of heterogeneous reactions render dinitrogen pentoxide (N2O5) hydrolysis as important as NO2 + OH (both 41 %) for global inorganic nitrate production near the surface (below 1 km altitude). All other nitrate production mechanisms individually represent less than 6 % of global nitrate production near the surface but can be dominant locally. Updated reaction rates for aerosol uptake of NO2 result in significant reduction of nitrate and nitrous acid (HONO) formed through this pathway in the model and render NO2 hydrolysis a negligible pathway for nitrate formation globally. Although photolysis of aerosol nitrate may have implications for NOx, HONO, and oxidant abundances, it does not significantly impact the relative importance of nitrate formation pathways. Modeled Δ17O(nitrate) (28.6±4.5 ‰) compares well with the average of a global compilation of observations (27.6±5.0 ‰) when assuming Δ17O(O3) = 26 ‰, giving confidence in the model's representation of the relative importance of ozone versus HOx (= OH + HO2 + RO2) in NOx cycling and nitrate formation on the global scale.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-20-3859-2020

DOI: 10.5194/acp-20-3859-2020-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2020

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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3

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Global tropospheric halogen (Cl, Br, I) chemistry and its impact on oxidants

Wang, Xuan ; Jacob, Daniel J. ; Downs, William ; [weitere]

Copernicus GmbH ; 2021

In: Atmospheric Chemistry and Physics Vol. 21, No. 18 ( 2021-09-21), p. 13973-13996

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 21, No. 18 ( 2021-09-21), p. 13973-13996

Kurzfassung: Abstract. We present an updated mechanism for tropospheric halogen (Cl + Br + I) chemistry in the GEOS-Chem global atmospheric chemical transport model and apply it to investigate halogen radical cycling and implications for tropospheric oxidants. Improved representation of HOBr heterogeneous chemistry and its pH dependence in our simulation leads to less efficient recycling and mobilization of bromine radicals and enables the model to include mechanistic sea salt aerosol debromination without generating excessive BrO. The resulting global mean tropospheric BrO mixing ratio is 0.19 ppt (parts per trillion), lower than previous versions of GEOS-Chem. Model BrO shows variable consistency and biases in comparison to surface and aircraft observations in marine air, which are often near or below the detection limit. The model underestimates the daytime measurements of Cl2 and BrCl from the ATom aircraft campaign over the Pacific and Atlantic, which if correct would imply a very large missing primary source of chlorine radicals. Model IO is highest in the marine boundary layer and uniform in the free troposphere, with a global mean tropospheric mixing ratio of 0.08 ppt, and shows consistency with surface and aircraft observations. The modeled global mean tropospheric concentration of Cl atoms is 630 cm−3, contributing 0.8 % of the global oxidation of methane, 14 % of ethane, 8 % of propane, and 7 % of higher alkanes. Halogen chemistry decreases the global tropospheric burden of ozone by 11 %, NOx by 6 %, and OH by 4 %. Most of the ozone decrease is driven by iodine-catalyzed loss. The resulting GEOS-Chem ozone simulation is unbiased in the Southern Hemisphere but too low in the Northern Hemisphere.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-21-13973-2021

DOI: 10.5194/acp-21-13973-2021-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2021

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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Importance of reactive halogens in the tropical marine atmosphere: a regional modelling study using WRF-Chem

Badia, Alba ; Reeves, Claire E. ; Baker, Alex R. ; [weitere]

Copernicus GmbH ; 2019

In: Atmospheric Chemistry and Physics Vol. 19, No. 5 ( 2019-03-12), p. 3161-3189

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 19, No. 5 ( 2019-03-12), p. 3161-3189

Kurzfassung: Abstract. This study investigates the impact of reactive halogen species (RHS, containing chlorine (Cl), bromine (Br) or iodine (I)) on atmospheric chemistry in the tropical troposphere and explores the sensitivity to uncertainties in the fluxes of RHS to the atmosphere and their chemical processing. To do this, the regional chemistry transport model WRF-Chem has been extended to include Br and I, as well as Cl chemistry for the first time, including heterogeneous recycling reactions involving sea-salt aerosol and other particles, reactions of Br and Cl with volatile organic compounds (VOCs), along with oceanic emissions of halocarbons, VOCs and inorganic iodine. The study focuses on the tropical east Pacific using field observations from the Tropical Ocean tRoposphere Exchange of Reactive halogen species and Oxygenated VOC (TORERO) campaign (January–February 2012) to evaluate the model performance. Including all the new processes, the model does a reasonable job reproducing the observed mixing ratios of bromine oxide (BrO) and iodine oxide (IO), albeit with some discrepancies, some of which can be attributed to difficulties in the model's ability to reproduce the observed halocarbons. This is somewhat expected given the large uncertainties in the air–sea fluxes of the halocarbons in a region where there are few observations of their seawater concentrations. We see a considerable impact on the inorganic bromine (Bry) partitioning when heterogeneous chemistry is included, with a greater proportion of the Bry in active forms such as BrO, HOBr and dihalogens. Including debromination of sea salt increases BrO slightly throughout the free troposphere, but in the tropical marine boundary layer, where the sea-salt particles are plentiful and relatively acidic, debromination leads to overestimation of the observed BrO. However, it should be noted that the modelled BrO was extremely sensitive to the inclusion of reactions between Br and the oxygenated VOCs (OVOCs), which convert Br to HBr, a far less reactive form of Bry. Excluding these reactions leads to modelled BrO mixing ratios greater than observed. The reactions between Br and aldehydes were found to be particularly important, despite the model underestimating the amount of aldehydes observed in the atmosphere. There are only small changes to the inorganic iodine (Iy) partitioning and IO when the heterogeneous reactions, primarily on sea salt, are included. Our model results show that tropospheric Ox loss due to halogens ranges between 25 % and 60 %. Uncertainties in the heterogeneous chemistry accounted for a small proportion of this range (25 % to 31 %). This range is in good agreement with other estimates from state-of-the-art atmospheric chemistry models. The upper bound is found when reactions between Br and Cl with VOCs are not included and, consequently, Ox loss by BrOx, ClOx and IOx cycles is high (60 %). With the inclusion of halogens in the troposphere, O3 is reduced by 7 ppbv on average. However, when reactions between Br and Cl with VOCs are not included, O3 is much lower than observed. Therefore, the tropospheric Ox budget is highly sensitive to the inclusion of halogen reactions with VOCs and to the uncertainties in current understanding of these reactions and the abundance of VOCs in the remote marine atmosphere.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-19-3161-2019

DOI: 10.5194/acp-19-3161-2019-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2019

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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Evaluating the impact of blowing-snow sea salt aerosol on springtime BrO and O〈sub〉3〈/sub〉 in the Arctic

Huang, Jiayue ; Jaeglé, Lyatt ; Chen, Qianjie ; [weitere]

Copernicus GmbH ; 2020

In: Atmospheric Chemistry and Physics Vol. 20, No. 12 ( 2020-06-25), p. 7335-7358

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 20, No. 12 ( 2020-06-25), p. 7335-7358

Kurzfassung: Abstract. We use the GEOS-Chem chemical transport model to examine the influence of bromine release from blowing-snow sea salt aerosol (SSA) on springtime bromine activation and O3 depletion events (ODEs) in the Arctic lower troposphere. We evaluate our simulation against observations of tropospheric BrO vertical column densities (VCDtropo) from the GOME-2 (second Global Ozone Monitoring Experiment) and Ozone Monitoring Instrument (OMI) spaceborne instruments for 3 years (2007–2009), as well as against surface observations of O3. We conduct a simulation with blowing-snow SSA emissions from first-year sea ice (FYI; with a surface snow salinity of 0.1 psu) and multi-year sea ice (MYI; with a surface snow salinity of 0.05 psu), assuming a factor of 5 bromide enrichment of surface snow relative to seawater. This simulation captures the magnitude of observed March–April GOME-2 and OMI VCDtropo to within 17 %, as well as their spatiotemporal variability (r=0.76–0.85). Many of the large-scale bromine explosions are successfully reproduced, with the exception of events in May, which are absent or systematically underpredicted in the model. If we assume a lower salinity on MYI (0.01 psu), some of the bromine explosions events observed over MYI are not captured, suggesting that blowing snow over MYI is an important source of bromine activation. We find that the modeled atmospheric deposition onto snow-covered sea ice becomes highly enriched in bromide, increasing from enrichment factors of ∼5 in September–February to 10–60 in May, consistent with composition observations of freshly fallen snow. We propose that this progressive enrichment in deposition could enable blowing-snow-induced halogen activation to propagate into May and might explain our late-spring underestimate in VCDtropo. We estimate that the atmospheric deposition of SSA could increase snow salinity by up to 0.04 psu between February and April, which could be an important source of salinity for surface snow on MYI as well as FYI covered by deep snowpack. Inclusion of halogen release from blowing-snow SSA in our simulations decreases monthly mean Arctic surface O3 by 4–8 ppbv (15 %–30 %) in March and 8–14 ppbv (30 %–40 %) in April. We reproduce a transport event of depleted O3 Arctic air down to 40∘ N observed at many sub-Arctic surface sites in early April 2007. While our simulation captures 25 %–40 % of the ODEs observed at coastal Arctic surface sites, it underestimates the magnitude of many of these events and entirely misses 60 %–75 % of ODEs. This difficulty in reproducing observed surface ODEs could be related to the coarse horizontal resolution of the model, the known biases in simulating Arctic boundary layer exchange processes, the lack of detailed chlorine chemistry, and/or the fact that we did not include direct halogen activation by snowpack chemistry.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-20-7335-2020

DOI: 10.5194/acp-20-7335-2020-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2020

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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6

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Fundamental oxidation processes in the remote marine atmosphere investigated using the NO–NO 2 –O 3 photostationary state

Andersen, Simone T. ; Nelson, Beth S. ; Read, Katie A. ; [weitere]

Copernicus GmbH ; 2022

In: Atmospheric Chemistry and Physics Vol. 22, No. 24 ( 2022-12-15), p. 15747-15765

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 22, No. 24 ( 2022-12-15), p. 15747-15765

Kurzfassung: Abstract. The photostationary state (PSS) equilibrium between NO and NO2 is reached within minutes in the atmosphere and can be described by the PSS parameter, φ. Deviations from expected values of φ have previously been used to infer missing oxidants in diverse locations, from highly polluted regions to the extremely clean conditions observed in the remote marine boundary layer (MBL), and have been interpreted as missing understanding of fundamental photochemistry. Here, contrary to these previous observations, we observe good agreement between PSS-derived NO2 ([NO2]PSS ext.), calculated from measured NO, O3, and jNO2 and photochemical box model predictions of peroxy radicals (RO2 and HO2), and observed NO2 ([NO2]Obs.) in extremely clean air containing low levels of CO (〈90 ppbV) and VOCs (volatile organic compounds). However, in clean air containing small amounts of aged pollution (CO 〉 100 ppbV), we observed higher levels of NO2 than inferred from the PSS, with [NO2]Obs. / [NO2]PSS ext. of 1.12–1.68 (25th–75th percentile), implying underestimation of RO2 radicals by 18.5–104 pptV. Potential NO2 measurement artefacts have to be carefully considered when comparing PSS-derived NO2 to observed NO2, but we show that the NO2 artefact required to explain the deviation would have to be ∼ 4 times greater than the maximum calculated from known interferences. If the additional RO2 radicals inferred from the PSS convert NO to NO2 with a reaction rate equivalent to that of methyl peroxy radicals (CH3O2), then the calculated net ozone production rate (NOPR, ppbV h−1) including these additional oxidants is similar to the average change in O3 observed, within estimated uncertainties, once halogen oxide chemistry is accounted for. This implies that such additional peroxy radicals cannot be excluded as a missing oxidant in clean marine air containing aged pollution and that modelled RO2 concentrations are significantly underestimated under these conditions.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-22-15747-2022

DOI: 10.5194/acp-22-15747-2022-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2022

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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The atmospheric impacts of monoterpene ozonolysis on global stabilised Criegee intermediate budgets and SO〈sub〉2〈/sub〉 oxidation: experiment, theory and modelling

Newland, Mike J. ; Rickard, Andrew R. ; Sherwen, Tomás ; [weitere]

Copernicus GmbH ; 2018

In: Atmospheric Chemistry and Physics Vol. 18, No. 8 ( 2018-05-02), p. 6095-6120

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 18, No. 8 ( 2018-05-02), p. 6095-6120

Kurzfassung: Abstract. The gas-phase reaction of alkenes with ozone is known to produce stabilised Criegee intermediates (SCIs). These biradical/zwitterionic species have the potential to act as atmospheric oxidants for trace pollutants such as SO2, enhancing the formation of sulfate aerosol with impacts on air quality and health, radiative transfer and climate. However, the importance of this chemistry is uncertain as a consequence of limited understanding of the abundance and atmospheric fate of SCIs. In this work we apply experimental, theoretical and numerical modelling methods to quantify the atmospheric impacts, abundance and fate of the structurally diverse SCIs derived from the ozonolysis of monoterpenes, the second most abundant group of unsaturated hydrocarbons in the atmosphere. We have investigated the removal of SO2 by SCIs formed from the ozonolysis of three atmospherically important monoterpenes (α-pinene, β-pinene and limonene) in the presence of varying amounts of water vapour in large-scale simulation chamber experiments that are representative of boundary layer conditions. The SO2 removal displays a clear dependence on water vapour concentration, but this dependence is not linear across the range of [H2O] explored. At low [H2O] a strong dependence of SO2 removal on [H2O] is observed, while at higher [H2O] this dependence becomes much weaker. This is interpreted as being caused by the production of a variety of structurally (and hence chemically) different SCIs in each of the systems studied, which displayed different rates of reaction with water and of unimolecular rearrangement or decomposition. The determined rate constants, k(SCI+H2O), for those SCIs that react primarily with H2O range from 4 to 310  ×  10−15 cm3 s−1. For those SCIs that predominantly react unimolecularly, determined rates range from 130 to 240 s−1. These values are in line with previous results for the (analogous) stereo-specific SCI system of syn-/anti-CH3CHOO. The experimental results are interpreted through theoretical studies of the SCI unimolecular reactions and bimolecular reactions with H2O, characterised for α-pinene and β-pinene at the M06-2X/aug-cc-pVTZ level of theory. The theoretically derived rates agree with the experimental results within the uncertainties. A global modelling study, applying the experimental results within the GEOS-Chem chemical transport model, suggests that 〉 97 % of the total monoterpene-derived global SCI burden is comprised of SCIs with a structure that determines that they react slowly with water and that their atmospheric fate is dominated by unimolecular reactions. Seasonally averaged boundary layer concentrations of monoterpene-derived SCIs reach up to 1.4  ×  104 cm−3 in regions of elevated monoterpene emissions in the tropics. Reactions of monoterpene-derived SCIs with SO2 account for 〈 1 % globally but may account for up to 60 % of the gas-phase SO2 removal over areas of tropical forests, with significant localised impacts on the formation of sulfate aerosol and hence the lifetime and distribution of SO2.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-18-6095-2018

DOI: 10.5194/acp-18-6095-2018-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2018

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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BrO and inferred Br〈sub〉〈i〉y〈/i〉〈/sub〉 profiles over the western Pacific: relevance of inorganic bromine sources and a Br〈sub〉〈i〉y〈/i〉〈/sub〉 minimum in the aged tropical tropopause layer

Koenig, Theodore K. ; Volkamer, Rainer ; Baidar, Sunil ; [weitere]

Copernicus GmbH ; 2017

In: Atmospheric Chemistry and Physics Vol. 17, No. 24 ( 2017-12-22), p. 15245-15270

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In: Atmospheric Chemistry and Physics, Copernicus GmbH, Vol. 17, No. 24 ( 2017-12-22), p. 15245-15270

Kurzfassung: Abstract. We report measurements of bromine monoxide (BrO) and use an observationally constrained chemical box model to infer total gas-phase inorganic bromine (Bry) over the tropical western Pacific Ocean (tWPO) during the CONTRAST field campaign (January–February 2014). The observed BrO and inferred Bry profiles peak in the marine boundary layer (MBL), suggesting the need for a bromine source from sea-salt aerosol (SSA), in addition to organic bromine (CBry). Both profiles are found to be C-shaped with local maxima in the upper free troposphere (FT). The median tropospheric BrO vertical column density (VCD) was measured as 1.6×1013 molec cm−2, compared to model predictions of 0.9×1013 molec cm−2 in GEOS-Chem (CBry but no SSA source), 0.4×1013 molec cm−2 in CAM-Chem (CBry and SSA), and 2.1×1013 molec cm−2 in GEOS-Chem (CBry and SSA). Neither global model fully captures the C-shape of the Bry profile. A local Bry maximum of 3.6 ppt (2.9–4.4 ppt; 95 % confidence interval, CI) is inferred between 9.5 and 13.5 km in air masses influenced by recent convective outflow. Unlike BrO, which increases from the convective tropical tropopause layer (TTL) to the aged TTL, gas-phase Bry decreases from the convective TTL to the aged TTL. Analysis of gas-phase Bry against multiple tracers (CFC-11, H2O ∕ O3 ratio, and potential temperature) reveals a Bry minimum of 2.7 ppt (2.3–3.1 ppt; 95 % CI) in the aged TTL, which agrees closely with a stratospheric injection of 2.6 ± 0.6 ppt of inorganic Bry (estimated from CFC-11 correlations), and is remarkably insensitive to assumptions about heterogeneous chemistry. Bry increases to 6.3 ppt (5.6–7.0 ppt; 95 % CI) in the stratospheric "middleworld" and 6.9 ppt (6.5–7.3 ppt; 95 % CI) in the stratospheric "overworld". The local Bry minimum in the aged TTL is qualitatively (but not quantitatively) captured by CAM-Chem, and suggests a more complex partitioning of gas-phase and aerosol Bry species than previously recognized. Our data provide corroborating evidence that inorganic bromine sources (e.g., SSA-derived gas-phase Bry) are needed to explain the gas-phase Bry budget in the upper free troposphere and TTL. They are also consistent with observations of significant bromide in Upper Troposphere–Lower Stratosphere aerosols. The total Bry budget in the TTL is currently not closed, because of the lack of concurrent quantitative measurements of gas-phase Bry species (i.e., BrO, HOBr, HBr, etc.) and aerosol bromide. Such simultaneous measurements are needed to (1) quantify SSA-derived Bry in the upper FT, (2) test Bry partitioning, and possibly explain the gas-phase Bry minimum in the aged TTL, (3) constrain heterogeneous reaction rates of bromine, and (4) account for all of the sources of Bry to the lower stratosphere.

Materialart: Online-Ressource

ISSN: 1680-7324

URL: Article

DOI: 10.5194/acp-17-15245-2017

DOI: 10.5194/acp-17-15245-2017-supplement

Sprache: Englisch

Verlag: Copernicus GmbH

Publikationsdatum: 2017

ZDB Id: 2092549-9

ZDB Id: 2069847-1

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Alpine ice evidence of a three-fold increase in atmospheric iodine deposition since 1950 in Europe due to increasing oceanic emissions

Legrand, Michel ; McConnell, Joseph R. ; Preunkert, Susanne ; [weitere]

Proceedings of the National Academy of Sciences ; 2018

In: Proceedings of the National Academy of Sciences Vol. 115, No. 48 ( 2018-11-27), p. 12136-12141

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In: Proceedings of the National Academy of Sciences, Proceedings of the National Academy of Sciences, Vol. 115, No. 48 ( 2018-11-27), p. 12136-12141

Kurzfassung: Iodine is an important nutrient and a significant sink of tropospheric ozone, a climate-forcing gas and air pollutant. Ozone interacts with seawater iodide, leading to volatile inorganic iodine release that likely represents the largest source of atmospheric iodine. Increasing ozone concentrations since the preindustrial period imply that iodine chemistry and its associated ozone destruction is now substantially more active. However, the lack of historical observations of ozone and iodine means that such estimates rely primarily on model calculations. Here we use seasonally resolved records from an Alpine ice core to investigate 20th century changes in atmospheric iodine. After carefully considering possible postdepositional changes in the ice core record, we conclude that iodine deposition over the Alps increased by at least a factor of 3 from 1950 to the 1990s in the summer months, with smaller increases during the winter months. We reproduce these general trends using a chemical transport model and show that they are due to increased oceanic iodine emissions, coupled to a change in iodine speciation over Europe from enhanced nitrogen oxide emissions. The model underestimates the increase in iodine deposition by a factor of 2, however, which may be due to an underestimate in the 20th century ozone increase. Our results suggest that iodine’s impact on the Northern Hemisphere atmosphere accelerated over the 20th century and show a coupling between anthropogenic pollution and the availability of iodine as an essential nutrient to the terrestrial biosphere.

Materialart: Online-Ressource

ISSN: 0027-8424 , 1091-6490

URL: Article

DOI: 10.1073/pnas.1809867115

RVK:

TA 1000

RVK:

WA 15000

Sprache: Englisch

Verlag: Proceedings of the National Academy of Sciences

Publikationsdatum: 2018

ZDB Id: 209104-5

ZDB Id: 1461794-8

SSG: 11

SSG: 12

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10

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Isotopic evidence for acidity-driven enhancement of sulfate formation after SO 2 emission control

Hattori, Shohei ; Iizuka, Yoshinori ; Alexander, Becky ; [weitere]

American Association for the Advancement of Science (AAAS) ; 2021

In: Science Advances Vol. 7, No. 19 ( 2021-05-07)

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In: Science Advances, American Association for the Advancement of Science (AAAS), Vol. 7, No. 19 ( 2021-05-07)

Kurzfassung: After the 1980s, atmospheric sulfate reduction is slower than the dramatic reductions in sulfur dioxide (SO 2 ) emissions. However, a lack of observational evidence has hindered the identification of causal feedback mechanisms. Here, we report an increase in the oxygen isotopic composition of sulfate ( Δ 17 O SO 4 2 − ) in a Greenland ice core, implying an enhanced role of acidity-dependent in-cloud oxidation by ozone (up to 17 to 27%) in sulfate production since the 1960s. A global chemical transport model reproduces the magnitude of the increase in observed Δ 17 O SO 4 2 − with a 10 to 15% enhancement in the conversion efficiency from SO 2 to sulfate in Eastern North America and Western Europe. With an expected continued decrease in atmospheric acidity, this feedback will continue in the future and partially hinder air quality improvements.

Materialart: Online-Ressource

ISSN: 2375-2548

URL: Article

DOI: 10.1126/sciadv.abd4610

Sprache: Englisch

Verlag: American Association for the Advancement of Science (AAAS)

Publikationsdatum: 2021

ZDB Id: 2810933-8

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