Comparison of model and ground observations finds snowpack and blowing snow both contribute to Arctic tropospheric reactive bromine

Swanson, W.; Holmes, Christopher D.; Simpson, W. R.; Confer, Kaitlyn; Marelle, Louis; Thomas, Jennie L.; Jaeglé, Lyatt; Alexander, Becky; Zhai, Shumenghui; Chen, Qianjie; Wang, Xuan; Sherwen, Tomás

doi:10.5194/acp-2022-44

Cited by 2 publications

(2 citation statements)

References 89 publications

(171 reference statements)

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“…Chemical modelling can be particularly useful to study reactive bromine source mechanisms along with specific multiphase reactions (e.g. Marelle et al, 2021;Ahmed et al, 2022;Swanson et al, 2022;Wang and Pratt, 2017). However, as noted in Wang and Pratt (2017), there are few vertically (and horizontally) resolved observations that can be used to evaluate the modelling of different halogen compounds, making observations that can fill this knowledge gap particularly important.…”

Section: Introductionmentioning

confidence: 99%

Tropospheric Bromine Monoxide Vertical Profiles Retrieved Across the Alaskan Arctic in Springtime

Brockway

Peterson

Bigge

et al. 2023

Preprint

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Abstract. Reactive halogen chemistry in the springtime Arctic causes ozone depletion events and alters the rate of pollution processing. There are still many uncertainties regarding this chemistry, including the multiphase recycling of halogens and how sea ice impacts the source strength of reactive bromine. Adding to these uncertainties are the impacts of a rapidly warming Arctic. We present observations from the CHemistry in the Arctic: Clouds, Halogens, and Aerosols (CHACHA) field campaign based out of Utqiag ̇vik, Alaska from mid-February to mid-April of 2022 to provide information on the vertical distribution of bromine monoxide (BrO), which is a tracer for reactive bromine chemistry. Data was gathered using the Heidelberg Airborne Imaging DOAS Instrument (HAIDI) on the Purdue University Airborne Laboratory for Atmospheric Research (ALAR) and employing a unique sampling technique of vertically profiling the lower atmosphere with the aircraft via "porpoising" ma- neuvers. Observations from HAIDI were coupled with radiative transfer model calculations to retrieve mixing ratio profiles throughout the lower atmosphere (below 1000 m), with unprecedented vertical resolution (50 m) and total information gathered (average of 17.5 degrees of freedom) for this region. A cluster analysis was used to categorize 245 retrieved BrO mixing ratio vertical profiles into four common profile shapes. We often found the highest BrO mixing ratios at the Earth’s surface with a mean of nearly 30 pmol mol−1 in the lowest 50 m, indicating an important role for multiphase chemistry on the snowpack in reactive bromine production. Most lofted BrO profiles corresponded with an aerosol profile that peaked at the same altitude (225 m above the ground), suggesting that BrO was maintained due to heterogeneous reactions on particle surfaces aloft during these cases. A majority, 11 of 15, of the identified lofted BrO cases occurred on a single day, March 19, 2022, over an area covering more than 24,000 km2, indicating that this was a large scale lofted BrO event. The clustered BrO mixing ratio profiles should be particularly useful for MAX-DOAS studies, where prior BrO profiles, needed for the optimal estimation retrieval, are not often based on previous observations. Future MAX-DOAS studies (and past reanalyses) could rely on the profiles provided in this work to improve BrO retrievals.

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Section: Introductionmentioning

confidence: 99%

Tropospheric Bromine Monoxide Vertical Profiles Retrieved Across the Alaskan Arctic in Springtime

Brockway

Peterson

Bigge

et al. 2023

Preprint

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“…Recent modeling efforts have been most successful in reproducing the seasonal cycle of SSA mass concentrations observed at multiple polar sites with a blowing snow source and have found that blowing snow is the dominant source of SSA in polar regions during winter and spring (Huang & Jaeglé, 2017;Rhodes et al, 2017). Several studies have proposed that snow-sourced SSA likely plays an important role in polar tropospheric ozone and halogen chemistry through the release of active bromine in polar spring contributing to ozone depletion events (ODEs) (Choi et al, 2018;Huang et al, 2020;Kalnajs et al, 2013;Marelle et al, 2021;Swanson et al, 2022;Yang et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Impact of changing Arctic sea ice extent, sea ice age, and snow depth on sea salt aerosol from blowing snow and the open ocean for 1980-2017

Confer

Jaeglé

Liston

et al. 2022

Preprint

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Comparison of model and ground observations finds snowpack and blowing snow both contribute to Arctic tropospheric reactive bromine

Cited by 2 publications

References 89 publications

Tropospheric Bromine Monoxide Vertical Profiles Retrieved Across the Alaskan Arctic in Springtime

Tropospheric Bromine Monoxide Vertical Profiles Retrieved Across the Alaskan Arctic in Springtime

Impact of changing Arctic sea ice extent, sea ice age, and snow depth on sea salt aerosol from blowing snow and the open ocean for 1980-2017

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