4.7 Article

Reproducing Arctic springtime tropospheric ozone and mercury depletion events in an outdoor mesocosm sea ice facility

期刊

ATMOSPHERIC CHEMISTRY AND PHYSICS
卷 22, 期 3, 页码 1811-1824

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COPERNICUS GESELLSCHAFT MBH
DOI: 10.5194/acp-22-1811-2022

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  1. Natural Sciences and Engineering Research Council of Canada [RGPIN-2016-06000]
  2. Canada Research Chairs [CRC 950-231031]

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The episodic buildup of reactive bromine species over sea ice and snowpack in the springtime Arctic leads to concurrent depletion of ozone and gaseous elemental mercury. However, there are significant knowledge gaps regarding the cryo-photochemical processes and meteorological conditions causing these events. A mesocosm study in Canada successfully reproduced ozone and mercury depletion events, providing new insight into these processes and their sensitivities to climate change.
The episodic buildup of gas-phase reactive bromine species over sea ice and snowpack in the springtime Arctic plays an important role in boundary layer processes, causing annual concurrent depletion of ozone and gaseous elemental mercury (GEM) during polar sunrise. Extensive studies have shown that these phenomena, known as bromine explosion events (BEEs), ozone depletion events (ODEs), and mercury depletion events (MDEs) are all triggered by reactive bromine species that are photochemically activated from bromide via multi-phase reactions under freezing air temperatures. However, major knowledge gaps exist in both fundamental cryo-photochemical processes causing these events and meteorological conditions that may affect their timing and magnitude. Here, we report an outdoor mesocosm study in which we successfully reproduced ODEs and MDEs at the Sea-ice Environmental Research Facility (SERF) in Winnipeg, Canada. By monitoring ozone and GEM concentrations inside large acrylic tubes over bromide-enriched artificial seawater during sea ice freeze-and-melt cycles, we observed mid-day photochemical ozone and GEM loss in winter in the in-tube boundary layer air immediately above the sea ice surface in a pattern that is characteristic of BEE-induced ODEs and MDEs in the Arctic. The importance of UV radiation and the presence of a condensed phase (experimental sea ice or snow) in causing such reactions were demonstrated by comparing ozone and GEM concentrations between the UV-transmitting and UV-blocking acrylic tubes under different air temperatures. The ability of reproducing BEE-induced photochemical phenomena in a mesocosm in a non-polar region provides a new approach to systematically studying the cryo-photochemical processes and meteorological conditions leading to BEEs, ODEs, and MDEs in the Arctic, their role in biogeochemical cycles across the ocean-sea ice-atmosphere interface, and their sensitivities to climate change.

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