Sea-Ice-Driven Mercury Depletion over the Arctic Marginal Ice Zone Revealed by Direct Shipborne Observations

The Arctic is undergoing rapid environmental change, with sea-ice loss altering key exchanges among the cryosphere, atmosphere, and biosphere. During spring, atmospheric mercury and ozone depletion events (AMDEs and ODEs) drive rapid declines in gaseous elemental mercury (Hg0) and ozone (O3), promoting mercury deposition to snow, ice, and marine ecosystems. Despite three decades of research, AMDEs have been documented almost exclusively at coastal land-based stations, leaving their occurrence and mechanisms over oceanic sea-ice poorly constrained. To address this gap, we conducted a research cruise in the Arctic marginal ice zone to study the connections between sea-ice and atmospheric Hg chemistry. We measured atmospheric Hg0, reactive gaseous Hg (RGM), and O3 along the cruise track, identifying the simultaneous occurrences of AMDEs and ODEs. Air mass back-trajectory analysis combined with sea-ice images from satellite remote sensing revealed that these depletion events occurred exclusively when air masses originated from over sea-ice and were near its surface. Our findings confirm that Arctic sea-ice plays a pivotal role in initiating AMDEs observed in the marginal ice zone, driven by halogen release from the sea-ice surface. This study advances understanding of the interplay between sea-ice dynamics and atmospheric chemistry, with important implications for Hg deposition in polar ecosystems and the consequences for human and wildlife health, given the potential impacts of a rapidly changing Arctic.