Polar Aerosol Atmospheric Rivers: Detection, Characteristics, and Potential Applications

Aerosols play a key role in polar climate, and are affected by long‐range transport from the mid‐latitudes, both in the Arctic and Antarctic. This work investigates poleward extreme transport events of aerosols, referred to as polar aerosol atmospheric rivers (p‐AAR), leveraging the concept of atmos...

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Published in:Journal of geophysical research. Atmospheres 2024-01, Vol.129 (2), p.n/a
Main Authors: Lapere, Rémy, Thomas, Jennie L., Favier, Vincent, Angot, Hélène, Asplund, Julia, Ekman, Annica M. L., Marelle, Louis, Raut, Jean‐Christophe, Silva, Anderson, Wille, Jonathan D., Zieger, Paul
Format: Article
Language:English
Subjects:
Aerosols
Air masses
Algorithms
Atmospheric particulates
Black carbon
Carbon aerosols
Climate
Complementarity
Detection
Latitude
Moisture
Ocean, Atmosphere
Organic carbon
Polar climates
Polar environments
Polar regions
Rivers
Sciences of the Universe
Seasonal distribution
Seasonal variations
Seasonality
Sensitivity analysis
Spatial distribution
Trends
Vertical profiles
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Summary:Aerosols play a key role in polar climate, and are affected by long‐range transport from the mid‐latitudes, both in the Arctic and Antarctic. This work investigates poleward extreme transport events of aerosols, referred to as polar aerosol atmospheric rivers (p‐AAR), leveraging the concept of atmospheric rivers (AR) which signal extreme transport of moisture. Using reanalysis data, we build a detection catalog of p‐AARs for black carbon, dust, sea salt and organic carbon aerosols, for the period 1980–2022. First, we describe the detection algorithm, discuss its sensitivity, and evaluate its validity. Then, we present several extreme transport case studies, in the Arctic and in the Antarctic, illustrating the complementarity between ARs and p‐AARs. Despite similarities in transport pathways during co‐occurring AR/p‐AAR events, vertical profiles differ depending on the species, and large‐scale transport patterns show that moisture and aerosols do not necessarily originate from the same areas. The complementarity between AR and p‐AAR is also evidenced by their long‐term characteristics in terms of spatial distribution, seasonality and trends. p‐AAR detection, as a complement to AR, can have several important applications for better understanding polar climate and its connections to the mid‐latitudes. Plain Language Summary The extreme transport of aerosol‐containing air masses, from the mid‐latitudes to the polar regions, can be characterized and quantified by leveraging polar Aerosol Atmospheric Rivers (p‐AARs). This is similar to the Atmospheric Rivers (ARs) which carry large amounts of water to the poles and affect the overall stability of polar ecosystems. In this work, we establish a detection algorithm for p‐AARs and evaluate it for different well‐known aerosol intrusions or AR events. The areas most affected by p‐AARs are described, their trends are investigated and we discuss the potential applications of p‐AAR detection for a better understanding of polar climate. Key Points A catalog of polar aerosol atmospheric rivers (p‐AAR) is provided for 1980–2022 by adapting an atmospheric river (AR) detection scheme Important p‐AAR events, representing rapid poleward transport of aerosol‐enriched air masses, are presented Combining AR and p‐AAR can improve our understanding of the links between mid‐ and polar‐latitudes, in the past, present and future climate
ISSN:2169-897X
2169-8996
2169-8996
DOI:10.1029/2023JD039606