Characterization of Moisture Sources for Austral Seas and Relationship with Sea Ice Concentration

Abstract: In this study, the moisture sources acting over each sea (Weddell, King Haakon VII, East Antarctic, Amundsen-Bellingshausen, and Ross-Amundsen) of the Southern Ocean during 1980-2015 are identified with the FLEXPART Lagrangian model and by using two approaches: backward and forward analyses. Backward analysis provides the moisture sources (positive values of Evaporation minus Precipitation, E − P > 0), while forward analysis identifies the moisture sinks (E − P < 0). The most important moisture sources for the… Show more

“…Excepting Δu 10 , we find that median maximum correlations between all variables in Figure 7 and ΔSIC are negative for all ETC time steps. This further confirms that northerly warm, moist airflow within the cyclone's warm sector leads to thermodynamic (relative to the climatology) and pushes the sea ice edge poleward (e.g., Pezza et al, 2012;Reboita et al, 2019) while southerly winds induce equatorward sea ice drift and enhance thermodynamic growth behind the cold front. We note that within-composite correlation variability is high (i.e., many Figure 7 boxes have negative and .…”

“…(2016)). Although the South Pacific region, where both Bellingshausen and Ross ETCs form, has been shown to contribute more moisture to the Antarctic than the South Indian and South Atlantic Oceans (H. Wang et al., 2020), we hypothesize that total moisture transport is larger for E. Antarctic and E. Weddell cyclones because they form at lower latitudes (Reboita et al., 2019). E. Antarctic and E. Weddell composite ETCs also exhibit greater meridional movement (Table 1), which has been shown to be an important factor for ETC‐induced moisture transport (Sinclair & Dacre, 2019).…”

“…We find that E. Antarctic and E. Weddell composite ETC warm sectors produce greater poleward moisture transport prior to Lysis (160 − 200 kg m −1 s −1 ) than Bellingshausen or Ross ETCs (140 − 160 kg m −1 s −1 ), despite greater regional sea ice cover (see Figure 1 in Hobbs et al (2016)). Although the South Pacific region, where both Bellingshausen and Ross ETCs form, has been shown to contribute more moisture to the Antarctic than the South Indian and South Atlantic Oceans (H. Wang et al, 2020), we hypothesize that total moisture transport is larger for E. Antarctic and E. Weddell cyclones because they form at lower latitudes (Reboita et al, 2019). E. Antarctic and E. Weddell composite ETCs also exhibit greater meridional movement (Table 1), which has been shown to be an important factor for ETC-induced moisture transport (Sinclair & Dacre, 2019).…”

“…ETCs form within the polar jet (Uotila et al., 2011) and move southeastward toward the Antarctic coast over the course of days. These storms are important to Antarctic climate because they are cumulatively responsible for the majority of all meridional moisture and energy transport between the middle and high latitudes (Tsukernik & Lynch, 2013; Gorodetskaya et al., 2014; Papritz et al., 2014; Kurita et al., 2016; Reboita et al., 2019; H. Wang et al., 2020; Naakka et al., 2021). Storm fronts circulate air masses around the low pressure center and affect regional cloud and precipitation processes, temperature, surface energy, and sea ice (Nicolas & Bromwich, 2011; Binder et al., 2017; Y. Wang et al., 2019; Alexander et al., 2021).…”

“…ETCs form within the polar jet (Uotila et al, 2011) and move southeastward toward the Antarctic coast over the course of days. These storms are important to Antarctic climate because they are cumulatively responsible for the majority of all meridional moisture and energy transport between the middle and high latitudes (Tsukernik & Lynch, 2013;Gorodetskaya et al, 2014;Papritz et al, 2014;Kurita et al, 2016;Reboita et al, 2019;H. Wang et al, 2020;Naakka et al, 2021).…”

Present‐Day Regional Antarctic Sea Ice Response to Extratropical Cyclones

“…Excepting Δu 10 , we find that median maximum correlations between all variables in Figure 7 and ΔSIC are negative for all ETC time steps. This further confirms that northerly warm, moist airflow within the cyclone's warm sector leads to thermodynamic (relative to the climatology) and pushes the sea ice edge poleward (e.g., Pezza et al, 2012;Reboita et al, 2019) while southerly winds induce equatorward sea ice drift and enhance thermodynamic growth behind the cold front. We note that within-composite correlation variability is high (i.e., many Figure 7 boxes have negative and .…”

“…(2016)). Although the South Pacific region, where both Bellingshausen and Ross ETCs form, has been shown to contribute more moisture to the Antarctic than the South Indian and South Atlantic Oceans (H. Wang et al., 2020), we hypothesize that total moisture transport is larger for E. Antarctic and E. Weddell cyclones because they form at lower latitudes (Reboita et al., 2019). E. Antarctic and E. Weddell composite ETCs also exhibit greater meridional movement (Table 1), which has been shown to be an important factor for ETC‐induced moisture transport (Sinclair & Dacre, 2019).…”

“…We find that E. Antarctic and E. Weddell composite ETC warm sectors produce greater poleward moisture transport prior to Lysis (160 − 200 kg m −1 s −1 ) than Bellingshausen or Ross ETCs (140 − 160 kg m −1 s −1 ), despite greater regional sea ice cover (see Figure 1 in Hobbs et al (2016)). Although the South Pacific region, where both Bellingshausen and Ross ETCs form, has been shown to contribute more moisture to the Antarctic than the South Indian and South Atlantic Oceans (H. Wang et al, 2020), we hypothesize that total moisture transport is larger for E. Antarctic and E. Weddell cyclones because they form at lower latitudes (Reboita et al, 2019). E. Antarctic and E. Weddell composite ETCs also exhibit greater meridional movement (Table 1), which has been shown to be an important factor for ETC-induced moisture transport (Sinclair & Dacre, 2019).…”

“…ETCs form within the polar jet (Uotila et al., 2011) and move southeastward toward the Antarctic coast over the course of days. These storms are important to Antarctic climate because they are cumulatively responsible for the majority of all meridional moisture and energy transport between the middle and high latitudes (Tsukernik & Lynch, 2013; Gorodetskaya et al., 2014; Papritz et al., 2014; Kurita et al., 2016; Reboita et al., 2019; H. Wang et al., 2020; Naakka et al., 2021). Storm fronts circulate air masses around the low pressure center and affect regional cloud and precipitation processes, temperature, surface energy, and sea ice (Nicolas & Bromwich, 2011; Binder et al., 2017; Y. Wang et al., 2019; Alexander et al., 2021).…”

“…ETCs form within the polar jet (Uotila et al, 2011) and move southeastward toward the Antarctic coast over the course of days. These storms are important to Antarctic climate because they are cumulatively responsible for the majority of all meridional moisture and energy transport between the middle and high latitudes (Tsukernik & Lynch, 2013;Gorodetskaya et al, 2014;Papritz et al, 2014;Kurita et al, 2016;Reboita et al, 2019;H. Wang et al, 2020;Naakka et al, 2021).…”

Present‐Day Regional Antarctic Sea Ice Response to Extratropical Cyclones

Quantifying the related precipitation and moisture sources in the lifecycle of subtropical cyclones in the South Atlantic basin

Identifying the provenance and quantifying the contribution of dust sources in EPICA Dronning Maud Land ice core (Antarctica) over the last deglaciation (7–27 kyr BP): A high-resolution, quantitative record from a new Rare Earth Element mixing model