The impacts of combined ENSO and SAM on the Antarctic sea-ice budget
ID:1724 View Protection:ATTENDEE Updated Time:2021-06-16 14:31:17 Hits:1531 Poster Presentation

Start Time:2021-07-10 09:10(Asia/Shanghai)

Duration:5min

Session:SP 张贴报告专场 » SP-16主题16、冰冻圈科学 墙报

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Abstract
Both the Southern Annular Mode (SAM) and the El Niño Southern Oscillation (ENSO) are two critical factors contributing to the Antarctic sea ice variability, with strong correlation with each other. The impacts of combined ENSO and SAM on the Antarctic seasonal sea ice anomalies budget are assessed in this study by investigating sea ice concentration (SIC) observations and atmospheric reanalysis data. Based on the monthly ENSO–SAM standardized indices four special situations are selected, including LN/SAM+, LN/SAM-, EN/SAM+, and EN/SAM-. In phase events (LN/SAM+ & EN/SAM–) are characterized with distinct sea level pressure anomalies in the Amundsen Sea and a 850-hPa temperature dipole over the West Antarctic coastal oceans, while out of phase events (EN/SAM+ & LN/SAM–) with only pressure anomalies over the whole Antarctic and few temperature anomalies. All the four situations contribute to the similar spatial patterns of sea ice concentration anomalies with seasonal variations, presenting a dipole over the Atlantic and Pacific sectors. Sea ice dynamic and thermodynamic budget analyses are conducted to determine the leading processes involving the sea ice anomalies. The results show that thermodynamic processes dominate in summer and spring, due to the increased short-wave radiation fluxes and the ice-albedo feedback. Dynamic processes have larger contributions in autumn and winter than other seasons, with advection causes sea ice anomalies at the ice edge and divergence works in the inner ice pack. Meanwhile, sensible and latent heat fluxes result in the thermodynamically sea ice anomalies.
Both the Southern Annular Mode (SAM) and the El Niño Southern Oscillation (ENSO) are two critical factors contributing to the Antarctic sea ice variability, with strong correlation with each other. The impacts of combined ENSO and SAM on the Antarctic seasonal sea ice anomalies budget are assessed in this study by investigating sea ice concentration (SIC) observations and atmospheric reanalysis data. Based on the monthly ENSO–SAM standardized indices four special situations are selected, including LN/SAM+, LN/SAM-, EN/SAM+, and EN/SAM-. In phase events (LN/SAM+ & EN/SAM–) are characterized with distinct sea level pressure anomalies in the Amundsen Sea and a 850-hPa temperature dipole over the West Antarctic coastal oceans, while out of phase events (EN/SAM+ & LN/SAM–) with only pressure anomalies over the whole Antarctic and few temperature anomalies. All the four situations contribute to the similar spatial patterns of sea ice concentration anomalies with seasonal variations, presenting a dipole over the Atlantic and Pacific sectors. Sea ice dynamic and thermodynamic budget analyses are conducted to determine the leading processes involving the sea ice anomalies. The results show that thermodynamic processes dominate in summer and spring, due to the increased short-wave radiation fluxes and the ice-albedo feedback. Dynamic processes have larger contributions in autumn and winter than other seasons, with advection causes sea ice anomalies at the ice edge and divergence works in the inner ice pack. Meanwhile, sensible and latent heat fluxes result in the thermodynamically sea ice anomalies.
Keywords
Antarctic,Sea ice,Thermodynmic,Dynamic
Speaker
王今菲
中山大学

Submission Author
王今菲 中山大学
杨清华 中山大学
于乐江 中国极地研究中心
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Important Date
  • Conference Date

    Jul 09

    2021

    to

    Jul 11

    2021

  • May 30 2021

    Abstract Submission Deadline

  • May 30 2021

    Draft paper submission deadline

  • May 30 2021

    Early Bird Registration

  • Jul 10 2021

    Registration deadline

  • Jul 11 2021

    Contribution Submission Deadline

Sponsored By
青年地学论坛理事会
Organized By
中国科学院地球化学研究所
贵州大学
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