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1. Stirring of Sea‐Ice Meltwater Enhances Submesoscale Fronts in the Southern Ocean

   https://doi.org/10.1029/2020JC016814  

   Giddy, I. ; Swart, S. ; du Plessis, M. ; Thompson, A. F. ; Nicholson, S.‐A. ( April 2021 , Journal of Geophysical Research: Oceans)

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2. Local Air‐Sea Interactions at Ocean Mesoscale and Submesoscale in a Western Boundary Current

   https://doi.org/10.1029/2021GL097003  

   Strobach, Ehud ; Klein, Patrice ; Molod, Andrea ; Fahad, Abdullah A. ; Trayanov, Atanas ; Menemenlis, Dimitris ; Torres, Hector ( April 2022 , Geophysical Research Letters)
3. Sea-ice production and air/ice/ocean/biogeochemistry interactions in the Ross Sea during the PIPERS 2017 autumn field campaign

   https://doi.org/10.1017/aog.2020.31  

   Ackley, S. F. ; Stammerjohn, S. ; Maksym, T. ; Smith, M. ; Cassano, J. ; Guest, P. ; Tison, J.-L. ; Delille, B. ; Loose, B. ; Sedwick, P. ; et al ( September 2020 , Annals of Glaciology)

   Abstract The Ross Sea is known for showing the greatest sea-ice increase, as observed globally, particularly from 1979 to 2015. However, corresponding changes in sea-ice thickness and production in the Ross Sea are not known, nor how these changes have impacted water masses, carbon fluxes, biogeochemical processes and availability of micronutrients. The PIPERS project sought to address these questions during an autumn ship campaign in 2017 and two spring airborne campaigns in 2016 and 2017. PIPERS used a multidisciplinary approach of manned and autonomous platforms to study the coupled air/ice/ocean/biogeochemical interactions during autumn and related those to spring conditions. Unexpectedly, the Ross Sea experienced record low sea ice in spring 2016 and autumn 2017. The delayed ice advance in 2017 contributed to (1) increased ice production and export in coastal polynyas, (2) thinner snow and ice cover in the central pack, (3) lower sea-ice Chl- a burdens and differences in sympagic communities, (4) sustained ocean heat flux delaying ice thickening and (5) a melting, anomalously southward ice edge persisting into winter. Despite these impacts, airborne observations in spring 2017 suggest that winter ice production over the continental shelf was likely not anomalous. 

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4. Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves

   https://doi.org/10.1029/2019MS001836  

   Roach, Lettie A. ; Bitz, Cecilia M. ; Horvat, Christopher ; Dean, Samuel M. ( December 2019 , Journal of Advances in Modeling Earth Systems)

   Recent field programs have highlighted the importance of the composite nature of the sea ice mosaic to the climate system. Accordingly, we previously developed a process‐based prognostic model that captures key characteristics of the sea ice floe size distribution and its evolution subject to melting, freezing, new ice formation, welding, and fracture by ocean surface waves. Here we build upon this earlier work, demonstrating a new coupling between the sea ice model and ocean surface waves and a new physically based parameterization for new ice formation in open water. The experiments presented here are the first to include two‐way interactions between prognostically evolving waves and sea ice on a global domain. The simulated area‐average floe perimeter has a similar magnitude to existing observations in the Arctic and exhibits plausible spatial variability. During the melt season, wave fracture is the dominant FSD process driving changes in floe perimeter per unit sea ice area—the quantity that determines the concentration change due to lateral melt—highlighting the importance of wave‐ice interactions for marginal ice zone thermodynamics. We additionally interpret the results to target spatial scales and processes for which floe size observations can most effectively improve model fidelity.

    

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5. Contributions of aerosol‐cloud interactions to mid‐Piacenzian seasonally sea ice‐free Arctic Ocean

   https://doi.org/10.1029/2019GL083960  

   Feng, Ran ; Otto‐Bliesner, Bette L. ; Xu, Yangyang ; Brady, Esther ; Fletcher, Tamara ; Ballantyne, Ashley ( August 2019 , Geophysical Research Letters)

   Forcings and feedbacks controlling the seasonally sea ice‐free Arctic Ocean during the mid‐Piacenzian Warm period (3.264–3.025 Ma, MPWP), a period when CO₂level, geography, and topography were similar to present day, remain unclear given that many complex Earth System Models with comparatively higher skills at simulating twentieth century Arctic sea ice tend to produce perennial Arctic sea ice for this period. We demonstrate that explicitly simulating aerosol‐cloud interactions and the exclusion of industrial pollutants from model forcing conditions is key to simulating seasonally sea ice‐free Arctic Ocean of MPWP. The absence of industrial pollutants leads to fewer and larger cloud droplets over the high‐latitude Northern Europe and North Pacific, which allows greater absorption of solar radiation at the surface during the early summer. This enhanced absorption triggers the seasonally runaway sea ice surface albedo feedback that gives rise to September sea ice‐free Arctic Ocean and strongly amplified northern high‐latitude surface warmth.

    

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