Turbulence in the sea ice impacted Southern Ocean and its implications for primary production and carbon export
Sammanfattning
The sea ice impacted Southern Ocean, south of the Antarctic Circumpolar Current,
is one of the most important regions on earth for the cycling of carbon and distribution
of heat and freshwater around the globe. Here, along-isopycnal upwelling of
warm, carbon-rich circumpolar deep water coincides with the annual growth and melt
of Antarctic sea ice that represents one of the worlds largest surface water transformations.
The air-sea-ice buoyancy exchanges and biological processes that change the
surface water properties therefore have global consequences, as they set the properties
of downwelling intermediate waters that enter the upper branch of the global thermohaline
circulation. The region hosts some of the largest uncertainties in global climate
models. The reason for this stems from two sources. Firstly, the spatio-temporal resolution
of global climate models is limited by computational constraints such that smaller
scale processes need to be parameterized. Secondly, the challenges associated with
making observations in or near sea ice and in the harsh and remote conditions of the
Southern Ocean means that the region is sparsely sampled, and as such, the parameterizations
of the small scale and turbulent terms in global climate models are validated
based only on a few in situ samples. This thesis concerns the observation and interpretation
of (sub)meso- to micro scale turbulence and its implications in the sea ice impacted
Southern Ocean. I aimed to understand the 0.01-1 km scale physical and biological processes
that drive changes in the properties of the upper ocean following sea ice melt,
using groundbreaking sustained high temporal and spatial resolution observations made
by gliders. There are three main findings. Firstly, we find that sea ice melt enhances
stirring of submesoscale flows (0.1-10 km) and therefore lateral variability in the upper
ocean, but simultaneously constrains vertical fluxes between the ocean interior and
surface. Secondly, turbulent diapycnal mixing and double diffusive convection (0.1-1
m scales) drive the warming of the subsurface winter water, therefore mediating fluxes
between the ocean interior and surface. Finally, phytoplankton respond favourably to
larger volume sea ice that enhances winter mixing of nutrients from the deep reservoir
and upper ocean stratification in the summer. The preliminary evidence from this study
suggests that the resultant higher intensity phytoplankton bloom translates to enhanced
short term carbon export but not necessarily long term export. Overall, we show, using
observations, that the variability and transport of heat and freshwater flux in the sea
ice impacted Southern Ocean is sensitive to sea ice, with downstream impacts on phytoplankton,
the biological carbon pump and ultimately the upper cell of the meridional
overturning circulation.
Delarbeten
Paper I: Swart, S., M. du Plessis, A.F. Thompson, L. Biddle, I. Giddy, T. Linders, M.
Mohrmann, S-A. Nicholson, 2020. Submesoscale Fronts in the Antarctic Marginal
Ice Zone and Their Response to Wind Forcing. Geophysical Research Letters, 47 (6),
e2019GL086649. https://doi.org/10.1029/2019GL086649 Paper II: Giddy, I., S. Swart, M. du Plessis, A.F. Thompson, S-A Nicholson. (2021). Stirring
of Sea-Ice Meltwater Enhances Submesoscale Fronts in the Southern Ocean. Journal
of Geophysical Research: Oceans, 126(4), e2020JC016814. https://doi.org/10.1029/2020JC016814 Paper III: Giddy, I., I. Fer, S. Swart, S-A Nicholson. (manuscript, 2022). Vertical convergence
of turbulent and double diffusive heat flux drives warming and erosion of Antarctic
Winter Water in summer. in prep for submission to Journal of Physical Oceanography Paper IV: Giddy, I., S-A Nicholson, B. Y. Queste, S. Thomalla, S. Swart. (in review, 2022).
Sea-ice impacts inter-annual variability in phytoplankton phenology and carbon export
in the Weddell Sea. Geophysical Research Letters
Examinationsnivå
Doctor of Philosophy
Universitet
University of Gothenburg, Faculty of Science
Institution
Department of Marine Sciences ; Institutionen för marina vetenskaper
Disputation
Fredagen den 10:e juni 2022 kl. 13:30 i Botanhusets hörsal, Institutionen för marina vetenskaper, Carl Skottsbergs gata 22B, Göteborg
Datum för disputation
2022-06-10
Datum
2022-05-12Författare
Giddy, Isabelle
Nyckelord
Southern Ocean, sea ice, submesoscale, diapycnal mixing, heat fluxes, primary production, carbon export, gliders.
Publikationstyp
Doctoral thesis
ISBN
ISBN 978-91-8009-769-7 (printed) and/or ISBN 978-91-8009-770-3 (pdf)
Språk
eng