Research
Non-belspo (1992-ongoing)
ISMIce - Ice Shelf Marine Ice
Project description
This research project deals with
ice-ocean interactions at ice sheet boundaries. The main goal
of the project is to study, understand and quantify how ice shelves
stability is affected by interactions with ocean water masses,
in a changing climate perspective. Focus is put on what is known
as “marine ice” i.e. ice formed in the water column
below or at the front of ice shelves, as a result of thermohaline
circulation loops affecting the water masses in the sub-ice shelf
cavity. This ice then floats up and accretes at the bottom of
the ice shelf and potentially acts as a welding agent of the
large crevasses forming either at the grounding line (where the
ice shelf gets afloat) or at ice shelf fronts (degenerating into
rifts as iceberg calving proceeds).
The approach is through multiparametric studies of ice from shallow
marine ice cores (max. 50 meters) or landfast sea ice cores,
in the area fringing the ice shelf. These measurements include: δ180,
ice textures and fabrics, bulk salinity, major ions and included
particulate matter. Since the project mainly results from a tight
collaboration with the Italian “Progetto Nazionale di Ricerce
in Antartide”, the area of investigation has been centered
on the Terra Nova Bay (Ross Sea) region (Hells Gate and Nansen
Ice Shelves). These ice shelves have the peculiar characteristic
to show marine ice outcrops at the glacier surface close to the
ice shelf front, because of the very strong katabatic winds regime
which is also partly responsible of the existence of the Terra
Nova Bay polynya. Results indicate a varying intensity of the
Deep Thermohaline Convection during the winter (probably driven
by major katabatic wind events) and the existence of a Shallow
Thermohaline Convection loop, active during the summer in the
frontal zone of the ice shelf, as warmer surface waters are forced
under the ice shelf’s front by tidal currents. Both convection
loops are responsible for marine ice formation in the study area,
showing contrasted characteristics.
One of the major peculiarities of marine ice bodies is their
very low salinity (down to 0.03 psu) for ice originated from
a sea water source. We have proposed a simple two-phase approach
model to explain the stable isotope/salinity signal of marine
ice that combines fractionation processes occurring during both
the individual frazil ice crystal generation and the subsequent
consolidation process at the base of the ice shelf, under slow
heat conduction.
In parallel with the analytical studies, a model has been developed
in collaboration with Drs. A. Khazendar and A. Jenkins, that
simulates the marine ice production in rift configurations affecting
the ice shelf. It shows, among others, that very high marine
ice production rates are the rule, when Ice Shelf Water is transiting
under the ice shelf at the rift’s location.
Project team
Coordinator:
Involved research group:
- Glaciology
lab-ULB
Tison Jean-Louis, Souchez Roland, Lorrain Réginald, Khazendar Ala, Lelouchier Claire, El Amri Saïda - Dipartimento di Scienze
dell’Ambiente e del Territorio
Università di Milano, Italy - Dipartimento
di Geografia
Università di Padova, Italy - British
Antarctic Survey
BAS, UK - Laboratorio
di Scienze Geologiche, Ambientali e Marine
Università degli studi di Trieste, Italy - Progetto di
Ricerche Nazionale in Antartide
PNRA, Italy
Foreign partners: