Stockholm university

Martim Mas e Braga

About me

PhD in Physical Geography, working on numerical modeling of ice flow between glacial and interglacial periods at different spatial scales: from idealised ice-flow experiments to the entire Antarctic Ice Sheet. My goal is to both use numerical models of ice flow to better interpret in situ data (e.g. cosmogenic-nuclide exposure dating) in regions of strong topographic relief, and in turn use this data to better constrain large-scale ice sheet models at target periods of the geological past.

On the cosmogenic dating side, I am supervised by Prof. Arjen Stroeven (main supervisor, Stockholm University) and Prof. Jon Harbor (Purdue University Global). On the numerical modeling side, I am supervised by Prof. Irina Rogozhina (NTNU Trondheim), and work in close collaboration with Dr. Jorge Bernales (IMAU - Utrecht University).

My profile on ResearchGate

Research interests:

  • Ice-sheet and ice-flow modeling
  • Paleoglaciology
  • Paleoclimate

 

Apart from research, I have been a member of the PhD Council at the Department of Physical Geography since 2020, and have been a part of the teaching team in the following courses (past and present):

  • GE2018 Geografi I (BSc course)
  • GE2021 Naturgeografi (BSc course)
  • GE5033 Geomorfologiska processer, naturkatastrofer och riskanalys (BSc course)
  • GE5003 Glaciers and high alpine environments (Summer course)
  • GE7079 Polar and alpine envrionments and climate change (MSc course)
  • GE7053 Paleoglaciology (MSc course)

 

Publications

A selection from Stockholm University publication database

  • Sensitivity of the Antarctic ice sheets to the warming of marine isotope substage 11c

    2021. Martim Mas e Braga (et al.). The Cryosphere 15 (1), 459-478

    Article

    Studying the response of the Antarctic ice sheets during periods when climate conditions were similar to the present can provide important insights into current observed changes and help identify natural drivers of ice sheet retreat. In this context, the marine isotope substage 11c (MIS11c) interglacial offers a suitable scenario, given that during its later portion orbital parameters were close to our current interglacial. Ice core data indicate that warmer-than-present temperatures lasted for longer than during other interglacials. However, the response of the Antarctic ice sheets and their contribution to sea level rise remain unclear. We explore the dynamics of the Antarctic ice sheets during this period using a numerical ice sheet model forced by MIS11c climate conditions derived from climate model outputs scaled by three glaciological and one sedimentary proxy records of ice volume. Our results indicate that the East and West Antarctic ice sheets contributed 4.0-8.2 m to the MIS11c sea level rise. In the case of a West Antarctic Ice Sheet collapse, which is the most probable scenario according to far-field sea level reconstructions, the range is reduced to 6.7-8.2 m independently of the choices of external sea level forcing and millennialscale climate variability. Within this latter range, the main source of uncertainty arises from the sensitivity of the East Antarctic Ice Sheet to a choice of initial ice sheet configuration. We found that the warmer regional climate signal captured by Antarctic ice cores during peak MIS11c is crucial to reproduce the contribution expected from Antarctica during the recorded global sea level highstand. This climate signal translates to a modest threshold of 0.4 degrees C oceanic warming at intermediate depths, which leads to a collapse of the West Antarctic Ice Sheet if sustained for at least 4000 years.

    Read more about Sensitivity of the Antarctic ice sheets to the warming of marine isotope substage 11c
  • Nunataks as barriers to ice flow

    2021. Martim Mas E. Braga (et al.). The Cryosphere 15 (10), 4929-4947

    Article

    Numerical models predict that discharge from the polar ice sheets will become the largest contributor to sea-level rise over the coming centuries. However, the predicted amount of ice discharge and associated thinning depends on how well ice sheet models reproduce glaciological processes, such as ice flow in regions of large topographic relief, where ice flows around bedrock summits (i.e. nunataks) and through outlet glaciers. The ability of ice sheet models to capture long-term ice loss is best tested by comparing model simulations against geological data. A benchmark for such models is ice surface elevation change, which has been constrained empirically at nunataks and along margins of outlet glaciers using cosmogenic exposure dating. However, the usefulness of this approach in quantifying ice sheet thinning relies on how well such records represent changes in regional ice surface elevation. Here we examine how ice surface elevations respond to the presence of strong topographic relief that acts as an obstacle by modelling ice flow around and between idealised nunataks during periods of imposed ice sheet thinning. We find that, for realistic Antarctic conditions, a single nunatak can exert an impact on ice thickness over 20 km away from its summit, with its most prominent effect being a local increase (decrease) of the ice surface elevation of hundreds of metres upstream (downstream) of the obstacle. A direct consequence of this differential surface response for cosmogenic exposure dating is a delay in the time of bedrock exposure upstream relative to downstream of a nunatak summit. A nunatak elongated transversely to ice flow is able to increase ice retention and therefore impose steeper ice surface gradients, while efficient ice drainage through outlet glaciers produces gentler gradients. Such differences, however, are not typically captured by continent-wide ice sheet models due to their coarse grid resolutions. Their inability to capture site-specific surface elevation changes appears to be a key reason for the observed mismatches between the timing of ice-free conditions from cosmogenic exposure dating and model simulations. We conclude that a model grid refinement over complex topography and information about sample position relative to ice flow near the nunatak are necessary to improve data-model comparisons of ice surface elevation and therefore the ability of models to simulate ice discharge in regions of large topographic relief.

    Read more about Nunataks as barriers to ice flow
  • Regional sea-level highstand triggered Holocene ice sheet thinning across coastal Dronning Maud Land, East Antarctica

    2022. Yusuke Suganuma (et al.). Communications Earth & Environment 3 (1)

    Article

    The East Antarctic Ice Sheet stores a vast amount of freshwater, which makes it the single largest potential contributor to future sea-level rise. However, the lack of well-constrained geological records of past ice sheet changes impedes model validation, hampers mass balance estimates, and inhibits examination of ice loss mechanisms. Here we identify rapid ice-sheet thinning in coastal Dronning Maud Land from Early to Middle Holocene (9000–5000 years ago) using a deglacial chronology based on in situ cosmogenic nuclide surface exposure dates from central Dronning Maud Land, in concert with numerical simulations of regional and continental ice-sheet evolution. Regional sea-level changes reproduced from our refined ice-load history show a highstand at 9000–8000 years ago. We propose that sea-level rise and a concomitant influx of warmer Circumpolar Deep Water triggered ice shelf breakup via the marine ice sheet instability mechanism, which led to rapid thinning of upstream coastal ice sheet sectors.

    Read more about Regional sea-level highstand triggered Holocene ice sheet thinning across coastal Dronning Maud Land, East Antarctica
  • Antarctic ice stream thickening under Pliocene warmth

    Martim Mas e Braga (et al.).

    Ice streams regulate most ice mass loss in Antarctica. Determining their response to Pliocene warmth could provide insights into their future behaviour, but is hindered by poor representation of subglacial topography in ice-sheet models. We address this limitation using a high-resolution regional model for Dronning Maud Land (East Antarctica). We show that the region’s largest ice stream, Jutulstraumen, thickens by 700 m under warm late-Pliocene conditions despite ice-shelf collapse and a retrograde bed slope, while nearby ice streams thin. While it is known that unstable retreat on a retrograde slope can be slowed under certain conditions, this finding illustrates that an ice stream can thicken and gain mass. We attribute thickening to high lateral stresses at its flux gate, which constrict ice drainage. Similar stress balances occur today in 27% of East Antarctica, and understanding how lateral stresses regulate ice-stream discharge is necessary for accurately assessing Antarctica’s sea-level rise contribution.

    Read more about Antarctic ice stream thickening under Pliocene warmth

Show all publications by Martim Mas e Braga at Stockholm University