High-resolution Geophysical Mapping of Submarine Glacial Landforms M. Jakobsson 1 , J.A. Dowdeswell 2 , M. Canals 3 , B.J. Todd 4 , E.K. Dowdeswell 2 , K.A. Hogan 5 L.A. Mayer 6 1 Stockholm University, Sweden ([email protected]) 2 Scott Polar Research Institute, University of Cambridge, UK ([email protected]) 3 CRG Marine Geosciences, University of Barcelona, Spain ([email protected]) 4 Geological Survey of Canada, Dartmouth, Nova Scotia, Canada ([email protected]) 5 British Antarctic Survey, Cambridge, UK ([email protected]) 6 Center for Coastal and Ocean Mapping, University of New Hampshire, USA
17
Embed
High-resolution Geophysical Mapping of Submarine Glacial ... · High-resolution Geophysical Mapping of Submarine Glacial Landforms . M. Jakobsson. 1, J.A. Dowdeswell. 2, M. Canals.
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
High-resolution Geophysical Mapping of Submarine Glacial Landforms M. Jakobsson1, J.A. Dowdeswell2, M. Canals3, B.J. Todd4, E.K. Dowdeswell2, K.A. Hogan5 L.A. Mayer6
1Stockholm University, Sweden ([email protected]) 2Scott Polar Research Institute, University of Cambridge, UK ([email protected]) 3CRG Marine Geosciences, University of Barcelona, Spain ([email protected]) 4Geological Survey of Canada, Dartmouth, Nova Scotia, Canada ([email protected]) 5British Antarctic Survey, Cambridge, UK ([email protected]) 6Center for Coastal and Ocean Mapping, University of New Hampshire, USA
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
● Glacial landforms are generated from the activity of glaciers and display spatial dimensions ranging from below one meter up to tens of kilometers
● This presentation illustrates how the evolution of marine geophysical mapping techniques made it possible to study submarine glacial landforms in detail
High-resolution Geophysical Mapping of Submarine Glacial Landforms
Three examples illustrating what higher resolution seafloor mapping revealed
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Spatial dimensions: from meters to kilometers
Image from: DOWDESWELL, J. A., DOWDESWELL, E. K., RODRIGO, C. & J. DIAZ. Assemblage of glacial and related landforms in the fjords of southern Chile (890)
Tens of meters - meters
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
From single beam to multibeam
C D
Bathymetric profiles
Norwegian Channel
Sellevoll, M.A., Sundvor, E., 1974. The Origin of the Norwegian Channel—A Discussion based on Seismic Measurements. Canadian Journal of Earth Sciences 11, 224-231.
Seismic reflection profile
Example 1: Norwegian Channel
Presenter
Presentation Notes
Glacier troughs was at this time not a fully established concept, simply because the shelves had not yet been mapped
Ottesen, D., Dowdeswell, J.A., Rise, L., 2005. Submarine landforms and the reconstruction of fast-flowing ice streams within a large Quaternary ice sheet: The 2500-km-long Norwegian-Svalbard margin (57°–80°N). Geological Society of America Bulletin 117, 1033-1050.
Mapped with Simrad’s first multibeam EM100, 95 kHz
Shade relief from grid with cell-size 50 m
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Simrad EM12S, 12 kHz
Canals, M., Urgeles, R., Calafat, A.M., 2000. Deep sea-floor evidence of past ice streams off the Antarctic Peninsula. Geology 28, 31-34.
The first(?) multibeam mapping of MSGLs
Example 2: Pine Island Bay Jakobsson, M., Anderson, J. et al., 2011. Geological record of Ice Shelf Breakup and Grounding Line Retreat, Pine Island Bay, West Antarctica. Geology 39, 691-694.
Multibeam was financed by: Knut & Alice Wallenberg Foundation Swedish Research Council Swedish Maritime Administration
“Foot print”, depending on beam width and depth
From wide to narrower foot print
Presenter
Presentation Notes
It is not all about frequency
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Pine Island Trough: grid-cell size 50 m
1 km
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Pine Island Trough: grid-cell size 30 m
1 km
Grid-cell size 20 m
Analyzed ridge height variation along bathymetric profile
Jakobsson, M., Anderson, J.B., et al., 2011. Geological record of Ice Shelf Breakup and Grounding Line Retreat, Pine Island Bay, West Antarctica. Geology 39, 691-694.
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Getting closer to the seabed with higher resolution system
Deep water
Shallow water
Bolin Centre for Climate Research A collaboration between Stockholm University, KTH and the Swedish Meteorological and Hydrological Institute
Example 3: Enigmatic ridges in Lake Vättern, Sweden Atlas contribution: GREENWOOD, S. L. & M. JAKOBSSON. Enigmatic ridges in Lake Vättern, Sweden (857)
EM2040, 300 kHz, grid-cell size 1 m. Possible explanations i) Small moraine
segments, formed at/near the grounding line
ii) The “matchsticks” are formed from basal crevasse infill
Enigmatic ridges
Typical nose
Ice flow
Possible explanations i) Small moraine segments,
formed at/near the grounding line
ii) The “matchsticks” are formed from basal crevasse infill
New global grid at 30 x 30 arc second resolution: GEBCO_2014 See poster: OS31B-0990 General Bathymetric Chart of the Oceans (GEBCO) – Mapping the Global Seafloor