EP23A-0945
Coastal Mapping for Baseline Geoscience Knowledge to Support Community Hazard Assessment and Sustainable Development, Eastern Baffin Island, Nunavut

Tuesday, 15 December 2015
Poster Hall (Moscone South)
Donald L Forbes1,2, Trevor Bell2, D Calvin Campbell1, Beth Cowan2, Robert L Deering2, Scott V Hatcher2, John E Hughes Clarke3,4, Melanie Irvine5, Gavin K. Manson6 and I Rod Smith7, (1)Geological Survey of Canada, Natural Resources Canada, Dartmouth, NS, Canada, (2)Memorial University of Newfoundland, Department of Geography, St. John's, NL, Canada, (3)University of New Brunswick, Fredericton, NB, Canada, (4)University of New Hampshire, Durham, NH, United States, (5)Geological Survey of Newfoundland & Labrador, St. John's, NL, Canada, (6)Geological Survey of Canada Atlantic, Dartmouth, NS, Canada, (7)Geological Survey of Canada, Natural Resources Canada, Calgary, AB, Canada
Abstract:
Since 2012 we have carried out extensive multibeam bathymetric and backscatter surveys in coastal waters of eastern Baffin Island, supplemented by sub-bottom imaging and coring. Shore-zone surveys have been undertaken in proximity to the communities of Iqaluit and Qikiqtarjuaq, following earlier work in Clyde River. These support benthic habitat mapping, geological exploration, analysis of past and present sea-level trends, and assessment of coastal hazards relating to climate change and seabed instability. Outputs include a seamless topographic-bathymetric digital elevation model (DEM) of extensive boulder-strewn tidal flats in the large tidal-range setting at Iqaluit, supporting analysis of coastal flooding, wave run-up, and sea-ice impacts on a rapidly developing urban waterfront in the context of climate change. Seabed mapping of inner Frobisher Bay seaward of Iqaluit reveals a potential local tsunami hazard in widespread submarine slope failures, the triggers, magnitudes, and ages of which are the subject of ongoing research. In fjords of the Cumberland Peninsula, this project has mapped numerous submerged delta terraces at 19 to 45 m present water depth. These attest to an early postglacial submerged shoreline, displaced by glacial-isostatic adjustment. It rises linearly over a distance of 100 km east to west, where a submerged boulder barricade on a -16 m shoreline was discovered at a proposed port site in Broughton Channel near Qikiqtarjuaq. Palaeotopographic mapping using the multibeam data revealed an enclosed estuarine environment quite different from the present-day open passage swept by tidal currents. At Clyde River, combined seabed and onshore DEMs with geohazard mapping provided foundation data for community assessment and planning under a local knowledge co-production initiative. The geohazard work identified portions of the town-site more vulnerable to both coastal flooding and potential thaw subsidence, while the shallow delta terrace suggested a reversal from falling to rising relative sea levels. Overall, the coastal mapping results constitute baseline geoscience knowledge infrastructure for navigation, fisheries, port engineering, municipal planning, and informing sustainability initiatives in the isolated coastal communities of this Arctic region.