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January 2003 Permafrost modeling in the Mackenzie River valley: transient aspects of climate change Researchers: F. Wright, C. Duchesne, M. Côté, M. Nixon and E. Roberts Natural Resources Canada Geological Survey of Canada
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January 2003 Research objectives To acquire and synthesize fundamental permafrost- engineering field data. To develop analytical and numerical methods describing climate-driven transient aspects of the ground thermal regime. To apply GIS-based analysis techniques to generate predictions of the time-dependent responses of permafrost to climate change scenarios at local and regional scales.
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January 2003 Area of interest
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January 2003 Impact/Relevance Support engineering design of proposed oil/gas production and delivery systems. Enhanced capability for: terrain evaluation project planning route selection Improved knowledge-base for development of adaptation strategies and/or remedial measures.
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January 2003 Conceptual model of climate-permafrost relations Assume dominance of conductive heat transfer processes The influence of snow cover is implicit in the buffer layer Assumes a uniform substrate
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January 2003 Data sources Vegetation Cover: N-factors & Moisture content Surficial Geology: Thermal conductivities Interpolated mean annual air temperature: DDT & DDF
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January 2003 Equilibrium distribution of permafrost Baseline climate2°C warming4°C warming
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January 2003 Transient aspect of ground thermal response 200 years ?? 30 years ?? Timing of the ground thermal response to climate change depends on the physical and thermal characteristics of the terrain: Insulating properties of vegetation and snow cover Thermal conductivity and heat capacity Frozen water content Finite-element modeling can be used to generate time-dependent predictions of climate change on ground thermal conditions.
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January 2003 Site scale investigation Degree to which ground temperature profiles diverge from an ideal state of equilibrium Consistency between different sites with respect to this divergence Establishment of input values for initial and boundary conditions
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January 2003 GIS-based transient modeling solution Time-dependant GIS-based outputs: Stand-alone finite-element ground thermal model is linked to the GIS at both the model input and output stages. GIS inputs:
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January 2003 Identification of terrain impacts Magnitude of the expected impacts controlled by the physical and thermal properties of the sediments. Evaluation of model predictions of changes in ground thermal state vs potential impacts on terrain: Relating expected temperature changes to temperature- dependent sensitivities of different terrain types. Relation of excess ice content and sediment compactability to subsidence potential.
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January 2003 Users and partners Engineering firms: Colt Geomatic Solutions Ltd preparation for pipeline engineering in the Mackenzie Valley Territorial government departments: DOT, RWED Support associated transportation routes Territorial organisations : MVLWB Information base to support policy development and decision-making Federal government: CCRS, Northern POL Integrated Assessment Model on Climate Change: impact of permafrost change on the carbon balance Geocomplexity of Mackenzie Beaufort Hydrocarbon Development Region
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January 2003 Summary of goals Completed: GSC steady-state model of permafrost characteristics Database development at a regional scale Analysis and synthesis of field data GIS input interface for the transient model In progress: Database development at a local scale GIS output interface for the transient model Impact assessment, predicting permafrost changes in 30, 50 and 100 year time frames, at both local and regional scales
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