High Resolution Hydro-climatological Projections for Western Canada
Accurate identification of the impact of global warming on water resources and hydro-climatic extremes represents a significant challenge to the understanding of climate change on the regional scale. Here an analysis of hydro-climatic changes in western Canada is presented, with specific focus on th...
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2016
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| Online Access: | http://hdl.handle.net/1807/70929 |
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ftunivtoronto:oai:localhost:1807/70929 2023-05-15T15:26:04+02:00 High Resolution Hydro-climatological Projections for Western Canada Erler, Andre Richard Peltier, William R Physics 2016-01-13T05:08:19Z http://hdl.handle.net/1807/70929 unknown http://hdl.handle.net/1807/70929 Dynamical Downscaling Extreme Value Analysis Hydro-climatology Precipitation Regional Climate Western Canada 0404 Thesis 2016 ftunivtoronto 2020-06-17T11:57:43Z Accurate identification of the impact of global warming on water resources and hydro-climatic extremes represents a significant challenge to the understanding of climate change on the regional scale. Here an analysis of hydro-climatic changes in western Canada is presented, with specific focus on the Fraser and Athabasca River basins and on changes in hydro-climatic extremes. The analysis is based on a suite of simulations designed to characterize internal variability, as well as model uncertainty. A small ensemble of Community Earth System Model version 1 (CESM1) simulations was employed to generate global climate projections, which were downscaled to 10 km resolution using the Weather Research and Forecasting model (WRF V3.4.1) with several sets of physical parameterizations. Downscaling was performed for a historical validation period and a mid- and end-21st-century projection period, using the RCP8.5 greenhouse gas trajectory. Daily station observations and monthly gridded datasets were used for validation. Changes in hydro-climatic extremes are characterized using Extreme Value Analysis. A novel method of aggregating data from climatologically similar stations was employed to increase the statistical power of the analysis. Changes in mean and extreme precipitation are found to differ strongly between seasons and regions, but (relative) changes in extremes generally follow changes in the (seasonal) mean. At the end of the 21st century, precipitation and precipitation extremes are projected to increase by 30% at the coast in fall and land-inwards in winter, while the projected increase in summer precipitation is smaller and changes in extremes are often not statistically significant. Reasons for the differences between seasons, the role of precipitation recycling in atmospheric water transport, and the sensitivity to physics parameterizations are discussed. Major changes are projected for the Fraser River basin, including earlier snowmelt and a 50% reduction in peak runoff. Combined with higher evapotranspiration, a significant increase in late summer drought risk is likely, but increasing fall precipitation might also increase the risk of moderate flooding. In the Athabasca River basin, increasing winter precipitation and snowmelt is balanced by increasing evapotranspiration in summer and no significant change in flood or drought risk is projected. Ph.D. Thesis Athabasca River University of Toronto: Research Repository T-Space Athabasca River Canada Fraser River ENVELOPE(-62.243,-62.243,56.619,56.619) |
| institution |
Open Polar |
| collection |
University of Toronto: Research Repository T-Space |
| op_collection_id |
ftunivtoronto |
| language |
unknown |
| topic |
Dynamical Downscaling Extreme Value Analysis Hydro-climatology Precipitation Regional Climate Western Canada 0404 |
| spellingShingle |
Dynamical Downscaling Extreme Value Analysis Hydro-climatology Precipitation Regional Climate Western Canada 0404 Erler, Andre Richard High Resolution Hydro-climatological Projections for Western Canada |
| topic_facet |
Dynamical Downscaling Extreme Value Analysis Hydro-climatology Precipitation Regional Climate Western Canada 0404 |
| description |
Accurate identification of the impact of global warming on water resources and hydro-climatic extremes represents a significant challenge to the understanding of climate change on the regional scale. Here an analysis of hydro-climatic changes in western Canada is presented, with specific focus on the Fraser and Athabasca River basins and on changes in hydro-climatic extremes. The analysis is based on a suite of simulations designed to characterize internal variability, as well as model uncertainty. A small ensemble of Community Earth System Model version 1 (CESM1) simulations was employed to generate global climate projections, which were downscaled to 10 km resolution using the Weather Research and Forecasting model (WRF V3.4.1) with several sets of physical parameterizations. Downscaling was performed for a historical validation period and a mid- and end-21st-century projection period, using the RCP8.5 greenhouse gas trajectory. Daily station observations and monthly gridded datasets were used for validation. Changes in hydro-climatic extremes are characterized using Extreme Value Analysis. A novel method of aggregating data from climatologically similar stations was employed to increase the statistical power of the analysis. Changes in mean and extreme precipitation are found to differ strongly between seasons and regions, but (relative) changes in extremes generally follow changes in the (seasonal) mean. At the end of the 21st century, precipitation and precipitation extremes are projected to increase by 30% at the coast in fall and land-inwards in winter, while the projected increase in summer precipitation is smaller and changes in extremes are often not statistically significant. Reasons for the differences between seasons, the role of precipitation recycling in atmospheric water transport, and the sensitivity to physics parameterizations are discussed. Major changes are projected for the Fraser River basin, including earlier snowmelt and a 50% reduction in peak runoff. Combined with higher evapotranspiration, a significant increase in late summer drought risk is likely, but increasing fall precipitation might also increase the risk of moderate flooding. In the Athabasca River basin, increasing winter precipitation and snowmelt is balanced by increasing evapotranspiration in summer and no significant change in flood or drought risk is projected. Ph.D. |
| author2 |
Peltier, William R Physics |
| format |
Thesis |
| author |
Erler, Andre Richard |
| author_facet |
Erler, Andre Richard |
| author_sort |
Erler, Andre Richard |
| title |
High Resolution Hydro-climatological Projections for Western Canada |
| title_short |
High Resolution Hydro-climatological Projections for Western Canada |
| title_full |
High Resolution Hydro-climatological Projections for Western Canada |
| title_fullStr |
High Resolution Hydro-climatological Projections for Western Canada |
| title_full_unstemmed |
High Resolution Hydro-climatological Projections for Western Canada |
| title_sort |
high resolution hydro-climatological projections for western canada |
| publishDate |
2016 |
| url |
http://hdl.handle.net/1807/70929 |
| long_lat |
ENVELOPE(-62.243,-62.243,56.619,56.619) |
| geographic |
Athabasca River Canada Fraser River |
| geographic_facet |
Athabasca River Canada Fraser River |
| genre |
Athabasca River |
| genre_facet |
Athabasca River |
| op_relation |
http://hdl.handle.net/1807/70929 |
| _version_ |
1766356622533197824 |