Uncertainty in climate projections and time of emergence of climate signals in the western Canadian Prairies

• Published in: International journal of climatology Vol. 39; no. 11; pp. 4358 - 4371
• Main Authors: Barrow, Elaine M., Sauchyn, David J.
• Format: Journal Article
• Language: English
• Published: Chichester, UK John Wiley & Sons, Ltd 01.09.2019; Wiley Subscription Services, Inc
• Subjects: Air temperature; Ambient noise; Background noise; Climate change; Climate models; Climate variability; Climatic indexes; CMIP5; Emergence; Future climates; Global climate; Global climate models; Intercomparison; Mean temperatures; Moisture index; Natural variability; Noise; Prairies; Precipitation; Radiative forcing; Signal-to-noise ratio; Summer; Summer climates; Summer precipitation; Surface-air temperature relationships; Temperature effects; time of emergence; Uncertainty; Variability; variance partitioning
• ISSN: 0899-8418; 1097-0088
• DOI: 10.1002/joc.6079

This paper has examined the relative significance of uncertainty in future climate projections from a subset of the coupled model intercomparison project phase 5 (CMIP5) global climate models for the Prairie Provinces of western Canada. This was undertaken by determining: (a) the contribution of model and scenario uncertainty and natural variability to the total variance of these future projections, and (b) the timing of climate signal emergence from the background noise of natural climate variability. We examined future projections of mean temperature, precipitation and summer climate moisture index (CMI). In this region, natural climate variability plays an important role in future uncertainty until the end of this century, particularly for precipitation and to a lesser extent, summer CMI. Model uncertainty also contributes to total uncertainty for these variables throughout this century, while scenario uncertainty becomes more important towards the end of the century. For the region as a whole, significant climate change (i.e., signal/noise >2) occurs earliest for summer mean temperature, with median time of emergence around 2035 for the RCP8.5 radiative forcing scenario. Although the median precipitation signal emerges from the noise (i.e., signal/noise >1) around the 2070s in winter and the 2080s in spring, significant values do not occur in any season for this variable before 2100. For summer CMI, the median time of emergence for significant change is around 2085. At the grid scale, signal‐to‐noise ratios are significant for all seasons for mean surface air temperature, with earliest times of emergence occurring in summer. In contrast, the summer precipitation signal is not significant this century; for summer CMI, significant values are obtained in the eastern half of the region, occurring from about 2065 onwards. Median times of emergence are towards the end of the century for summer CMI in western Saskatchewan and in Alberta, although some areas of Alberta do not exhibit significant signals this century. The relative significance of uncertainty in future climate projections from a subset of the CMIP5 global climate models was undertaken for the Prairie Provinces of western Canada. Natural climate variability plays an important role in future uncertainty in the summer climate moisture index, a simple measure of drought, and precipitation until the end of this century. Scenario uncertainty becomes more important in the longer‐term.