Abstract
The pace of climate change can have a direct impact on the efforts required to adapt. For short timescales, however, this pace can be masked by internal variability (IV). Over a few decades, this can cause climate change effects to exceed what would be expected from the greenhouse gas (GHG) emissions alone or, to the contrary, cause slowdowns or even hiatuses. This phenomenon is difficult to explore using ensembles such as CMIP5, which are composed of multiple climate models and thus combine both IV and inter-model differences. This study instead uses CanESM2-LE and CESM-LE, two state-of-the-art large ensembles (LE) that comprise multiple realizations from a single climate model and a single GHG emission scenario, to quantify the relationship between IV and climate change over the next decades in Canada and the USA. The mean annual temperature and the 3-day maximum and minimum temperatures are assessed. Results indicate that under the RCP8.5, temperatures within most of the individual large ensemble members will increase in a roughly linear manner between 2021 and 2060. However, members of the large ensembles in which a slowdown of warming is found during the 2021–2040 period are two to five times more likely to experience a period of very fast warming in the following decades. The opposite scenario, where the changes expected by 2050 would occur early because of IV, remains fairly uncommon for the mean annual temperature, but occurs in 5 to 15% of the large ensemble members for the temperature extremes.
Highlights
Global temperatures are expected to increase due to the radiative forcing of anthropogenic greenhouse gases (van Vuuren et al 2011; Collins et al 2013; Settele et al 2014)
Our study aims to use CanESM2-large ensembles (LE) and CESM-LE to quantify the impact of internal variability (IV) on the pace of warming in Canada and the United States of America (USA) for the upcoming decades
CMIP5 is included in this analysis, as this ensemble is commonly used for climate studies and, it is relevant to assess how its variability compares with CanESM2-LE and CESM-LE
Summary
Global temperatures are expected to increase due to the radiative forcing of anthropogenic greenhouse gases (van Vuuren et al 2011; Collins et al 2013; Settele et al 2014). This can mean that long-term trends such as the 2050 horizon could be reached a few decades early if the right conditions meet In this context, our study aims to use CanESM2-LE and CESM-LE to quantify the impact of IV on the pace of warming in Canada and the United States of America (USA) for the upcoming decades. Our study aims to use CanESM2-LE and CESM-LE to quantify the impact of IV on the pace of warming in Canada and the United States of America (USA) for the upcoming decades This will be realized through an analysis of the disparity in short-term trends and variability between individual members of both large ensembles. CMIP5 is included in this analysis, as this ensemble is commonly used for climate studies and, it is relevant to assess how its variability compares with CanESM2-LE and CESM-LE
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
