Abstract
Recent studies indicated that the internal climate variability plays an important role in various aspects of projected climate changes on regional and local scales. Here we present results of the spreads in projected trends of wintertime North American surface air temperature and extremes indices of warm and cold days over the next half-century, by analyzing a 50-member large ensemble of climate simulations conducted with CanESM2. CanESM2 simulations confirm the important role of internal variability in projected surface temperature trends as demonstrated in previous studies. Yet the spread in North American warming trends in CanESM2 is generally smaller than those obtained from CCSM3 and ECHAM5 large ensemble simulations. Despite this, large spreads in the climate means as well as climate change trends of North American temperature extremes are apparent in CanESM2, especially in the projected cold day trends. The ensemble mean of forced climate simulations reveals high risks of warm days over the western coast and northern Canada, as well as a weakening belt of cold days extending from Alaska to the northeast US. The individual ensemble members differ from the ensemble mean mainly in magnitude of the warm day trends, but depart considerably from the ensemble mean in spatial pattern and magnitude of the cold day trends. The signal-to-noise ratio pattern of the warm day trend resembles that of the surface air temperature trend, with stronger signals over northern Canada, Alaska, and the southwestern US than the midsection of the continent. The projected cold day patterns reveal strong signals over the southwestern US, northern Canada, and the northeastern US. In addition, the internally generated components of mean and extreme temperature trends exhibit spatial coherences over North America, and are comparable to their externally forced trends. The large-scale atmospheric circulation-induced temperature variability influences these trends. Overall, our results suggest that climate change trends of North American temperature extremes are likely very uncertain and need to be applied with caution.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
Climate mean and extreme changes on local, regional and continental scales directly influence human and natural systems (IPCC 2013). Three sources of uncertainty in climate change predictions involve external forcing, model response, and internal variability (e.g., Hawkins and Sutton 2011; Deser et al. 2012a, b, 2014, and references therein). As detailed in previous studies, external forcing uncertainty arises from incomplete knowledge of anthropogenic forcings employed in emission scenarios. Model uncertainty comes from different climate changes in response to the same external forcing simulated by various climate models, which are constructed with different dynamical cores, physics, and resolutions. Internal variability is natural climate variability and results from processes intrinsic to the climate system, in particular coupled interactions between the atmosphere, oceans, land, and cryosphere.
The role of internal variability in climate change projections on regional scales has been found to be significant and comparable to externally forced responses (e.g., Deser et al. 2012a, 2014). Different approaches have been proposed to isolate internal climate variability generated responses from externally forced climate responses. In particular, the influence of internal climate variability has been considered as the residual from different order polynomial fits to time series of forced climate responses (e.g., Hawkins and Sutton 2009, 2011; Boer 2009). It has also been considered by analyzing a suite of climate simulations forced by identical external forcings but with slightly different atmospheric initial conditions in a given climate model (e.g., Collins and Allen 2002; Deser et al. 2012a; Wallace et al. 2014; Kay et al. 2015). In addition, Thompson et al. (2015) suggested that the internal climate variability in projected climate trends could be estimated from the statistics of observed climates and an unforced climate simulation of sufficient length.
Recently, the large ensemble approach has been widely used in exploring the role of internal climate variability in various aspects of climate changes, such as climate projections of surface air temperature and precipitation (e.g., Deser et al. 2012a, b, 2014; Kay et al. 2015; Chen et al. 2019), atmospheric circulation (Kang et al. 2013), sea level rise (Hu and Deser 2013; Deser et al. 2012b), Arctic sea ice (Wettstein and Deser 2014; Kirchmeier-Young et al. 2017), and the extratropical atmospheric forcing on the tropical El Niño-Southern Oscillation variability (Chen and Yu 2019). Results from large ensemble simulations enable a robust quantification of the responses to external forcings and internal climate variability. Uncertainties in the forced response are found to be generally larger for sea level pressure compared to precipitation, and smallest for surface air temperature. Large-scale atmospheric circulation variability is mainly responsible for the spread in future climate changes.
The purpose of this study is to document the role of internal variability in climate change projections of North American surface air temperature and temperature extremes in a 50-member ensemble of climate simulations conducted with the second-generation Canadian Earth System Model (CanESM2). CanESM2 is a global climate model participating in the Phase 5 of the Coupled Model Intercomparison Project (CMIP5) of the World Climate Research Programme (WCRP). As demonstrated in Sheffield et al. (2013), most CMIP5 models, including CanESM2, can reasonably well reproduce the observed variability over North America from intraseasonal to decadal time scales. Here, we analyze the projected surface air temperature trends in CanESM2 over the period 2010–2055 and compare them to those obtained from large ensemble simulations with similar external forcings in other climate models. In particular, we would like to know if there are projected cooling trends over North America in CanESM2 as appeared in ensemble members of some other models (Deser et al. 2014). We then examine the projected trends of extreme temperatures in CanESM2. Unlike many previous studies that focused on the trends of regional mean extreme temperatures (e.g., Sillmann et al. 2013b; Kay et al. 2015), we analyze the spatial pattern and its uncertainty of extreme temperature trends over North America. We examine the diversity of the projected trends, compare forced and internal components of the projected trends, and analyse the influence of large-scale atmospheric circulation variability on these trends. This analysis would also support our further studies to explore the physical processes of the interannual variability and projected changes of extreme temperatures using the outputs simulated from CanESM2 and its next generation CanESM5 model participating in CMIP6. In addition, previous studies indicated that global warming would be most pronounced during the cold season over high latitudes (Manabe and Stouffer 1980; IPCC 2013). CMIP5 models can reasonably well simulate extreme temperatures and the simulations are generally better in boreal winter than summer (Krueger et al. 2015). Hence, we only analyze the wintertime temperature trend in this study.
The rest of the paper is organized as follows: Sect. 2 describes the observational and reanalysis datasets, CanESM2 climate model simulations, and analysis methods we used. Section 3 evaluates the model performance in simulating the climatological means of surface air temperature and temperature extremes over North America. Section 4 documents the climate change projected trends of North American surface air temperature, inter-member trend variance, forced and internal components of the trends, and contributions of large-scale atmospheric circulation variability on the trends. Section 5 describes the corresponding analyses as in Sect. 4 but for warm and cold extremes. A summary and discussion are given in Sect. 6.
2 Data and Methodology
-
(a)
Observational and reanalysis data
The monthly surface air temperature (SAT) data employed in this study are extracted from the National Centers for Environmental Prediction/National Center for Atmospheric Research (NCEP/NCAR) reanalysis (NCEP hereafter, Kistler et al. 2001) on standard 2.5° × 2.5° grids. The observed monthly temperature extremes analyzed are extreme indices from the HadEX2 dataset (Donat et al. 2013) on 3.75° × 2.5° (longitude-latitude) grids. We use the warm day index TX90 (cold day index TX10) with the percentage of time when daily maximum temperature is greater than its 90th (less than its 10th) percentile. The percentile-based indices are derived using 1961–1990 as the base period and based on a 5-day running window. A bootstrap resampling procedure is applied in the index calculation to avoid inhomogeneity at the boundaries between the base and out-of-base periods (Zhang et al. 2005). The extreme temperatures are examined on a seasonal basis following previous studies (e.g., Klein Tank et al. 2009; Sillmann et al. 2013a). We analyze December-February (DJF) mean SAT and extreme TX90 and TX10 indices for the period from 1951 to 2000. Years refer to the January dates throughout this study.
-
(b)
CanESM2 climate model simulations
Outputs from a large ensemble of climate simulations conducted with the second-generation Canadian Earth System Model are employed to explore projected climate trends. CanESM2 is a fully coupled ocean–atmosphere-land-sea ice climate model (http://climate-modelling.canada.ca/climatemodeldata/data.shtml; Arora et al. 2011; von Salzen et al. 2013). Its atmospheric component is a spectral model with T63 triangular resolution of approximately 2.81° × 2.81° grids and 35 vertical layers extending from the surface to the stratopause (Scinocca et al. 2008). The oceanic component was developed from the NCAR Community Ocean Model, with a horizontal resolution of approximately 1.41° × 0.94° (longitude-latitude) and 40 vertical levels. Detailed descriptions of CanESM2 can be found on the above website. The climate simulations we analyzed consist of 50 ensemble members of 150-year simulations for the period from 1950 to 2100, with slightly different initial conditions for each run in 1950 (Kirchmeier-Young et al. 2017; Chen and Yu 2019). Each of the simulations is forced by identical historical greenhouse gas concentration, sulfate aerosols, and other observation based radiative forcings from 1950 to 2005 and the representative concentration pathway 8.5 scenario (RCP8.5, van Vuuren et al. 2011; Collins et al. 2013) from 2006 to 2100. Hence, differences seen in these simulations are due solely to internally generated climate variability (Deser et al. 2014; Wallace et al. 2014).
The monthly mean SAT, sea level pressure (SLP), and temperature extremes (TX90 and TX10) from historical and climate change simulations are employed. As in the observations, the modelled extreme indices are calculated using 1961–1990 as the base period. The climate model simulated variables are compared to the corresponding reanalysis/observation based results to evaluate the model performance. To compare with the observed temperature extremes (Fig. 1), TX90 and TX10 indices are analysed on 3.75° × 2.5° (longitude-latitude) grids. Except this, all modelled variables examined are interpolated to 2.5° × 2.5° grids.
-
(c)
Analysis methods
All analyses are based on DJF seasonal means of variables considered. The multi-member ensemble mean (EnM) quantity is obtained by summarizing the statistics of individual members, i.e. the ensemble average of the 50 member results. The linear trend for the time series of interest is calculated using a least squares method. We partition the temperature trend into external anthropogenic radiative forced and internal climate variability generated components: TrendTotal = TrendForced + TrendInternal, following Deser et al. (2014). The externally forced contribution of the trend is obtained by averaging the projected trends over the 50 ensemble members (i.e., the EnM), whereas the internal variability generated component is estimated by subtracting the externally forced component from the total trend.
Deser et al. (2014) investigated North American SAT trends over the period 2010–2060 using the NCAR Community Climate System Model, version 3 (CCSM3) climate simulations. Their simulations are under the Special Report on Emission Scenarios (SRES) A1B, with carbon dioxide concentrations increasing from approximately 380 ppm in 2000 to about 570 ppm in 2060. The CanESM2 climate change simulations are forced by the RCP8.5 scenario, where carbon dioxide concentrations increase to approximately 570 ppm in 2055. Hence, we calculate SAT trends over the period 2010–2055 using CanESM2 simulations to make our results reasonably comparable to those in Deser et al. (2014), although both models are also driven by other external forcings. Nevertheless, the SAT trend pattern reported here is not sensitive to slight changes of the period analyzed.
The relative agreement of individual member-based spatial patterns with the reanalysis/observation or EnM result is mainly evaluated by calculating second-order space–time climate difference statistics and is illustrated using a modified Taylor diagram termed a BLT diagram (Boer and Lambert, 2001). A BLT diagram displays the pattern correlation, ratio of modeled to reanalysis/observation or EnM variances, and relative mean square difference between each member and reanalysis/observation or EnM quantities. The ratio of variances compares the smoothness of the spatial pattern in an individual member to the reference pattern. The relative mean square difference is a scaled mean square difference, in terms of the reference variance, between the pattern in an individual member and the reference pattern. In addition, an empirical orthogonal function (EOF) analysis is performed to characterize dominant modes of inter-member variability of SLP trends.
3 Climatological means of surface temperature and temperature extremes
Figure 1 displays the DJF climatological means of North American surface air temperatures and extreme indices of warm and cold days over 1951–2000 for the 50-member EnM, observation based result, and their differences. For SAT, the similarity of the spatial patterns with a poleward temperature decrease is quite remarkable in the EnM and NCEP reanalysis (Fig. 1, left column). The pattern is also robust for all ensemble members. Figure 2a presents the relative agreement of the DJF mean SATs for individual members compared to the NCEP reanalysis result using a BLT diagram. The pattern correlations are 0.97–0.98 for the 50 members, with a mean value of 0.98, over North America. Meanwhile, all members have nearly identical spatial variances compared to NCEP as is seen from the ratio of variances of the simulated to reanalysis (approximately 100%, the green numbers and dashed circles in Fig. 2a). Accordingly, the distinction between individual members is barely discernible in the diagram. In addition, the mean square difference between model and reanalysis based patterns (the blue numbers and solid circles in Fig. 2a) indicates that the values for all members, as well as the EnM, are low (about 7.0%). Overall, the reanalysis based SAT pattern over North America is well simulated by CanESM2. However, all the historical simulations, and their EnM, show a warm bias (about 1–2 °C) over most of the continent, especially around the Great Lakes (~ 3.2 °C; Fig. 1, lower left panel). The model bias will be partially removed when considering climate change trends below.
The EnM patterns of warm day index TX90 (Fig. 1, middle column) and cold day index TX10 (Fig. 1, right column) also bear resemblance to the observed results. The patterns show relatively high TX90 values over the southwestern US and central-eastern Canada, as well as low TX10 values over the southeastern US. The pattern correlation of TX90 (TX10) between the EnM and observation is 0.79 (0.88) over North America. It is noted that the climatological means of the warm and cold extreme indices are slightly different from 10% in both the observations and EnM. This is mainly because of climate differences between the base period 1961–1990 used to define the extreme indices and period 1951–2000 analyzed in this study and of daily temperature variability (Yu et al. 2019). In addition, the EnMs of TX90 and TX10 exhibit slightly high intensity biases (less than 1% compared to the observations) over most of the continent, with exceptions over eastern Canada and eastern Mexico for TX90.
The relative agreement of climatological mean TX90 and TX10 patterns for individual members with the corresponding observed results is further compared in Fig. 2b, c. For warm extreme TX90 (Fig. 2b), there exhibits a considerable range of pattern correlations, from 0.08 to 0.84, indicating large uncertainties in the DJF mean TX90 simulations. Meanwhile, 49 members show lower spatial variances compared to the observation, implying that the simulated TX90 patterns are generally flatter than the observed pattern over North America. In addition, the mean square difference between each member and the observation shows that the EnM value is lower than values of most members. For cold extreme TX10 (Fig. 2c), considerable differences are also apparent in pattern correlation and spatial variance across the 50 members. The EnM tends to have the best result in terms of pattern correlation and the mean square difference between model and observation patterns. Overall, the ensemble mean patterns of warm and cold extreme indices are qualitatively similar to the corresponding observed patterns. However, both TX90 and TX10 show much larger uncertainties in spatial pattern and magnitude of the DJF mean indices across the 50 CanESM2 members than that seen in SAT, indicating that the internal climate variability influences temperature extremes more than SAT.
4 Surface temperature trend
-
(a)
Projected trend, trend variance, and signal-to-noise ratio
Figure 3 displays the DJF mean SAT trends over the period 2010–2055 for each of the 50 ensemble members and the EnM. The overall signature of poleward amplification of temperature trends can be seen in all ensemble members, as well as the EnM. However, the SAT trends also reveal diversities, in terms of magnitude and spatial structure, across the ensemble members. The regional means of area-weighted SAT trends over land within the North American domain (20°–70°N, 170°–50°W), as shown in Fig. 3, range from 2.80 °C/45 year (member 26, M26) to 5.17 °C/45 year (member 40, M40), with an average of 3.85 °C/45 year for the EnM. Figure 4 further compares the projected SAT trends for individual members to the EnM. The pattern correlations over the North American domain range from 0.79 to 0.97, with a mean of 0.92, confirming the broad similarity of the spatial patterns across the 50 members. Additionally, the ensemble members exhibit a wide range of spatial variances compared to their EnM, with the ratio of variances ranging roughly from 50 to 150%. The uncertainty seen in the CanESM2 SAT trend is generally consistent with those obtained from other climate models (Deser et al. 2014; Kay et al. 2015). However, unlike those reported from the CCSM3 and ECHAM5 (Max Planck Institute climate model, version 5) large ensemble simulations (Deser et al. 2014), no cooling is observed over North America in the CanESM2 trends projected for 2010–2055. This suggests that CanESM2 tends to be less uncertain in projecting North American warming trends in the next half century than CCSM3 and ECHAM5.
The internal variability of the SAT responses to external forcing can be further quantified by the ensemble standard deviation (ESTD) of SAT trends across the 50 members. The relative contributions of external forcing and internal variability can be measured by the signal-to-noise ratio (SNR) of the ensemble mean SAT trend to the ESTD of the trends. SNR is a measure commonly used to compare the level of desired signal to the level of background noise. Figure 5 shows the ESTD and SNR of the SAT trends over 2010–2055. The inter-member variability is high over Canada and Alaska. The variability pattern resembles those obtained from CCSM3 and ECHAM5, while the variability magnitude is more comparable to that from ECHAM5 and slightly lower than that from CCSM3 (Fig. 5 in Deser et al. 2014). The SNR exhibits high values (greater than 3.5) over northern Canada, Alaska, and the southwestern US, and relatively low values mostly confined to the midsection of North America. This suggests that the SAT response to external forcing tends to be less detectable over the central parts than elsewhere over the continent. The SNR pattern is attributed to both the ensemble mean (Fig. 3, last panel) and inter-member variability trends. The SNR magnitude is also more comparable to that in ECHAM5 than in CCSM3. The differences among the three ensembles result likely from differences in model configuration and physics and/or different ensemble sizes used in these calculations.
-
(b)
Forced and internal components of projected trend
As described above, the externally forced SAT trend (the EnM trend) reveals an expected feature of poleward-intensified warming, with warming trends below 2 °C/45 year over the southeast US, approximately 2–4 °C/45 year over the western-central US and southern Canada, and about 4–7 °C/45 year over northern Canada (shading in Fig. 6, middle row). The forced SAT trend from CanESM2, including magnitude and spatial distribution, is comparable to those from other climate models (Deser et al. 2014; Kay et al. 2015).
The internally generated SAT trends from the 50 ensemble members exhibit large diversities, like those seen in the total trends (Fig. 3). The regional means of internal trends over North America range from − 1.05 °C/45 year (M26) to 1.32 °C/45 year (M40) among the 50 members. The color shading in Fig. 6 displays the total, externally forced and internally generated SAT trends for the least and most warming members. For the total trend (Fig. 6, top row), the two cases exhibit broadly similar patterns compared to the EnM, with a spatial correlation of 0.94 (0.92) between M26 (M40) and EnM. However, notable differences between them are apparent in trend magnitude, especially with differences of 3–6 °C/45 year over Canada. This is also clearly evident in the internally generated trend (Fig. 6, bottom row). In addition, the magnitude of the internal SAT trend is comparable to that of the forced trend (Fig. 6, middle row), especially over western-central Canada. Hence, the total trend is contributed by both the externally forced and internally generated components. Moreover, the internal temperature trend exhibits large-scale spatial coherence rather than small-scale noise structure, consistent with Deser et al. (2014). Nevertheless, pattern correlations between most ensemble members and the least (most) warming member M26 (M40) are not high over North America, owing primarily to large spatial variations of action centers of the SAT trends (not shown).
-
(c)
Dynamically adjusted trend
The large-scale atmospheric circulation anomaly and its induced temperature advection influence atmospheric temperature anomalies, particularly in boreal winter. The circulation-induced internal variability is found to play a crucial role in the climate change projection (e.g., Deser et al. 2012a, 2014; Holmes et al. 2016). Figure 6 also compares the total forcing to the externally forced and internally generated components of SLP (contours) and SAT trends over 2010–2055 for M26 and M40. For the total trend (Fig. 6, top panels), the circulation influence is evident over the northern parts of North America in M40, but not clear in M26. The anomalous warm maritime air flows from the North Pacific into the northern parts of the continent in M40, which contributes to the warming trends over Canada and the northern US. The circulation influence is also evident in the forced SAT trend over the northern portions of the continent, but not clear in the south (Fig. 6, middle panels). EnM reveals a decrease of SLP trends over the North Pacific, indicating the Aleutian low is projected to enhance in CanESM2. The deepening of the Aleutian low is consistent with previous studies, which demonstrated an intensification and northward expansion of the Aleutian low in response to greenhouse warming (e.g., Meehl and Washington 1996; Gan et al. 2017). The deepening of the Aleutian low with global warming can be driven by an El Niño-like warming in the tropical Pacific (Gan et al. 2017). The Aleutian low change has also been found to be associated with changes in storm tracks at midlatitudes (Salathe 2006) as well as remote influences of the Atlantic Ocean (Zhang and Delworth 2007) and Arctic sea ice loss (Sun et al. 2015; Deser et al. 2016).
For the internally generated trend (Fig. 6, bottom panels), which shows the dominant SAT changes of reverse signs in M26 and M40 cases, the circulation influence is also obvious. In particular, the anomalous cold air flows from the north in M26, which follows the dominant anticyclonic anomaly with the center of action over the North Pacific, leading to cold trends over North America. By contrast, the anomalous warm maritime air flows from the North Pacific into Canada and the northern US in M40, which follows the cyclonic anomaly over the North Pacific, resulting in warm trends over the northern parts of North America.
To further demonstrate the impact of circulation-induced variability on SAT trends, we perform an EOF analysis on the SLP trends within the Pacific-North American domain (20°–70°N, 150°E–50°W), as shown in Fig. 6, across the 50 ensemble members. The first three EOF modes account for 84.3% of the inter-member SLP trend variance and are well separated from subsequent EOFs as per the criterion of North et al. (1982). The SLP anomalies in association with the principal components (PCs) related to these three modes are analyzed (not shown). The leading PC associated SLP anomalies reveal an Arctic Oscillation (AO, Thompson and Wallace 1998) like pattern, with opposite SLP anomalies over the Arctic region and northern mid-latitudes. The second PC associated SLP anomalies somewhat resemble the Pacific-North American pattern (PNA, Wallace and Gutzler 1981), with a dominant center of action over western Canada and Alaska. The third PC related SLP anomalies feature a Western Pacific (WP, Wallace and Gutzler 1981) like pattern, with a dominant action center over the Kamchatka Peninsula. The three orthogonal SLP trend predictor patterns are then determined for SAT trends at each grid cell using the method of partial least squares. We remove the influence of these three SLP trend predictor patterns to get the dynamically adjusted version of SAT trends for each ensemble member. This is generally similar to the dynamically adjusted method used in Deser et al. (2014) and Wallace et al. (2014).
Figure 7 compares the total and dynamically adjusted SAT trends for the two members discussed above. By partially removing the circulation-induced component of internal trend variability, M26 and M40 resemble more than their total trend counterparts do. This is apparent both visually in spatial pattern and magnitude (Fig. 7) and from a spatial correlation calculation. The correlation between M26 and M40 is 0.77 over North America for the total SAT trend, and increases to 0.91 for the dynamically adjusted trend. In addition, the adjusted M26 and M40 trend patterns are more comparable to the forced trend, i.e. the EnM (shading in Fig. 6, middle row), with the spatial correlation between M26 (M40) and EnM increasing slightly from 0.94 (0.92) for the total SAT trend to 0.98 (0.94) for the adjusted trend. The result demonstrates the influence of circulation-induced internal variability on the SAT trends. Figure 8 further compares the dynamically adjusted SAT trends for 2010–2055 over the North American domain for the 50 individual members to the EnM in a BLT diagram. The pattern correlations between each member and EnM range from 0.83 to 0.98, with a mean of 0.94 that is slightly higher than that of the total trend (0.92). The ratios of individual member variances to the EnM variance as well as the mean square differences between each member and EnM for the adjusted trend are also slightly lower compared to the counterparts for the total trend (cf. Fig. 8 with Fig. 4). These results suggest that the spread in climate change projections in the ensemble simulations is partially due to the dynamically induced internal variability.
5 Warm and cold extreme trends
-
(a)
Projected trends, trend variances, and signal-to-noise ratios
Figure 9 displays the DJF mean warm extreme TX90 trends over the period 2010–2055 for each ensemble member and the EnM. Figure 10 shows the corresponding cold extreme TX10 results. In general, TX90 increases and TX10 decreases over North America. This suggests that more severe warm days and fewer extreme cold days are projected over North America in the next half century, generally consistent with previous studies (e.g., Meehl and Washington 1996; Sillmann et al. 2013b). The patterns of the warm and cold extreme trends differ from that of the SAT trends described above. In addition, the projected TX10 trends show larger uncertainties across the 50 members compared to the TX90 trends.
The projected TX90 trends exhibit consistent increases of warm days over North America across the ensemble members, with strong warm extreme increases over the western coast and northern Canada, accompanied by relatively weak extreme increases over the midsection of the continent (Fig. 9). The pattern correlations between each member and the EnM range from 0.70 to 0.96, with a mean of 0.87. Meanwhile, most members have relatively higher spatial variances than the EnM variance, with the variance ratio below 150% (Fig. 11, upper-left). These further indicate the good correspondence in the individual members, and differences mainly in trend magnitude. Hence, an increase in extreme warm temperature days will be seen in the future, with high risks of extreme warm days over the western coast and northern Canada, although large uncertainties are seen in the climatological means of individual ensemble members (Fig. 2). By contrast, the projected TX10 trends reveal considerable differences across the 50 ensemble members (Fig. 10). The TX10 trends are dominated by decreases in extreme cold days for most members, but with large variations in spatial pattern and magnitude. Additionally, 9 out of the 50 members show patches of cold extreme increases over North America, especially with TX10 increases over the central US in member 5. The EnM of TX10 trends reveals a somewhat northwest-to-southeast orientation belt of strong cold extreme decreases, extending from Alaska to the northeast US. The pattern correlations between each member and this EnM are low, with a wide range from 0.14 to 0.68 and a mean of 0.43. In addition, all members have much higher spatial variances than the EnM variance, with the variance ratio ranging approximately from 150 to 350% (Fig. 11, upper-right). The spread in individual values of spatial correlations and variances indicates that the individual members depart considerably from the EnM. Overall, the agreement of the TX90 trends among individual members is evident, whereas large uncertainties are apparent in the TX10 trends.
Figure 12 further shows the ESTD and SNR patterns of the TX90 and TX10 trends. For warm extreme trends, the inter-member variability features a broadly uniform structure, with relatively high variances over the western-central US. The SNR pattern tends to be dominated by the EnM trend pattern, with strong signals over the western coast and northern Canada, accompanied by relatively weak signals over the midsection of North America. This SNR pattern also bears some resemblance to that of the SAT trends (Fig. 5). In contrast, large variances of the cold extreme trends across the ensemble members appear over the western-central parts of southern Canada and the US, especially the Great Plains of North America. The SNR pattern is contributed by both the EnM and ESTD patterns of TX10 trends, with strong signals over the southwestern US, northern Canada, and the northeastern US.
The large spread of projected TX10 changes has also been found in previous studies, especially for weak climate change scenarios (Sillmann et al. 2013b). It remains unclear what is responsible for the spread difference between the projected TX10 and TX90 trends. The difference may be attributed to different changes in the surface temperature advection and local radiative and turbulent fluxes that are directly related to the temperature variation through the surface energy balance (e.g., Campbell and Vonder Haar 1997; Durre and Wallace 2001; Loikith and Broccoli 2012; Horton et al. 2015; Krueger et al. 2015; Tamarin-Brodsky et al. 2019), and/or to differences in remote driving mechanisms for warm and cold extremes (e.g., Johnson et al. 2018).
-
(b)
Forced and internal components of projected trends
The temperature extreme trend is also decomposed into externally anthropogenic forced and internal climate variability generated components. For warm extreme TX90, the regional means of total trends over North America range from 13.01%/45 year (member 27, M27) to 21.18%/45 year (member 40, M40) across the 50 members, with a mean of 16.83%/45 year that is also the regional mean of the forced trend. Hence, the regional means of internally generated TX90 trends have a changing range from − 3.82%/45 to 4.35%/45 year. Figure 13 shows the total, externally forced, and internally generated TX90 trends for the two members with the lowest and highest regional mean trends. These two members have broadly similar structure of total trends compared to their EnM (Fig. 13, top and middle rows), with a spatial correlation of 0.89 (0.83) between M27 (M40) and EnM over North America. The most notable discrepancy between them is in trend magnitude, with differences of 10–25%/45 year over the central parts of North America. The difference is also clearly evident in the internally generated TX90 trend (Fig. 13, bottom row), which shows large-scale spatial coherence over North America. In addition, the internally generated trend is comparable to the forced trend in the central parts of the continent, and hence contributes noticeably to the total trend.
For cold extreme TX10, the regional means of total trends range from − 7.25%/45 year (member 17, M17) to − 2.89%/45 year (member 5, M5) over the 50 members, with a mean of − 4.40%/45 year, over North America. Figure 14 presents the total, externally forced and internally generated TX10 trends for M17 and M5. Unlike those seen in TX90 trends, the total TX10 trends in these two members are quite different from their EnM or the forced trend (Fig. 14, top and middle rows), including spatial structure and magnitude of the trends. M17 exhibits decreases of extreme cold days over the whole continent, with striking changes over western-central Canada and the northern US. In contrast, M5 reveals decreases of extreme cold days mainly over Canada and the western and northeastern US, accompanied by cold extreme increases over the central US. The two patterns are hence uncorrelated, with a correlation of 0.04 over North America. The pattern correlation between M17 (M5) and EnM is 0.58 (0.39). In addition, the magnitude of internally generated TX10 trends (Fig. 14, bottom row) is also comparable to that of the forced trend, especially over the central portions of the continent.
The internally generated TX90 and TX10 trends show large-scale spatial coherence over North America, a feature seen above in the SAT trends. The uncertainties in the climatological means and projected changes of extreme warm and cold days suggest that the simulation of North American temperature extremes is likely very uncertain and needs to be applied with caution.
-
(c)
Dynamically adjusted trends
Given the association between large-scale circulation anomalies and the synoptic-scale weather variability (e.g., Wallace and Gutzler 1981; Yu et al. 2019), as analyzed above, we remove the influence of the first three SLP trend predictors to get dynamically adjusted versions of the warm and cold extreme trends. The lower panels of Fig. 11 compare the spatial pattern correlation and variance for individual members to their EnMs for the adjusted TX90 and TX10 trends. For warm extreme TX90, the pattern correlations between each member and the EnM range from 0.71 to 0.96, with a mean of 0.89 that is slightly higher than that of the total trends (0.87) described above. For cold extreme TX10, the pattern correlations still show a wide range from 0.21 to 0.72, with a mean of 0.47 that is also slightly higher than the mean of the total trend (0.43). In addition, the ratios of individual member variances to their EnM variance for the adjusted TX90 and TX10 trends are slightly lower compared to those for the corresponding total trends.
The total and dynamically adjusted TX90 and TX10 trends for the two members discussed above in Figs. 13 and 14 have further been compared. For TX90, the dynamically adjusted trends for M27 and M40 exhibit similar structure compared to the corresponding total trends, with slightly weaker trend values over the centers of action (not shown). The pattern correlation increases slightly from 0.89 for the total trend to 0.94 for the adjusted trend between M27 and EnM, and from 0.83 to 0.86 between M40 and EnM. For TX10, the dynamically adjusted trends also show slightly weaker action centers than their total trends for M17 and M5 (cf. Fig. 15 with the top row of Fig. 14). In addition, a cold extreme decrease belt extending from northwest Canada to the northeast US prevails in the dynamically adjusted patterns for both members (Fig. 15), which broadly follows the extreme decrease belt apparent in the EnM (Fig. 14, middle panels). Accordingly, the two adjusted patterns resemble more than their total trend counterparts do. The pattern correlation of the dynamically adjusted trend between M17 and M5 is 0.60, much higher than that of the total trend (0.04) discussed above. In addition, the pattern correlation increases from 0.58 for the total trend to 0.67 for the adjusted trend between M17 and EnM, and from 0.39 to 0.56 between M5 and EnM.
Overall, by partially reducing the contribution of the circulation-induced components of the TX90 and TX10 trends, the individual ensemble members resemble their ensemble mean more than the total trends do. However, the circulation influence on the projected temperature extreme trends is generally modest, especially for the cold extreme TX10 (Fig. 11, right column).
6 Summary and discussion
Based on a 50-member large ensemble of climate simulations conducted with CanESM2, together with the observational and NCEP reanalysis data, we study the role of internal climate variability in climate change projections of wintertime surface air temperature and temperature extremes over North America. The CanESM2 performance is evaluated by comparing the DJF climatological patterns of surface air temperatures as well as extreme indices of warm and cold days in its historical simulations with the corresponding observation based results. We then focus on exploring the projected trends of mean and extreme temperatures over the period 2010–2055, by analyzing the anthropogenic radiative forced simulations with the RCP8.5 scenario. The projected mean surface temperature trends obtained from CanESM2 are also compared to those from other climate models. We examine the external anthropogenic forced and internal climate variability generated components of the projected temperature and temperature extreme trends, and analyze the influences of large-scale circulation-induced variability on these trends. The main findings from this analysis can be summarized as follows.
-
1.
CanESM2 large ensemble simulations confirm the important role of internal climate variability in the projected SAT trends, including magnitude and spatial structure, which is consistent with those obtained from other climate models. However, CanESM2 tends to be less uncertain in projecting North American warming trends in the next half century than CCSM3 and ECHAM5. The SAT response to external forcing is more detectable over northern Canada, Alaska, and the southwestern US than the midsection of the continent.
-
2.
The role of internal climate variability in temperature extreme simulations is apparent in both the DJF climatological mean and projected trend. The ensemble mean climatological patterns of TX90 and TX10 indices are qualitatively similar to the corresponding observed patterns. However, both indices exhibit large uncertainties in spatial structure and magnitude of the DJF means across the 50 ensemble members. More severe warm days and fewer extreme cold days are projected over North America in the next half century. Yet the projected TX10 trends show larger uncertainties compared to the TX90 trends. The ensemble mean of the TX90 trends reveals high risks of extreme warm days over the western coast and northern Canada. The difference across the ensemble members mainly appears in magnitude. Additionally, the signal-to-noise ratio pattern of the TX90 trends is similar to that of the SAT trends. By contrast, the ensemble mean of the TX10 trends exhibits an extreme cold day decrease belt extending from Alaska to the northeast US. The individual members depart considerably from this ensemble mean in spatial pattern and magnitude of the trends. The SNR pattern of the TX10 trends reveals strong signals over the southwestern US, northern Canada, and the northeastern US.
-
3.
The internal climate variability generated components of the mean and extreme temperature trends exhibit large-scale spatial coherences over North America, as well as variations across ensemble members. The internally generated trend is comparable to the externally forced trend, especially in the central parts of North America, and hence contributes noticeably to the total trend. The large-scale atmospheric circulation-induced temperature variability influences these projected trends. Removing the influences of the three leading SLP trend predictor patterns on the mean and extreme temperature trends, the dynamically adjusted trends for individual members resemble the corresponding ensemble mean more than the total trends do.
The dynamically adjusted method applied here in estimating the large-scale circulation influence on climate change projected trends may not be the best approach in capturing the circulation-induced variability on temperature extremes. For example, the linkage between the projected sea level pressure and temperature extreme trends is not obvious in the southern parts of North America (cf. contours in the middle row of Fig. 6 with the middle rows of Figs. 13 and 14). The circulation anomalies in association with the temperature extreme trends may be more closely related to the synoptic-scale circulation variability (e.g., Favre and Gershunov 2006; Yu et al. 2019). Regional-scale dynamical and thermodynamical anomalies as discussed in Sect. 5 would also lead to surface temperature and temperature extreme anomalies through the variation of the surface energy budget. These relevant issues remain to be investigated. In addition, McKinnon et al. (2017) found that the internal variability in forced climate trends over North America tends to be overestimated in large ensemble climate simulations. Internal variability simulated by climate models may be inconsistent with observations due to model biases. It remains to be clarified whether CanESM2’s consistent SAT warming trends are related to its warm model bias.
References
Arora VK et al (2011) Carbon emission limits required to satisfy future representative concentration pathways of greenhouse gases. Geophys Res Lett 38:3–8
Boer GJ (2009) Changes in interannual variability and decadal potential predictability under global warming. J Clim 22:3098–3109. https://doi.org/10.1175/2008JCLI2835.1
Boer GJ, Lambert S (2001) Second-order space-time climate difference statistics. Clim Dyn 17:213–218
Campbell GG, Vonder Haar TH (1997) Comparison of surface temperature minimum and maximum and satellite measured cloudiness and radiation. J Geophys Res 102:16639–16645
Chen S, Yu B (2019) The seasonal footprinting mechanism in large ensemble simulations of the second generation Canadian Earth System Model: Uncertainty due to internal climate variability. Clim Dyn (under review)
Chen S, Wu R, Chen W (2019) Projections of climate changes over mid-high latitudes of Eurasia during boreal spring: uncertainty due to internal variability. Clim Dyn 53:6309–6327
Collins M, et al (2013) Long-term climate change: projections, commitments and irreversibility. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, pp 1029–1036
Collins M, Allen MR (2002) Assessing the relative roles of initial and boundary conditions in interannual to decadal climate predictability. J Clim 15:3104–3109
Deser C, Knutti R, Solomon S, Phillips AS (2012a) Communi-cation of the role of natural variability in future North American climate. Nat Clim Change 2:775–779. https://doi.org/10.1038/nclimate1562
Deser C, Phillips AS, Bourdette V, Teng H (2012b) Uncertainty in climate change projections: the role of internal variability. Clim Dyn 38:527–546. https://doi.org/10.1007/s00382-010-0977-x
Deser C, Phillips AS, Alexander MA, Smoliak BV (2014) Projecting North American climate over the next 50 years: uncertainty due to internal variability. J Clim 27:2271–2296. https://doi.org/10.1175/JCLI-D-13-00451.1
Deser C, Sun L, Tomas RA, Screen J (2016) Does ocean coupling matter for the northern extratropical response to projected Arctic sea ice loss? Geophys Res Lett 43:2149–2157
Donat MG et al (2013) Updated analyses of temperature and precipitation extreme indices since the beginning of the twentieth century: the HadEX2 dataset. J Geophys Res Atmos 118:2098–2118
Durre I, Wallace JM (2001) Factors influencing the cold-season diurnal temperature range in the United States. J Clim 14:3263–3278
Favre A, Gershunov A (2006) Extra-tropical cyclone/anticyclone activity in North Eastern Pacific and air temperature extremes in Western North America. Clim Dyn 26:617–629
Gan B et al (2017) On the response of the Aleutian low to greenhouse warming. J Clim 30:3907–3925
Hawkins E, Sutton R (2009) The potential to narrow un-certainty in regional climate predictions. Bull Am Meteorol Soc 90:1095–1107
Hawkins E, Sutton R (2011) The potential to narrow uncertainty in pro-jections of regional precipitation change. Clim Dyn 37:407–418. https://doi.org/10.1007/s00382-010-0810-6
Holmes CR, Woollings T, Hawkins E, De Vries H (2016) Robust future changes in temperature variability under greenhouse gas forcing and the relationship with thermal advection. J Clim 29:2221–2236
Horton DE et al (2015) Contribution of changes in atmospheric circulation patterns to extreme temperature trends. Nature 522:465–469
Hu A, Deser C (2013) Uncertainty in future regional sea level rise due to internal climate variability. Geophys Res Lett 40:2768–2772. https://doi.org/10.1002/grl.50531
IPCC (2013) Climate Change 2013: the physical science basis. Cambridge University Press, Cambridge, p 1535
Johnson NC, Xie SP, Kosaka Y, Li X (2018) Increasing occurrence of cold and warm extremes during the recent global warming slowdown. Nat Commun 9:1724
Kang SM, Deser C, Polvani LM (2013) Uncertainty in climate change projections of the Hadley circulation: the role of internal variability. J Clim 26:7541–7554
Kay J et al (2015) The Community Earth System Model (CESM) large ensemble project: a community resource for studying climate change in the presence of internal climate variability. Bull Am Meteorol Soc 96:1333–1349. https://doi.org/10.1175/BAMS-D-13-00255.1
Kirchmeier-Young MC, Zwiers FW, Gillett NP (2017) Attribution of extreme events in Arctic sea ice extent. J Clim 30:553–571. https://doi.org/10.1175/JCLI-D-16-0412.1
Kistler R et al (2001) The NCEP-NCAR 50-year reanalysis: monthly means CD-ROM and documentation. Bull Am Meteorol Soc 82:247–268
Klein Tank MG, Zwiers FW, Zhang X (2009) Guidelines on analysis of extremes in a changing climate in support of informed decisions for adaptation, Climate data and monitoring WCDMP-72, WMO-TD No. 1500, 56 pp
Krueger O, Hegerl GC, Tett SF (2015) Evaluation of mechanisms of hot and cold days in climate models over Central Europe. Environ Res Lett 10(1):014002
Loikith PC, Broccoli AJ (2012) Characteristics of observed atmospheric circulation patterns associated with temperature extremes over North America. J Clim 25:7266–7281
Manabe S, Stouffer RJ (1980) Sensitivity of a global climate model to an increase of CO2 concentration in the atmosphere. J Geophys Res 85:5529–5554
McKinnon KA, Poppick A, Dunn-Sigouin E, Deser C (2017) An “observational large ensemble” to compare observed and modeled temperature trend uncertainty due to internal variability. J Clim 30:7585–7598
Meehl GA, Washington WM (1996) El Niño–like climate change in a model with increased atmospheric CO2 concentrations. Nature 382:56–60
North GR, Moeng FJ, Bell TJ, Cahalan RF (1982) Sampling errors in the estimation of empirical orthogonal functions. Mon Weather Rev 110:699–706
Salathe EP (2006) Influences of a shift in North Pacific storm tracks on western North American precipitation under global warming. Geophys Res Lett 33:L19820
Scinocca JF, McFarlane NA, Lazare M, Li J (2008) The CCCma third generation AGCM and its extension into the middle atmosphere. Atmos Chem Phys 8:7055–7074
Sheffield J et al (2013) North American climate in CMIP5 experiments. Part II: evaluation of historical simulations of intraseasonal to decadal variability. J Clim 26:9247–9290
Sillmann J, Kharin VV, Zwiers FW, Zhang X, Bronaugh D (2013a) Climate extremes indices in the CMIP5 multimodel ensemble: part 2. Future climate projections. J Geophys Res Atmos 118:2473–2493
Sillmann J, Kharin VV, Zwiers FW, Zhang X, Bronaugh D (2013b) Climate extremes indices in the CMIP5 multimodel ensemble: part 1. Model evaluation in the present climate. J Geophys Res Atmos 118:1716–1733
Sun L, Deser C, Tomas RA (2015) Mechanisms of stratospheric and tropospheric circulation response to projected Arctic sea ice loss. J Clim 28:7824–7845
Tamarin-Brodsky T, Hodges K, Hoskins B, Shepherd T (2019) A dynamical perspective on atmospheric temperature variability and its response to climate change. J Clim 32:1707–1724
Thompson DWJ, Wallace JM (1998) The Arctic Oscillation signature in wintertime geopotential height and temperature fields. Geophys Res Lett 25:1297–1300
Thompson DWJ et al (2015) Quantifying the role of internal climate variability in future climate trends. J Clim 28:6443–6456. https://doi.org/10.1175/JCLI-D-14-00830.1
van Vuuren DP et al (2011) The representative concentration pathways: an overview. Clim Change. 109:5–31. https://doi.org/10.1007/s10584-011-0148-z
von Salzen K et al (2013) The Canadian fourth generation atmospheric global climate model (CanAM4). Part I: representation of physical processes. Atmos Ocean 51:104–125
Wallace JM, Gutzler DS (1981) Teleconnections in the geopotential height field during the Northern Hemisphere Winter. Mon Weather Rev 109:784–812
Wallace JM, Deser C, Smoliak BV, Phillips AS (2014) Attribution of climate change in the presence of internal variability. In: Chang CP et al (eds) Climate change: multidecadal and beyond, vol 6. Asia-Pacific weather and climate series. World Scientific, Singapore, pp 1–29
Wettstein JJ, Deser C (2014) Internal variability in pro-jections of twenty-first century Arctic sea ice loss: role of the large-scale atmospheric circulation. J Clim 27:527–550
Yu B, Lin H, Kharin VV, Wang XL (2019) Interannual variability of North American winter temperature extremes and its associated circulation anomalies in observations and CMIP5 simulations. J Clim. https://doi.org/10.1175/JCLI-D-19-0404.1
Zhang R, Delworth TL (2007) Impact of the Atlantic multidecadal oscillation on North Pacific climate variability. Geophys Res Lett 34:L23708
Zhang X et al (2005) Avoiding inhomogeneity in percentile-based indices of temperature extremes. J Clim 18:1641–1651
Acknowledgements
We greatly appreciate the work of colleagues at the CCCma in the production of the model results analyzed here. We thank Tommy Jang and Hui Wan for assistance in data processing, Yang Feng for help with graphing, and Dr. Megan Kirchmeier-Young for helpful comments on an early version of the manuscript. We thank the two anonymous reviewers for their constructive suggestions and comments, which helped to improve the study. Data used in this study are described in Sect. 2. Shangfeng Chen is supported by the National Natural Science Foundation of China grants (41605050, 41530425, and 41775080), and the Young Elite Scientists Sponsorship Program by the China Association for Science and Technology (2016QNRC001).
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Yu, B., Li, G., Chen, S. et al. The role of internal variability in climate change projections of North American surface air temperature and temperature extremes in CanESM2 large ensemble simulations. Clim Dyn 55, 869–885 (2020). https://doi.org/10.1007/s00382-020-05296-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00382-020-05296-1