Abstract
Marine Cold-Air Outbreaks (MCAO) can be used as a large-scale measure of the potential for development of Polar Lows in the Northern North Atlantic Ocean during NH winter. We applied an MCAO index to 30 members of the Community Earth System Model Large Ensemble to investigate model-projected future changes in the Nordic and Barents Seas in response to anthropogenic climate change. In agreement with previous studies we found an overall decrease in the MCAO index due to increased tropospheric static stability. We also found a changed seasonal profile, with a stronger decrease in December–January than in February–March, effectively leading to the peak occurring in February rather than January in the Nordic Seas. In the Barents Sea, the reductions were only statistically significant in the autumn and spring, with the winter reduction due to increased static stability was partly balanced by a retracting sea-ice edge. The contribution from circulation changes in mean sea-level pressure was assessed by a cluster analysis in lower-dimensional phase-space, spanned by the projections onto the four leading Empirical Orthogonal Functions. While there was a small but statistically significant increase of the Atlantic Ridge-like pattern, the overall changes in MCAO were dominated by changes in temperature at the sea surface and aloft.
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1 Introduction
When a cold air mass, typically originating from an ice-covered sea area, is advected over open water, a large flux of latent heat is triggered from the ocean to the atmosphere, due to the (relatively) much higher temperature of the water. This pattern is called a Marine Cold-Air Outbreak (MCAO, Kolstad and Bracegirdle 2008; Mansfield 1974), and is important for the formation of small-scale, marine cyclones, polar lows (PL), which cause severe weather conditions that combine strong winds with heavy snow-fall and freezing sea-spray at the high latitudes.
Due to their small size (diameter \({\sim }\) 200 to 1000 km) and short lifetime (1–2 days), polar lows (e.g. Harrold and Browning 1969; Reed 1979; Wilhelmsen 1985; Businger 1985; Emanuel and Rotunno 1989; Nordeng and Rasmussen 1992; Kristjánsson et al. 2011; Rasmussen 2011) have historically been difficult to detect and forecast. They still cannot be well resolved in global climate models, which typically still employ grid mesh widths of \(1{^\circ}\)–2°, thus typically resolving structures with wavelengths larger than a thousand kilometers. MCAO, however, are large-scale phenomena, and can serve as a proxy for conditions governing polar low development.
Kolstad and Bracegirdle (2008) from now KB08, developed an MCAO index, quantifying the lower tropospheric static stability based on potential temperature at 700 hPa, sea-surface skin temperature, and surface pressure. They applied it to 13 models from the Coupled Model Intercomparison Project phase 3 (CMIP3) ensemble, and found a future northward shift and weakening of the MCAO. Zahn and von Storch (2010) performed dynamical downscaling with \({\sim }\) 50 km grid mesh width and found a future northward shift of the polar low genesis regions.
Stoll et al. (2018) compared over 20 different criteria for polar low detection using the STARS polar low database (Noer et al. 2011), and reanalysis data from ERA-Interim and the Arctic Systems Reanalysis (ASR). They found the MCAO criterium from KB08 to be very close to their most effective criterium.
Romero and Emanuel (2017) used a statistical-deterministic model to investigate PLs in the CMIP5 ensemble. They found an overall reduction in frequency of occurrence, but an increase in the Norwegian and Barents Seas. They analysed the change to be mostly driven by changes in SST and the frequency and intensity of Cold-Air Outbreaks.
Kolstad et al. (2009) from now KBS09, analysed the same index as KB08 in relation to governing circulation patterns for three different North Atlantic areas, and found a negative correlation (\(r = -\,0.42\)) between North Atlantic Oscillation (NAO) and MCAO indices in the Barents Sea region.
In general, the spread in future climate estimates can be traced to three causes (Hawkins and Sutton 2009): future scenario uncertainty, model process uncertainty, and internal natural variability. The first point relates to the assumed scenarios of socioeconomic pathways, including geopolitical issues and technological advancements. The second point relates to how different modelling groups choose and formulate physical processes in their models, such as sub-grid-scale turbulence, deep convection, aerosols and cloud microphysics, radiation, ground-surface processes, or biogeochemistry. The protocol of the CMIP experiments helps to dispense with this issue by using common future scenarios and a standard output format that facilitates sharing and comparing model results. The third point, internal variability, relates to both how the climate system as a chaotic non-linear dynamical system is sensitive to small perturbations, and how modes of naturally occurring patterns of variability, e.g. NAO, evolve. Investigating the role of internal variability under non-stationary climate conditions, requires a large ensemble of climate simulations from a model with satisfactory representation of the variability patterns.
All of the above mentioned studies are based on model ensembles with few members of each model. This is partly due to the high computational resources associated with running a climate model for hundreds of years. This makes it difficult to adequately quantify the internal variability, and to separate it from the response to different external forcing applied in the future scenario or from the spread due to model uncertainty. In the multi-model ensemble approach of e.g. the CMIP3 and CMIP5, although they do contain over 100 members in total, each model is typically represented by a single-digit number of realisations. Such ensembles may therefore still not be able to answer the question of the role of natural variability.
With the relatively recent arrival of large ensembles such as the CCSM 1.4 62-member ensemble (Selten et al. 2004), the 17-member ECHAM5/MPI-OM ensemble (Sterl et al. 2008), the 50-member ensemble of CanESM2 (Kirchmeier-Young et al. 2016) and the 40-member CESM Large Ensemble, from now on referred to as CESM-LE, (Kay et al. 2015), we now have better opportunities for separating natural variability and systematic effects of an external forcing. Of these four, the CESM-LE has the highest horizontal resolution (\(\sim\)1 degree, compared to 3.75, 1.89 and 2.81 for the other three). CESM-LE and CanESM2 also use a more recent emissions scenario (RCP 8.5, Riahi et al. 2011). By neglecting model uncertainty, all of the ensemble spread from a single-model ensemble originates from internal variability as it is represented in the specific model. In multi-model ensembles, the spread is a combination of model uncertainty and internal variability. In the CMIP5 ensemble, for example, the sampling of model uncertainty is quite arbitrary, as there is no systematic generation of perturbations of model process formulations in the ensemble. Furthermore, the part of the ensemble spread that represents natural variability is under-sampled, as there are few ensemble members per model.
In this study we apply the same MCAO index and two of the same areas as KBS09 to 30 membersFootnote 1 of the CESM-LE to investigate what processes condition future changes in MCAO. Apart from retreat of sea-ice and increase in surface and tropospheric temperatures, we also hypothesize that changes in the frequency of occurrence of circulation patterns may play a role (e.g. as in, Corti et al. 1999). We attempt to answer the following four questions: (1) how well does the CESM-LE represent MCAO compared to ERA-Interim? (2) What are the projected future changes in MCAO and how does natural variability change? (3) How can these changes be attributed to different processes? and (4) Can any trends be explained by changes in circulation?
The structure of the article is as follows: the data and methods are presented in Sect. 2, including the definition of the MCAO index used. Section 3 presents the results and discussion, including model evaluation (Sect. 3.1), projected future changes and attribution (Sect. 3.2), and relation to circulation patterns (Sect. 3.3). Conclusions are presented in Sect. 4.
2 Data and methods
2.1 Model and reanalysis data
We retrieved data from members 1–30 of the CESM Large Ensemble (Kay et al. 2015) for the years 1920–2005 (historical greenhouse gas emissions) and 2006–2080 (RCP 8.5 scenario). The variables used are listed in Table 1. All variables were retrieved as daily means, while some of the analysis is performed aggregated to monthly means or percentiles. For validation we also retrieved the corresponding variables from the ERA-Interim reanalysis (Dee et al. 2011).
Potential temperature \(\theta\) was calculated using \(\theta = T(p_0 / p) ^{R/c_p}\), where \(R/c_p = 0.286\) and \(p_0 =\) 1000 hPa.
2.2 MCAO index
We use an MCAO index \(\mu\) from KB08, but with potential temperatures at the 500 hPa rather than 700 hPa level:
where \(\theta _{\text {SKT}}\) is the 'potential surface skin temperature', as in KB08, by
\(\mu\) is a measure of the lower atmospheric static stability and is calculated at each grid point on daily time resolution. For more details about the index we refer to KB08. In their review of different PL detection criteria, Stoll et al. (2018) found \(\theta _{\text {SKT}}-\theta _{500}\) to be the most efficient criterium, but the performance of \(\mu\) was very close (with a threshold including 90% of the PLs, the \(\theta _{\text {SKT}}-\theta _{500}\) criterium excluded 88.5% non-PL cyclones, compared with 86.9% for the KB08 criterium).
Bracegirdle and Gray (2008) argued for using the 700 hPa level due to the high diabatically induced vertical motion around this level in many Nordic seas polar low case studies, and stated that the 500 hPa level may be too far above the boundary layer to detect the relevant air-sea temperature difference. On the other hand, Stoll et al. (2018) found that using the potential temperature at the 500 hPa level more efficiently filters out non-PL cyclones. They also noted that Bracegirdle and Gray (2008) used a smaller database of only 58 cases, consisting of both PLs and weaker cyclones. The difference between SST and the temperature at 500 hPa is also routinely used for polar low forecasting at the Norwegian Meteorological Institute. Additionally, because daily data from CESM-LE for the full period 1920–2080 were only available at a few pressure levels (850, 500, 200 and 10 hPa), we could not choose 700 hPa directly, so we settled on 500 hPa. However, for comparison we also performed the analysis based on potential temperature at 700 hPa interpolated from 500 and 850 hPa. We focus particularly on two areas, shown in Fig. 1, which are the same as in KBS09:
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1.
Nordic Seas (NS): \(20^\circ\)W–\(20^\circ\)E, \(65^\circ\)N–\(78^\circ\)N (consisting of the Greenland, Iceland, Norwegian Seas, sometimes referred to as the GIN Seas).
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2.
Barents Sea (BS): \(20^\circ\)E–\(54^\circ\)E, \(70^\circ\)N–\(78^\circ\)N.
As in Kolstad (2011), grid points with a surface skin temperature below \(-\,1.9^\circ\) C were assumed to be covered with sea ice and not used. The remaining grid points were analysed either directly for daily values, or they were aggregated by taking the 90-percentiles of all available points within each area each month. These monthly time-series are from now on referred to as MCAOmon90p.
2.3 Cluster analysis
Following the method of Dawson et al. (2012) we applied a k-means clustering algorithm to diagnose occurrence of circulation patterns. Sea-level pressure anomalies were calculated relative to 1920–2005 climatology. The Euro-Atlantic area \(90^\circ\)W–\(50^\circ\)E, \(30^\circ\)N–\(90^\circ\)N was used. For the DJFM season and member 1 of the ensemble, the phase space was reduced by projecting onto the four leading principal components. The data was then analysed using k-means clustering to form four clusters. These were used as initial centroids for assigning daily DJFM data for all ensemble members. A filter was applied in order to only include periods with at least 3 consecutive days assigned to the same pattern, removing approximately 13.8% of the days. For each day the 90-percentile of the grid point values within each area (i.e. percentile in the longitude and latitude dimension) was calculated, giving a time series for each area. The 90-percentile was then taken again, in the time dimension, in order to select the days with the 10% highest (90–100 p) values. The cluster assignments for these days were then used to analyse the frequency of occurrence of the four circulation patterns.
3 Results and discussion
3.1 Model evaluation
3.1.1 Temperature biases
The biases of \(\theta _\text {SKT}\) and \(\theta _{850}\), \(\theta _{500}\) and ice fraction from CESM-LE, taken as the ensemble mean of DJFM climatology minus ERA-Interim, is presented in Fig. 2 (individual months in Fig. S1 in the supplementary material). The model ensemble has a large cold bias in the surface skin temperature, particularly over sea-ice. For CESM1, Park et al. (2014) found that these biases are mostly of radiative origin related to clouds. On the other hand, ERA-Interim is also known to have near-surface warm biases in the winter season (e.g. Serreze et al. 2012; Simmons and Poli 2015), so the CESM-LE cold bias presented here may in fact be a few degrees smaller in reality. ERA-Interim is also only one realisation of the climate, so the spread of any ensemble can be assumed to be greater. Since we use a single-model ensemble, the unavoidable systematic model errors, or climate biases, are not compensated in the way it could have been in a carefully designed multimodel ensemble. On the other hand, we have a clean estimate of internal, natural variability. The focus of this study is, however, on open water areas in the Nordic Seas and Barents Sea, over which both the \(\theta _\text {SKT}\) and \(\theta _{850}\) biases are relatively small (\(-1\) to + 1 K are shown in grey). There is however a warm (cold) bias in \(\theta _\text {SKT}\) (\(\theta _{500}\)) around Iceland, which leads to too high MCAO index values.
3.1.2 Sea-ice concentration
The fourth panel in Fig. 3 shows that the model ensemble has a positive bias in sea-ice fraction. This is particularly strong near the eastern coast of Greenland (the Fram Strait and the East-Greenland current) but weaker and over a larger area in the Barents Sea. This sea-ice bias also explains the surface skin temperature biases in these regions. One challenge lies in the strong observed sea-ice reduction in recent decades, especially in the Barents Sea. Li et al. (2017) attributed the strong sea-ice decline in the Barents Sea to enhanced oceanic heat transport due to strong regional internal variability, which is not sufficiently well represented in CMIP5 models. Onarheim and Årthun (2017) compared sea-ice concentration in CESM-LE and three other earth system models with observations over the Barents Sea. They found that internal variability can explain 72% of the trend in the past 30 years, if one assumes that the ensemble mean of CESM-LE represents the trend from external forcing correctly. Both references highlight the combination of forced response and internal variability needed to represent the observed sea-ice decline.
Swart et al. (2015) analysed the long-term trend in September Arctic sea ice and concluded that neither the CESM-LE nor the CMIP5 ensembles systematically under-represent the sea-ice response to external forcing when accounting for internal variability. Sea-ice biases may however be larger on a regional scale, as can be seen in Fig. 3. While the northern hemispheric total sea-ice concentration follows ERA-Interim rather closely, a positive sea-ice bias in CESM-LE is more apparent in the smaller regions. In the future period the autumn minimum is extended, with the Barents Sea region becoming ice-free for half of the year and the peak being delayed by 1–2 months. The ensemble spread is largest for the Barents Sea, which is expected as it is also the smallest area.
3.1.3 Circulation patterns
The four clusters obtained from the k-means clustering method are shown in Fig. 4. These patterns are similar to those found in Dawson et al. (2012), although with distortions compared to re-analyses. We refer to the patterns using the same names, although we note that Davini and Cagnazzo (2014) caution that what is detected as the NAO from different CMIP5 models may actually come from different physical processes, so the implications under climate change may be different for different models.
Kim et al. (2017) found that the CESM-LE represents well the observed NAO on interannual to decadal time scale, but underrepresents the multidecadal variability. In terms of spatial structure, our NAO− pattern indicates too zonal storm tracks, as discussed in Day et al. (2018) and Zappa et al. (2013) for the CESM-LE and CMIP5 ensembles, respectively. Dawson et al. (2012) showed that the horizontal resolutions typically used in the CMIP5 ensemble may not be sufficient to reproduce observationally based circulation regimes.
3.2 Projected future changes and attribution
In the future period high values of the MCAO index, indicating a statically unstable troposphere, become less frequent. The spatial distribution of MCAO index values is shown in Fig. 5. Here the 90-percentile is estimated separately from the time series of each grid cell and model ensemble member, and then averaged over all ensemble members. Areas of high values are located around the southern tip of Greenland as well as between the Norwegian mainland and Svalbard. The values from CESM-LE are higher than those from ERA-Interim due to the temperature biases discussed in Sect. 3.1.1.
There are two main competing mechanisms driving the future changes in different areas: first, over open water, there is an increase in the tropospheric temperature which is larger than the SST increase and therefore increases the static stability (reduces the MCAO index values). This is strongest in the North-Atlantic ocean, but apparent in the Pacific ocean as well. A particularly strong signal is found south of Greenland, where a weakening Atlantic Meridional Overturning Circulation leads to a much smaller increase in SST as discussed in Kolstad and Bracegirdle (2008). Second, there is a decrease in sea-ice concentration (Fig. 3), which enables higher frequency of occurrence of MCAO over new areas with open water.
Separating the statistics into different months, Fig. 6 shows the ensemble mean trend in the MCAO index as well as trends of SST, \({\uptheta _{500}}\) and ice fraction. (The change in mean \(p_\text {SL}\) corresponds to an MCAO index change of less than 1% and is not shown.) To select days relevant for polar lows, we apply a threshold of − 20 K/bar. This value is the 10-percentile value of the MCAO index of PLs in Stoll et al. (2018), i.e. 90% of all PLs in that study occur when the MCAO index is above that value. We then select only 10% of the days—the ones with largest area above the threshold. This is done for each month and member separately, so that there are on average 3 days per month from each member. There are naturally months with no days as well as months with more than 10 days selected due to persistent circulation favouring MCAO. For each selected day the regional mean of the SST, \({\uptheta _{500}}\) and ice fraction is calculated, and the timeseries of the ensemble mean is shown in Fig. 6.
In both regions, \(\theta _{500}\) shows a smaller warming in January and February than in December and March. In the Nordic Seas, this in combination with the weak SST increase in December and January, means that these two months have a stronger decline in MCAO index. An effect of this is the future peak of the strong MCAO season being shifted from January and more towards February in the Nordic Seas.
While Nov–Jan shows a stronger MCAO decrease than Feb–Apr in the Nordic Seas, the results are the opposite for the Barents Sea. There, the start of the freeze-up season is delayed month by month, accompanied by a gradually increasing SST. The lower temperatures and larger seasonal variation of sea ice in Barents Sea (cf. Fig. 3) also means that the SST trends can be stronger in December there. The large BS SST increases counteract the increase in \({\uptheta _{500}}\), resulting in a smaller decrease in the MCAO index in the beginning of the winter season.
Interestingly, the months with the largest reduction in sea-ice cover are also the ones with the largest decrease in MCAO index. While this may sound contradictory to the earlier statement that MCAO values increase in areas of melting sea-ice, both are in fact true. Starting out from very low surface temperatures over ice, the MCAO index increases locally as the ice melts, but with Cold-Air Outbreaks also being dependent on the cold extremes formed over sea-ice areas, the regional warming indicated by strong ice melt may also form fewer cold air masses.
The results are not very sensitive to the choice of tropospheric level. When using the 700 hPa level (interpolated from 500 to 850 hPa), instead of 500 hPa, to calculate the MCAO index, the results look similar (not shown), with the exception that the \({\text {T}}_{850}\) increase is even stronger in December, and gradually smaller in the later months. This leads to a more pronounced December MCAO decrease.
As an overview of the change in mean climatology, the vertical structure of the tropospheric warming is presented in Fig. 7. This is done without any MCAO-specific selection because data on vertical levels is only available on monthly time resolution. We can clearly see the near-surface warming in the winter months, commonly referred to as Arctic amplification, which is found in reanalyses (Simmons and Poli 2015) as well as climate models (Pithan and Mauritsen 2014; Laîné et al. 2016). Pithan and Mauritsen (2014) showed that the annual Arctic amplification is dominated by the temperature lapse-rate feedback, while the surface albedo feedback dominates during summer.
In addition to the pattern of surface warming, we see a mid-tropospheric autumn maximum and a spring minimum. Laîné et al. (2016) found a similar pattern of tropospheric temperature increase when comparing CMIP5 model runs for years 1981–2000 and 2081–2100 using the RCP4.5 scenario, although in our analysis of CESM-LE, the peak appears one month later (September rather than August). The timing of this maximum follows the peak in SST change, but contrasts the change in surface temperature, which peaks in December–January, and has its minimum in July. In the future, when the freeze-up season starts later (Fig. 3), heat fluxes from the ocean play a role also in the early winter months. Since the temperature change (Fig. 7) at the 500 hPa level is steeper throughout the winter than the SST, illustrated by the December and February values marked as dots, the impact on the MCAO index is different for different months (Fig. 6).
We then separate into areas of open water, ice only, and melting ice; shown in Fig. 7b–d, respectively. Over open water, the strong near-surface warming is gone, and the 500 hPa Dec–Feb change is comparable to the Dec–Feb SST change, giving no change in the (mean) MCAO index values. In contrast, over melting ice (d) the Dec–Feb change is more than twice as large, 4.2–3.1 at the highlighted dots compared to 0.95–0.53 for the SST.
It is worth noting that even with the strong near-surface warming, these levels are still around 15–20 K colder than the SST, which will naturally remain the source of heat for MCAO.
Figure 8 shows changes in different quantiles of the MCAO index. In the Nordic Seas the MCAO index decreases more in December and January than later in the winter, leading to a shift in the timing of the peak from January to February. In both regions the higher quantiles decrease more than the 0.75 quantile. As discussed above this is mainly due to the increase of SST and decrease of sea ice in the beginning of the season. In the Barents Sea the reduction is larger in the end of the season (except for the 0.999 quantile). Using a single-model ensemble makes it easier to draw conclusions on a changing seasonal cycle of MCAO, compared to a multi-model ensemble, when different models have very different representation of for example sea-ice.
In order to relate the MCAO index to occurrence of polar lows, we again apply the threshold of − 20 K/bar. The number of days per month with at least one grid point with value exceeding this is shown in Fig. 9. Comparing the future period with the reference period, the Nordic Seas experiences a slightly shifted peak in the future, as expected from Fig. 8. Changes in the Barents Sea are much smaller than in the Nordic Seas, but statistically significant only for non-peak months, indicating a possible shortening of the PL season in the future. The advantage of a single-model ensemble in this case is that the ensemble spread shown in Fig. 9 is only from the model system’s representation of internal variability.
The change in variability is quantified by taking the IQR (interquartile range, \(p_{75}-p_{25}\)) of the future period divided by the IQR for the historical period. The results are presented in Table 2. Not surprisingly, the variability in ice fraction decreases the most, with the Barents Sea region having all members reach total or near ice-free conditions in December and January, together with an accompanying SST variability increase. Most variables do not show a significant change in variability. The variability of frequency of potential polar low days, i.e. at least one grid point has a value above − 20 K/bar, is increased in the Nordic Seas.
A possible limitation of this study is that the two focus areas are based on favorable conditions for polar low development in the present-day. With sea ice projected to retreat one could also argue that it could be worthwhile to perform similar analyses in other areas, such as the Kara Sea. The future 90-percentiles shown in Fig. 5 indicate that although the values increase considerably in the Kara Sea, they are still lower than in the Nordic and Barents Seas.
3.3 MCAO in relation to circulation patterns
To assess if changes in circulation can explain changes in the MCAO index value, we selected days with high MCAO index values and compared the distribution of circulation during those days. The cluster analysis provided daily time-series of cluster assignments for each of the 30 ensemble members. For the two areas and each member, days with the 10% highest MCAO index values were selected. The distribution of circulation patterns for these days is shown in Fig. 10. Mallet et al. (2013) compares the occurrences of these weather patterns in six different PL articles and gives a detailed explanation of how the different patterns favour polar low development. Our results are similar in that the AR pattern gives the highest occurrence when selecting days of high MCAO index values. Looking at the changes in occurrence for all DJFM days (not only days above the 90-percentile of MCAO index) the change is significant for the NAO+ and AR patterns (grey boxes in Fig. 10), with p-values 0.0037 and 0.0130, respectively. The timeline of frequencies during the period 1920–2080 (Fig. 11) however indicates that the detected NAO+ change may be sensitive to the selection of periods.
We initially performed the analysis using \(Z_{500}\) anomalies instead of \(p_{SL}\), but due to changes over time in the mean \(Z_{500}\) field this would ideally require a more sophisticated detrending approach. Using a simple linear detrending we nevertheless found a similar increase in the frequency of the AR pattern in the 21st century.
For days with high MCAO index, the relative frequency changes are not statistically significant for any of the patterns (comparing white and red boxes in the top panels of Fig. 10), although there is a future increase in ensemble spread. When taking into account that the number of days with high MCAO index values decreases in the future (bottom panels in Fig. 10) it is clear that changes in circulation can only play a minor role. For example, despite AR (the pattern of highest occurrence of high MCAO values) increasing in the future period (grey boxes in Fig. 10), the number of days above the MCAO 90-percentile sees a large decrease in the Nordic Seas. In the Barents Sea however, there are no significant changes.
Mallet et al. (2017) found that circulation patterns give a reduced influence on the static stability in the future, as sea-ice retreat reduces the variability. The historical link between circulation pattern and static stability (and thus as a proxy for polar lows) is therefore not the same in the future, posing a challenge when using it as part of a statistical downscaling approach. In agreement with our results, they also found that the strongest stability index decrease appeared for the patterns associated with high index values (NAO and AR). They also found very small changes in the Barents Sea compared to the Norwegian Sea.
4 Conclusions
The index of Marine Cold-Air Outbreaks can serve as a large-scale diagnosis of conditions associated with the occurrence of polar lows. We applied an MCAO index to 30 members of the CESM Large Ensemble to investigate changes over the Nordic Seas and Barents Seas.
Relative to ERA-Interim, the model ensemble has some biases, but for our domain of interest the biases were found to be small over open water, which was the focus of the study. The model system in general has a positive sea-ice concentration bias ice during the ERA-Interim period. Because this may also affect atmospheric fields, this may be a limitation to the relevance of the results in this study, particularly in the Barents Sea where the sea-ice bias and future sea-ice loss is largest. We have therefore focused more on the signs and magnitudes of the changes than the actual values. We conclude as follows:
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The CESM-LE shows an overall increase in tropospheric temperature which is stronger than the surface skin temperature increase, leading to a tropospheric static stability increase and a reduction in MCAO index values.
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In areas of strong sea-ice melt, the MCAO index increases, resulting in a northward shift of MCAO. This is consistent with other studies such as Kolstad and Bracegirdle (2008) and Zahn and von Storch (2010).
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A threshold of − 20 K/bar was applied to select polar low-relevant days. Using this threshold there were statistically significant future reductions in the Nordic Seas for all months (Oct–May), with Nov–Jan exhibiting stronger reduction than Feb–Apr.
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The Nordic Seas MCAO—and potentially polar low—season is therefore shortened and shifted, with a future peak in February instead of January.
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Despite the overall reduction of the MCAO index in the Barents Sea, the only statistically significant changes in the number of days above the threshold are during off-peak season. This is likely because the future sea-ice reduction enables MCAO over larger areas during the winter months. While the peak may remain, reductions during autumn and spring months however may shorten the polar low season in the Barents Sea.
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The fraction of days with MCAO index values above − 20 K/bar shows increased variability in mid-winter in the Nordic Seas. The ice fraction has decreased variability for the December–March season in both regions. SST variability increases in the Barents Sea, particularly in December–January.
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Our k-means clustering method shows a small but statistically significant increase in the Atlantic Ridge-like circulation regime, but failed to yield any significant implications to the MCAO, and potentially polar low occurrence. The changes were completely dominated by changes in temperatures and sea ice.
In the end, polar lows are too small to be resolved by coarse global models, and the MCAO index serves only as a proxy for favorable conditions for polar low development. Current ongoing work therefore applies dynamical downscaling and a cyclone tracking algorithm to the CESM-LE, in order to assess to what extent the MCAO seasonality change also implies a change in polar low seasonality.
Notes
Between analysis and submission additional members became available, giving a current number of 40 members available. We used the first 30 members, i.e. there was no systematic selection.
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Acknowledgements
This study was funded by the Norwegian Research Council project EVA—Earth system modelling of climate Variations in the Anthropocene, Grant number 229771 under the KLIMAFORSK programme. We acknowledge the CESM Large Ensemble Community Project and supercomputing resources provided by NSF/CISL/Yellowstone. We would also like to thank the team at MPI-MET for the data processing tool Climate Data Operators, CDO (http://www.mpimet.mpg.de/cdo), as well as Charlie Zender at UCI for NetCDF Operators, NCO (http://nco.sourceforge.net/nco.html), which have made processing large amounts of climate data much easier. We also thank the three anonymous reviewers for their constructive comments.
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Landgren, O.A., Seierstad, I.A. & Iversen, T. Projected future changes in Marine Cold-Air Outbreaks associated with Polar Lows in the Northern North-Atlantic Ocean. Clim Dyn 53, 2573–2585 (2019). https://doi.org/10.1007/s00382-019-04642-2
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DOI: https://doi.org/10.1007/s00382-019-04642-2