1 Introduction

Anomalous variability in the stratosphere is an important precursor for surface weather anomalies and extremes on weekly to monthly timescales in winter and spring. In particular, sudden stratospheric warming (SSW) and strong vortex events are windows of opportunity for extended-range weather prediction e.g.,. Indeed, the stratosphere has an extended predictability limit with respect to the troposphere . These longer characteristic timescales in the stratosphere suggest a potential for increased predictability of surface weather arising from stratospheric forcing, particularly on subseasonal-to-seasonal (S2S) timescales, ranging from weeks to months. However, when it comes to predicting the variability in the stratosphere in the first place, extreme stratospheric events, especially SSW events, have a more limited predictability as compared to more neutral states of the vortex. The average predictability of an SSW is around 5–10 d in dynamical models , indicating a higher uncertainty ahead of such events.

Uncertainty in the prediction of stratospheric variability can be contributed by model uncertainty in the stratospheric mean state and in upward wave propagation , as the strength of the stratospheric polar vortex is modulated by the interaction of planetary waves with the stratospheric mean flow. The planetary waves entering the stratosphere can break, depositing momentum and thereby forcing a weakening of the westerly vortex winds. As a secondary effect, the breaking of planetary waves can also precondition the vortex into a state that is more favorable for wave propagation , which acts to guide waves towards the vortex , thus making the deposition of wave momentum more focused in the vortex area. Stratospheric variability can also be influenced by internal variability, where the stratosphere can be modulated by internal oscillations e.g.,, or through amplifying wave activity that propagates from the troposphere e.g.,, which can lead to the triggering of SSWs, even if the wave activity in the troposphere is not anomalous . Hence, the strength and geometry of vortex winds and upward wave propagation can strongly influence the subsequent evolution of the polar vortex, and model biases related to these factors can therefore strongly impact the uncertainty in the prediction of the stratosphere.

Subseasonal-to-seasonal forecast systems are subject to model biases in both polar vortex strength and climatological tropospheric stationary waves , which can interact with wave anomalies to enhance or suppress upward wave flux . For instance, the accurate representation of the vortex background state is found to be important for the successful prediction of the 2021 SSW event . Yet, it has been suggested that the dominant factor in limiting the prediction of SSWs is the prediction of planetary wave activity rather than the mean state . The major sources of uncertainty in predicting the wave activity driving SSWs are suggested to be associated with the model representation of tropospheric stationary wave ridges in western North America and the North Atlantic region . For individual SSW events, the uncertainty in wave activity is suggested to be related to the representation of extratropical blocking, as found for the 2018 SSW event , and to localized synoptic-scale tropospheric perturbations, as shown by for the 2013 SSW event.

Through teleconnection pathways, variability in the tropics can contribute to uncertainty in the extratropics, which can further propagate into the stratosphere . The Madden–Julian Oscillation (MJO), the dominant mode of intraseasonal variability in the tropics, influences the extratropics by modulating extratropical tropospheric stationary waves, over the North Pacific in particular , and can further impact the stratospheric polar vortex by exciting poleward and vertical wave propagation . Model initializations that better capture the MJO show better prediction skill over the North Pacific and Euro-Atlantic region e.g., and better upward coupling of the troposphere to the stratosphere , often resulting in a better simulation of SSWs .

Uncertainty in the troposphere can also be a response to the extreme states of the polar vortex itself e.g.,. Forecast skill can be enhanced after stratospheric extreme events but can also be reduced since the forecasts can be overconfident , especially over Europe . In particular, tropospheric internal variability can limit the coupling of stratospheric variability to the troposphere . For instance, following the 2018 SSW event, the uncertainty in the development of synoptic activity after the SSW onset impacted the predictability of surface anomalies .

Given that the uncertainty in the stratosphere is coupled to uncertainty in the troposphere, this study aims to systematically investigate the link between stratospheric and tropospheric uncertainty in the ECMWF subseasonal-to-seasonal (S2S) hindcasts and to identify regions and pathways for which better model representation might enhance the skill of stratospheric prediction.

2 Data and methods

The northern hemispheric (NH) winter (November to February) subseasonal-to-seasonal (S2S) hindcasts of ECMWF model versions CY43R3 and CY45R1 are analyzed for the period 1998–1999 to 2017-2018. The hindcasts consist of 11 ensemble members, are integrated for 46 d, and are initialized twice a week. Both versions share similar configurations and are initialized with the ECMWF ERA-I reanalysis .

In addition, a hindcast for a case study initialized on 27 January 2018, 16 d before the onset of the 2018 SSW event on 12 February 2018, is chosen for a re-run to investigate the development of the large ensemble spread associated with this particular hindcast. This specific hindcast initialization date is chosen for a re-run because it displays a larger ensemble spread and consists of a larger portion of ensemble members that successfully predict the SSW event than the initializations available from the ECMWF real-time forecast on neighboring dates (Fig. ). The hindcast is computed for an increased ensemble size (51 members compared to 11 in the original hindcast) and for more pressure output levels to enable a more robust investigation of the spread. The hindcast is re-run using model version CY47R3, computed on 27 January 2022, and is initialized with ERA5 reanalysis . The daily means of the 20-year hindcasts of the same model version are chosen as the climatology to compute anomalies for the hindcasts.

The zonal-mean zonal wind at 60° N and 10 hPa ($U_{\mathrm{10},\mathrm{60}}$) is used as a measure of the strength of the stratospheric polar vortex. As a measure of upward wave activity in the lower stratosphere, we use the zonal average of meridional eddy heat fluxes ($\stackrel{\mathrm{‾}}{v^{\prime }{T}^{\prime }}$) averaged over 40–80° N at 100 hPa and weighted by the cosine of latitude, where $v$ is the meridional wind, $T$ is the temperature, and the prime (^′) denotes the departure from the zonal mean.

Hindcasts are categorized based on their ensemble spread in $U_{\mathrm{10},\mathrm{60}}$. The uncertainty is estimated by first calculating the daily standard deviation of $U_{\mathrm{10},\mathrm{60}}$ across the ensemble members of each hindcast. These daily standard deviations are then averaged over the 46 d integration period of the hindcast to obtain an estimate of the overall uncertainty present in the hindcast. Based on this 46 d average uncertainty, the hindcasts are separated into composites of large and small uncertainty, each consisting of 328 hindcasts. Specifically, the large uncertainty composite (large $U_{\mathrm{10},\mathrm{60}}$ spread) is composed of hindcasts with an ensemble spread above the 75th percentile of all hindcasts (9.16 m s⁻¹), and the small uncertainty composite (small $U_{\mathrm{10},\mathrm{60}}$ spread) is composed of hindcasts with an ensemble spread below the 25th percentile (5.86 m s⁻¹). Similar separations of hindcasts are found when using shorter averaging windows instead of the full 46 d average, and the results do not change significantly based on the definitions used (not shown).

3 Uncertainty in the ensemble prediction of the stratosphere

We start by comparing and characterizing the features of high and low uncertainty hindcasts in the ECMWF subseasonal-to-seasonal (S2S) model. Hindcasts that exhibit large uncertainty in the prediction of the strength of the stratospheric polar vortex ($U_{\mathrm{10},\mathrm{60}}$) are associated with strong growth in the spread at around 5–25 d after initialization (Fig. a). For hindcasts that exhibit small uncertainty, the spread in $U_{\mathrm{10},\mathrm{60}}$ grows as lead time increases, but the rate of increase is much smaller than for the large uncertainty composite. Hereafter, the large uncertainty and small uncertainty composites are referred to as large $U_{\mathrm{10},\mathrm{60}}$ spread and small $U_{\mathrm{10},\mathrm{60}}$ spread composite, respectively.

Figure 1

Evolution of (a) ensemble spread in $U_{\mathrm{10},\mathrm{60}}$, (b) ensemble mean of $U_{\mathrm{10},\mathrm{60}}$, and (c) ensemble mean of $\stackrel{\mathrm{‾}}{v^{\prime }{T}^{\prime }}$ at 100 hPa in composites of hindcasts classified as having large uncertainty (large $U_{\mathrm{10},\mathrm{60}}$ spread, black) and small uncertainty (small $U_{\mathrm{10},\mathrm{60}}$ spread, grey), respectively, for the prediction of the stratospheric polar vortex. The solid line denotes the median, the shaded region denotes the 25th to 75th percentiles, and dotted lines denote the 5th and 95th percentiles, for the large and small spread composites. The median of all hindcasts is shown in yellow. Solid lines are printed in bold when the composites are significantly different from all hindcasts at the 95 % confidence interval using a $t$ test. The dashed purple line in (a) corresponds to the ensemble spread of the hindcast of the 2018 SSW event, and the dashed purple lines in (b) and (c) correspond to the ensemble mean of the hindcast for the 2018 SSW. Dotted vertical purple and grey lines indicate the onset and the peak of the uncertainty in $U_{\mathrm{10},\mathrm{60}}$ for the 2018 SSW event, respectively. The number of hindcasts in each composite is given in brackets in the legend.

[Figure omitted. See PDF]

The ensemble mean evolution in $U_{\mathrm{10},\mathrm{60}}$ of the identified composites (Fig. b) shows that on the day of initialization (day 0), the large $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts are more generally associated with a strong vortex, and the small $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts are associated with a weak vortex, with the medians of the composites being 36.28 and 13.25 m s⁻¹ on day 0, respectively. After day 0, the large $U_{\mathrm{10},\mathrm{60}}$ spread composite shows an overall weakening of the vortex, and the small $U_{\mathrm{10},\mathrm{60}}$ spread composite shows an overall strengthening of the vortex. The $U_{\mathrm{10},\mathrm{60}}$ evolution of the composites is likely related to the fact that SSWs or vortex weakenings in the large $U_{\mathrm{10},\mathrm{60}}$ spread composite occur predominantly at relatively long lead times (from 10 d after initialization), while the SSWs or vortex weakenings in the small spread composite occur mostly at early lead times (within the first 10 d after initialization) (Fig. ). The difference in vortex strength between the composites reduces with lead time but remains significantly different from that of all hindcasts until 24 and 29 d after initialization, for the large and small $U_{\mathrm{10},\mathrm{60}}$ spread composites, respectively. Towards longer lead times, from around 35 d after initialization, the composites display a vortex strength similar to all hindcasts, likely linked to the model's drift towards climatology at long lead times. After that, the small $U_{\mathrm{10},\mathrm{60}}$ spread composite stagnates at a vortex strength similar to all hindcasts, while the large $U_{\mathrm{10},\mathrm{60}}$ spread composite weakens further and shows significantly weaker vortex strength than all hindcasts starting on day 37, possibly due to the stronger-than-average wave activity of the composite, which lasted until the end of the hindcasts (Fig. c).

The respective behavior of the composites is consistent with our understanding that when the stratospheric mean flow is westerly, vertical wave propagation in the NH is possible for small wavenumbers , while the exact propagation properties of the waves are modulated by the three-dimensional structure of the stratospheric flow. A strong vortex can further act as a waveguide, guiding waves from the troposphere towards the polar stratosphere . On the other hand, when the vortex in the lower stratosphere is very weak, such as after an SSW event, waves can be inhibited from propagating upwards, and the vortex can strengthen radiatively . Indeed, as expected, the large $U_{\mathrm{10},\mathrm{60}}$ spread composite that is associated with a stronger vortex is associated with stronger eddy heat flux in the lower stratosphere, as compared to the small $U_{\mathrm{10},\mathrm{60}}$ spread composite, which is associated with a weaker vortex and weaker eddy heat flux (Fig. b and c).

To better understand the regional contributions to the spread in $U_{\mathrm{10},\mathrm{60}}$, we now investigate the longitudinal structure of the lower stratospheric heat flux (Fig. ). The large $U_{\mathrm{10},\mathrm{60}}$ spread composite shows anomalously positive eddy heat flux over the North Pacific (NP), Northern Europe (NE), and Siberia (Sib) and anomalously negative heat flux over North America (NA) (Fig. a). The heat flux associated with NP peaks in the first few days after initialization, while that in the NA peaks after 10 d and in the NE after 15 d. For the small $U_{\mathrm{10},\mathrm{60}}$ spread composite, the heat flux is weaker than for the large $U_{\mathrm{10},\mathrm{60}}$ spread composite (Fig. b) and comparable to the average of all hindcasts (yellow contours in Fig. b). The heat flux of the small $U_{\mathrm{10},\mathrm{60}}$ spread composite is strongest at initialization and gradually decreases within the first 10 d for all longitudes. Interestingly, the heat flux over the North Pacific of the small $U_{\mathrm{10},\mathrm{60}}$ spread composite increases again around 25 d after initialization, which might explain the stagnation of the increase in $U_{\mathrm{10},\mathrm{60}}$ for the small spread composite in Fig. b. The largest difference in the ensemble mean heat flux between the composites is found over the North Pacific, owing to the very strong positive heat flux over the North Pacific associated with the large $U_{\mathrm{10},\mathrm{60}}$ spread composite (Fig. c).

In terms of ensemble spread, the large $U_{\mathrm{10},\mathrm{60}}$ spread composite shows large uncertainty in the heat flux in all regions that also exhibit large positive and negative ensemble mean heat flux (Fig. d). For the small $U_{\mathrm{10},\mathrm{60}}$ composite, uncertainty is found in the same regions as for the large $U_{\mathrm{10},\mathrm{60}}$ composite, but the ensemble spread is much weaker (Fig. e). The largest difference between the high and low spread composites in descending order is over Northern Europe, followed by North America, the North Pacific, and Siberia (Fig. f).

Figure 2

Hovmöller diagrams of composite ensemble mean and ensemble spread of $v^{\prime }{T}^{\prime }$ at 100 hPa for (a, d) hindcasts with large spread in $U_{\mathrm{10},\mathrm{60}}$ and (b, e) hindcasts with small spread in $U_{\mathrm{10},\mathrm{60}}$. The difference between the composites, given as large minus small spread composite, in the ensemble mean and ensemble spread is displayed in (c) and (f), respectively. The averages over all hindcasts are plotted by grey contours. Stippling indicates significant differences at the 95 % confidence level determined by a $t$ test in (a) and (b) and in (d) and (e) between the corresponding hindcast composite and all hindcasts and in (c) and (f) between the hindcast composites. The grey vertical lines separate the regions of investigation, from left to right: North Pacific (NP; 140° E–130° W), North America (NA; 130–40° W), Northern Europe (NE; 40° W–50° E), and Siberia (Sib; 50–140° E). Note that the negative range of the color bars is smaller than the positive range for visualization purposes, but the contour levels are kept constant.

[Figure omitted. See PDF]

As a next step, we investigate whether the uncertainty in the stratosphere is related to uncertainty in the troposphere by comparing the temporal and spatial evolution of the uncertainty of the large and small $U_{\mathrm{10},\mathrm{60}}$ composites in mean sea level pressure (MSLP) anomalies (Fig. ). In the first 5 d after initialization, only small significant patches of larger uncertainty are found in the large $U_{\mathrm{10},\mathrm{60}}$ spread composite compared to the small spread composite (Fig. a). At days 5–10, a significant difference between the large and small $U_{\mathrm{10},\mathrm{60}}$ spread composite is found over the North Pacific, the polar regions, Northern Europe, and the Ural region. The difference in uncertainty between the composites at these regions persists and amplifies as lead time increases (Fig. b–f), especially over the North Pacific and Scandinavia.

Other regions with significant differences between the large and small spread composites include the Azores High and the tropics during days 10–30 (Fig. c–f). Smaller uncertainty is found in the large $U_{\mathrm{10},\mathrm{60}}$ spread composite than the small $U_{\mathrm{10},\mathrm{60}}$ spread composite over the Azores High during days 10–25 (Fig. c–e). In the tropics, a small but significant difference is found from days 10–15 over the Maritime Continent and the tropical Pacific Ocean where the large $U_{\mathrm{10},\mathrm{60}}$ spread composite shows larger uncertainty than the small $U_{\mathrm{10},\mathrm{60}}$ composite (Fig. c). The difference in uncertainty between the composites expands to more regions in the tropics and subtropics as lead time increases (Fig. c–f), including Africa at around day 25–30 (Fig. f). Small significant differences are also found in the Southern Hemisphere extratropics and over Antarctica. These anomalies, especially at longer lead times (Fig. d–f), may be connected to tropical precursors, such as for example the MJO or El Niño–Southern Oscillation . The phases of these phenomena are related to the strength of the Northern Hemisphere polar vortex and its predictability , according to which the ensemble was separated here, but they also exhibit teleconnections to the Southern Hemisphere e.g.,.

The regions in the troposphere where uncertainty emerges are consistent with precursor regions that are known to modulate upward wave propagation into the stratosphere, namely over the North Pacific and Northern Europe and over Scandinavia and the Ural mountains, regions where increased blocking frequency occurs before SSWs . The consistency between the identified tropospheric origins of uncertainty and the precursor regions might suggest a propagation of uncertainty from the troposphere into the stratosphere through uncertainty in upward wave propagation, associated with uncertainty in tropospheric stationary waves and in synoptic-scale conditions located in these regions . Larger uncertainty in the tropospheric stationary wave anomalies is associated with the large $U_{\mathrm{10},\mathrm{60}}$ spread composite as compared to the small $U_{\mathrm{10},\mathrm{60}}$ spread composite over the North Pacific, North America, and Northern Europe at lead times beyond 20 d (Fig. f). This uncertainty in the stationary waves might have contributed to the uncertainty in upward wave propagation (Fig. f), as suggested in . Tropospheric variability in these regions could thus contribute to the polar vortex weakening in the large $U_{\mathrm{10},\mathrm{60}}$ spread composite, in which SSWs in the composite occur mainly at lead times of more than 10 d (Fig. b).

Figure 3

Difference in the evolution of composite ensemble spread of mean sea level pressure anomalies (MSLP_anom) given by hindcasts of large $U_{\mathrm{10},\mathrm{60}}$ spread minus small $U_{\mathrm{10},\mathrm{60}}$ spread. Differences that are significant at the 95 % confidence level according to a $t$ test are marked by stippling.

[Figure omitted. See PDF]

At the same time, several of these regions are known to be impacted by stratospheric forcing, e.g., after SSW events. SSW can have a downward impact over the Euro-Atlantic sector, resulting in a shift of storm track position , in a change of cyclone frequency , and in the transition of weather regimes . Hence, since SSW events occur more frequently within the first 10 d after initialization in the small $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts (Fig. c), the regions highlighted at longer lead times (Fig. d–f) could also be related to downward impacts from the stratosphere. However, due to the substantial variability in the timing of SSW occurrence in both the large and small $U_{\mathrm{10},\mathrm{60}}$ spread composites (Fig. b, c), it is not possible to clearly determine whether these regions correspond directly to upward or downward coupling in these composites at a given lead time. Therefore, in Sect. , we further investigate the upward and downward pathways in a case study of the 2018 SSW prediction.

A case with particularly high uncertainty in the prediction of the stratosphere was the SSW event on 12 February 2018. This case therefore represents a prime example for studying the origins of stratospheric uncertainty and their link to the troposphere. Furthermore, this event had a wide range of surface impacts e.g.,, while its prediction itself exhibited high uncertainty despite a range of suggested precursors, including extratropical troughs and blocking , and an MJO teleconnection .

Figure 4

Ensemble plumes of (a) $U_{\mathrm{10},\mathrm{60}}$ and $\stackrel{\mathrm{‾}}{v^{\prime }{T}^{\prime }}$ at 100 hPa averaged over 45–75° N for (b) wave-1 and (c) wave-2, respectively, for the hindcast of the 2018 SSW event. Ensemble members are separated into strong vortex cluster (red) and SSW cluster (blue). The solid dark-colored lines denote the median of the composite. Solid lines are printed in bold when the ensemble clusters are significantly different from each other at the 95 % confidence interval using a $t$ test. The black line denotes ERA5. The vertical line denotes the central date of the SSW on 12 February 2018.

[Figure omitted. See PDF]

We therefore further explore the development of uncertainty for the case study of the 2018 SSW. For this purpose we use an additional hindcast initialization with a larger number of ensemble members, initialized 16 d before the onset of the 2018 SSW event (see “Data and methods”). This initialization is selected because it includes ensemble members that successfully predict the onset of the SSW event and members that erroneously predict a strong vortex state around the time of the SSW onset, contributing to the large spread in ensemble for $U_{\mathrm{10},\mathrm{60}}$. The selected initialization date shows a particularly extreme spread in $U_{\mathrm{10},\mathrm{60}}$ compared to other initialization dates, with the spread increasing beyond the 95th percentile of the climatology and peaking at 7 d after the SSW onset (dashed purple line in Fig. a). Consistent with the characteristics of the large uncertainty hindcasts discussed in Sect. , the hindcast is initialized under a strong vortex state (Fig. b) and is associated with strong eddy heat flux around 10–20 d after initialization (Fig. c), consistent with the occurrence of the SSW. Similar to methods used in, e.g., and , we separate the ensemble into two clusters, one with ensemble members that successfully predict the SSW (SSW cluster) and one that predicts a strong vortex state (strong vortex cluster) (Fig. a), to investigate the differences between the clusters that subsequently lead to different predictions of the vortex strength.

Before the onset of the SSW, the clusters do not differ significantly in wave-1 heat flux in the lower stratosphere, whereas they do differ significantly in wave-2 at around lag $-\mathrm{5}$ (Fig. b and c). Both clusters show an initial increase in wave-2 activity, but the wave activity of the strong vortex cluster decreases shortly after the initial increase. The observed difference between the two clusters in the wave-2 activity suggests that accurately predicting the wave-2 activity is crucial for successfully predicting the SSW, in agreement with previous studies . Although the SSW cluster on average still underestimates the wave activity as compared to reanalysis, and as a consequence the vortex deceleration, several individual ensemble members predict eddy heat fluxes comparable to reanalysis.

Figure 5

Difference between the SSW cluster and the strong vortex cluster in weekly averages of (a, b) outgoing longwave radiation (OLR) anomalies before SSW onset and (c–h) mean sea level pressure (MSLP) anomalies before and after SSW onset for the hindcast of the 2018 SSW. Lag is given in days with respect to SSW onset. Anomalies are averaged every 7 d starting from 14 d before SSW onset (lag $-\mathrm{14}$ corresponds to 2 d after initialization), for MSLP anomalies up to 28 d after SSW onset (lag 28). Stippling indicates a significant difference between the two clusters by a $t$ test at the 95 % confidence level. Note that the upper and lower limits of the color bars are increased from (c) to (h), with a color bar range of $\pm$ 500 Pa in (c), $\pm$ 1500 Pa in (d) to (f), and $\pm$ 2500 Pa in (g) and (h).

[Figure omitted. See PDF]

To further understand the origin of the difference between the clusters in wave-2 activity, we compare the differences between the clusters in terms of their respective anomalies of outgoing longwave radiation (OLR) (Fig. a–b) and of geopotential height anomalies (Figs.  and ) before SSW onset and of mean sea level pressure (MSLP) anomalies before and after SSW onset (Fig. c–h). Before SSW onset, for lags $-\mathrm{14}$ to $-\mathrm{1}$, the SSW cluster shows more enhanced convection over the Maritime Continent and suppressed convection over parts of Africa and South America than the strong vortex cluster (Fig. a–b). During lags $-\mathrm{14}$ to $-\mathrm{8}$, the SSW cluster also shows a stronger negative-pressure anomaly over the Northwestern Pacific and a stronger positive-pressure anomaly over western North America and the North Atlantic (Fig. c). There is also a wave train pattern over the extratropics in the Southern Hemisphere that could be related to the enhanced convection over the tropics e.g.,. During lags $-\mathrm{7}$ to $-\mathrm{1}$, for the SSW cluster, the high-pressure anomaly over Scandinavia is amplified, and stronger negative-pressure anomalies over the North Atlantic and eastern Siberia are found (Fig. d). This pressure dipole between Scandinavia and the North Atlantic is remarkably similar to the pattern that is identified by to be crucial for successfully predicting the 2013 SSW, which was also preceded by strong wave-2 flux. The simultaneous increase in positive-pressure anomaly over Scandinavia and Alaska, combined with the reduced negative-pressure anomaly over eastern Siberia, projects onto a climatological wave-2 pattern, which likely forced the upward wave-2 activity flux (Figs. c and c, d) by amplifying the climatological stationary waves .

The development of extratropical precursors to the SSW could potentially be linked to the enhanced convection over the tropics, particularly the low-pressure anomaly over the Northwestern Pacific during lags $-\mathrm{14}$ to $-\mathrm{8}$ (Fig. c), which has been suggested to be associated with MJO phase 6/7 . A closer examination of the buildup of these anomalies indicates that the SSW cluster starts to show stronger convection over the Maritime Continent a few days after initialization (Figs. a and a), followed by a trough over the Northwestern Pacific (Figs. b and b) and a ridge over Alaska (Figs. b and c). During lags $-\mathrm{7}$ to $-\mathrm{4}$, the ridge over Alaska develops into anomalies that project onto the Pacific North American (PNA) pattern and form a wave train into Northern Europe (Fig. c), potentially contributing to the formation of the trough over the North Atlantic and the ridge over Scandinavia (Figs. d and d).

The higher pressure over Scandinavia and the lower pressure over the North Atlantic in the SSW cluster as compared to the strong vortex cluster before the SSW onset (Fig. d) persist and strengthen further after SSW onset, while the high-pressure anomaly extends further towards Greenland and then spreads across the Arctic (Fig. e–h). Starting at lag 7, the anomalies start resembling the negative phase of the North Atlantic Oscillation (NAO) (Fig. f–h), consistent with the downward impact associated with the SSW event that is observed in reanalysis (Fig. ).

The uncertainty in the prediction of the stratosphere and the origins of the uncertainty are systematically investigated using the S2S hindcasts of the ECMWF prediction system. By separating hindcasts into those that show large uncertainty versus those that show small uncertainty in the prediction of the polar vortex strength ($U_{\mathrm{10},\mathrm{60}}$), using ensemble spread as a measure of uncertainty, we find that hindcasts associated with large uncertainty (large $U_{\mathrm{10},\mathrm{60}}$ spread) tend to be initialized under a strong vortex, while hindcasts associated with small uncertainty (small $U_{\mathrm{10},\mathrm{60}}$ spread) tend to be initialized under a weak vortex. Large $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts are also associated with a stronger ensemble mean wave activity in the lower stratosphere and associated with larger uncertainty in the wave activity compared to small $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts. The characteristics of the hindcast composites suggest that the vortex background state at initialization of a given hindcast can indicate whether the uncertainty in the subsequent stratospheric prediction will be larger or smaller than average compare also to, and this relationship between hindcasts' uncertainty and the vortex state can in turn be explained by the different uncertainty in stratospheric wave activity under a different initial vortex state.

The difference in uncertainty between the hindcasts is further linked to the troposphere. Specifically, larger uncertainty is identified over the North Pacific and Northern Europe in large $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts, where synoptic-scale variability can modulate stratospheric vortex strength and impact the prediction of the stratosphere . This tropospheric pattern suggests upward propagation of uncertainty from the troposphere into the stratosphere through the uncertainty associated with the tropospheric stationary waves and the synoptic-scale conditions in these precursor regions . In turn, the stratosphere can also propagate uncertainty downward, impacting predictability of the troposphere, especially over the North Atlantic region . For instance, synoptic-scale tropospheric uncertainties following stratospheric disruptions can limit the predictability of the troposphere . Hence, the identified uncertainty signal in the North Atlantic region is likely linked to both precursors and responses to stratospheric extremes.

Since it is not possible to clearly separate tropospheric precursors and responses in the analysis of uncertainty for all cases, as there are substantial overlaps of upward and downward coupling when considering all hindcasts together (not shown), the upward and downward coupling of uncertainty between the troposphere and the stratosphere is further explored in a hindcast of the 2018 SSW initialized 16 d before the event onset under a strong vortex. Initialized at the end of MJO phase 5 and near the onset of a record-breaking MJO phase 6 , this event showed a particularly strong uncertainty in the stratosphere ahead of the event onset. The hindcast's ensemble spans a range from erroneously predicting a strong vortex to successfully predicting the observed SSW event. The ensemble members that successfully predict the SSW are preceded by enhanced convection over the Maritime Continent and followed by a trough over the Northwestern Pacific, which is suggested to be associated with MJO phase 7 . The development of the trough over the Northwestern Pacific is followed by the development of a ridge over Alaska, a wave train to Northern Europe, a trough over the Atlantic, a ridge over Scandinavia, and subsequently a development of wave-2 flux. Since the ensemble members that successfully predict the SSW capture anomalies that are consistent with the extratropical impact of the MJO , and since the MJO is also suggested to act as a trigger for the SSW event , this hindcast of the 2018 SSW represents an example demonstrating the propagation of uncertainty from the tropical troposphere into the stratosphere through teleconnection pathways . The ensemble members that successfully capture the MJO teleconnection and the SSW also better capture the downward impact associated with the SSW. Therefore, this hindcast also demonstrates the extended surface prediction skill that can be gained from the successful prediction of an SSW due to its precursors.

While tropospheric variability alone cannot fully explain the uncertainties in the stratosphere, and while not all wave activity that drives SSWs has a tropospheric origin e.g.,, this study highlights how uncertainties in the troposphere can contribute to uncertainty in the stratosphere, and vice versa. Thus, a better representation of the regions identified in this study can be beneficial for both tropospheric and stratospheric prediction, in agreement with the suggested precursor regions of SSWs, e.g., over the North Pacific; the North Atlantic e.g.,; and the tropics, for instance, over the Maritime Continent for MJO teleconnections e.g.,. Model improvements for these regions, e.g., higher model resolution and improved representation of sea surface temperature gradients and diabatic heating, may benefit the representation of the synoptic-scale conditions over the extratropics and, subsequently, the prediction of the stratosphere and its downward impacts.

Figure A1

Ensemble plumes of zonal-mean zonal wind at 10 hPa, 60° N of ECMWF real-time forecasts initialized on (a) 25 January 2018 and (c) 29 January 2018 and (b) of the re-run of the ECMWF hindcast initialized on 27 January 2018. Blue lines denote members that successfully predict the 2018 SSW event within 10 d following the SSW onset, and grey lines denote members that did not predict the SSW or that got the timing of the SSW wrong. Numbers in the brackets at the legend indicate the number of ensemble members in each category. Ensemble spread in zonal-mean zonal wind at 10 hPa; 60° N averaged over the entire hindcast/forecast period is indicated in the bottom-right corner of each panel. Lag 0 denotes the onset of the 2018 SSW.

[Figure omitted. See PDF]

Figure A2

Average occurrence of 10 d strong wind acceleration and deceleration events, with event definitions following , at a given day from initialization in (a) all hindcasts, (b) large $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts, and (c) small $U_{\mathrm{10},\mathrm{60}}$ spread hindcasts. Red and blue bars indicate the average occurrence of wind acceleration and deceleration events, respectively, in a 10 d window following a given day after initialization. Note that the blue bars and red bars are stacked on top of each other, and the bars together indicate the total average occurrence of wind acceleration and deceleration events in a given hindcast. The average number of events that evolve into an extreme state of the vortex, i.e., strong vortex events or sudden stratospheric warmings, during the 10 d event window is hatched.

[Figure omitted. See PDF]

Figure A3

Same as Fig. 2 but for zonal anomalies over geopotential height at 500 hPa (GH${*}_{\mathrm{500}\mathrm{hPa}}$) averaged over 40–60° N.

[Figure omitted. See PDF]

Figure A4

Difference between the SSW cluster and the strong vortex cluster in geopotential height at 100, 250, 500, and 850 hPa for the hindcast of the 2018 SSW, averaged every 4 d starting from 1 d after initialization (lag $-\mathrm{15}$) to SSW onset (lag 0). Stippling indicates a significant difference between the two clusters by a $t$ test at the 95 % confidence interval. Note that the range of the color bars is doubled with every time step from lag $-\mathrm{15}$ to $-\mathrm{12}$ to lag $-\mathrm{3}$ to 0. Blue boxes in the 250 hPa panels indicate regions where averages are taken for Fig. , from left to right, the Maritime Continent (15° S–15° N, 100–170° E), the Northwestern Pacific (30–50° N, 150–170° W), Alaska (55–80° N, 5–50° W), and Scandinavia (55–75° N, 5–80° E).

[Figure omitted. See PDF]

Figure A5

Ensemble plumes of geopotential height at 250hPa averaged over the following regions: (a) the Maritime Continent (15° S–15° N, 100–170° E), (b) the Northwestern Pacific (30–50° N, 150–170° W), (c) Alaska (55–80° N, 5–50° W), and (d) Scandinavia (55–75° N, 5–80° E). The regions are marked by blue boxes in Fig. . Ensemble members are separated into a strong vortex cluster (red) and SSW cluster (blue). The solid dark-colored lines denote the median of the composite. Solid lines are printed in bold when the ensemble clusters are significantly different from each other at the 95 % confidence interval using a $t$ test. The vertical line denotes the central date of the SSW on 12 February 2018.

[Figure omitted. See PDF]

Figure A6

Difference between the SSW cluster and the strong vortex cluster in eddy heat flux ($v^{\prime }{T}^{\prime }$) at 100 hPa for the hindcast of the 2018 SSW. Stippling indicates a significant difference between the two clusters by a $t$ test at the 95 % confidence interval.

[Figure omitted. See PDF]

Figure A7

Eddy heat flux anomalies ($v^{\prime }{T}_{\mathrm{anom}}^{\prime }$) at 100 hPa before the onset of the 2018 SSW in ERA5 reanalysis. Stippling indicates a significant difference from climatology at the 95 % confidence level.

[Figure omitted. See PDF]

Figure A8

Mean sea level pressure anomalies after onset of the 2018 SSW in ERA5 reanalysis. Stippling indicates significant difference from climatology at the 95 % confidence level.

[Figure omitted. See PDF]