In late December 2015, widespread media interest revolved around forecasts that the surface air temperature at the North Pole would rise above freezing. Although there has been significant interest in the enhanced warming that is occurring at high northern latitudes, a process known as arctic amplification, remarkably little is known about these midwinter warming events at the pole including their frequency, duration and magnitude as well as the environmental conditions responsible for their occurrence. Here we use buoy and radiosonde data along with operational weather forecasts and atmospheric reanalyses to show that such events are associated with surface cyclones near the pole as well as a highly perturbed polar vortex. They occur once or twice each decade with the earliest identified event taking place in 1959. In addition, the warmest midwinter temperatures at the North Pole have been increasing at a rate that is twice as large as that for mean midwinter temperatures at the pole. It is argued that this enhanced trend is consistent with the loss of winter sea ice from the Nordic Seas that moves the reservoir of warm air over this region northwards making it easier for weather systems to transport this heat polewards.
Media attention in late December 2015 was focused on the prospect that the surface air temperature at the North Pole would rise above freezing1,2. This event was reported to be unprecedented in the instrumental record of the International Arctic Buoy Program (IABP)3,4. It was the final extreme weather event in a year that had many such events and reports of causal connections between the warming event at the pole and severe weather that occurred during the preceding days in Texas and the United Kingdom were made5,6.
Mean temperatures in the Arctic have been warming at an accelerated rate as compared to the rest of the Northern Hemisphere, a process known as arctic amplification7,8. Positive feedbacks in the climate system associated with the loss of sea ice are thought to be responsible for this amplification7,9,10. This regional warming has resulted in modifications to the large-scale atmospheric circulation that have led to changes in the planetary wave field11. One consequence of these changes is hypothesized to be an enhanced waviness of the polar vortex, the region in the upper atmosphere where cold polar air is situated and whose boundary is the jet stream. This change in the upper-atmospheric circulation has been linked to more extreme mid-latitude weather including cold air outbreaks that are associated with the southward extension of the polar vortex7. There is however considerable debate concerning this linkage12,13.
Although the focus of current research on the connection between extreme weather and perturbations of the polar vortex has been on the impacts in mid-latitudes7,9,12, there are also instances in which the development of the planetary wave field results in the jet stream being displaced northwards leading to a ‘pinching’ of the polar vortex and a warming at high northern latitudes14. These events have been shown to be associated with the advection of moisture into the Arctic that is most pronounced in the Atlantic sector where is it typically associated with the presence of a low-pressure system over the Greenland Sea15,16. Longwave radiative effects associated with the increased concentration of water vapour and cloud formation have been shown to enhance the surface heating during these events15,17.
As we shall show, the late December 2015 warming event at the pole was associated with a perturbed polar vortex that advected warm and moist air into the North Pole region from the adjoining Nordic Seas. Indeed, forecasts suggested that it was raining at the pole during this event. These so-called ‘rain on snow’ events can cause significant stresses on Arctic sea ice, infrastructure and ecosystems18,19,20,21. We will also show that these midwinter warming events occur once or twice each decade with an event in 2014 as well as one in 1959. The identification of events prior to 1959 is hampered by the lack of a comprehensive upper-air observing network prior to this time22. In addition, the warmest midwinter surface air temperatures at the pole are increasing at a rate that is twice as high as that for the mean midwinter surface air temperatures indicating that these events may become more common in the future.
Although the North Pole has a mean surface air temperature close to −30 °C during the month of December, it is nevertheless adjacent to a region with a large meridional temperature gradient associated the transition from sea ice to open water that occurs in the vicinity of Fram Strait and Barents Sea (Fig. 1). Indeed on average during December, the 0 °C isotherm is situated over the Greenland and Barents Seas within 2000 km of the pole. Figure 1 also shows time series of the surface air temperature and pressure at the North Pole during December 2015 and early January 2016 as determined from the 7 IABP meteorological buoys that were in the vicinity of the pole during this period. The time series of precipitable water, the vertical integral of the specific humidity and a useful field for diagnosing the long-range transport of atmospheric moisture23, at Ny Alesund, the closest radiosonde site to the pole, is also shown. Please refer to the Methods for additional details.
For most of December 2015, the North Pole had a surface air temperature of ~−25 °C with a number of small amplitude warming events that were associated with passing cyclones. Over the 24 hour period from 06 UTC 29 December to 06 UTC 30 December, the surface air temperature at the North Pole rose from −26.8 °C to −0.8 °C. Based on the characteristics of the IABP buoys, the uncertainty in the surface air temperature at the pole is on the order of +/− 0.5 °C24. This warming event was associated with a drop in surface pressure of ~24 mb. One day later, the surface air temperature had returned to more seasonal values that persisted through mid January 2016. The time series of precipitable water at Ny Alesund indicates that there were a number of events where there was a local maxima in this field with the largest occurring at 12 UTC on 29 December, approximately 18 hours before the maximum surface air temperature observed at the pole. Supplementary Figure 1 shows the vertical profiles of temperature and humidity from this sounding indicating that the thermal and moisture anomalies were largest at the surface with secondary maxima at ~2 km. The values attained during this event exceeded the 99th percentile values for the midwinter period throughout the lower troposphere.
There was considerable variability amongst the various buoys with respect to the magnitude of the warming observed during this event. Examples of this variability are presented in Fig. 2. The buoys with ids 132472 and 6400749 were only 120 km apart on 30 December (Fig. 1). Even though they were in close proximity, the warming at buoy 132472 was more pronounced than that for the buoy 6400749. The buoys with ids 6400473 and 6400476 were farthest from Fram Strait and yet experienced surface air temperatures of 0.5+/−0.5 °C and 0.7+/−0.5 °C respectively on the 30th as well as a distinct more modest warming on the 28th. The southernmost buoy with id 6400751 attained a surface air temperature of 2.2+/− 0.5 °C during the event. A common characteristic amongst all the buoys was the short duration of the warming event.
To investigate the spatial variability identified in Fig. 2, meteorological fields from the final operational analysis from the National Centers for Environmental Prediction (NCEP) Global Data Assimilation System25 (FNL-GDAS) were examined as well as those from the JRA5526 and NCEP27 and ERA-I28 Reanalyses. Please refer to the Methods for additional information on these datasets.
Time series of the surface air temperature and sea-level pressure at the North Pole as well as the precipitable water at Ny Alesund were extracted from the FNL-GDAS and the three reanalyses for the period 1 December 2015 to 14 January 2016. Scatterplots of the observed versus model data are shown in Fig. 3. In general the quality of the fit was better for the surface pressure as compared to the surface air temperature and precipitable water. With respect to the surface air temperature, the JRA55 and ERA-I Reanalyses and the FNL-GDAS had lower root mean square and bias errors and higher correlation coefficients as compared to the NCEP Reanalyses. In addition, all models were too cold with bias errors of ~1–2 °C. The NCEP and ERA-I Reanalyses had the lowest root mean square and bias errors for the precipitable water at Ny Alesund.
Figure 4 shows the sea-level pressure, surface air temperature, and the precipitable water from the FNL-GDAS at 06 UTC on 29 December (one day before the warming event) and 30 December (at the time of the warming). The corresponding fields at 06 UTC on 30 December from the JRA55, NCEP and ERA-I Reanalyses are shown in Supplementary Figure 2. There is good overall agreement between the models, however the lower horizontal resolution of the NCEP Reanalysis resulted in a more muted representation of the fine scale structure of the flow.
On the 29th, there was a pronounced zonal gradient in the sea-level pressure field between a low along the northeast Greenland coast and a high over northern Scandinavia. In such a situation, one would expect and indeed observed moist southerly flow over the Nordic Seas, the Fram Strait and the Barents Sea (Fig. 4a & b). In this case, the flow resulted in the northward advection of warm moist air that was captured in the Ny Alesund radiosonde data (Fig. 1 and Supplementary Figure 1). At this time, the warm air mass was as far north as Svalbard with the 0 °C isotherm situated over the northern Fram Strait and Barents Sea.
Twenty-four hours later, the low that had been over northeast Greenland was now situated to the west of the North Pole and had a central pressure of 965 mb. This movement and its depth had resulted in a further northward advection of the warm and moist air into the region near the pole (Fig. 4c & d). The 0 °C isotherm indicates that above freezing surface air temperatures were present in the warm sector of the low including in the vicinity of the North Pole. In particular, the mean above freezing temperature north of 85°N at this time was 0.7 °C.
For this event, the 0 °C isotherm also provides a useful diagnostic for the presence of the warm and cold fronts associated with the low29. The cold front, in this instance the boundary between the cold air to the south of the low and the warm air to its southeast, can be seen to be located between the two buoys, with ids 132472 and 6400749, that experienced different temperatures during the warming event (Fig. 2). The buoys with ids 6400473, 6400476 and 6400751 were in the warm sector of the low and, as seen in Fig. 2, experienced above freezing temperatures. The warm front, in this instance the boundary between the warm air and the cold air to the east of the low, was in the vicinity of these buoys. There is also evidence of the so-called ‘bent back’ warm front, near the low’s center where the warm front bends back towards the cold front30; in this case it was situated in the vicinity of the buoys with ids 6400474 and 6400477.
At 6 UTC on 31 December, all the models indicated a return to more seasonal surface air temperatures near the pole with the 0 °C isotherm retreating southwards to the vicinity of Svalbard (not shown).
The widespread and spatially contiguous area of above freezing temperatures extending from the latitude of Svalbard northwards was associated with a widespread reduction in sea ice cover. Supplementary Figure 3 shows the difference in daily mean sea ice concentration retrieved using the ARTIST algorithm and the AMSR-2 data31 between 30 December and 29 December 29 2015, i.e. during the period of maximum warming at the pole. Along the Fram Strait’s marginal ice zone as well as over the Barents Sea, there was widespread reduction in sea ice concentration. In addition, there was a region deep within the ice pack in the vicinity of 82°N 35°E where there was a reduction in ice cover. To place this reduction in context, the difference in daily mean sea ice concentration between successive days over the period December 1-January 15 2002–2016, the years for which AMSR-E/AMSR-2 data is available, was calculated. The resulting histogram is also shown in Supplementary Figure 3 and indicates that the one-day sea ice loss during the 2015 midwinter warming event occurs less then 1% of the time.
The frontal boundaries of extra-tropical cyclones are preferred locations for precipitation29,30. Given the above freezing temperatures that occurred during this event, it is therefore possible that it was raining in the vicinity of pole during the event. Supplementary Figure 4 shows the forecast snowfall and rainfall rate at the time of the warming event from the FNL-GDAS. As expected, much of the precipitation associated with the low was in the form of snow. However in the vicinity of the warm front and the ‘bent back’ warm front, rainfall was forecast to have occurred.
On 30 December, all models indicated the presence of a deep low, central pressure < 950 mb, centered over Iceland (Fig. 4 & Supplementary Figure 2). This second low was also associated with another pulse of precipitable water that is clearly distinct from that associated with the warming at the pole (Fig. 4d). This low was responsible for flooding in North England and Scotland and was named ‘Storm Frank’ by the UK Met Office32. It originated over the Texas on 26 December where it was associated with a deadly outbreak of tornados33.
There was, however, a connection between the two storms in that both were associated with a large-amplitude planetary wave14 that was located over the North Atlantic during late December 2015. This wave and its evolution can be seen in Fig. 5 where the 500 mb geopotential height (i.e. height of the 500 mb pressure surface) is shown at 06 UTC on 28 December and 30 December 2015 as well as 1 January 2016. The 5.6 km geopotential height contour provides a useful indicator for the high speed upper-level winds known as the jet stream as well as denoting the boundary of the polar vortex7. On the 28th, the trough of this wave, the region of low geopotential height, extended southeastwards from the Labrador Sea. The corresponding ridge, the region of high geopotential height, was situated over central Europe extending northwards towards the Nordic Seas as did the jet stream. By the 30th, the ridge along with the jet stream and the polar vortex was displaced to the northeast of Svalbard. As a result of this extension, there was a pronounced zonal gradient in geopotential height across the Nordic Seas that was associated with southerly flow that advected warm and moist air towards the pole (Fig. 4). By 1 January 2016, the ridge had weakened and moved off towards the east with the jet stream retreating southwards.
To investigate the uniqueness of the 2015 event, the JRA55 Reanalysis was used to identify the mean and 99th percentile surface air temperature and precipitable water in the region north of 85oN for each December from 1958–2015. The results of this calculation are shown in Fig. 6 and clearly reveal an increasing trend in the mean and 99th percentile values for both the surface air temperature and the precipitable water since the late 1950 s. All trends are statistically significant at the 95th percentile confidence interval using a test that takes into account the reduced degrees of freedom arising from temporal autocorrelation of geophysical time series34. For both fields, the positive trend in the extreme values was greater then that for the mean values. For the surface air temperature this ratio was ~2, while for the precipitable water it was ~4. The higher ratio for precipitable water is consistent with the idea that in a warming climate there is an intensification of the high latitude hydrological cycle resulting from the non-linear relationship between temperature and saturation specific humidity35. Supplementary Figures 4 and 5 indicate that similar behaviour was also observed in the NCEP and ERA-I Reanalyses.
This suggests that, in addition to a long-term warming of the North Pole region, there have been changes that result in a greater efficiency for cyclones to access the reservoir of warm and moist air that exists over the nearby Nordic Seas (Fig. 1) and transport it polewards leading to warmer and moister extreme events. Amongst the changes that may have contributed to this efficiency are reductions in the winter sea ice over the Greenland and Barents Seas that have moved this reservoir of warm and moist air closer to the pole. Figure 6 also shows the latitude of the 0 °C isotherm of the surface air temperature during December over Fram Strait from the JRA55 Reanalysis. The latitude of this isotherm is moving northwards at a statistically significant rate of ~0.5o/decade, a result that was also seen in the NCEP Reanalysis (Supplementary Figure 4).
A number of events during which the 99th percentile surface air temperature was close to 0 °C can be seen in Fig. 6. It should be noted that the surface air temperature from the JRA55 Reanalysis has a cold bias of ~2 °C and so, the mean and extreme values are most likely underestimated. Most of these warming events were also associated with maxima in precipitable water. Supplementary Figures 4 & 5 confirm that these warming events were also captured in the NCEP and ERA-I Reanalyses.
The earliest of these events occurred in December 1959. The atmospheric circulation during this event, as represented in the JRA55, is shown in Supplementary Figure 6. It shares many characteristics with the 2015 event, including the presence of a deep extra-tropical cyclone to the west of the pole, southerly flow in the vicinity of the pole that advected warm and moist air into the region and a perturbed polar vortex with the presence of the jet stream in the vicinity of the pole. The JRA55 Reanalysis indicates that a warming event also occurred during December 2014. This event was also captured by the ERA-I Reanalysis but was not as well pronounced in the NCEP Reanalysis. An examination of the environmental conditions during this event indicated a high degree of commonality with the 1959 and 2015 events. The NCEP Reanalysis failed to capture it because of its lower horizontal resolution.
The characteristics of the late December 2015 warming event have been investigated with in-situ buoy and radiosonde data as well as operational analyses and reanalyses. Based on buoy data, the surface air temperature at the North Pole rose by ~26 °C during a 24 hour period ending at 06 UTC on 30 December. The warming was associated with a drop in surface pressure of ~24 mb. Indeed, the central sea-level pressure of the low at 06 UTC on 30 December was the lowest sea-level pressure attained in the JRA55 in the vicinity of the pole during December 1958–2015 (not shown). There was considerable spatial variability in the model surface air temperature in the vicinity of the pole during this event that was associated with the organization of the extra-tropical cyclone that was responsible for the warming. However the model fields all are consistent with a short duration event.
Based on the available buoy data, the surface air temperature at the pole did not rise above freezing, although above freezing temperatures were observed at the buoys that were situated in the warm sector of the cyclone close to the pole. The uncertainty in the surface air temperature data from the IABP buoys is on the order of 0.5 °C and it is possible that the temperatures were close to freezing rather then being above 0 °C. However the 2 m air temperature field from the FNL-GDAS indicated that there was a large spatially coherent region of above freezing temperatures in the vicinity of the North Pole on the 30th that is in broad agreement with the buoy data. The boundaries of this region that are associated with the cyclone’s warm and cold fronts are consistent with the observed variability in the IABP data.
The surface warming associated with the event was coincident with a widespread reduction in sea ice cover in the region. Care must be taken in interpreting the one-day sea ice loss to the warming during the event. There are issues with the microwave retrieval of sea ice at low concentrations as well in the presence of water on ice, that may have occurred during this event due to the presence of rain, that could have influenced the one-day ice loss observed during this event36. In addition, the mechanical movement of sea ice by the surface wind field could also have contributed to the loss. However, the lack of large-scale regions of enhanced ice cover, as would be required to balance the mechanically-forced divergence, suggests that this process was not widespread. In any event, the reduction in sea ice concentration between the 29th and 30 in the region of interest was the largest during the midwinter period in the 15 year long record in the AMSR-E/AMSR-2 dataset.
The cyclone responsible for the warming also advected moisture polewards. On Svalbard, the magnitude of the moisture pulse exceeded the 99th percentile value during midwinter. The forecast fields from the FNL-GDAS predicted that this event resulted in rainfall in the vicinity of the North Pole. Care must be taken as the precipitation field from an analysis or reanalysis is not strongly constrained by observations and is therefore highly dependent on the characteristics of the underlying model27.
In addition to the advective surface warming that occurred during the event, the elevated levels of water vapour throughout the lower troposphere that were also present most likely warmed the surface by increasing the downwelling longwave radiation15,17. Models continue to have issues with this process at high latitudes as as a result of an inability to correctly represent the cloud fraction and cloud phase37,38. This issue may contribute to the cold bias observed in the model surface air temperature at the North Pole.
Contrary to media reports1,2,3, the cyclone responsible for the warming event at the pole was not the one responsible for the severe weather in Texas and the United Kingdom that preceded this event. There was however a connection in that all this severe weather was associated with a highly perturbed polar vortex that brought the jet stream close to the pole.
It was also shown that these warming events at the pole occur once or twice each decade with an event in 2014 and the earliest event that has been so far identified taking place in 1959. The 1959, 2014 and 2015 events share a number of common characteristics including the presence of a deep extra-tropical cyclone in the vicinity of the pole that transported warm and moist air towards the pole. All events also were associated with a highly perturbed polar vortex that brought the jet stream close to the pole.
The December 99th percentile surface air temperature and precipitable water in the vicinity of the North Pole have been increasing at a rate higher than that for mean values. This ratio is higher for precipitable water, a result that is consistent with an intensification of the high latitude hydrological cycle in a warming climate35. It is proposed that this enhanced trend in extreme warmth and moisture at the pole is associated with the loss of winter sea ice from the adjoining Greenland and Barents Seas that is moving the reservoir of warm and moist air that exists over the Nordic Seas closer to the pole allowing for a greater efficiency of cyclones in transporting this heat and moisture polewards.
Such warming events and the associated occurrence of rainfall at high northern latitudes can lead to significant stresses on Arctic infrastrcuture18 as well mammalian herbivoiries19,20,39 that inhabit the Arctic Islands, These stresses may become more pronounced as the occurrence of these midwinter warming events become more frequent as the region transitions towards the occurrence of warmer and wetter winters.
During December 2015, there were 7 meteorological buoys within 500 km of the North Pole (Fig. 1 & Table 1). These buoys provide hourly surface air temperature and pressure data that are available in near real time through the International Arctic Buoy Porgram (IABP)40. The root mean square temperature error for the buoys is on the order of 0.5 °C24. For the period 1 December 2015–14 January 2016, this data was interpolated to generate an estimate of the surface air temperature and pressure at the North Pole (Fig. 1). A linear interpolation scheme was used and the issue of converging meridians at the pole41 was taken into account through the use of a rotated co-ordinate system that placed the North Pole at 45oN, 45oW.
Data from the radiosonde site at Ny Alesund on Svalbard (78.91oN, 11.93oE) was also used to characterize the vertical structure of the moisture plume associated with the warming event. Please refer to Fig. 1 for the location of the radiosonde site. During December 2015, the data was typically available once-daily at 12 UTC. Data over the entire period of availablilty, December 1993-January 2016, was used to calculate mean as well as 95th and 99th percentile values.
In meteorology, the term analysis refers to the outcome of the process of data assimilation that generates a representation of the state of the atmosphere at a given time that is suitable for use as initial conditions in subsequent forecasts42. Operational analyses suffer from changes over time that render them unsuitable for longer term studies43. Retrospective analyses or reanalyses correct this fault by using a modern data assimilation system to assimilate all available historical observations to generate homogeneous time series of the state of the atmopshere that allow one to place current events in a longer-term context43. The precipitation field from an analysis or renalysis is not strongly constrained by observations and is therefore influenced by the characteristics of the model used in the data assimilation process27. In addition, it is typically stored as an average over the period of the short-term forecast used to advance the analysis or reanalysis27. The surface air temperature from a numerical model is typically expressed as the temperature at a height of 2 m above the surface.
The final operational analysis from the National Centers for Environmental Prediction (NCEP) Global Data Assimilation System25 (FNL-GDAS) is available in near real time at a horizontal resolutuion of 0.25o on 26 pressure levels with 25 mb spacing below 900 mb. Three reanalysis products, which are all available on a near real time basis, were also used. The JRA55 Reanalysis26 from the Japanese Meteorological Agency has a horizontal resolution of 1.25o and extends back to 1958. The NCEP Reanalysis27 has a horizontal resolution of 1.875° and extends back to 1948. However issues with sparseness of data at high northern latitudes exist up to the establishment of the global radiosonde network in 195822. For this reason, we restricted our investigation of warming events at the North Pole to the time period 1958–2015. The ERA-I Reanalysis28 from the European Center for Medium-Range Weather Forecasts has a horizontal resolution of 0.75o and extends back to 1979. All datasets are available at a temporal resolution of 6 hours.
The daily mean sea ice concentration derived from the AMSR-E/AMSR-2 instruments using the ARTIST algorithm31 was used to characterize the reduction in ice cover associated with the 2015 midwinter warming event. This instrument has additonal high frequency microwave channels that allow for higher spatial resolution retreivals as compared to the SSM/I31. This data is available at a horizontal resolution of 6.25 km for the period from 2002–2016. Comparsions of the results of the ARTIST algorithm with the NASA-Team 2 and Bootstrap algorithms show good agreement31.
How to cite this article: Moore, G. W. K. The December 2015 North Pole Warming Event and the Increasing Occurrence of Such Events. Sci. Rep. 6, 39084; doi: 10.1038/srep39084 (2016).
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Batty, D. North pole could be 35C warmer than average this week, warn meteorologists, The Guardian, London UK, December 30, 2015.
Samenow, J. Freak storm in North Atlantic to lash UK, may push temperatures over 50 degrees above normal at North Pole, The Washington Post, Washington, DC, December 28, 2015.
Holthaus, E. The Scariest Part of This Season’s Weird Weather Is Coming Soon, Slate, December 29, 2015.
Morison, J. The 2015 Midwinter Warming, North Pole Environmental Observatory Seattle, WA, psc.apl.washington.edu/northpole/NPEO2015_midwinter_warming.html, 2015.
Gillis, J. 2015 Was Hottest Year in Historical Record, Scientists Say, The New York Times, New York, NY, January 21, 2016.
Samenow, J. Global warming in 2015 made weather more extreme and it’s likely to get worse, The Washington Post, Washington, DC, January 20, 2016.
Francis, J. & Skific, N. Evidence linking rapid Arctic warming to mid-latitude weather patterns. Philosophical Transactions of the Royal Society a-Mathematical Physical and Engineering Sciences 373, doi: 10.1098/rsta.2014.0170 (2015).
Overland, J. E., Wang, M., Walsh, J. E. & Stroeve, J. C. Future Arctic climate changes: Adaptation and mitigation time scales. Earths Future 2, 68–74, doi: 10.1002/2013ef000162 (2014).
Cohen, J. et al. Recent Arctic amplification and extreme mid-latitude weather. Nature Geoscience 7, 627–637, doi: 10.1038/ngeo2234 (2014).
Screen, J. A. & Simmonds, I. The central role of diminishing sea ice in recent Arctic temperature amplification. Nature 464, 1334–1337, doi: 10.1038/nature09051 (2010).
Overland, J. E. & Wang, M. Large-scale atmospheric circulation changes are associated with the recent loss of Arctic sea ice. Tellus A 62, 1–9, doi: 10.1111/j.1600-0870.2009.00421.x (2010).
Overland, J. et al. The Melting Arctic and Midlatitude Weather Patterns: Are They Connected? Journal of Climate 28, 7917–7932, doi: 10.1175/jcli-d-14-00822.1 (2015).
Wallace, J. M., Held, I. M., Thompson, D. W. J., Trenberth, K. E. & Walsh, J. E. Global Warming and Winter Weather. Science 343, 729–730 (2014).
Palmén, E. & Newton, C. W. Atmospheric circulation systems: their structure and physical interpretation (Academic Press, 1969).
Woods, C., Caballero, R. & Svensson, G. Large-scale circulation associated with moisture intrusions into the Arctic during winter. Geophysical Research Letters 40, 4717–4721, doi: 10.1002/grl.50912 (2013).
Zhang, X. D., Walsh, J. E., Zhang, J., Bhatt, U. S. & Ikeda, M. Climatology and interannual variability of arctic cyclone activity: 1948–2002. Journal of Climate 17, 2300–2317, doi: 10.1175/1520-0442(2004)017<2300:caivoa>2.0.co;2 (2004).
Tjernstrom, M. et al. Warm-air advection, air mass transformation and fog causes rapid ice melt. Geophysical Research Letters 42, 5594–5602, doi: 10.1002/2015gl064373 (2015).
Brage, B. H. et al. Warmer and wetter winters: characteristics and implications of an extreme weather event in the High Arctic. Environmental Research Letters 9, 114021 (2014).
Putkonen, J. et al. Rain on Snow: Little Understood Killer in the North. Eos, Transactions American Geophysical Union 90, 221–222, doi: 10.1029/2009EO260002 (2009).
Stien, A. et al. Congruent responses to weather variability in high arctic herbivores. Biology Letters (2012).
Screen, J. A. & Simmonds, I. Declining summer snowfall in the Arctic: causes, impacts and feedbacks. Climate Dynamics 38, 2243–2256, doi: 10.1007/s00382-011-1105-2 (2011).
Kistler, R. et al. The NCEP–NCAR 50–Year Reanalysis: Monthly Means CD–ROM and Documentation. B Am Meteorol Soc 82, 247–267 (2001).
Moore, G. W. K., Field, R. D. & Benson, C. S. Impact of Source Region on the delta O-18 Signal in Snow: A Case Study from Mount Wrangell, Alaska. Journal of Hydrometeorology 17, 139–151, doi: 10.1175/jhm-d-14-0224.1 (2016).
Rigor, I. G., Colony, R. L. & Martin, S. Variations in Surface Air Temperature Observations in the Arctic, 1979–97. Journal of Climate 13, 896–914, doi: 10.1175/1520-0442(2000)013<0896:VISATO>2.0.CO;2 (2000).
Whitaker, J. S., Hamill, T. M., Wei, X., Song, Y. & Toth, Z. Ensemble Data Assimilation with the NCEP Global Forecast System. Monthly Weather Review 136, 463–482, doi: 10.1175/2007MWR2018.1 (2008).
Ebita, A. et al. The Japanese 55-year Reanalysis: An Interim Report. SOLA 7, 149–152 (2011).
Kalnay, E. et al. The NCEP/NCAR 40-year reanalysis project. B Am Meteorol Soc 77, 437–471 (1996).
Dee, D. P. et al. The ERA-Interim reanalysis: configuration and performance of the data assimilation system. Quarterly Journal of the Royal Meteorological Society 137, 553–597, doi: 10.1002/qj.828 (2011).
Browning, K. A. in The life cycles of extratropical cyclones (eds M. A. Shapiro & S. Grønas ) 265–283 (American Meteorological Society, 1999).
Neiman, P. J. & Shapiro, M. A. The Life Cycle of an Extratropical Marine Cyclone. Part I: Frontal-Cyclone Evolution and Thermodynamic Air-Sea Interaction. Monthly Weather Review 121, 2153–2176, doi: 10.1175/1520-0493(1993)121<2153:TLCOAE>2.0.CO;2 (1993).
Spreen, G., Kaleschke, L. & Heygster, G. Sea ice remote sensing using AMSR-E 89-GHz channels. Journal of Geophysical Research: Oceans 113, C02S03, doi: 10.1029/2005JC003384 (2008).
Brooks, L. After Storm Frank, Scotland rallies to fix itself amid the chaos, The Guardian, London, UK, January 1, 2016.
Montgomery, D. & Southall, A. Tornadoes Leave Paths of Rubble and 11 Dead in the Dallas Area, New York Times, New York, NY, December 27 2015.
Moore, G. W. K. Tibetan ice core evidence for an intensification of the East Asian jet stream since the 1870s. Atmospheric Science Letters 14, 235–242, doi: 10.1002/asl2.445 (2013).
Zhang, X. et al. Enhanced poleward moisture transport and amplified northern high-latitude wetting trend. Nature Clim. Change 3, 47–51 (2013).
Comiso, J. C. Enhanced Sea Ice Concentrations from Passive Microwave Data. Journal of the Remote Sensing Society of Japan 29, 199–215 (2009).
Walsh, J. E., Chapman, W. L. & Portis, D. H. Arctic Cloud Fraction and Radiative Fluxes in Atmospheric Reanalyses. Journal of Climate 22, 2316–2334, doi: 10.1175/2008jcli2213.1 (2009).
Pithan, F., Medeiros, B. & Mauritsen, T. Mixed-phase clouds cause climate model biases in Arctic wintertime temperature inversions. Climate Dynamics 43, 289–303, doi: 10.1007/s00382-013-1964-9 (2014).
Klein, D., Walsh, J. & Shulski, M. What Killed the Reindeer of Saint Matthew Island? Weatherwise 62, 32–38, doi: 10.1080/00431670903337581 (2009).
Rigor, I. G. & Wallace, J. M. & Colony, R. L. Response of sea ice to the Arctic oscillation. Journal of Climate 15, 2648–2663 (2002).
Sadourny, R. Conservative Finite-Difference Approximations of the Primitive Equations on Quasi-Uniform Spherical Grids. Monthly Weather Review 100, 136–144 (1972).
Bauer, P., Thorpe, A. & Brunet, G. The quiet revolution of numerical weather prediction. Nature 525, 47–55, doi: 10.1038/nature14956 (2015).
Bengtsson, L. et al. The need for a dynamical climate reanalysis. B Am Meteorol Soc 88, 495–501 (2007).
The FNL-GDAS, JRA55 Reanalysis and NCEP Reanalysis were provided by the Research Data Archive at the National Center for Atmospheric Research (http://rda.ucar.edu). The ERA-I reanalysis was provided by the ECMWF (http://ecmwf.int). The buoy data was provided by the International Arctic Buoy Program (http://iabp.apl.washington.edu). The radiosonde data was provided by the University of Wyoming (http://weather.uwyo.edu/upperair/sounding.html). The AMSR-E/AMSR-2 sea ice data was provided by the University of Bremen (http://www.iup.uni-bremen.de:8084/amsr2/). The author would like to thank C. Haas, R. Pickart, I. Renfrew and A. Wilson as well as the reviewers and editor for comments that improved the manuscript.
The author declares no competing financial interests.
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Moore, G. The December 2015 North Pole Warming Event and the Increasing Occurrence of Such Events. Sci Rep 6, 39084 (2016). https://doi.org/10.1038/srep39084
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