By WUWT Regular “Just The Facts”
If you aren’t familiar with Stratospheric Polar Vortexes, you can get acquainted here, here and here.
“A strong link exists between stratospheric variability and anomalous weather patterns at the earth’s surface. Specifically, during extreme variability of the Arctic polar vortex termed a “weak vortex event,” anomalies can descend from the upper stratosphere to the surface on time scales of weeks. Subsequently the outbreak of cold-air events have been noted in high northern latitudes, as well as a quadrupole pattern in surface temperature over the Atlantic and western European sectors, but it is currently not understood why certain events descend to the surface while others do not. This study compares a new classification technique of weak vortex events, based on the distribution of potential vorticity, with that of an existing technique and demonstrates that the subdivision of such events into vortex displacements and vortex splits has important implications for tropospheric weather patterns on weekly to monthly time scales. Using reanalysis data it is found that vortex splitting events are correlated with surface weather and lead to positive temperature anomalies over eastern North America of more than 1.5 K, and negative anomalies over Eurasia of up to −3 K. Associated with this is an increase in high-latitude blocking in both the Atlantic and Pacific sectors and a decrease in European blocking. The corresponding signals are weaker during displacement events, although ultimately they are shown to be related to cold-air outbreaks over North America. Because of the importance of stratosphere–troposphere coupling for seasonal climate predictability, identifying the type of stratospheric variability in order to capture the correct surface response will be necessary.” Mitchell et al. 2012 – Paywalled
During January 2014 the Northern Stratospheric Polar Vortex appears to have experienced a weak vortex event and displacement, i.e. here is a 10 hPa/mb – Approximately 31,000 meters (101,700 feet) Height Analysis showing the low pressure area of the Stratospheric Polar Vortex being displaced (squeezed) on January 7th;
and this Northern Hemisphere Temperature Analysis at 10 hPa/mb shows the Northern Stratospheric Polar Vortex apparently with two lobes on January 11th, 2014:
Northern Polar Wind at 10 hPa/mb also shows the Stratospheric Polar Vortex still displaced at present (if you click on the picture it will link to an animated version):
– NCEP / National Weather Service / NOAA – Click the pic to view animated at source
and when Polar Wind is overlaid with Temperature, you can clearly see the cold “air from very high altitudes” that descends “through the center of the vortex, moving air to lower altitudes over several months,” “NASA” (Click the pic to animate):
“Large regions in northern Asia, Europe and North America have been found to cool during the mature and late stages of weak vortex events in the stratosphere. A substantial part of the temperature changes are associated with changes in the Northern Annular Mode (NAM) and North Atlantic Oscillation (NAO) pressure patterns in the troposphere. The apparent coupling between the stratosphere and the troposphere may be of relevance for weather forecasting, but only if the temporal and spatial nature of the coupling is known. Using 51 winters of reanalysis data, we show that the development of the lower-tropospheric temperature relative to stratospheric weak polar vortex events goes through a series of well-defined stages, including the formation of geographically distinct cold air outbreaks. At the inception of weak vortex events, a precursor signal in the form of a strong high-pressure anomaly over north west Eurasia is associated with long-lived and robust cold anomalies over Asia and Europe. A few weeks later, near the mature stage of the weak vortex events, a shorter-lived cold anomaly emerges off the east coast of North America. The probability of cold air outbreaks increases by more than 50% in one or more of these regions during all phases of the weak vortex events. This shows that the stratospheric polar vortex contains information that can be used to enhance forecasts of cold air outbreaks. As large changes in the frequency of extremes are involved, this process is important for the medium-range and seasonal prediction of extreme cold winter days.” Kolstad et al. 2010
Here is Northern Hemisphere – Vertical Cross Section of Geopotential Height Anomalies and the Northern Annular Mode (NAM) or Arctic Oscillation (AO) Index, which shows large positive Height Anomalies and the AO swinging negative in January:
And here is North Atlantic Oscillation (NAO) Index for the prior 4 Months, showing a positive swing in mid-January:
So what caused the weak vortex event, displacement of the Northern Stratospheric Polar Vortex and cold air outbreaks?
There are several potential factors:
“A vortex displacement event is associated with anomalously high wavenumber-1 planetary wave activity entering the stratosphere and is characterized by a vortex with a comma-like shape that is shifting equatorward. Often this shifting occurs ‘‘top down’’ and the vortex has a baroclinic structure. Subsequently the Aleutian high, a weak anti- cyclone, encroaches over the pole and is especially dominant at lower levels.”
“A vortex splitting event is associated with anomalously high wavenumber-2 planetary wave activity entering the stratosphere. During such an event the vortex barotropically splits into two ‘‘daughter’’ vortices that tend to align along the 90°E – 90°W axis, with one centered over Siberia and the other centered over northeastern Canada (Matthewman et al. 2009, hereafter M09).”
“Analyses show that the most extreme vortex variability occurs most commonly in late January and early February, consistent with when most planetary wave driving from the troposphere is observed. Composites around sudden stratospheric warming (SSW) events reveal that the moment diagnostics evolve in statistically different ways between vortex splitting events and vortex displacement events, in contrast to the traditional diagnostics.” Mitchell et al. 2011
Planetary Wave 1 activity can be see on this Zonal Wave #1 Amplitude Jan, Feb, March Time Series;
and Planetary Wave 2 on this Zonal Wave #2 Amplitude Jan, Feb, March Time Series:
There was some Planetary Wave 2 activity in early January, however there was strong Planetary Wave 1 activity throughout much of the month.
A second likely factor in the weakening and displacement of the Polar Vortex is Eddy Heat, i.e. “strong negative fluxes indicate poleward flux of heat via eddies. Multiple strong poleward episodes will result in a smaller polar vortex, Sudden Stratospheric Warmings and an earlier transition from winter to summer circulations. Relatively small flux amplitudes will result in a more stable polar vortex and will extend the winter circulation well into the Spring.” NOAA
Here you can see that 10 day Averaged Eddy Heat Flux Towards The North Pole At 100mb neared a record daily maximum in early January:
A third potential factor in Polar Vortex behavior is that “geomagnetic activity (used as a measure of solar wind parameters)” plays a role in the “variability of large-scale climate patterns and on changes in the global temperature.”, i.e.: “We have found positive statistically significant correlations between global temperature and the distribution of surface temperature over Eurasia, the East and Equatorial Pacific and over the North Atlantic for the period 1966-2009 correspond to large-scale climate patterns defined by climate indices. We found very similar positive correlations between geomagnetic activity and the distribution of surface temperature in the mentioned regions. As an effect of geomagnetic storms, energetic particles penetrate from the magnetosphere into the region of the stratospheric polar vortex. The increase of temperature and pressure can be observed over northern Canada. The vortex shifts towards Europe, rotates counter-clockwise and the wind blows from the polar region over Greenland southwards. It diverts the warm flow proceeding northward over the Atlantic, eastward along the deep Icelandic low extending as far as the Barents Sea and takes part in warming Eurasia. The strengthened zonal flow from Siberia cools the western Pacific with the impact on the warming of the equatorial and eastern Pacific when also a distinct 1976-78 climate shift occurred. Processes in the Atlantic and Pacific play a significant role and a time delay (wind forcing over the previous 1-4 yr) appears to be the most important for the relocation of the oceanic gyres. Results showing statistically significant relations between time series for geomagnetic activity, for the sum of climate indices and for the global temperature help to verify findings concerning the chain of processes from the magnetosphere to the troposphere.” Studia Geophysica & Geodaetica, Bucha 2012
A Coronal Mass Ejection (CME); hit Earth around January 1st:
Ensemble WSA-ENLIL+Cone Model Evolution Movie for Median CME Input Parameters – Dynamic Pressure:
and the Magnetosphere was rocking and rolling:
However, potential influences of Solar activity on Polar Vorticity are speculative and in the past Leif Svalgaard has challenged the potential that Solar influences on the upper atmosphere could influence Earth’s climate.
Finally, we have the Wobbly Jet Steam hypothesis put forth by Jennifer Francis, of Rutgers University and other, i.e.:
“The Arctic is heating faster than the rest of the world, hurried along by the disappearance of polar sea ice. Bright white ice reflects energy back into space; dark blue water absorbs it. Arctic temperatures are about 2 degrees Celsius warmer there than they were in the mid-1960s. (The average temperature increase for the Earth’s atmosphere overall is about 0.7 degree C, since 1900.)
In other words, the temperature difference between the Arctic and North America is shrinking. That’s one factor causing wobbliness in the jet stream, the west-east current that circles the Northern Hemisphere, according to Jennifer Francis, research professor at Rutgers University. Normally, that river of air keeps low-pressure cold air contained above the Arctic and holds higher-pressure warm air above the temperate regions, where most people live.
Scientists tend to call the jet stream a “polar vortex,” Francis says.
A slowing in the jet stream has caused it to zigzag, carrying warmer temperatures farther north than usual—and Arctic cold farther south. “The real story,” Francis says, is that the jet stream is “taking these big swings north and south and that’s causing unusual weather to occur in a number of places around the Northern Hemisphere.” Bloomberg Businessweek
I am not sure which scientists beyond Jennifer Francis “tend to call the jet stream a ‘polar vortex,'” as these are two distinct and separate climatic phenomena, i.e.:
“The jet stream consists of ribbons of very strong winds which move weather systems around the globe. Jet streams are found 9-16 km above the surface of the Earth, just below the tropopause, and can reach speeds of 200 mph.” Met Office Whereas “the polar vortex extends from the tropopause (the dividing line between the stratosphere and troposphere) through the stratosphere and into the mesosphere (above 50 km). Low values of ozone and cold temperatures are associated with the air inside the vortex.” NASA
This graphic is helpful in seeing the height and location of the Polar Jet, one of the Jet Streams in relation to the Tropopause, down to which the Stratospheric Polar Vortex can extend:
Additionally, in the following image the Stratospheric Polar Vortex is delineated by the “Arctic Front”, whereas the Jet Stream is delineated by the “Polar Front”:
Jennifer Francis’ comment that “Scientist tend to call the jet stream a ‘polar vortex'” reminds me of this graphic:
But I digress, there are two key weaknesses in the Wobbly Jet Steam hypothesis. Firstly, there does not appear to be a correlation between Sea Ice Area and Extent and the Cold Air Outbreaks. Secondly, it seems highly suspect that the extent of Arctic Sea Ice in September and October could have a significant impact on Stratospheric Polar Vortex behavior in January.
From a correlation perspective, the prior most notable Polar Vortex associated Cold Air Outbreak was the January 1985 Arctic Outbreak:
“The January 1985 Arctic outbreak was the result of the shifting of the polar vortex further south than is normally seen. Blocked from its normal movement, polar air from the north pushed into nearly every section of the eastern half of the United States, shattering record lows in a number of states. The effects of the outbreak were damaging. At least 126 deaths were blamed on the cold snap and 90 percent of the citrus crop in Florida was destroyed in what the state called the “Freeze of the Century.” Florida’s citrus industry suffered $1.2 billion in losses ($2.3 billion in 2009 dollars) as a result of the inclement weather. The public inauguration of President Ronald Reagan for his second term was held in the Capitol Rotunda instead of outside due to the cold weather, canceling the inaugural parade in the process. (Because Inauguration Day fell on a Sunday, Reagan took a private oath on January 20 and the semi-public oath on January 21.)” NOAA
(An interesting aside, on January 12, 2014 “KinkyLipids” changed the Wikipedia January 1985 Arctic Outbreak page from ‘Arctic outbreak’ to ‘cold wave’, ‘Janaury’ to ‘Winter’ and “moved page Winter 1985 Arctic outbreak to Winter 1985 cold wave” because “Sources do not use the term ‘Arctic outbreak’. The term ‘cold wave’ matches other Wikipedia articles”. Not sure why one wouldn’t call “the outbreak of cold-air events” an “outbreak”, but you can visit the new Wikipedia “Winter 1985 cold wave” at the old January 1985 Arctic Outbreak link http://en.wikipedia.org/wiki/January_1985_Arctic_outbreak)
Regardless of what it’s called, the January 1985 Cold Air Outbreak occurred during a time of slightly above average Northern Sea Ice Area, where the January 2014 Cold Air Outbreak occurred during a time of slightly below average Northern Hemisphere Sea Ice Area:
Also, Arctic Sea Ice Extent was within two standard deviations of the 1981 – 2010 average for the entirety of 2013:
and there was signifacantly more Sea Ice Area prior to the recent the strong Cold Air Outbreaks occurred, versus 2012 when the Cold Air Outbreaks weren’t as strong:
Aside from the apparent lack of correlation between Cold Air Outbreaks and Arctic Sea Area and Extend, there is another aspect of Arctic Sea Ice that makes the Wobbly Jet Stream hypothesis even wobblier. The Arctic is mostly land locked and freezes over quickly in the Fall. Thus by December Sea Ice Extent has reached across much of the Arctic:
For the Wobbly Jet Stream hypothesis to be correct, either the approximately 1 Million Sq. km Sea Ice Area Anomaly in September and October must have a long lasting residual effect that lingers into January to disrupt the vortex, or the approximately 500K Sq km anomalies in November and December around the periphery of the Arctic are what must weakened and displaces the Stratospheric Polar Vortex.
Even Kevin Trenberth thinks the melting sea ice, warming Arctic, Wobbly Jet Steam causes cold January weather hypothesis is weak, i.e. “So with regards to the Arctic, there are certainly major changes in the Arctic Sea Ice. And those are biggest in the fall. We’ve had record low Arctic Sea Ice, about 40% decline in Arctic Sea Ice overall, since the 1970’s, in September. But the Arctic fills up in the winter time.” “And so at those times of years the Arctic Sea Ice it seems to me plays a much lesser role. The area affected is a lot less, simply because the arctic is land locked.”
So Planetary Waves, Eddy Heat, Geomagnetic Storms or Sea Ice, what do you think caused the weakening and displacement the Northern Stratospheric Polar Vortex in January 2014?
For an array of real time Northern Stratospheric Polar Vortex graphs and graphics please visit the WUWT Northern Polar Vortex Reference Page.
John F. Hultquist says:
February 1, 2014 at 9:14 pm
*******************
thats not the one I saw but seems to match what I had understood, thanks.
yay…although presently we are warm now so may not be any worse than normal.
oh well, feb in Maine is always cold so not a huge issue, was just trying to think/plan ahead as I sometimes have to leave water running.
Following several decades ofa decline of solar activity will cause such changes in the stratosphere, the climate goes back about 100 years.
Forecast jet stream on February 6. Can see the air from the pole of reaches the center of North America.
http://oi57.tinypic.com/16h2oog.jpg
it has been cooling in Alaska since 1998
http://oi40.tinypic.com/2ql5zq8.jpg
it will continue that way
because it depends on the sun…
Well this says there is a regular pattern to these events.
Polar Vortex
“It was shown that the detected earlier ∼60-year oscillations of the amplitude and sign of SA/GCR effects on the troposphere pressure at high and middle latitudes (Veretenenko and Ogurtsov, Adv.Space Res., 2012) are closely related to the state of a cyclonic vortex forming in the polar stratosphere. The intensity of the vortex was found to reveal a roughly 60-year periodicity affecting the evolution of the large-scale atmospheric circulation and the character of SA/GCR effects.”
Veretenenko & Ogurtsov
http://www.sciencedirect.com/science/article/pii/S0273117713005474
ren says:
February 2, 2014 at 7:51 am
Following several decades ofa decline of solar activity will cause such changes in the stratosphere, the climate goes back about 100 years.
Gradually changing stratosphere, with changes in the level of solar activity, from higher to lower. Sounds about right.
How about changes in LOD length of day, changes stratospheric winds, too.
Or changes in rotation, affect axial tilt beginning with minute changes..
If LOD fluctuates + – 3 ms over higher amplitude solar cycles. What happens to LOD when the solar cycle changes to several low consecutive solar cycles or numerous low amplitude cycles?
Carla says:
What happens to LOD when the solar cycle changes to several low consecutive solar cycles or numerous low amplitude cycles?
And this is the crux of the matter. One low cycle and cosmic radiation reaches the records. Whether will beat another record with the 2010?
Joel O’Bryan says:
February 1, 2014 at 9:28 pm
@goldminor
The serious physical problem you would have to overcome with your Moon phase observation-explanation is that lunar tidal forces diminish rapidly toward the poles (cosine of lat).
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Greg Goodman says:
February 2, 2014 at 1:35 am
goldminor: “Here is a possible piece to the puzzle. I had noted a potential correlation with moon phases and polar sea ice growth or retardation. ”
Detailed spectral analysis reveals perigee lunar cycles in Arctic ice extent.
———————————————————————————————
Thanks for the thoughts. Could pressure changes in the oceans from lunar tidal influences lead to the formation or decrease of sea ice? Another thought, is this occurring at a more noticeable rate now, because of alignment changes in other planetary bodies and/or through solar changes? It is apparent that this event is not seen on every moon phase during the course of a year. Is there another affect that combines with or is augmented by the moon phase?
lsvalgaard says:
February 1, 2014 at 3:59 pm
If solar activity were a primary factor in Stratospheric Warmings [SSW] one would expect that to occur in both the northern and the southern polar caps as solar-induced geomagnetic activity occurs equally in both hemispheres [being global and occurring at the same time in both polar caps]. However, SSW are almost exclusively a Northern Hemisphere phenomenon [I know of only one case of a southern SSW].
—————-
Why should one expect solar-induced geomagnetic activity to occur equally in both hemispheres when (a) the planet does not have two North (or South) magnetic poles, and (b) the solar wind is not electrically neutral? Is this not a case of fiat definition conveniently dissolving the scientific problem?
I agree with ren, Carla, Stephen Wilde, Brent Ra, and a few others – who are on the right road that only leads to solar activity as the cause. On the other hand, there’s this one solar scientist guy…
lsvalgaard says:@ur momisugly February 1, 2014 at 3:59 pm
“If solar activity were a primary factor in Stratospheric Warmings [SSW] one would expect that to occur in both the northern and the southern polar caps as solar-induced geomagnetic activity occurs equally in both hemispheres [being global and occurring at the same time in both polar caps]. However, SSW are almost exclusively a Northern Hemisphere phenomenon [I know of only one case of a southern SSW].”
I think Dr. S’s statement would apply if both the North and South poles were the same polarity magnetically. However, each pole, being polar opposites in magnetic polarity (pardon the puns), influence charged particles oppositely, do they not? Then why would we expect the atmosphere above the South pole to react to protons & electrons from the magnetosphere (delivered from CMEs) in the same way as the atmosphere above the North pole?
I would like to know when that southern SSW occurred, so we could study it and the solar and geomagnetic activity associated with it, and see how that event differed from northern SSW events.
Regarding surface and ocean temperatures: lower solar activity periods result in cooling because of concurrently less energetic photons in the solar flux, while higher solar activity periods result in warming from more energetic solar flux photons, in short term as well as over longer term periods.
The answer, my friends, is blowing in the wind: photons, protons, and electrons – delivered by solar flux and solar wind. I covered this at least a month ago – must I repeat myself? You wanted a mechanism – there it is – it’s that simple – albeit with some complications.
There’s a great 1977 video called ‘The Sunspot Mystery’ at http://youtu.be/v3frXY_rG8c that helps illustrate how far off course since then climate science has veered in interpreting the sun-earth connection (nothing in it about SSWs, polar vortices, or CO2).
Luther Bl’t says: February 2, 2014 at 1:03 pm
You must have been reading my mind – we said the same thing – LOL.
Note that whatever effect solar variability has it must alter the vertical temperature profile in the atmospheric column.
Furthermore, if the positions of the climate zones and the jet stream tracks are to be affected it must have differential effects between equator and poles.
It is ozone and ozone alone that creates the temperature inversion at the tropopause and so that is where we must look for the effect of solar variations.
To achieve more meridional jets in the LIA (and now) at a time of quiet sun one MUST have a warmer stratosphere and lower tropopause at the poles.
To achieve more zonal jets in the MWP and the late 20th century warming spell at a time of active sun one MUST have a colder stratosphere and higher tropopause at the poles.
No other scenario fits both observations and the basic laws of physics.
Bob Weber says: February 2, 2014 at 1:06 pm
I would like to know when that southern SSW occurred, so we could study it and the solar and geomagnetic activity associated with it, and see how that event differed from northern SSW events.
“The Southern Hemisphere (SH) sudden stratospheric warming (SSW) of 2002 was unique in more than four decades of observations not only in terms of its timing during the calendar year, but also in terms of its amplitude. Other papers in this volume deal extensively with the state of the tropospheric circulation during the period leading up to the SSW of 2002 and of the SH stratospheric circulation throughout the life cycle of the event (e.g., Charlton et al. 2005; Newman and Nash 2005; Orsolini et al. 2005).”
“The results presented in this study are remarkably similar to those observed in association with anomalies in the NH stratospheric polar vortex, as documented in Baldwin and Dunkerton (2001). Thus, the results provide independent verification for the observed relationships between long-lived anomalies in the NH stratosphere and the surface climate. One notable difference between the two hemispheres is the enhanced persistence of the SH anomalies. In the NH, major stratospheric events are followed by anomalies in the lower stratosphere and troposphere that persist for up to 60 days; in the SH; such events are followed by anomalies
in the lowermost stratosphere and troposphere that persist for up to 90 days. The enhanced persistence of anomalies in the SH stratosphere is consistent with the relative dearth of dynamical forcing there.”
http://www.atmos.colostate.edu/ao/ThompsonPapers/ThompsonBaldwinSolomon.pdf
“In late September 2002 the Southern Hemisphere stratosphere underwent its first recorded major stratospheric warming, splitting the vortex and tearing the normally quiescent Antarctic ozone hole into two parts. The occurrence of this “unprecedented event” (WMO, 2002), in which the stratosphere suddenly warmed, is in contrast to the trend for the last ~20 years toward a stronger, colder, longer-lasting Antarctic vortex.”
http://www.atmosp.physics.utoronto.ca/SPARC/News20/20_Baldwin.html
“We use ground-based and satellite measurements to examine, for the first time, the characteristics of equatorial electrodynamic perturbations measured during the 2002 major and 2010 minor Southern Hemisphere sudden stratospheric warming (SSW) events. Our data suggest the occurrence of enhanced quasi 2 day fluctuations during the 2002 early autumnal equinoctial warming. They also show a moderately large multi-day perturbation pattern, resembling those during arctic SSW events, during 2002 late equinox, as the major SSW was weakening. We also compare these data with extensive recent results that showed the fundamentally important role of lunar semidiurnal tidal effects on low latitude electrodynamic perturbations during arctic SSW events.”
http://onlinelibrary.wiley.com/doi/10.1002/jgra.50142/abstract
“Using absorption data measured by imaging riometer for ionospheric studies (IRIS) located at the South Africa National Antarctic Expedition (SANAE), Antarctica (72° S, 3° W), we extracted the parameters of gravity waves (GW) of periods between 40 and 50 min during late winter/spring of the year 2002, a period of the unprecedented major sudden stratospheric warming (SSW) in the Southern Hemisphere middle atmosphere. During this period, an unprecedented substantial increase of temperature by about 25–30 K throughout the stratosphere was observed. During the period of the occurrence of the major stratospheric warming, there was a reduction of both the GW horizontal phase speeds and the horizontal wavelengths at 90 km. The GW phase speeds and horizontal wavelengths were observed to reach minimum values of about 7 m s−1 and 19 km, respectively, while during the quiet period the average value of the phase speed and horizontal wavelength was approximately 23 m s−1 and 62 km, respectively. The observed event is discussed in terms of momentum flux and also a potential interaction of gravity waves, planetary waves and mean circulation.”
http://www.ann-geophys.net/31/1709/2013/angeo-31-1709-2013.html
“In summary, our data suggest that the during 2002 Southern Hemisphere SSW event there
were quasi-two day perturbations on equatorial ionospheric electric fields and currents. Our
autumnal equinoctial data also suggest the occurrence of multi-day coherent electrodynamic
perturbations with morning depression and afternoon enhancements near new moon. These
perturbation resemble those observed during Northerm Hemisphere warmings and which were
associated with enhanced lunar tidal effects. However, additional measurements during
Southern Hemisphere and also equinoctial Northern Hemisphere SSWs are clearly needed to
fully characterize the response of the low latitude ionosphere during these events and to
determine the importance of lunar tidal and the occurrence of enhanced wave-like fluctuations.”
http://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=3&ved=0CDwQFjAC&url=http%3A%2F%2Fwww.igp.gob.pe%2Fits%2Ffile.php%3Fnf%3DIGP-1-1-1-1359998202.pdf%26sub%3D1&ei=fsHuUrbdLIvJsQS0hoGICw&usg=AFQjCNGXyPuIILl0cDdwM0FUVTqgK8PyZw&bvm=bv.60444564,d.cWc&cad=rja
“The circulation in the stratosphere is characterized by a series of planetary wave events in 2002 winter that weakened he polar vortex and triggered the SSW in the late September. In Fig. 4, we compare the zonal winds at ∼ 94 km from SANAE HF radar with the zonal mean zonal winds from NCEP stratospheric data (at 10 hPa), and the results show that the reversal event in the MLT took place in a few days (about a week) prior to the reversal in the stratosphere. This behaviour indicates that there may be a downward propagation of circulation disturbance in the middle atmosphere. Similar results were also reported by Dowdy et al. (2004). SANAE HF radar results show similarities to the previous observations of the major SSWs both in the southern and the Northern Hemisphere. Lee et al. (2009) also reported the same behaviour of the middle atmosphere, where they studied the vertical structure and evolution of the wintertime Northern Hemisphere Annular Mode (NAM). In their study they concluded that the time evolution of NAM suggested that significant NAM anomalies typically appear first in the mesosphere and progress downwards”
http://www.atmos-chem-phys.net/10/3397/2010/acp-10-3397-2010.pdf
Thanx justthefactswuwt says: February 2, 2014 at 2:24 pm. I’ll spend some quality time with that.
Bob Weber says:
February 2, 2014 at 1:06 pm
I agree with ren, Carla, Stephen Wilde, Brent Ra, and a few others – who are on the right road that only leads to solar activity as the cause. On the other hand, there’s this one solar scientist guy…
lsvalgaard says:@ur momisugly February 1, 2014 at 3:59 pm
“If solar activity were a primary factor in Stratospheric Warmings [SSW] one would expect that to occur in both the northern and the southern polar caps as solar-induced geomagnetic activity occurs equally in both hemispheres [being global and occurring at the same time in both polar caps]. However, SSW are almost exclusively a Northern Hemisphere phenomenon [I know of only one case of a southern SSW].”
————————–
Sudden stratospheric warmings of late.. are a combination of solar activity and warmed areas of the planet due to mankinds error.. Like for instance that Asian sector where in that quadrant you have the most populated area of the planet. India, China etc., well its observed that there is a contribution from this sector and when the sun belts the equator with a solar storm it puffs up the atmosphere and waves carry the agw with it.
You know, without the solar activity to push the agw around, it would seem that agw is on pause..
Carla says:
February 2, 2014 at 2:54 pm
I agree with ren, Carla, Stephen Wilde, Brent Ra, and a few others – who are on the right road that only leads to solar activity as the cause.
If solar activity is the primary cause of SSWs then we should observe those equally in both hemisphere and we do not, so ‘the right road’ appears to be falsified. Of course, what is a little falsification for true believers?
As an observer to the above discussions – in particular, the development of intense high and low pressure systems above North America and the consequent polar vortex – might I inject another possible trigger. It seems to me that there has been a significant rise in both sea and land surface temperatures in the NW corner of the North America continent during the summer and autumn months of 2012 and 2013. These increases have been particularly evident along the west coast of the USA, western Canada and Alaska and coincide with the intensification of stationary high pressure systems centered on the Bering Sea.
Now, high pressure systems are usually accompanied by clear skies and sinking air – which inevitably lead to atmospheric warming. When the high pressure system remains stationary for a protracted period of time, this can lead to a significant increase in surface temperature. However, the absence of cloud cover should counter this trend because there is no natural barrier to trap rebounded long-wave radiation. So what is driving the current temperature increases?
Between the 1960s and 1990s jet aircraft routes were primarily between the USA and Japan on the one hand and to Europe on the other. Most aircraft were limited in range and hence refueling stopovers were made in Alaska en route to Japan and Europe. Accordingly, aircraft movements across the Arctic Ocean were confined to those proceeding to Europe. Following the development of long-range jet aircraft the need for an intermediate stopover in Alaska was effectively eliminated. Concurrent with the development of these long-range aircraft, routes broadened across the entire Arctic Ocean – this being due to the opening of markets in SE Asia and, particularly, China and India. Could this be driving the observed “heating” of the Arctic region, Alaska and western Canada?
Now jet aircraft travelling at cruising altitude often produce condensation trails. These vapor trails intensify as one moves from the tropics to high latitudes and can drive the formation of a cirrus-like cloud in the lower stratosphere. Such “clouds” can trap rebounded radiation; leading to an artificial heating of regions beneath the dispersed vapors.
Also, polar routes become increasingly problematic as one moves from summer to winter. It becomes necessary for aircraft to travel at progressively lower altitudes as winter approaches in order to avert problems with fuel supply. Is it possible that an artificial “heat-trap” is being created as a consequence of aircraft movements between the USA and SE Asia/China and that this trap intensifies in winter as cruising altitudes drop during the winter months?
Could such a “trap” account (in part), for (1) the heating that we are witnessing along the west coast of the USA, western Canada and Alaska and (2) the intensification of the high pressure system along this spine?
Greg Beasley
(Prospect, NSW)
goldminor: “It is apparent that this event is not seen on every moon phase during the course of a year. Is there another affect that combines with or is augmented by the moon phase?”
There is much more to lunar motion and hence its influence on tides than the visible cycle.
Even the synodic month or “lunation” period varies from around 28.2 to 29.9 days through the year and from year to year. The lunar distance varies around 27.55 days. That means there will be a phase slippage of around 2 days per lunar month, so just eye-balling the bumps on the annual cycle it will appear to come and go.
I don’t think it has much to do with pressure affecting ice formation. except possible atmospheric pressure via it’s affect on weather.
The amplitude of the monthly effects is quite small but implies that the long term interactions of the various lunar cycles, that lead to periods of 8.85, 9.3 and 18.6 years need to be considered.
For example addition of 8.85 and 9.3 will produce 9.05 modulated by 356 years ( thus with a beat period of 183 years). Now it’s possible such effects just average out but it’s also possible That they produce long term tidal periods that involve large scale bulk displacement of water , and hence heat.
Scafetta and BEST team (land surface temp) have already reported 9.1 +/-0.1 year periodicity in various phenomena
The same period appears in cross-correlation of N.Atlantic and ex-tropical N. Pacific SST
http://climategrog.wordpress.com/?attachment_id=755
Keeling and Whorf (1997) additionally suggested 6.0 years. I find 9.15 and 6.02 in cross-correlation of north and south Atlantic SST.
http://climategrog.wordpress.com/?attachment_id=761
Chandler nutation period of about 436 days (variation is the position of the geographic north pole) is also to be found.
That is not to argue against a solar linkage, much more likely there are many inputs that are significant. However, such repetitive and globally spread signals argue against the simplistic idea that it’s all just stochastic “noise” on top of a steady , exponentially rising CO2 effect.
neither can any such ‘oscillations’ be assume to average out to zero. The spurious and unfounded assumption usually put forward by AGW proponents.
If lunar tidal forces evacuate warm waters from the tropics this will provoke non linear responses in tropical climate. Even if the water is drawn back 4.5 or 9 years later it will not be the same temp as when it left. The idea that this kind of thing can average out like the phases of some harmonic oscillation is clearly not applicable.
lsvalgaard says:
February 2, 2014 at 3:39 pm
Carla says:
February 2, 2014 at 2:54 pm
I agree with ren, Carla, Stephen Wilde, Brent Ra, and a few others – who are on the right road that only leads to solar activity as the cause.
If solar activity is the primary cause of SSWs then we should observe those equally in both hemisphere and we do not, so ‘the right road’ appears to be falsified. Of course, what is a little falsification for true believers?
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How long have we known about SSW in any hemisphere? The space age or period of mankinds history when the solar cycle was in a medium high phase of solar activity? Do they begin to occur early in their season and with more frequency during extended periods of years, of higher solar activity? During times when the atmosphere is already jet puffed up and out by solar storms, seems more likely suitable for any wave, solar, lunar, planetary or combination thereof to do the job.
little bipolar spots and their tilt angles suggestive of changes in solar differential rotation.
MRI shearing through horizontal magnetic laminate sheet, preventing rise (buoyancy damping) of vertical magnetic fields, keeping us in little bipolar spots and specs on the sun?
Carla says:
February 2, 2014 at 4:51 pm
How long have we known about SSW in any hemisphere?
Why don’t you try to find out? GIYF
lsvalgaard says:
February 2, 2014 at 3:39 pm
‘If solar activity is the primary cause of SSWs then we should observe those equally in both hemisphere and we do not…”
It is my understanding (limited as it is) that SSW occurs in winter. Could the fact that currently during SH winter Earth is farthest from the Sun and the lower energy received due to this extra distance would be reason for the lack of SSW in the SH?
eeek
The space age..and during the period of medium high consecutive solar cycles…..
http://en.wikipedia.org/wiki/Sudden_stratospheric_warming
A sudden stratospheric warming (SSW) is an event where the polar vortex of westerly winds in the winter hemisphere slows down or even reverses direction over the course of a few days. The change is accompanied by a rise of stratospheric temperature by several tens of kelvins.
The first continuous measurements of the stratosphere were taken by Richard Scherhag in 1951. He used radiosondes to take reliable temperature readings in the upper stratosphere (~40 km).
It was his persistence which led him to witness the first ever observed stratospheric warming on
27 January 1952.
After his discovery, Scherhag assembled a team of meteorologists specifically to study the stratosphere at the Free University of Berlin. This group continued to map the northern-hemisphere stratospheric temperature and geopotential height for many years using radiosondes and rocketsondes. In 1979 when the satellite era began, meteorological measurements became far more frequent. Although satellites were primarily used for the troposphere they also recorded data for the stratosphere. Today both satellites and stratospheric radiosondes are used to take measurements of the stratosphere
Dr. S., do the sector boundarys form a hour glass like shape around the solar disk? Like a baseball seams?
Tom in Florida says:
February 2, 2014 at 5:19 pm
It is my understanding (limited as it is) that SSW occurs in winter. Could the fact that currently during SH winter Earth is farthest from the Sun and the lower energy received due to this extra distance would be reason for the lack of SSW in the SH?
The difference is only a few percent, so can hardly be significant.
Carla says:
February 2, 2014 at 5:24 pm
Dr. S., do the sector boundarys form a hour glass like shape around the solar disk? Like a baseball seams?
http://www.leif.org/research/Solar%20Sector%20Structure.pdf has more on sector boundaries, see e.g. Slide 7.
“lsvalgaard says:
February 2, 2014 at 3:39 pm
Carla says:
February 2, 2014 at 2:54 pm
I agree with ren, Carla, Stephen Wilde, Brent Ra, and a few others – who are on the right road that only leads to solar activity as the cause.
If solar activity is the primary cause of SSWs then we should observe those equally in both hemisphere and we do not, so ‘the right road’ appears to be falsified. Of course, what is a little falsification for true believers?”
Show me a electrical dynamic plasma pumping system that is symmetrical….. The SSW’s are a cyclical events and I doubt they are driven “directly” by the sun but the energy certainly comes from the sun.. I am however certain that if one were to look closely one would find a basic rhythm if you will, that is driven by the sun as a resonant system.