~ ENSO plays weather maker along with dwindling sea ice extent
~ Extra 2015-16 snowfall a major role in twisting jet stream
~ 2016 warmest consecutive year in history known since beginning of March, but not official till January 2017
~ 2008 Big Blue repeat, cloud seeding theory confirmed yet again.
The sun is of course a giant thermometer, not only a source of energy. Notice apparent lack of sunspots didn't cool anything though.
Arctic deflated sun as seen through many atmospheres. The sun and Earth atmosphere are telling how hot it is anywhere on our planet. The same sun taken in the tropics at the same altitude would look a whole lot rounder.
Rare near dead center lone sunspot is the signature event of this spring. Can you tell which suns as posted above were upright?
Annual coming summer/fall/winter projection:.
First the projection,
Because it is so
obvious, 2016 will be the warmest year
in history despite a forming LaNina. which is the most
lethal combination for the survival of the Arctic Ocean ice pack. Less North American tornados than average is
expected because of collapse of cold air in the higher atmosphere, despite it being very cold during January and
February just past. However there will be a return of
Hurricanes hitting North American shores. Rain for the west Coast of North America will resume to more normal
levels until September. Very hot
summer temperatures for the middle North
American continent will extend towards the entire East coast. NW Europe will be wet which makes it slightly cool, but drier cold fall. Eurasia and Western Russia super heat waves are expected.
The potential for
the North Pole to be sea ice free at Minima coming mid September has never been higher. Arctic sea ice extent will be smaller than all time lowest record of 2012. Clouds
will span less in all regions of the world favoring droughts and heat waves everywhere even where they don't usually occur.
Winter coming will be at first very warm, becoming bitterly cold in January, and so will the sea ice recover rapidly but with far less multi-year ice.
Prognosis:
End of
winter/early spring average vertical sun disk size comparisons ending April 21, 2016
What is the
score?
2016 is #1 at 15.45%.
#2 2015 at 11.82%
#3 [2005, 2006 and 2013] at 10%
#4 [2009, 2010, 2011] at 8.18%
5th place 2012 7.27 %.
6.7%
should be considered a normal year to year fluctuation of all time average vertical sun disk maximum dimensions.
Data from 110 vertical sun disk decimal
levels extending from -0.9 to +10.9 degrees elevations, including 540 observations, above normal year acquisition numbers due to no clouds currently continuing. With about 42 sun disk measurements per
degree elevation, each yearly vertical sun disk average is compared between years
2002 to 2016 inclusively (15 seasons).
What does this
mean? Vertical sun disks are expanded in
a tropical atmosphere as opposed to much compressed for a polar
atmosphere. If there is a warming of the atmosphere in the polar regions, vertical sun disks dimensions have to
expand. But not necessarily evenly at
all sun elevations. The truer measure of expansiveness is clearly depicted by
comparing vertical sun disk dimensions from year to year. Sun disks are another way of signaling over
all temperature trends of the entire atmosphere from 2 times its actual
vertical thickness to about 40 times. It is
the most precise depiction of warming since it incorporates huge atmospheric
distances, far more than any satellite or
possibly radars.
Year
2016 gave extraordinary results despite all time high levels of snow depth on sea ice and land surfaces. This snow dates back to October-November 2015. Laid out more than twice thick than
normal. As a good insulator, thicker snow depth kept permafrost warmer and
the sea ice thinner. It also made the
rising sun ineffective in warming surface air.
Despite more reflection to space, overall winter temperature averages
were above normal. Not by much, but
above average. Expanded sun disk dimensions mirrored the
state of the atmosphere up to where the deeper snow had an impact. All time average highest expansion averages occurred 12 times
between 10 to 5 degrees elevations and 4 times -1 to 4 degrees elevations. Moreover, the upper air above 5 degrees
elevation has had many, the most numerous ever, exploded sun disk sizes especially in the critically
usually very cold Northwest atmosphere from Southern Cornwallis Island
Nunavut Canada. The coldest high atmosphere
air seems to have collapsed or warmed substantially. This is a remarkable event and affects the outlook of coming weather everywhere over the Northern Hemisphere.
El-Nino event just
past was largely felt by more clouds during the entire Arctic long night.
Unlike central Arctic Archipelago, the larger Arctic was found to
be extremely warmed with large temperature anomalies easily more than 4 C in
many regions. ENSO reverted quickly
towards La-Nina lately. Replicating 2008 "big blue" event which was and consists numerous consecutive days without clouds. Interruptions of this years “big blue” was
only by encroaching cyclones, there are no substantial cooling cloud spans about. At season
end, mid
May, there should be nearly the same amount of sun disk observations
than during 2008. The 'big blue" event of 2008 had huge consequences
for water puddles over sea ice.
Optical to remote sensing Correlations:
The seen warming occurred at 250 mb covering almost exactly the Archipelago. But this was the same location where the coldest surface air persisted. Very much conducive to little clouds. A vertical temperature anomaly event from no clouds with deeper surface snow pack reflecting the gradually intensifying sun rays?
Where is summer cold Arctic air going to hang out?
The imminent collapse of the Alaska to North
Pole sector pack Ice will impact the jet stream. But there are other factors largely related
to current La-Nina trending. Cloud
seeding theory predicts less clouds for the Arctic when ENSO
turns towards La-Nina, as it has
already occurred, this favors
Anticyclone genesis as has happened
especially above the Arctic Ocean gyre area.
Mid-April onwards should usually be a very cloudy Arctic Ocean sky, characterized with hardly distinguishable geographic and pack ice lead features perceivable by satellite
photos. So far, this was not the
case, reinforcing again a cloud seeding theory largely correct. But note,
North Atlantic and Pacific Ocean
SST’s were cooled for a prolonged time period because of the same cloud seeding reason when El-Nino was full blast,
more clouds occurred over the Northern Oceans by enormous consecutive Polar Vortex cyclones. These cooler vast areas of sea water will have an important
impact just as well. Past winter circulation pattern of North Atlantic to Pole
cyclones favored a lot of moisture covering most of the Canadian Arctic Archipelago
Southwards. This same pattern likely
gave less snow for Central Northern
Eurasia, very unlike winter 2014-15 huge transcontinental pattern.
Again I split it in three distinct
periods:
April May:
3 distinct
Cold Temperature North Poles (CTNP) vortices
are expected. 2 will eventually
collapse and only one will remain at sea ice Minima. The current Arctic Dipole will largely remain
in place for 4 distinct reasons: Warm
winter continued to spring with temperature to dew
point ratio spread further apart, less
cloud coverage because La-Nina trends, mesoscale CTNP Polar vortices favor a High Pressure between them, with descending air above the Gyre High much warmer than normal.
Note the gyre High moving towards Russia mainly because of CTNP placement.
August September
Greenland largest ice with Ellesmere becomes the center of Cold teamed with what is left of pack ice , Cyclones now linger over the Beaufort Gyre. The big difference with last year is the diminished Polar jet stream not as high in latitude over the Pacific. I'd expect some major heat wave action North Eurasia along with great cyclone diversions NE american continent.