More whitish sea ice"goodbye" waves appeared through wavy clouds, likely under wind driven stratocumulus or altocumulus appearing slightly greyer on August 1, 2016. They now occupy top of sea water once covered by sea ice pans July 21 past. Break up and dispersion of once a huge solid ice field expanse, surrounding with water its broken up smaller pieces, accelerated the melting a great deal. At this date there are huge number of sea ice floes surrounded by open water everywhere in the Arctic.
Beaufort Sea comprises many drift zones, some intertwine, South of Banks island mainly Tidal driven ice tends to move East. Just to the west of Banks is Gyre driven to the Southwest, the 2 give similar but orientated "goodbye waves" according to prevailing current. We can see the gradual rapid melt in progress, but there are still thousands of incoming ice islands from CAB to turn to water.
Lincoln Sea opening to Nares Strait has always a significant tidal (southwards) drift, but in this case the winds, characterized by August 1 lens NW shaped Stratocumulus , easily push away the sea ice Northwestwards, note the "goodbye waves" appear the most fluid and mobile zooming like arrows with the wind. Northern Ellesmere ice conditions are now badly broken and can easily move open for miles in less than a day, it does so even in the dead of winter because of daily tidal activity causing the "big lead" at times , this is a good summer example. WD Aug31,2016
Monday, August 1, 2016
Sunday, July 31, 2016
Back to water..... That just melted "goodbye" wave look
North of Beaufort sea has similar features to Fram Strait especially now. Ice almost completely melted gives waves, similar to cirrus clouds announcing an approaching front:
At extremes of the great Fram Strait melting zone lies the last remnants of sea ice, whose physical nature really becomes elastic, from solid to slush/rubber to water. It is a sight everywhere sea ice melts. In this frame, present Cirrus clouds may be confused with melting sea ice.
Even North of Beaufort Sea:
Its melting North of Beaufort very fast. But just before disappearing, sea ice takes the shape of waves not so dictated by being very rigid, these waves are water in transition from appearing solid white to dark liquid. Each melt region has different melt transition characteristics. Which is of course as individualistic of the geophysical features about.WDJuly31, 2016
At extremes of the great Fram Strait melting zone lies the last remnants of sea ice, whose physical nature really becomes elastic, from solid to slush/rubber to water. It is a sight everywhere sea ice melts. In this frame, present Cirrus clouds may be confused with melting sea ice.
Even North of Beaufort Sea:
Its melting North of Beaufort very fast. But just before disappearing, sea ice takes the shape of waves not so dictated by being very rigid, these waves are water in transition from appearing solid white to dark liquid. Each melt region has different melt transition characteristics. Which is of course as individualistic of the geophysical features about.WDJuly31, 2016
Saturday, July 30, 2016
Rapid Supply and Melt North of Mackenzie Delta Inuvialuit nunangani
At present, the Beaufort Gyre current is very healthy with rapid continuous ice floes for the melt slaughter, again to the point where we can't readily easily identify any ice pan which disintegrates in shape and size in a matter of days. Note in particular the apparent lack of day to day extent shrinking. JAXA and other Grids may show very little melt progress but there is in fact huge ongoing melting.
Melting occurs while the supply lasts:
Further North of Northeast, the Central Arctic Basin has not an infinite supply of sea ice, although it may appear as such. Note CAB sea ice pack density literally going smaller day by day, again extent numbers wont really explain this rapid melting until there is less ice than the required 15% threshold . Archipelago Islands of course provide no such resupply, with the current flowing of sea ice away from them, these Islands provide "land shadows" , these give a net but small extent drop, however this is how the NW channels open suddenly, there is much more room for sea ice to move about. WDjuly30,2016
Melting occurs while the supply lasts:
Further North of Northeast, the Central Arctic Basin has not an infinite supply of sea ice, although it may appear as such. Note CAB sea ice pack density literally going smaller day by day, again extent numbers wont really explain this rapid melting until there is less ice than the required 15% threshold . Archipelago Islands of course provide no such resupply, with the current flowing of sea ice away from them, these Islands provide "land shadows" , these give a net but small extent drop, however this is how the NW channels open suddenly, there is much more room for sea ice to move about. WDjuly30,2016
Friday, July 29, 2016
Water temperature +.9 C at 77.8N 157.1W last report of Mass Buoy 2015j
Near 80 N water temperatures still with quite a lot of ice cover, was measured a very warm if not hot +.91 C July 22, by Mass Buoy 2015J last report. The arrow points to very near its location. Well further away from wide open water. This temperature means bye bye sea ice, and mass buoy 2015J should turn soon into a boat at any moment. What surprises is how dense the ice was with so warm a water under. The bottom thermistors read -1 C which may be more accurate, however throughout the winter the Buoy appears to have recorded very good water temps.Mass Buoy 2015f, well further North 83.49 North, has -1.4 C water.
There are 2 more locations with 1 degree sst much nearer the Pole, likely retrieved from remote sensing. Those in circles are in doubt, not necessarily incorrect, although the one North of Greenland +28C may be judged incorrect. Note Chukchi sea +10 C North of Novaya Zemlya +6 C, incredibly warm waters.
WDJuly29,2016
There are 2 more locations with 1 degree sst much nearer the Pole, likely retrieved from remote sensing. Those in circles are in doubt, not necessarily incorrect, although the one North of Greenland +28C may be judged incorrect. Note Chukchi sea +10 C North of Novaya Zemlya +6 C, incredibly warm waters.
WDJuly29,2016
What does JAXA AMSR2 68377 km2 sea ice loss in a day looks like? Less than what it seems
Thursday, July 28, 2016
See through Cyclone; not so much clouds
This very artistic, elegant, cyclone North of East Siberian sea is not very cloudy. Adds to the complexity of already mixed up ice, along with with different weather features. wdJuly27,2016
Wednesday, July 27, 2016
Very little wind significant change North of New Siberian Islands
Again the larger question is how already badly broken up 2016 sea ice is reacting to Cyclonic winds? Let's see what merely an approaching Cyclone did North of Siberia after July 19:
There are at least 2 concurring major contributors to icescape dilution: one is critical temperature of sea ice core nearing multiple possible melting points, 2 is the approaching Cyclone covered in the previous article. Spreading and shattering ice around and very likely accelerating melting. Let's see the net effect with 2 clearest pictures:
Devastation with very little wind, water to ice extent ratios have increased substantially, many ice pans have shattered and are difficult to recognize. This is a small example of what a truly powerful Cyclone can do. WD July 27,2016
Arctic Cyclone storm surge effects on already badly broken 2016 sea ice
It is really in reality deja vu, August 5 2012 had a deep cyclone apparently clearing sea ice very quickly. It was so, but there was pre-conditioning of sea ice, already on the verge of melting completely, with ice column temperatures at or near the melting points of saltier bottom and top fresh water like ice. The Cyclone opened up sea ice much further, stirred the sea water column where there was open water. Now we have a somewhat slower, quasi stationary approx 990 mb large Low North of East Siberian Sea. Sea ice was already broken up before it flayed it further, it will be very interesting to see if there has been residual effects similar with 2012 Aug 5 event:
Cyclone July 26 opened up the ice much further, black water is seen near its centre, a particular place where sea water level rises more than at the far perimeter of the cloud waves. Prior to the cyclone, North of East Siberian sea was already quite open, part of the "Laptev bite" look. What is very interesting is the storm centre black zone.
What is the difference with 2012?
Cyclone July 26 opened up the ice much further, black water is seen near its centre, a particular place where sea water level rises more than at the far perimeter of the cloud waves. Prior to the cyclone, North of East Siberian sea was already quite open, part of the "Laptev bite" look. What is very interesting is the storm centre black zone.
What is the difference with 2012?
July 26 2012 same area had sea ice far less broken, which eventually melted/compacted at minima. Although the East Siberian sea of 2016 had similar open water to the Laptev sea of 2012.
We can conclude from AMSR2 data and the NASA overviews that this Cyclone had not quite the same effect as August 2012 Low, after all it was not as strong, but did indeed create a great deal more open water, highlighting the fragility of sea ice surely to vanish come mid September, especially if the ratio of open water to sea ice extent was increased. WD July 26,2016
Monday, July 25, 2016
Beaufort area 400,000 km2 almost permanent broken ice area is clearing/melting.
Unless it is a big melt year, end of July usually offers a few clues about coming minima outlook.
This year is no different, but has its own quirks, namely an area about 400,000 km2 north of Beaufort sea which had a continuous injection of broken ice pans, the physics involved is simple
and complex by many varying geophysical parameters.
Ice melts quicker when ice core temperature is close to 0 C. This is the main reason why melting occurs faster at end of July, there are of course other factors, which is warmer air and sea temperatures, but it is very difficult for surface air to warm a whole lot with the presence of sea ice2 meters below.
From the constant presence of ice a summer temperature battle ensues, and thus temperatures without a great deal of very warm advection injections remain steady, especially by latent heat of fusion of ice, the warming can't really be measured by air temps. Eventually the most vulnerable sea ice, an ice pan surrounded by warmed sea water, vanishes quickly. The melting point in the ice column was achieved by many pieces of sea ice as per July 25 2016, achieving a greater melt than all previous days.
Before July 25, the smallest blocks of ice didn't survive very long, leaving the larger ones to travel Westwards. However now is the time when the greatest melting can happen, the heat transferred to sea ice, a continuous heat sink, renders sea ice to mush to melt to water.
The only Mass Buoys currently active; 2015f 83.11 N 139.14W has an average core temperature above -1 C and strategically located Mass Buoy 2015 J 77.8N 157.16W has similar ice core temps. These buoys ice surface are more or less not surrounded by open water. Again, the latent heat of fusion of sea ice captures a lot of the heat otherwise manifested warmer on ground surfaces of the near by archipelago Islands.
Summer DMI model calculation of surface air temperatures appear usually steady, over all past summers, rarely at great variance with about +1.5 C at peak. This is a good example of sea ice moderating air temperatures when the latent heat of fusion is active. The wild variances over the dark season are due to warm air advection largely by Northwards penetrating cyclones, these carry a much wider temperature difference than sea ice during winter, summer cyclones apparently do not give such effects, which is quite fascinating. wd July25,2016
Laptev bite vs Beaufort melting zone; there is a substantial difference
June 21 to July 23 2016 AMSR2 Shizuku satellite displays many melting areas, but the two most prominent have different features, Beaufort receives a great deal of sea ice from the Gyre current, most ice pans usually perish westwards, some survive long and cause a distorted calculation of apparent more sea ice due to the 15% extent criteria. The Laptev 'bite' has no such qualms, when it sweeps Northwards there is no sea ice replenishment process. We may conclude that most surviving ice in Beaufort Area will melt and eventually cause rather large extent drop numbers. Furthermore the Laptev sea Northward expansion has a huge potential since Northward ice displaces very fluidly. A double "arch" water area is forming along 150E longitude line widening water zones Eastwards and Westwards from sea ice displacements to the North all the way to 85N and likely Polewards very fast. WD july25,2016
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