ARCTIC SEA ICE –Ralph Rains?–

Ralph hasn’t become the gale some models were foreseeing, but is a persistent feature at the Pole, and a wrench in the works of the summer thaw.   In essence Ralph creates clouds where I expect sun. This slows the creation of melt-water pools, which are a creation that quickly changes the albedo equation, for the brilliant white of the snows (which reflects light in a highly efficient manner) is changed to the battleship gray of slush (which absorbs more sunlight and accelerates the surface melt.) Once the slush turns into an actual pool particles of soot, volcano ash, and arctic algae often create a black bottom to the pool, which hastens the melt further, and on occasion melt down and create a hole to the sea beneath, weakening the ice and contributing to the break up of floes.

This is a time I sorely miss the floating cameras, for they gave you a visual proof of what otherwise is merely modeled guess-work. The only camera we have is lodged in the ice of Parry Channel, and can’t give us a clear idea of the conditions out in the open sea. However it is better than nothing, and does show the crispness of the drifted snow softening in the thaw.

Obuoy 14 0623 webcam

O-buoy 14 is down around 74° north latitude, and away from the center of Ralph near the Pole. I have an insatiable curiosity about higher latitudes. The DMI graph shows the mean, north of 80°, as being below normal but above freezing.

DMI4 0622 meanT_2017

To look at Dr. Ryan Maue’s maps of modeled temperatures (free week trial available at Weatherbell site) isn’t exactly helpful, because the GFS tends to average it all out to a blandness, while the Canadian differentiates to a degree where it seems to make storms more intense. Which is a curious George to trust? (GFS to left; JEM to right)

 The reason this matters is because in the polar summer snow can change to rain, and this makes an enormous difference. Snow (usually a dusting to an inch, as the arctic is a desert), slows the melt by adding more brilliant white to reflect heat, while rain immediately creates slushy, gray spots and speeds the melt. As is often the case in the arctic, a half degree can make a big difference.

One of my favorite examples was the case of “Lake North Pole”, in 2013. The melt-water pool directly in front of the camera, expanded by summer rains in mid July, generated no end of media hype, complete with stories of Santa drowning and so on.

LNP 1 np-july-26-npeo_cam2_20130726072121 However no sooner had the media gotten everyone looking that way, when the water drained away down through a crack in the ice (as is often the case.)

LNP 2 np-july-28-npeo_cam2_20130728131212

The ice was still gray and capable of absorbing more heat than snow, but, rather than summer rains, summer snows followed.

LNP 5 np-july-29-npeo_cam2_20130729071817

And by August 5 all talk of “Lake North Pole” was muted. It had gone from being an Alarmist talking point on July 26 to being a Skeptic’s talking point.

LNP 3 np-aug-5-npeo_cam2_20130805065710

The camera allowed the curious to compare the August 5 view of 2012 (left) with 2013 (right).

To the dispassionate it simply looked like perhaps 2013 was a colder summer than 2012, but, in terms of getting a political message across, I fear cameras had gone from seeming like an excellent idea on July 26 to seeming like a very bad idea on August 5. This may be one reason funding dried up, and we are without their wonderful visual evidence this summer.

In any case, we now are stuck with what a satellite can see from afar. Ralph’s clouds can then present one with a bit of a problem, though there are usually plenty of interesting views further south, if you are in the mood to ruin your schedule with a wonderful form of procrastination. Here’s a nice, current view of Petermann Glacier and Nares Strait.

The problem is we are too far away to get the intimate feel for conditions the cameras gave us. We can’t see if it snowed or rained, last night. And, in cases where radar attempts to see through clouds, we are not even sure if we are looking at open water or a melt-water pool.

I sure do miss those cameras.

The best I can do is look at Ryan Maue’s “precipitation type” maps, keeping in mind they are models. The GFS seems to suggest Ralph will not rain. Ralph will continue to dust the north with snow (blue). The only rain (green) is towards the Alaska coast.

The maps below represent the GFS forecasts for 6, 72, 120 and 168 hours. Recognizing these are forecasts and not reality, Ralph looks like he will peak in 72 hours, down at 977 mb, but persist for a week. Only then are there signs Byoof (the Beaufort High) will come back.

Ralph B3 gfs_ptype_slp_arctic_2

Ralph B4 gfs_ptype_slp_arctic_13

Ralph B5 gfs_ptype_slp_arctic_21

Ralph B6 gfs_ptype_slp_arctic_29

To me it seems Ralph is being a real spoil sport to the melt-season. Right when the sun is at its highest he is murking up the sky and dusting everything with snow. Of course, most of the melt comes from below, but we won’t be setting any records unless Ralph takes a hike.

I should confess I blew a forecast, for I did not expect Ralph to show up much this summer. My assumption was that the lagged effects of the weak La Nina would reduce the difference in temperatures between the tropics and the arctic, and that it was that difference that fueled the anomaly I call “Ralph”.

This is merely my wondering, and likely should not be dignified with the word “hypothesis”, but the persistence of “Ralph” intrigues me and calls for an explanation, and what I wonder is this:

If the “Quiet Sun” does deliver less energy to the earth in various ways, could it be that less energy warms the Equator while cooling the Pole? At the Equator less energy would produce less wind,  indirectly leading to warming, by stirring up less cold water, and therefore intensifying El Ninos while weakening La Ninas. Meanwhile, up at the Pole, less energy has a more direct effect during the summer, making it colder. During the winter there is no sun so no effect, but the import of warm surges makes the winter’s milder. All year long the tropics are generally warmer (so far) and this fuels a more meridional jet, which is what creates the “feeder bands” that fuel Ralph.

That’s my story, and I’m sticking to it.

Before Ralph reappeared Byoof did manage to push the ice away from the western entrance to the Northwest Passage, (lower right) but the ice is still fast against the shore at Barrow (top right).

Daytime sea-breeze shifted to a light land-breeze during Barrow’s “night”, and warm inland temperatures wafted over them, lifting them to a balmy 41°F.

Barrow 20170623 05_27_09_508_ABCam_20170623_132400

Here’s the Navy thickness map. (Ice-out starting in Hudson Bay):

Thickness 20170623 Attachment-1

And here’s the “extent” graph everyone likes to watch:

DMI4 0622 osisaf_nh_iceextent_daily_5years_en

Stay tuned!


8 thoughts on “ARCTIC SEA ICE –Ralph Rains?–

  1. Caleb u need a fund me page to send you to Santa’s workshop.
    Yesterday morning the snow at OB 14 had that mottled, it has been raining look to it. Not so now and so it likely cooled and then the snow began to drift.

  2. Meanwhile, I saw calculated temps on nullschool in Antarctica yesterday of c.-67C. For what we are about to receive……

    • There was an interesting post on WUWT attributing the decrease in sea-ice around Antarctica to stronger storms gnawing at the ice. (You had to read between the genuflections to Global Warming). I immediately wondered if the pattern has been more meridional in the southern hemisphere as well. Likely the continent is just too high and cold for any jets to penetrate to the Pole and create a “Ralph”, but instead fed big high latitude gales around the edges.

      • Yes, we have meridionality, but I will search for lows etc. over the land.

    • Yes, I caught that. Watch the time laps and you can see an earlier set from a couple days ago that drifted over before the latest set ambled by. Lucky the camera didn’t go “click” when they were near, as we have lost cameras before to curious bears.


    That’s about it at the moment, and most of the time. The high pressure half of the continent is very much uplifted. One joy of physics is that is, strangely, dependent on the actual physical conditions, for all our ‘Laws’. MSLP never happens there, and it is all downhill after landfall, a feeling we know well….katabatics rule!
    Will try to keep an eye out for highland lows.

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