Coastal Arctic Temperatures hit 84.2 F Today

Fossil fuel burning is really ramping up the global heat. And for the typically cold Arctic Ocean coastal region, this means that temperatures are now able to strike into the 80s during mid-May.

Today, a very extreme wave in the Jet Stream produced an elongated ridge pattern that ran far to the north over Eastern Europe. This high amplitude wave brought with it temperatures that ranged up to 20 degrees Celsius (36 degrees Fahrenheit) above normal for this time of year. A heat surge which pushed temperatures to 29 C or 84.2 F near Archangel, Russia.

Extreme heat Arkangel

(Severe heat strikes northeastern Europe as part of an extreme jet stream wave pattern. Image source: WX Charts. Hat tip to Peter Sinclair.)

The kind of jet stream wave that spurred this extreme heat has become common over recent years. It’s an atmospheric feature that some scientists have associated with polar amplification — an aspect of human-forced climate change in which the poles warm faster than the lower latitudes.

During 2019, heat transfer into the Arctic has contributed to near record low and record low sea ice extent values in the months of March, April and May. The wavy jet stream patterns have also been associated with a number of severe weather events. Today’s extreme northern heatwave fits into a longer-term pattern of similar occurrences.

(Analysis of recent extreme jet stream pattern over Eastern Europe.)

Wavy, persistent jet streams have recently been associated with worsening weather — heat waves and wild fires in the ridge zones and severe precipitation in the trough zones. Scientists like Dr. Michael E. Mann and Dr. Jennifer Francis have warned that the associated Jet Stream waves are linked to human-forced climate change and are likely contributors to recent events.

Dr. Mann notes:

The extreme weather we’re seeing around the Northern Hemisphere, such as heat waves, floods, droughts, and wildfires, is related to an unusual, undulating pattern in the jet stream. The other part of this that’s atypical is that this undulating pattern doesn’t usually hold longer than a few days.┬áBut this one isn’t going anywhere. Our work shows that this sort of pattern, which has been associated with many of the most extreme, persistent weather events in recent years, including the 2003 European heatwave, the 2010 Moscow wildfires, the 2011 Texas and Oklahoma drought, and the 2016 Alberta wildfires to name a few, is becoming more common because of human-caused climate change, and in particular, because of amplified Arctic warming.

It looks like 2019 is no exception to the longer-term trend. And we have already seen a number of instances of middle latitude extreme weather contributed to by the jet stream features Dr. Mann mentions above this year.

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Ominous Arctic Methane Spikes Continue — 2666 Parts Per Billion on October 26th

Imagine, for a moment, the darkened and newly liberated ocean surface waters of the Kara, Laptev, and East Siberian Seas of the early 21st Century Anthropocene Summer.

Where white, reflective ice existed before, now only dark blue heat-absorbing ocean water remains. During summer time, these newly ice-free waters absorb a far greater portion of the sun’s energy as it contacts the ocean surface. This higher heat absorption rate is enough to push local sea surface temperature anomalies into the range of 4-7 C above average.

Remnant Arctic sea surface heat

(Remnant extreme heat at Arctic Ocean surface on October 8, 2014. Extraordinary warmth in the range 0f 4-7 C above average is due to recent loss of summer sea ice in the Kara, Laptev, East Siberian and Beaufort Seas. Newly exposed dark surface waters absorb more of the sun’s rays which results in a highly visible temperature anomaly. Image source: Climate Reanalyzer. Image archived by: Arctic News.)

Some of the excess heat penetrates deep into the water column — telegraphing abnormal warmth to as far as 50 meters below the surface. The extra heat is enough to contact near-shore and shallow water deposits of frozen methane on the sea-bed. These deposits — weakened during the long warmth of the Holocene — are now delivered a dose of heat they haven’t experienced in hundreds of thousands or perhaps millions of years. Some of these deposits weaken, releasing a portion of their methane stores into the surrounding oceans which, in turn, disgorges a fraction of this load into the atmosphere.

The rate of release intensifies throughout summer. But during the Arctic Fall, it reaches a peak. Then, as sea ice begins to re-form over the surface waters, a kind of temperature inversion wedge develops. The surface cools and the ice solidifies — forming an insulating blanket, trapping heat. The insulating layer, in turn, pushes the anomalously hot mid level waters toward the bottom. This process delivers a final and powerful dose of heat to the Arctic Ocean bottom water and sea bed.

Methane release rates spike as the methane flooding up from the sea bed squeezes out through cracks in the newly forming ice or bubbles up through open waters just beyond the ice edge.

Observed Arctic Methane Over-Burden

During recent years, a troubling methane over-burden has been observed in the atmosphere above these regions during the months of September through November. Dr. Leonid Yurganov — a researcher at the University of Maryland — has been using the IASI sensor to record these events. Last year, he developed this map of September through November methane readings for the 2009-2012 period:

Arctic methane concentrations Sep-Nov 2009-2012

(Highest lower troposphere global atmospheric methane readings were found in the region of the East Siberian, Laptev and Kara seas during September through November of 2009 through 2012. Data provided by IASI. Image source: Dr. Leonid Yerganov via Arctic News.)

The readings above show near-surface averages over a three month period in the regions of highest release. Note that highest methane levels occur over coastal Siberia and in the above ocean zones of near-Russia Arctic Ocean waters.

These measurements have been ramping higher in recent years with near-surface readings in the range of 1950 to 2000 ppb now common for the months of September through November in the areas affected (for comparison, global surface averages are now in the range of 1840 ppm).

By themselves, these measurements are evidence of a substantial Arctic methane release. But further up in the troposphere — at the mid cloud level — even higher levels of methane have been recorded.

For as methane releases from the sea and land surface, it becomes trapped in the mid-cloud layer. There, a sandwich of cloud and moisture form a cap beneath which methane tends to concentrate. In this layer, readings can be quite a bit higher than surface measurements. Recent years have shown numerous instances where methane readings in the mid-cloud layer spiked above 2300 parts per billion.

Last year during September, the now annual plume of methane emitting from the Arctic Ocean pushed readings as high as 2571 parts per billion at this level of the atmosphere. It was a reading more than 700 parts per billion above the global surface average. A spike fueled by the anomalously high rates of methane emission from the Arctic surface waters and Siberian tundra during the Fall of 2013.

This year, despite extraordinarily spotty coverage due to cloud interference, the METOP sensor found Arctic methane concentrations in the range of 2666 parts per billion in the mid cloud layer. The spike occurred just this past Sunday and exceeds the September 2013 spike by 95 parts per billion — a level more than 800 parts per billion above current global surface averages.

Arctic methane spike 2666

(Arctic methane spikes to 2666 parts per billion in the mid-cloud layer on Sunday October 26. Image source: OSPO/METOP.)

In combination, observations of a rapidly warming Arctic Ocean and observations of Arctic methane readings between 6 and 60 percent above the global average in near surface regions and in the mid cloud layer are a clear signal that human-caused Arctic warming is forcing an ever-greater methane release. To a greater and greater extent, large carbon stores are being weakened and tapped by the various mechanisms that are an up-shot of human warming. The location of these large-scale releases, as observed in the satellite record, is confirmation of ground and ocean based observations conducted by Arctic researchers such as Dr. Semiletov and Shakhova. And the releases themselves may well be some validation of our more dire concerns.

This new spike is yet more evidence of a sizeable, anthropogenic-spurred, release that is impacting not only regional methane levels, but global levels as well. Whether this newly observed release is part of a slow global response to the initial human heat forcing — one that will take centuries to fully emerge — or is part of a much more rapid and dangerous response to an also very rapid human heat forcing is now unclear.

What is clear is that feedbacks to the human heat forcing are now starting to become plainly visible. That they are providing evidence of a stronger release from some sources on a yearly basis. A troubling amplifying feedback to the already dangerous and extraordinary human emission. One that should serve both as a warning and as a spur to reduce and eliminate human greenhouse gas emissions from all sources and to switch energy systems away from fossil fuels as swiftly as possible.

Links:

OSPO/METOP

Climate Reanalyzer

NOAA’s Office of Satellite Operations

Arctic News

Dr. Leonid Yurganov

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