Arctic News: temperature

Showing posts with label temperature. Show all posts

Thursday, June 18, 2020

2020 Siberian Heatwave continues

Very high temperatures hit Northern Europe and Eastern Siberia near the Arctic Ocean on June 18, 2020. This is a continuation of the heatwave that hit Siberia in May 2020.

The image below, from an earlier post, shows temperature anomalies that were forecast to be at the high end of the scale over Siberia on May 22, 2020, 06:00 UTC, i.e. 30°C or 54°F higher than 1979-2000. At the same time, cold temperatures were forecast for much of eastern Europe.

What enables such a strong heatwave to develop is that the Jet Stream is getting more wavy as the temperature difference between the North Pole and the Equator is narrowing, causing both hot air to move up into the Arctic (red arrow) and cold air to descend out of the Arctic (blue arrow).

On June 19, 2020, at 03:00 UTC, a temperature of 33.2°C or 91.8°F was recorded in Siberia near the Arctic Ocean (green circle).

The image below shows a temperature forecast of 33.5°C or 92.2°F in Siberia near the Arctic Ocean on June 20, 2020, at 03:00 UTC (green circle).

The image below is a forecast for June 23, 2020, showing how a distorted Jet Stream enables cold air to move down into Russia, while at the same time enabling hot air to move north over Scandinavia and Siberia, near the Arctic Ocean.

The image below is a forecast for June 25, 2020, showing the coast of Siberia near the Arctic Ocean getting hit by temperature anomalies at the top end of scale, i.e. 30°C or 54°F higher than 1979-2000.

The image on the right is an update, showing how wavy the Jet Stream turned out to be on June 25, 2020.

This facilitates hot air getting carried north over Western Europe, East Siberia and through the Bering Strait, while cold air is moving south over the European part of Russia. Blocking patterns that prolong such a situation go hand in hand with a more wavy Jet Stream.

Record High Temperature in Arctic

The image below shows that temperatures in Siberia were as high as 40°C or 104°F at 5 cm above the ground on June 21, 2020, at 3 pm, the Ventusky.com map shows.

This indicates how much the soil of what once was permafrost is heating up. At 2 m above ground level, i.e. the default height for air temperature measurements, it was 30°C or 86°F, as the image below shows. The location marked by the star is at 71°28' North latitude and 142°59' East longitude, and at and altitude of 13 m.

The day before, Verkhoyansk in Siberia reached a temperature of 38°C or 100.4°F on June 20, 2020, a record high for the Arctic. Verkhoyansk is located at 67°55′ North latitude.

Both locations are well north of the Arctic Circle that - at 66°30′ N - constitutes the southern limit of the area within which, for one day or more each year, the Sun does not set (about June 21) or rise (about December 21).

High Ocean Temperatures

The heatwave is heating up the sea surface of the East Siberian Arctic Shelf (ESAS), as illustrated by above image. The ESAS is quite shallow, making that heat can quickly reach the seafloor.

Additionally, the heatwave is heating up rivers that carry large amounts of hot water into the Arctic Ocean.

The image on the right shows sea surface temperatures in the Bering Strait as high as 18.9°C or 66.02°F on June 22, 2020.

The nullschool.net website shows that sea surface temperatures in the Bering Strait were as high as 16.1°C or 60.9°F on June 20, 2020, in the Bering Strait (in Norton Sound, Alaska), i.e. 15.1°C or 27.2°F hotter than 1981-2011.

In summary, the Arctic Ocean is heating up in a number of ways:

- Sea currents are moving hot water from the Pacific Ocean into the Arctic Ocean. Similarly, sea currents are moving hot water from the Atlantic Ocean into the Arctic Ocean.

- The Siberian heatwave is heating up the sea surface of the ESAS.

- The heatwave is heating up rivers that carry large amounts of hot water into the Arctic Ocean.

- Numerous feedbacks can speed up the temperature rise, such as changes to the jet stream that can prolong heatwaves and make them more intense.

The rising temperatures result in record low Arctic sea ice volume, as illustrated by the image on the right and as also discussed in an earlier post.

Heat threatens to destabilize methane hydrates

As discussed in earlier posts such as this one, this heat threatens to destabilize methane hydrates contained in sediments at the seafloor of the Arctic Ocean.

As the panel on the left shows, sea surface temperatures in the Bering Strait were as much as 15.1°C or 27.2°F hotter than 1981-2011 on June 20, 2020 (in Norton Sound, Alaska, at the green circle).

The bathymetry map in the right panel of above image shows how shallow seas in the Arctic Ocean can be. The water over the ESAS is quite shallow, making that the water can warm up very quickly during summer heat peaks and heat can reach the seafloor, which comes with the risk that heat will penetrate cracks in sediments at the seafloor. Melting of ice in such cracks can lead to abrupt destabilization of methane hydrates contained in sediments.

Large abrupt methane releases will quickly deplete the oxygen in shallow waters, making it harder for microbes to break down the methane, while methane rising through waters that are shallow can enter the atmosphere very quickly.

The situation is extremely dangerous, given the vast amounts of methane present in sediments in the ESAS, given the high global warming potential (GWP) of methane following release and given that over the Arctic there is very little hydroxyl in the air to break down the methane.

[ from earlier post ]

Ominously, the MetOp-1 satellite recorded a peak methane level of 2847 parts per billion on the afternoon of June 24, 2020, at 469 mb.

The next day, on the afternoon of June 25, 2020, MetOp-1 recorded a mean methane level of 1903 parts per billion at 293 mb. The 469 mb pressure level on above image corresponds with altitude of 6,041 m or 19,820 feet on the conversion table below. The 293 mb mean on the image below corresponds with a much higher altitude, i.e. 9,318 m or 30,570 feet on the conversion table below.

Methane reaching the Stratosphere

The MetOp satellites typically record the highest annual mean methane level in September. The image below, from an earlier post, shows that on the afternoon of September 30, 2019, the MetOp-1 satellite recorded the highest mean methane level, i.e. 1914 parts per billion, at 293 mb.

Above image shows that methane levels have risen most at higher altitude over the years. As discussed in an earlier post, methane eruptions from the Arctic Ocean can be missed by measuring stations that are located on land and that often take measurements at low altitude, thus missing the methane that rises in plumes from the Arctic Ocean. Since seafloor methane is rising in plumes, it hardly shows up on satellite images at lower altitude either, as the methane is very concentrated inside the area of the plume, while little or no increase in methane levels is taking place outside the plume. Since the plume will cover less than half the area of one pixel, such a plume doesn't show up well at low altitudes on satellite images.

Over the poles, the Troposphere doesn't reach the heights it does over the tropics. At higher altitudes, methane will follow the Tropopause, i.e. the methane will rise in altitude while moving closer to the Equator.

Methane rises from the Arctic Ocean concentrated in plumes, pushing away the aerosols and gases that slow down the rise of methane elsewhere, which enables methane erupting from the Arctic Ocean to rise straight up fast and reach the stratosphere.

The rise of methane at these high altitudes is very worrying. Once methane reaches the stratosphere, it can remain there for a long time. The IPCC in 2013 (AR5) gave methane a lifetime of 12.4 years. The IPCC in 2001 (TAR) gave stratospheric methane a lifetime of 120 years, adding that less than 7% of methane did reach the stratosphere.

Further Feedbacks

Furthermore, the Siberian heatwave is also threatening to trigger forest fires that can cause huge amounts of emissions, including black carbon that can settle on the snow and ice cover, further speeding up its demise and causing albedo changes that result in a lot more heat getting absorbed in the Arctic, instead of getting reflected back into space as was previously the case. This is illustrated by the image below showing forest fires in East Siberia on June 19, 2020.

Finally, more intense forest fires threaten to cause organic carbon compounds to enter the stratosphere and damage the ozone layer, as discussed in an earlier post.

The situation is dire and calls for immediate, comprehensive and effective action as described in the Climate Plan.

Links

• Climate Plan
https://arctic-news.blogspot.com/p/climateplan.html

• Very High Greenhouse Gas Levels
https://arctic-news.blogspot.com/2020/05/very-high-greenhouse-gas-levels.html

• April 2020 temperatures very high
https://arctic-news.blogspot.com/2020/05/april-2020-temperatures-very-high.html

• Methane Erupting From Arctic Ocean Seafloor
https://arctic-news.blogspot.com/2017/03/methane-erupting-from-arctic-ocean-seafloor.html

• When Will We Die?
https://arctic-news.blogspot.com/2019/06/when-will-we-die.html

• Could Humans Go Extinct Within Years?
https://arctic-news.blogspot.com/2020/01/could-humans-go-extinct-within-years.html

• Fast Path to Extinction
https://arctic-news.blogspot.com/2020/06/fast-path-to-extinction.html

• Arctic records its hottest temperature ever
https://www.cbsnews.com/news/arctic-records-its-hottest-temperature-ever-2020-06-20/

Sunday, June 14, 2020

Fast Path to Extinction

[ click on images enlarge ]

May 2020 was the hottest May on record, the third monthly record in the year to date, even though there was no El Niño in 2020 (yet). An El Niño event later in 2020, combined with further warming elements, such as loss of the aerosol masking effect due to COVID-19 lockdowns, could trigger a huge temperature rise, as the red trend illustrates. The year 2020 looks set or close to become the hottest on record, as illustrated by the blue trend that points at a continuing rise reaching 3°C by 2026, i.e. likely driving humans into extinction.

The May 2020 ocean temperature anomaly on the Northern Hemisphere was 0.94°C or 1.67°F higher than the 20th century average, the highest May anomaly on record.

The latent heat tipping point threatens to be crossed as ocean temperature anomalies on the Northern Hemisphere reach 1°C above the 20th century average, in turn threatening the methane hydrates tipping point to get crossed, i.e. as ocean temperature anomalies on the Northern Hemisphere become higher than 1.35°C above the 20th century average.

Arctic sea ice is getting very thin and, at this time of year, it is melting rapidly from below, due to the rising temperature of the Arctic Ocean. The sea ice underneath the surface of the Arctic Ocean is disappearing rapidly, due to the influx of warm and salty water from the Atlantic Ocean and the Pacific Ocean.

Sea surface temperature anomalies from the 20th century on the Northern Hemisphere in °C.
Yellow circles are anomalies for the month May, red circles are anomalies for other months.

An earlier analysis indicates that the latent heat tipping point threatens to get crossed as ocean temperature anomalies on the Northern Hemisphere reach 1°C above the 20th century average. As above image indicates, the tipping point was briefly crossed before, but this year it looks set to get crossed irreversibly.

At that point, there will be little or no Arctic sea ice left underneath the sea surface all year long, so the sea ice has lost most of its capacity to act as a buffer to consume further heat arriving from the Atlantic Ocean and the Pacific Ocean.

Arctic sea ice volume has been at record low for almost all of 2020 to date, while 2019 volume was at a record low from October, making that volume has been at record low for almost 8 months straight.

Crossing the latent heat tipping point means that huge amounts of incoming heat will get absorbed by the Arctic Ocean, instead of getting consumed by the melting of sea ice, as was previously the case.

As long as there is sea ice in the water, this sea ice will keep absorbing heat as it melts, so the temperature will not rise at the sea surface.

There is ever less sea ice left underneath the surface to absorb ocean heat, and the amount of energy that used to be absorbed by melting ice is as much as it takes to heat an equivalent mass of water from zero to 80°C.

Meanwhile, global heating continues and more than 90% of global heating is going into oceans.

As discussed in an earlier post, the loss of subsurface sea ice is only one of ten tipping points hitting the Arctic. As the temperature of the oceans keeps rising, more heat will reach sediments at the seafloor of the Arctic Ocean that contain vast amounts of methane, as discussed in this page and this post. The danger is that this heat will destabilize the ice and the hydrates, resulting in huge releases of methane. The methane hydrates tipping point threatens to get crossed as ocean temperature anomalies on the Northern Hemisphere become higher than 1.35°C above the 20th century average, which threatens to occur early next year.

The danger is illustrated by the image below, posted in February 2019 and showing a potential rise of 18°C or 32.4°F from 1750 by the year 2026.

Indeed, a rise of 18°C could eventuate by 2026, as illustrated by the image below and as discussed in an earlier post.

Friday, May 15, 2020

April 2020 temperatures very high

Temperatures in April 2020 were very high. The image below shows very high temperature anomalies over the Arctic.

The combination image below shows in the left panel the same very high anomalies, compared to 1951-19180. Comparisons with earlier periods can be complicated, due to a lack of data over polar regions, as illustrated by the image in the right panel that shows grey colors over polar regions, indicating missing data.

Temperatures in polar regions have risen strongly, so leaving out the rise in polar regions would downplay the global temperature rise since pre-industrial. A recent analysis of the temperature rise therefore uses an adjustment of 0.1°C to compensate for missing data.

Ocean heat on the Northern Hemisphere is driving up temperatures in the Arctic.

The image below shows that the April ocean temperature anomaly in the Gulf of Mexico in 2020 was 1.71°C or 3.08°F higher than the 1910-2000 average, and the highest on record.

Temperatures in the Gulf of Mexico were already very high in March 2020, as illustrated by the image on the right, from an earlier post.

There are three reasons why this is very worrying:

1. The Gulf Stream carries ever hotter water along the path of the Gulf Stream toward the Arctic Ocean, thus speeding up the temperature rise of the Arctic Ocean.

2. As the Gulf Stream slows down, due to increased meltwater, more heat is accumulating along the path toward the Arctic Ocean, threatening to invade the Arctic Ocean in abrupt strong bursts, powered by stronger winds over the North Atlantic, as discussed in earlier posts such as this one.

3. There's also the danger that a freshwater lid is extending at the surface of the North Atlantic that threatens to cause more ocean heat to move underneath the sea surface toward the Arctic Ocean, as discussed in earlier posts, such as at this one and this one.

As the image below shows, the April ocean temperature anomaly on the Northern Hemisphere in 2020 was 0.97°C or 1.75°F higher than the 20th century average, and the highest on record.

Arctic sea ice is getting very thin and, at this time of year, it is melting rapidly from below, due to rising temperature of the Arctic Ocean.

Arctic sea ice volume has been at record low since the start of 2020, while 2019 volume was at a record low from October, making that volume has now been at record low for almost 8 months straight.

An earlier analysis indicates that there is a tipping point at 1°C at which the sea ice underneath the surface of the Arctic Ocean disappears, which means that there will be little or no buffer left to consume the influx of ever warmer and salty water from the Atlantic Ocean and Pacific Ocean.

As long as there is sea ice in the water, this sea ice will keep absorbing heat as it melts, so the temperature will not rise at the sea surface.

But there is ever less sea ice volume left to absorb ocean heat, and the amount of energy absorbed by melting ice is as much as it takes to heat an equivalent mass of water from zero to 80°C.

Meanwhile, global heating continues and more than 90% of global heating is going into oceans.

As the temperature of the oceans keeps rising, more heat will reach sediments at the seafloor of the Arctic Ocean that contain vast amounts of methane, as discussed in this page and this post. The danger is that this heat will destabilize the ice and the hydrates, resulting in huge releases of methane.

Friday, March 13, 2020

2°C crossed

It's time to stop denying how precarious the situation is.

Remember the Paris Agreement? In 2015, politicians pledged to hold the global temperature rise to well below 2°C above pre-industrial levels and pledged they would try and limit the temperature rise to 1.5°C above pre-industrial levels. Well, an analysis by Sam Carana shows that it was already more than 1.5°C above pre-industrial when the Paris Agreement was reached.

View details of Sam Carana's analysis

In Sam Carana's analysis, the year 1750 is used as the baseline for pre-industrial. The analysis shows that we meanwhile have also crossed the 2°C threshold (in February 2020) and that the temperature rise looks set to rapidly drive humans and eventually most if not all species on Earth into extinction.

Yet, our politicians refuse to act!

Accelerating temperature rise

Indeed, there are indications that the recent rise is part of a trend that points at even higher temperatures in the near future, as also discussed at this analysis page. Polynomial trends can highlight such acceleration better than linear trends. The 1970-2030 polynomial trend in the image below is calculated over the period from 1880 through to February 2020. The trend points at 3°C getting crossed in 2026.

In above image, the January 2020 and February 2020 anomalies are above the trend. This indicates that the situation might be even worse.

A polynomial trend calculated over a shorter period can highlight short-term variation such as associated with El Niño events and can highlight feedbacks that might otherwise be overlooked. The 2010-2022 trend in the image below is calculated with 2009-Feb.2020 data. The trend indicates that 2°C was crossed in February 2020, and looks set to keep rising and cross 3°C in 2021, more specifically in January next year, which is less than a year away.

Such a steep rise is in line with unfolding developments that are causing the aerosol masking effect to fall away, such as a decrease in industrial activity due to COVID-19 fears. The image below shows a potential rise of 18°C or 32.4°F from 1750 by the year 2026.

Above image was posted more than a year ago and illustrates that much of this potentially huge temperature rise over the next few years could eventuate as a result of a reduction in the cooling now provided by sulfates. In other words, a steep temperature rise could result from a decline in industrial activity that is caused by fears about the spread of a contagious virus, as also discussed in the video at an earlier post.

The situation is dire and calls for immediate, comprehensive and effective action, as described in the Climate Plan.

Links

• Analysis: Crossing the Paris Agreement thresholds
https://arctic-news.blogspot.com/p/crossing.html

• A rise of 18°C or 32.4°F by 2026?
https://arctic-news.blogspot.com/2019/02/a-rise-of-18c-or-324f-by-2026.html

• How much warming have humans caused?
https://arctic-news.blogspot.com/2016/05/how-much-warming-have-humans-caused.html

• Arctic Ocean January 2020
https://arctic-news.blogspot.com/2020/02/arctic-ocean-february-2020.html

• Climate Plan
https://arctic-news.blogspot.com/p/climateplan.html

In the video below, Guy McPherson discusses the situation.

Wednesday, February 19, 2020

Arctic Ocean February 2020

On February 20, 2020, 09Z, surface temperature anomalies reached both ends of the scale over North America, while the Arctic was 3.7°C or 6.7°F warmer than in 1979-2000. On that day, the average 2 m temperature anomaly for the Arctic was 3.5°C or 6.3°F.

These high temperature anomalies at 2 meters in the left panel go hand in hand with the wind patterns at 250 hPa (jet stream) as shown in the center panel and the wind patterns at 10 meters shown in the right panel. Closer to sea level, circular winds around low pressure areas bring warm air into the Arctic, from Russia and from the Pacific Ocean.

Above image shows winds at 250 hPa (jet stream) with speeds as high as 317 km/h or 197 mph (green circle) in the left panel, while the right panel shows circular winds at 850 hPa reaching speeds as high as 176 km/h or 109 mph (green circle).

These wind patterns have caused much warm air to enter the Arctic, while relatively little cold air has moved out of the Arctic. Furthermore, stronger winds cool the sea surface. As a result, Arctic sea ice extent on February 24, 2020, was 14.1 million km², slightly more than the 2010s average of 14 million km².

Arctic sea ice, however, is very thin. Stronger winds can also accelerate the speed at which ever warmer water is flowing into the Arctic Ocean from the Atlantic Ocean and from the Pacific Ocean, as discussed in a previous post. The overall result is that sea ice volume is at a record low for the time of the year.

This is further illustrated by the sea ice thickness (in meters) comparison below between February 28, 2015 and February 28, 2020, i.e. forecasts for February 28, run on February 27.

Rise in greenhouse gas levels is accelerating

Temperatures are rising at ever faster speed as the rise in greenhouse gas levels in the atmosphere is accelerating. As illustrated by the image below, the daily average CO₂ level at Mauna Loa, Hawaii, was 416.08 ppm on February 10, 2020, higher than it has been for millions of years. Since the annual peak is typically reached in May, even higher levels can be expected soon.

From the way emissions are rising now, it looks like we could soon reach even higher CO₂e forcing than during the Paleocene–Eocene Thermal Maximum (PETM) mass extinction event, some 55.5 million years ago, as discussed in a previous post. Very worrying also is the recent rise in methane levels recorded at Barrow, Alaska, as illustrated by the image below.

The buffer is gone

As the sea ice is getting thinner, there is little or no buffer left to consume the influx of ever warmer and salty water from the Atlantic Ocean and Pacific Ocean. As illustrated by the image below, there is a tipping point at 1°C above the 20th century average, i.e. there are indications that a rise of 1°C will result in most of the sea ice underneath the surface to disappear.

[ from earlier post ]

As long as there is sea ice in the water, this sea ice will keep absorbing heat as it melts, so the temperature will not rise at the sea surface. But there is ever less sea ice volume left to absorb ocean heat, and the amount of energy absorbed by melting ice is as much as it takes to heat an equivalent mass of water from zero to 80°C.

Meanwhile, temperatures keep rising globally and more than 90% of global warming is going into oceans.

As the temperature of the oceans keeps rising, the danger increases that heat will reach the seafloor of the Arctic Ocean and will destabilize hydrates contained in sediments at the seafloor, resulting in huge releases of methane.

Are humans functionally extinct?

For more background as to when temperatures
could cross 2°C, see also this discussion on trends

Species can be regarded to be ‘functionally extinct’ when their numbers have declined below levels needed for them to reproduce healthy offspring. This can occur due to causes such as loss of habitat and disappearance of other species that they depend on.

Species can also be declared to be ‘functionally extinct’ when they are threatened to be wiped out by a catastrophe that appears to be both imminent and inescapable, which would cause their numbers to dwindle below a critical threshold required for survival of the species.

Rising temperatures now threaten most, if not all, species to go extinct in a matter of years. In 2020, the global temperature rise could cross the critical guardrail of 2°C above preindustrial that politicians at the Paris Agreement promised would not be crossed. In fact, they pledged to take efforts to avoid a 1.5°C rise. Their failure to do so constitutes a de facto declaration that humans are now functionally extinct and that the looming temperature rise will drive most, if not all species on Earth into extinction.

See also the 2015 post: WARNING -

Planetary Omnicide between 2023 and 2031

Dire Situation

The situation is dire, in many respects. Current laws punish people for the most trivial things, while leaving the largest crime one can imagine unpunished: planetary omnicide!

In the video below, Guy McPherson warns that a rapid decline in industrial activity could result in an abrupt rise in temperature of 1°C, as much of the aerosol masking effect falls away.

The dire situation calls for immediate, comprehensive and effective action, as described in the Climate Plan.

P.S. Don't forget to vote!

One of the most important things one can do to change things is to vote, e.g. in the U.S., vote for Bernie Sanders and the Green New Deal!

Fossil fuel and control over its supply is behind much of the conflict, violence and pollution that has infested the world for more than a century.

Instead of using fossil fuel, the world must rapidly transition to the use of wind turbines, geothermal power, solar power, wave power, and similar clean and renewable ways to generate energy.

The transition to clean, renewable energy removes much cause for conflict, since it is available locally around the world and its use in one place doesn't exclude use of clean, renewable energy elsewhere.

The transition to clean, renewable energy will provide greater energy security and reliability, besides its numerous further benefits, e.g. it will make more land and water available for growing food and it will give us more jobs, better health, and a cleaner environment. And, because it's more economic, the transition to clean, renewable energy will pay for itself as we go.

Bernie Sanders calls for a rapid transition to clean, renewable energy as part of the Green New Deal.

Please share this message, vote for Bernie Sanders and support the GND!