Showing posts with label jet stream. Show all posts
Showing posts with label jet stream. Show all posts

Friday, February 2, 2024

Blue Ocean Event 2024?

How likely is an Arctic Blue Ocean Event (BOE) to occur in 2024 or even a Double BOE? The image below is alarming. 


The highest daily sea surface temperatures on record (going back to 1981) were reached in February 2024, even higher than the peaks in 2023. Even higher temperatures may be reached over soon, in March 2024 and April 2024.

As the above image shows, the highest temperatures for the year are typically reached in March. This was the case for the previous years on record, except for 2023 when the current El Niño started to emerge and when the highest peak for the year occurred in August. According to NOAA, the majority of models indicate that this El Niño will persist through March-May 2024. 

Antarctic sea ice extent typically reaches an annual minimum end February, while Arctic sea ice extent typically reaches an annual minimum in September, after a steep decline resulting from more sunlight reaching higher latitudes North and ocean heat reaching a second peak in August.   

Ominously, daily surface air temperatures in the Southern Hemisphere exceeded 17°C recently, something that never happened before in the record going back to 1981. Antarctic sea ice extent typically reaches an annual minimum end February. Loss of sea ice acts as a self-reinforcing feedback loop, accelerating the temperature rise. The daily surface air temperature in the Southern Hemisphere was 17.005°C on Feb 1, 2024, following a peak of 17.01°C on Jan 31, 2024.


Higher temperatures can cause sea ice to melt, even out of season

As illustrated by the image below, adapted from Pidwirny, sunlight does not reach the North Pole until the March Equinox. From that time on, insolation rises steeply. Around the June Solstice, more sunlight reaches the North Pole than anywhere else on Earth. In the image below, insolation is calculated taking into account the combined effects of angle of incidence and day length duration. 

The conclusion is that ocean heat is the main reason why melting of Arctic sea ice can occur early in the year. More specifically, the narrowing of the temperature difference between the Arctic and the Tropics can at times cause strong wind to be present along the path of the Gulf Stream. Rising ocean heat combined with strong wind can cause heat to move abruptly toward the Arctic Ocean, causing sea ice to fall in extent. 

Such an event is illustrated by the image below, adapted from NSIDC. The image shows a drop in sea ice extent at the end of January 2024 (blue), a time of year when Arctic sea ice is still expected to increase in extent and to keep increasing in extent for some time to come (grey). In this case, strong wind may have caused a huge amount of ocean heat that is present in the North Atlantic to move abruptly toward the Arctic Ocean, as discussed in an earlier post

For the time of year, Arctic sea ice extent is currently still extensive, compared to earlier years, which is a reflection of more water vapor in the atmosphere and more precipitation. While sea ice extent is relatively large, sea ice volume is among the lowest of all years on record for the time of year, as illustrated by the image below. 

This indicates that Arctic sea ice is very thin. Ominously, the image below indicates that there is a huge area near the North Pole with very thin sea ice. 


Furthermore, much of the thicker sea ice is located off the east coast of Greenland, which means that this sea ice is likely to melt away quickly as more sunlight starts reaching the Northern Hemisphere and temperatures rise in line with seasonal changes (see the insolation image further above).


The North Atlantic sea surface temperature was 20.4°C on February 15, 2024, i.e. 0.6°C higher than on February 15, 2023.

High North Atlantic sea surface temperatures spell bad news for the Arctic, as much ocean heat gets pushed toward the Arctic from the North Atlantic. 

North Atlantic sea surface temperatures are just starting to heat up from their annual minimum and can be expected to rise strongly, in line with seasonal changes. 

[ click on images to enlarge ]
Ominously, a peak temperature of 25.4°C was reached on Aug.31, 2023, much higher than the peak in any of the preceding years dating back to 1981.

During the six months between the September Equinox and the March Equinox (see image further above), no sunlight is reaching the North Pole. 

Nonetheless, temperature anomalies in the Arctic are already extremely high, due to ocean heat that has entered the Arctic Ocean from the North Atlantic, as illustrated by the two maps on the right and the two maps on the right further below.

Northern Hemisphere Sea Surface Temperature Anomalies were as much as 12.6°C or 22.7°F higher than 1981-2011 on February 15, 2024, locarion marked by the green circle on the image below.


Feedbacks 

Slowing down of AMOC and cooling due to heavier melting of Greenland's ice is causing less ocean heat to reach the Arctic Ocean, while a huge amount of ocean heat is accumulating in the North Atlantic, as it did in 2023. A large part of this heat in the North Atlantic can also be present underneath the sea surface.

These developments occur at the same time as ocean stratification increases (as temperatures rise, see above images), as more freshwater enters the ocean (as a result of more meltwater and of runoff from land and from rivers), and as more evaporation takes place and more rain falls further down the path of the Gulf Stream, all of which can contribute to formation and growth of a cold, freshwater lid at the surface of the North Atlantic.

cold freshwater lid on North Atlantic ]

Furthermore, storms can get stronger as temperatures rise and as changes take place to the Jet Stream. Strong wind can temporarily speed up currents that carry huge amounts of ocean heat with them toward the Arctic Ocean, as discussed in earlier posts such as this one. Much of the ocean heat in the North Atlantic can therefore be pushed abruptly underneath this freshwater lid and flow into the Arctic Ocean. The image below shows that the Jet Stream reached speeds as high as 455 km/h or 283 mph north of Washington on February 18, 2024 03:00 UTC, with Instantaneous Wind Power Density as high as 387.5 kW/m².


The image below shows wind speed at 250 hPa on a background of sea surface temperature anomalies versus 1981-2011. 


The danger is that, due to strong wind along the path of the Gulf Stream, huge amounts of ocean heat will abruptly get pushed into the Arctic Ocean, with the influx of ocean heat causing destabilization of hydrates contained in sediments at the seafloor of the Arctic Ocean, resulting in eruptions of huge amounts of methane.

Changes to the Jet Stream and ocean heat accumulating in the North Atlantic Ocean are both consequences of the overall temperature rise. A distorted Jet Stream can cause an abrupt influx of ocean heat into the Arctic Ocean.

Such additional ocean heat, combined with a steep rise in insolation hitting the Arctic in April and May, may suffice to cause a Blue Ocean Event (BOE) to occur in 2024.

[ click on images to enlarge ]
The far North has the highest temperature anomalies, they can as high as 7.04°C, as the image on the right shows.

A BOE occurs when virtually all sea ice disappears and less than 1 million km² of sea ice remains. As the sea ice disappears, the surface color changes from white (sea ice) to blue (ocean) resulting in far more sunlight getting absorbed by the Arctic Ocean, instead of getting reflected back into space as was previously the case.

Albedo change constitutes a huge self-reinforcing feedback loop, i.e. the more sea ice disappears, the more sunlight gets absorbed by the Arctic Ocean, further accelerating sea ice melting. 

[ Albedo change, from the Albedo page ]

Next to the albedo loss, there is loss of the latent heat buffer constituted by the sea ice. Latent heat is energy associated with a phase change, such as the energy consumed when solid ice turns into water (i.e. melts). During a phase change, the temperature remains constant. Sea ice acts as a buffer that absorbs heat, while keeping the temperature at about zero degrees Celsius. As long as there is sea ice in the water, this sea ice will keep absorbing heat, so the temperature doesn't rise at the sea surface.

The amount of energy absorbed by melting ice is as much as it takes to heat up an equivalent mass of water from zero to 80°C. 

Without the buffer constituted by thicker sea ice, an influx of ocean heat could destabilize hydrates contained in sediments at the seafloor of the Arctic Ocean, resulting in eruptions of huge amounts of methane.

[ click on images to enlarge ]
The above image illustrates these tipping points and Northern Hemisphere Ocean Temperature anomalies vs 1901-2000, created with NOAA data. Trends and tipping point estimates are added. The magenta trend is based on Jan.1880-Jan.2024 data and warns that the Seafloor Methane Tipping Point may be crossed in 2025. The red trend is based on Jan.2010-Jan.2024 data and better reflects variables such as El Niño, and it warns that the Seafloor Methane Tipping Point may be crossed in 2024. 


The above image, adapted from tropicaltidbits.com, shows a forecast for November 2024 of the 2-meter temperature anomaly in degrees Celsius, based on 1984-2009 model climatology. The anomalies are forecast to be very high for the Arctic Ocean.

Many additional feedbacks are active, such as changes to the Jet Stream and slowing down of AMOC, and they could speed up the crossing of such tipping points, as also discussed at the feedbacks page. The danger is that a cascade of events will unfold like a domino effect, leading to extinction of most species, including humans, as the image below warns. 

[ from earlier post - click on images to enlarge ]

Greenhouse gases rising

Meanwhile, concentrations of greenhouse gases keeps rising, as illustrated by the image below. 

The average daily carbon dioxide (CO₂) at Mauna Loa, Hawaii, was 426.21 ppm (parts per million) on February 4, 2024. The weekly average was 425.83 ppm. 

Critical is the rate of change, in particular the rapid rise in temperatures and greenhouse gas concentrations. To find higher CO₂ concentrations, one has to go back millions of years. 


A recent study concludes that: 
- A doubling of CO₂ is predicted to warm the planet a whopping 5°C to 8°C.
- The last time atmospheric CO₂ consistently reached today’s human-driven levels of 420 ppm was 14 million years ago.
- The hottest period was about 50 million years ago, when temperatures were as much as 12°C higher than today.

Climate Emergency Declaration

The situation is dire and the precautionary principle calls for rapid, comprehensive and effective action to reduce the damage and to improve the situation, as described in this 2022 post, where needed in combination with a Climate Emergency Declaration, as discussed at this group.



Links

• Blue Ocean Event
https://arctic-news.blogspot.com/p/blue-ocean-event.html

• Climate Reanalyzer - Daily Sea Surface Temperature, World (60°S-60°N)
https://climatereanalyzer.org/clim/sst_daily

• Pidwirny, M. "Earth-Sun Relationships and Insolation". Fundamentals of Physical Geography, 2nd Edition (2006)
http://www.physicalgeography.net/fundamentals/6i.html

• NOAA - ENSO: Recent Evolution, Current Status and Predictions
https://www.cpc.ncep.noaa.gov/products/analysis_monitoring/lanina/enso_evolution-status-fcsts-web.pdf 

• NSIDC - Arctic sea ice extent
https://nsidc.org/arcticseaicenews/charctic-interactive-sea-ice-graph

• Polar Portal - Sea Ice Thickness and Volume
http://polarportal.dk/en/sea-ice-and-icebergs/sea-ice-thickness-and-volume

• University of Bremen - Arctic sea ice

• Scripps Institution of Oceanography at UC San Diego.

• Toward a Cenozoic history of atmospheric CO₂ - by The Cenozoic CO₂ Proxy Integration Project (CenCO₂PIP) Consortium






Sunday, January 7, 2024

2024 looks to be worse than 2023


The year 2024 looks to be worse than the year 2023. The above chart shows sea surface temperatures that were extremely high in 2023 followed by a steep rise in 2024, crossing 21°C in early January 2024.

The chart below illustrates this further, showing the daily sea surface temperature anomaly using 1 Sep. 1981 to 31 Dec. 2023 data versus the 1982-2011 mean for latitudes between 60°S and 60°N.

The importance of sea surface temperatures

Slowing down of the Atlantic meridional overturning circulation (AMOC) results in less ocean heat reaching the Arctic Ocean and, instead, a huge amount of ocean heat has been accumulating in the North Atlantic in 2023.

Much of the heat in the North Atlantic could soon be pushed abruptly into the Arctic Ocean, as storms can temporarily speed up currents strongly, carrying huge amounts of ocean heat with them into the Arctic Ocean.


The mechanism behind this has been described often in earlier posts and this page. Meltwater and rain can cause a freshwater lid to form and grow at the surface of the North Atlantic and this, in combination with greater stratification as ocean temperatures rise (above image), can enable more ocean heat to increasingly travel underneath this lid from the North Atlantic into the Arctic Ocean, and especially so at times when Jet Stream changes are causing storms that speed up ocean currents along this path.


The danger is illustrated by the above image, showing a forecast for January 11, 2024, with the Jet Stream moving almost vertically over the North Atlantic to the north. The image below shows heat over the North Atlantic, with temperatures reaching as high as 10.5°C or 50.8°F over Greenland (at the green circle) at 1000 hPa on January 10, 2024, 07:00 UTC.


The image below shows 2 meter temperature anomalies on January 11, 2024. 


Very high sea surface temperature anomalies can occur in the path of the Gulf Stream, as illustrated by the image below showing high sea surface temperatures on January 3, 2024, as high as 11.7°C (21°F) at the green circle, over the counterpart of the Gulf Stream in the Pacific, off the coast of Japan. 


Earlier posts have warned about this, such as this post and this video, almost seven years ago. This could cause events during which much ocean heat moves abruptly into the Arctic Ocean, resulting in seafloor methane releases, overwhelming of the latent heat buffer and causing sea ice loss (and thus albedo loss), as well as loss of lower clouds (thus causing further albedo loss), while open oceans are also less efficient than sea ice when it comes to emitting in the far-infrared region of the spectrum and while an ice-free Arctic Ocean will also release more ocean heat into the atmosphere.


Arctic sea ice volume is very low for the time of year, as illustrated by the above image.

A large part of the thicker sea ice is located off Greenland's East Coast, as illustrated by the above image. Much of the sea ice will therefore rapidly disappear as the water heats up in 2024.


The above image, adapted from tropicaltidbits.com, shows a forecast for October 2024 of the 2-meter temperature anomaly in degrees Celsius, based on 1984-2009 model climatology. The anomalies are forecast to be very high for the Arctic Ocean.

In the video below, Jennifer Francis is interviewed by Nick Breeze. 



The importance of daily air temperatures, Northern Hemisphere


[ from the Extinction page ]
The situation is dire. The Northern Hemisphere is getting hit hardest by high temperatures, as illustrated by the above image. 

The Northern Hemisphere is home to some 90% of the world population of more than 8 billion people, with much of them living in South-East Asia.

As more people become aware of the dire situation, widespread panic may set in.

People may stop showing up for work, resulting in a rapid loss of the aerosol masking effect, as industries that now co-emit cooling aerosols (such as sulfates) grind to a halt.

Many people may start to collect and burn more wood, resulting in an increase in emissions that speed up the temperature rise.

As temperatures rise, more fires could also break out in forests, peatlands and urban areas including landfills and waste dumps, further contributing to emissions that speed up the temperature rise.

The image on the right illustrates how fast a huge temperature could unfold.

As a somewhat sobering footnote, humans will likely go extinct with a 3°C rise and most life on Earth will disappear with a 5°C rise, as discussed in an earlier post.


Climate Emergency Declaration

The situation is dire and the precautionary principle calls for rapid, comprehensive and effective action to reduce the damage and to improve the situation, as described in this 2022 post, where needed in combination with a Climate Emergency Declaration, as discussed at this group.



Links






Saturday, August 12, 2023

Return of the Blob?


The Blob is a large mass of water with relatively high heat content, floating at the surface and underneath the surface of the North Pacific Ocean. The Blob did appear several times before, including in 2016, which was a strong El Niño year. The above image shows high sea surface temperature anomalies in the North Pacific on August 10, 2023, raising the question of whether this constitutes a return of the Blob.

As temperatures rise, the Arctic is heating more rapidly than the rest of the world. The narrowing temperature difference between the Arctic and the Tropics is weakening the speed at which the jet stream circumnavigates Earth and this is making the jet stream more wavy.

In a 2012 study, Jennifer Francis et al. warned that this makes atmospheric blocking events in the Northern Hemisphere more likely, aggravating extreme weather events related to stagnant weather conditions, such as droughts, flooding and heatwaves. The Blob appears to be the marine version of a heatwave on land.

The image below shows that, on August 12, 2023, sea surface temperatures were as much as 7°C or 12.6°F higher than 1981-2011 in the Pacific Ocean (at the green circle, follow the arrow). A strongly deformed Jet Stream shows many circular wind patterns, prolonging, intensifying and increasing the occurrence of extreme weather events such as accumulation of heat during heatwaves. 


Is the Kuroshio Current slowing down?

The Kuroshio Current is an ocean current that carries heat along its path in the North Pacific, similar to the Gulf Stream in the North Atlantic Ocean. Is the Kuroshio Current slowing down as temperatures rise and is such slowing down causing hot water to accumulate in the western part of the North Pacific, leading to a return of a new Blob moving across the North Pacific toward the coast of North America?

The North Atlantic has been experiencing record high sea surface temperatures recently. A return of the Blob increases the danger of more heat reaching sediments at the seafloor of the Arctic Ocean.

[ 2022 animation ]
The animation on the right shows how remnants of Typhoon Merbok were forecast to enter the Arctic Ocean through the Bering Strait from September 17 to 19, 2022.

Studies, some of them dating back more than two decades, show that over the shallow East Siberian Arctic Shelf (ESAS) winds at times can mix the water column from the top to the bottom. A 2005 study of the ESAS led by Igor Semiletov recorded water temperatures at the seafloor, in September 2000, of 4.7°C at 20m depth at one location and 2.11°C at 41m depth at another location, with salinity levels of 29.7‰ and of 31.7‰, respectively.

A deformed Jet Stream, in combination with a cyclone, could result in strong winds abruptly pushing a huge amount of heat through the Bering Strait into the Arctic Ocean. This could cause methane hydrates to destabilize and huge amounts of methane to erupt from the seafloor and enter the atmosphere.

Conclusion

The situation is dire and is getting more dire every day, which calls for a Climate Emergency Declaration and implementation of comprehensive and effective action, as described in the Climate Plan with an update at Transforming Society.


Links

• The Blob

• Evidence Linking Arctic Amplification to Extreme Weather in Mid-Latitudes, by Jennifer Francis et al. (2012)
https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2012GL051000 

• The Kuroshio current
https://en.wikipedia.org/wiki/Kuroshio_Current

• Record high North Atlantic sea surface temperature

• Remnants of Typhoon Merbok forecast to enter the Arctic Ocean through the Bering Strait from September 17 to 19, 2022.

• The East Siberian Sea as a transition zone between Pacific-derived waters and Arctic shelf waters - by Igor Semiletov et al. (2005)
https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2005GL022490

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

• Transforming Society
https://arctic-news.blogspot.com/2022/10/transforming-society.html

• Climate Emergency Declaration
https://arctic-news.blogspot.com/p/climate-emergency-declaration.html



Thursday, July 27, 2023

Record high North Atlantic sea surface temperature

On July 25, 2023, the North Atlantic sea surface reached a record high temperature of 24.9°C. The previous record was in early September 2022, when the temperature peaked at 24.89°C, according to NOAA scientist Xungang Yin and as illustrated by the image below. 

In previous years, a La Niña was suppressing temperatures, whereas El Niño is now pushing up temperatures. Arctic sea ice typically reaches its minimum extent about half September. We are facing huge sea ice loss over the coming weeks.

Temperatures are very high (and rising) and the following eight points contribute to this rise:

1. Emissions are high and greenhouse gas levels keep rising, and this is increasing Earth's Energy Imbalance. Oceans take up 89% of the extra heat.

2. El Niño is pushing up temperatures, whereas in previous years La Niña was suppressing temperatures. Moving from the bottom of a La Niña to the peak of a strong El Niño could make a difference of more than half a degree Celsius, as discussed in an earlier post.

In February 2016, when there was a strong El Niño, the temperature on land was 3.28°C (5.904°F) hotter than 1880-1896, and 3.68°C (6.624°F) hotter than February 1880 on land. Note that 1880-1896 is not pre-industrial, the difference will be even larger when using a genuinely pre-industrial base.

The above image, from an earlier post discussing extreme heat stress, adds a poignant punchline: Looking at global averages over long periods is a diversion, peak temperature rise is the killer!

[ click on images to enlarge ]
3. Sunspots in June 2023 were more than twice as high in number as predicted, as illustrated by the image on the right, from an earlier post and adapted from NOAA.

If this trend continues, the rise in sunspots forcing from May 2020 to July 2025 may well make a global temperature difference of more than 0.25°C, a recent analysis found.

4. A submarine volcano eruption near Tonga in January 2022 did add a huge amount of water vapor to the atmosphere, as discussed in an earlier post and also at facebook.

Since water vapor is a potent greenhouse gas, this further contributes to speeding up the temperature rise. A 2023 study calculates that the eruption will have a warming effect of 0.12 Watts/m² over the next few years.

5. Aerosol changes are also contributing to the temperature rise, such as less Sahara dust than usual and less sulfur aerosols that are co-emitted with fossil fuel combustion, which previously masked the full impact of greenhouse gases.

6. The Jet Stream is getting increasingly deformed as the temperature difference between the Arctic and the Tropics narrows, and this can strongly increase the intensity, duration and frequency of extreme weather events in the Northern Hemisphere. 

The image on the right shows North Atlantic sea surface temperatures as much as 8.2°C or 14.7°F higher than 1981-2011 (green circle) on July 24, 2023. The image also shows that the Jet Stream is very deformed and features many circular patterns that contribute to stronger heating up of the North Atlantic, especially along the path of the Gulf Stream where the Jet Stream has a strong presence.

Deformation of the Jet Stream can also lead to stronger heatwaves on land that extend over the Arctic Ocean, which in turn can also strongly heat up the water of rivers that end in the Arctic Ocean. The image on the right shows huge amounts of heat surrounding Arctic sea ice and also shows that on July 28, 2023, the sea surface was as much as 19.7°C or 35.4°F hotter than 1981-2011 at an area where the Ob River meets the Kara Sea (green circle).

7. 
AMOC (the Atlantic meridional overturning circulation) is slowing down, further contributing to more hot water accumulating in the North Atlantic. Instead of reaching the Arctic Ocean gradually, a huge part of this heat that is now accumulating in the
North Atlantic may abruptly be pushed into the Arctic Ocean by strong storms that gain strength as the Jet Stream gets increasingly deformed. This danger grows as more ocean heat is accumulating in the North Atlantic and this situation threatens to cause huge eruptions of methane from the seafloor. 

8. Increased stratification, as temperatures rise, combines with increased meltwater and with stronger evaporation over the North Atlantic and stronger precipitation further down the path of the Gulf Stream. This threatens to result in the formation of a freshwater lid on top of the North Atlantic, enabling more hot water to flow underneath this lid into the Arctic Ocean, further increasing the methane threat.


Arctic reaches record high air temperature

The Arctic reached a record high 2-meter air temperature of 5.81°C on July 27, 2023, almost 2°C higher than the daily mean for the period 1979-2000, as illustrated by the image below. Arctic sea ice typically reaches its minimum extent half September, when the temperature in the Arctic falls below 0°C and water at the surface starts refreezing. 


One danger is that, as more heat is reaching sediments at the seafloor of the Arctic Ocean, hydrates will be destabilized, resulting in eruption of huge amounts of methane from the seafloor.

As sea ice melts away, less sunlight gets reflected back into space, so more heat will reach the Arctic ocean and heat up the water, as discussed at the albedo page.

Furthermore, Arctic sea ice is already very thin, as illustrated by the image on the right. The thinner the sea ice, the less heat can be consumed in the process of melting the ice, as discussed at the latent heat page.

These are just three out of numerous developments that could unfold in the Arctic soon, such as tipping points getting crossed and feedbacks starting to kick in with greater ferocity, as discussed in an earlier post.

Latent heat loss, feedback #14 on the Feedbacks page

Feedbacks

Syee Weldeab et al., in a 2022 study, looked at the early part (128,000 to 125,000 years ago) of the penultimate interglacial, the Eemian, when meltwater from Greenland caused a weakening of the Atlantic meridional overturning circulation (AMOC). “What happens when you put a large amount of fresh water into the North Atlantic is basically it disturbs ocean circulation and reduces the advection of cold water into the intermediate depth of the tropical Atlantic, and as a result warms the waters at this depth,” he said. “We show a hitherto undocumented and remarkably large warming of water at intermediate depths, exhibiting a temperature increase of 6.7°C from the average background value,” Weldeab said.

Weldeab and colleagues used carbon isotopes (13C/12C) in the shells of microorganisms to uncover the fingerprint of methane release and methane oxidation across the water column. “This is one of several amplifying climatic feedback processes where a warming climate caused accelerated ice sheet melting,” he said. “The meltwater weakened the ocean circulation and, as a consequence, the waters at intermediate depth warmed significantly, leading to destabilization of shallow subsurface methane hydrates and release of methane, a potent greenhouse gas.”

Furthermore, more methane over the Arctic would push up temperatures locally over the Arctic Ocean as well as over permafrost on land. A 2020 study by Turetsky et al. found that Arctic permafrost thaw plays a greater role in climate change than previously estimated.

Ominously, some very high methane levels were recorded recently at Barrow, Alaska, as illustrated by the NOAA image below.
Further feedbacks can make the situation even more threatening. As an example, dissolved oxygen in oceans decreases as the temperature rises, further pushing up the temperature rise, as discussed, e.g., in a 2022 study by Jitao Chen et al. As the temperature rises, soil moisture content decreases, further pushing up temperatures, as discussed in an earlier post.

Conclusion

The situation is dire and is getting more dire every day, which calls for a Climate Emergency Declaration and implementation of comprehensive and effective action, as described in the Climate Plan with an update at Transforming Society.


Links

• N. Atlantic ocean temperature sets record high: US agency

• Nullschool
https://earth.nullschool.net

• Climate Reanalyzer - sea surface temperature
https://climatereanalyzer.org/clim/sst_daily

• Copernicus
https://climate.copernicus.eu

• University of Bremen - Arctic sea ice
https://seaice.uni-bremen.de/start

• A Prehistoric Climate Feedback Loop - Paleoclimatologist uncovers an ancient climate feedback loop that accelerated the effects of Earth's last warming episode (news release)
Evidence for massive methane hydrate destabilization during the penultimate interglacial warming - by Syee Weldeab et al. (study, 2022)

• Marine anoxia linked to abrupt global warming during Earth’s penultimate icehouse - by Jitao Chen et al. (2022)

• Carbon release through abrupt permafrost thaw - by Merritt Turetsky et al. (2020)
• NOAA - Global Monitoring Laboratory - Barrow, Alaska
https://gml.noaa.gov/dv/iadv/graph.php?code=BRW&program=ccgg&type=ts


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

• Will there be Arctic sea ice left in September 2023?
• Dire situation gets more dire every day
https://arctic-news.blogspot.com/2023/07/dire-situation-gets-more-dire-every-day.html

• Transforming Society
https://arctic-news.blogspot.com/2022/10/transforming-society.html

• Climate Emergency Declaration
https://arctic-news.blogspot.com/p/climate-emergency-declaration.html





Tuesday, January 3, 2023

A huge temperature rise threatens to unfold soon

A huge temperature rise threatens to unfold, as the already dire situation threatens to turn catastrophic due to the combined impact of a number of developments and feedbacks. 

The image below uses ERA5 data, with two trends added. The blue trend, based on 1940-2022 data, points at 3°C rise by 2044. The purple trend, based on 2008-2022 data, better reflects variables such as El Niño and sunspots, and shows that this could trigger a rise of as much as 3°C by 2025, as further discussed below. Note that anomalies are from 1850-1900, which isn't pre-industrial.


The upcoming El Niño

Temperatures are currently suppressed as we're in the depth of a persistent La Niña event. It is rare for a La Niña event to last as long as the current one does, as illustrated by the NASA image below and discussed in this NASA post. The blue line added in the image highlights an increase in peak ONI (strong El Niños) over the years. 


The above image was created using data up to September 2022. La Niña has since continued, as illustrated by the NOAA image on the right. NOAA adds that the dashed black line indicates that La Niña is expected to transition to ENSO-neutral during January-March 2023.

Chances are that we'll move into the next El Niño in the course of 2023. Moving from the bottom of a La Niña to the peak of a strong El Niño could make a difference of more than half a degree Celsius, as illustrated by the image below.

[ image adapted from NOAA ]
Joint impact of El Niño, sunspots and the volcano eruption near Tonga 

[ click on image to enlarge ]
An analysis in an earlier post warns that the rise in sunspots from May 2020 to July 2025 could make quite a difference, as the upcoming El Niño looks set to coincide with a high number of sunspots.

The current cycle of sunspots is forecast to reach a maximum in July 2025. Recent observations are higher than expected, as illustrated by the images on the right, adapted from NOAA, confirming a study mentioned in the earlier post that warns that the peak of this cycle could rival the top few since records began, which would further increase the difference.

Observed values for December 2022 are already very close to or above the maximum values that NOAA predicts will be reached in July 2025. If this trend continues, the rise in sunspots forcing from May 2020 to July 2025 may well make a difference of more than 0.25°C, a recent analysis found. 

A 2023 study calculates that the submarine volcano eruption near Tonga in January 2022, as also discussed at facebook, will have a warming effect of 0.12 Watts/m² over the next few years.

The joint impact of a strong El Niño, high sunspots and the volcano eruption near Tonga could make a difference of more than 0.87°C. This rise could trigger further developments and feedbacks that altogether could cause a temperature rise from pre-industrial of as much as 18.44°C by 2026, as illustrated by the image at the top and as discussed below.

As illustrated by the image below,  temperature anomalies on land can be very high, especially during El Niño events. In February 2016, during a strong El Niño, the land-only monthly anomaly from 1880-1920 was 2.95°C. Note that anomalies are from 1880-1920, which isn't pre-industrial.


Further developments and feedbacks 

A combination of further developments and feedbacks could cause a huge temperature rise. An example of this is the decline of the cryosphere, i.e. the global snow and ice cover.

Antarctic sea ice extent is currently at a record low for the time of year (see image on the right, adapted from NSIDC). 

Antarctic sea ice extent reached a record low on February 25, 2022, and Antarctic sea ice extent looks set to get even lower this year. The dangerous situation in Antarctica is discussed in more detail in a recent post

The currently very rapid decline in sea ice concentration around Antarctica is also illustrated by the animation of Climate Reanalyzer images on the right, showing Antarctic sea ice on November 16, November 29, December 15, 2022 and January 4, 2023.

Studies in Alaska and Greenland have found that submarine and ambient melting is substantially higher than previously thought.

Global sea ice extent is also at a record low for the time of year, as illustrated by the image below that shows that global sea ice extent was 16.67 million km² on January 5, 2023.


[ click on images to enlarge ]
As illustrated by the image on the right, adapted from NSIDC, Arctic sea ice extent was second lowest for the time of year on January 6, 2023.

Loss of sea ice results in loss of albedo and loss of the latent heat buffer that - when present - consumes ocean heat as the sea ice melts. These combined losses could result in a large additional temperature rise, while there are further contributors to the temperature rise, such as thawing of terrestrial permafrost and associated changes such as deformation of the Jet Stream, additional ocean heat moving into the Arctic from the Atlantic Ocean and the Pacific Ocean, and methane eruptions from the seafloor of the Arctic Ocean.

A 2019 analysis concludes that the latent heat tipping point gets crossed when the sea surface temperature anomaly on the Northern Hemisphere gets higher than 1°C above 20th century's temperature and when there is little or no thick sea ice left. 

The latent heat tipping point in the Arctic was crossed in 2020, while ocean heat has kept rising since, despite La Niña conditions, as illustrated by the images above and below. 


Temperature anomalies were high over the Arctic Ocean in December 2022, as illustrated by the image below. 


Ominously, methane levels are very high over the Arctic, as illustrated by the Copernicus image below and as discussed in section 16 of the methane page and at the Climate Alert group


The image below shows methane recorded by the N20 satellite on January 18, 2023, pm at 487.2 mb reaching a peak of 2624 ppb. 


The animation below is made with images recorded by the Metop-B satellite on Jan.6, 2023 PM, showing methane at the highest end of the scale (magenta color) first (at low altitude) becoming visible predominantly over oceans and at higher latitudes North, and then gradually becoming also visible more spread out over the globe at higher altitude, while reaching its highest mean (of 1925 ppb) and peak (of 2708 ppb) at 399 mb. 


This indicates that methane is rising up from the Arctic Ocean, as also discussed at the methane page and at this post at facebook. 

The image below is from tropicaltidbits.com and shows a forecast for September 2023 of the 2-meter temperature anomaly in degrees Celsius and based on 1984-2009 model climatology. The anomalies are forecast to be very high for the Arctic Ocean, as well as for the Southern Ocean around Antarctica, which spells bad news for sea ice at both hemispheres.


Similarly, the image below shows a forecast for October 2023. 


There are many further developments and feedbacks that could additionally speed up the temperature rise, such as rising greenhouse gases (including water vapor), falling away of the aerosol masking effect, more biomass being burned for energy and an increase in forest and waste fires, as also discussed at the Aerosols page

As an earlier post mentions, the upcoming temperature rise on land on the Northern Hemisphere could be so high that it will cause much traffic, transport and industrial activity to grind to a halt, resulting in a reduction in aerosols that are currently masking the full wrath of global warming.

The image below shows dust as high as 9.1887 τ, i.e. light at 550 nm as a measurement of aerosol optical thickness due to dust aerosols, on January 23, 2023 01:00 UTC (at the green circle).


[ see the Extinction page ]
2023 study concludes that the amount of atmospheric desert dust has increased globally by about 55% since the mid-1800s, resulting in a net masking effect of −0.2 ± 0.5 W m⁻² for dust aerosols alone, more than climate models previously thought.

As discussed in an earlier post, the IPCC in AR6 estimates the aerosol ERF to be −1.3 W m⁻², adding that there has been an increase in the estimated magnitude of the total aerosol ERF relative to AR5. In AR6, the IPCC estimate for liquid water path (LWP, i.e., the vertically integrated cloud water) adjustment is 0.2 W m⁻², but a recent analysis found a forcing from LWP adjustment of −0.76 W m⁻², which would mean that the IPCC estimate of −1.3 W m⁻² should be changed to -2.26 W m⁻². When using a sensitivity of 1°C per W m⁻², this translates into an impact of -2.26°C and that doesn't even include the above-mentioned extra impact of dust. Furthermore, the IPCC's total for aerosols includes a net positive impact for warming aerosols such as black carbon, so the impact of cooling aerosols alone (without warming aerosols) will be even more negative.

The image on the right, from the extinction page, includes a potential rise of 1.9°C by 2026 as the sulfate cooling effect falls away and of 0.6°C due to an increase in warming aerosols by 2026.

In the video below, Guy McPherson discusses our predicament.


Final conclusions and reflections

It's important to avoid using terminology that may cause confusion. The image below shows some terms that may cause confusion (left), and terms that could be considered to be used instead (right).


As an example, it's better to avoid terms such as 'overshoot' and target', as illustrated by the image below.  

It's important to look at the bigger picture and recognize that these developments and feedbacks could jointly cause a temperature rise (from pre-industrial) of as much as 18.44°C by 2026, as discussed at the Extinction page. Also note that humans are likely to go extinct with a rise of 3°C, as illustrated by the image below, from an analysis discussed in an earlier post and underpinned by this post.


Earlier versions of the text in the image below were posted here and here


The situation is dire and threatens to turn catastrophic soon. The right thing to do now is to help avoid or delay the worst from happening, through action as described in the Climate Plan.


Links

• Copernicus temperature

• NOAA National Centers for Environmental Information, State of the Climate: Monthly Global Climate Report for October 2022, retrieved November 16, 2022
https://www.ncei.noaa.gov/access/monitoring/monthly-report/global/2022010/supplemental/page-4

• Tonga volcano eruption raises ‘imminent’ risk of temporary 1.5C breach https://www.carbonbrief.org/tonga-volcano-eruption-raises-imminent-risk-of-temporary-1-5c-breach

• Tonga eruption increases chance of temporary surface temperature anomaly above 1.5 °C - by Stuart Jenkins et al. 
https://www.nature.com/articles/s41558-022-01568-2

• NSIDC - National Snow and Ice Data Center - Charctic Interactive Sea Ice Graph
https://nsidc.org/arcticseaicenews/charctic-interactive-sea-ice-graph

• Climate Reanalyzer
https://climatereanalyzer.org/wx/todays-weather/?var_id=seaice-snowc&ortho=7&wt=1

• Meltwater Intrusions Reveal Mechanisms for Rapid Submarine Melt at a Tidewater Glacier - by Rebecca Jackson et al. (2019)
https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2019GL085335

• Greenland’s Glaciers Might Be Melting 100 Times As Fast As Previously Thought (2022)
https://news.utexas.edu/2022/12/15/greenlands-glaciers-might-be-melting-100-times-as-fast-as-previously-thought

• An Improved and Observationally-Constrained Melt Rate Parameterization for Vertical Ice Fronts of Marine Terminating Glaciers - by Kirstin Schulz et al. (2022)
https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022GL100654

• National Institute of Polar Research, Japan
https://ads.nipr.ac.jp/vishop/#/extent

• NASA - GISS Surface Temperature Analysis (v4) - Global Maps

• NOAA - Climate at a Glance Global Time Series

• Critical Tipping Point Crossed In July 2019
• Another Year of Record Heat for the Oceans - by Lijing Cheng et al. 

• Copernicus - methane

• NOAA - methane MetOp-B satellite

• Methane - section 16. Methane rising from Arctic Ocean seafloor

• Tropicaltidbits.com
https://www.tropicaltidbits.com

• The upcoming El Nino and further events and developments

• Jet Stream

• Cold freshwater lid on North Atlantic

• Pre-industrial
https://arctic-news.blogspot.com/p/pre-industrial.html

• Invisible ship tracks show large cloud sensitivity to aerosol - by Peter Manhausen et al.
https://www.nature.com/articles/s41586-022-05122-0

• Methane keeps rising
https://arctic-news.blogspot.com/2022/10/methane-keeps-rising.html

• Global warming in the pipeline - by James Hansen et al. 
https://export.arxiv.org/ftp/arxiv/papers/2212/2212.04474.pdf

• Latent Heat
https://arctic-news.blogspot.com/p/latent-heat.html

• Extinction
https://arctic-news.blogspot.com/p/extinction.html

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

• When will humans go extinct?