Showing posts with label clouds tipping point. Show all posts
Showing posts with label clouds tipping point. Show all posts

Friday, February 3, 2023

Dire situation gets even more dire

Antarctic sea ice extent was 1.788 million km² on February 21, 2023, an all-time low in the NSIDC record.

Antarctic sea ice area was 1,050,708 km² on February 22, 2023, as illustrated by the Nico Sun image below.


This means that a huge amount of heat that was previously reflected back into space by the sea ice is now instead absorbed by the Southern Ocean, in a self-reinforcing feedback loop that results in further sea ice loss, in turn further speeding up the temperature rise and making the weather ever more extreme.


Arctic sea ice extent was 14,271,000 km² on February 19, 2023, the third-lowest extent in the NSIDC record for the time of year, as illustrated by the above image.


Global sea ice extent reached a record low of 15,500,000 km² on February 11, 2023, as illustrated by the above image.

The situation is dire

The dire situation is further illustrated by the image below, showing high sea surface temperature anomalies (from 1981-2011) over the Southern Ocean, the Atlantic ocean and the Arctic Ocean on February 19, 2023. 


Given the dire situation regarding sea ice and sea surface temperatures, Arctic sea ice may fall dramatically later in the year.

Furthermore, emissions, ocean heat and greenhouse gas levels all keep rising. 

Carbon dioxide (CO₂) at Mauna Loa, Hawaii, reached a record average daily high of 422.88 parts per million (ppm) on February 28, 2023, as illustrated by the above image and the image below. 


It is remarkable for CO₂ levels to already reach record high levels this early in the year, given that CO₂ levels typically reach their annual maximum in May. This spells bad news for developments over the next few months. Keep in mind that carbon dioxide reaches its maximum warming some 10 years after emission, so we haven't been hit by the full wrath of carbon dioxide pollution yet.

Possibly even worse is the rise in methane. The image below shows NOAA globally averaged marine surface monthly mean methane data from 2016, with methane reaching 1923.57 parts per billion (ppb) in November 2022. A moving average centered over 12 months is added to highlight the acceleration in the rise in methane.


Accordingly, temperatures keep rising. An earlier analysis concludes that we have already exceeded the 2°C threshold set at the Paris Agreement in 2015.

These dire conditions spell bad news regarding the temperature rise to come, the more so since, on top of these dire conditions, there are a number of circumstances, feedbacks and further developments that make the outlook even more dire.

Circumstances that make the situation even more dire

Firstly, as illustrated by the image on the right, adapted from NOAA, we're moving into an El Niño.

It looks like it's going to be a very strong El Niño, given that we've been in a La Niña for such a long time.

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, adapted from NOAA.

[ click on images to enlarge ]

Temperature anomalies can be very high during an El Niño. The February 2016 temperature on land-only was 2.96°C above 1880-1920, and in February 2020, it was 2.79°C higher, as illustrated by the image below, created with screenshots taken on February 15, 2023. Note that 1880-1920 isn't pre-industrial.


Secondly, sunspots look set to reach a very high maximum by July 2025, as illustrated by the next two images on the right, adapted from NOAA.

Observed values for January 2023 are already well above the maximum values that NOAA predicted to 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.

Thirdly, the 2022 Tonga submarine volcano eruption did add a huge amount of water vapor to the atmosphere.

Since water vapor is a potent greenhouse gas, this is further contributing to speed up the temperature rise.

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 image below, created with NOAA data, shows Annual Northern Hemisphere Land Temperature Anomalies and has two trends added. The blue trend, based on 1850-2022 data, points at 3°C rise by 2032. The pink trend, based on 2012-2022 data, better reflects variables such as El Niño and sunspots, showing that this could trigger a huge rise, with 3°C crossed in 2024. Anomalies are from 1901-2000 (not from pre-industrial).


Feedbacks and developments making things worse

Indeed, a huge temperature rise could be triggered, due to a multitude of feedbacks and further developments that could strongly deteriorate the situation even further.

On top of the water vapor added by the Tonga eruption, there are several feedbacks causing more water vapor to get added to the atmosphere, as discussed at Moistening Atmosphere.

Further feedbacks include additional greenhouse gas releases such as methane from the seafloor of the Arctic Ocean and methane, carbon dioxide and nitrous oxide from rapidly thawing permafrost on land.

The image below shows the Northern Hemisphere Ocean Temperature Anomaly, compared to 1901-2000. The pink trend, based on 1850-2022 data, shows that the Latent Heat Tipping Point (at 1°C) was crossed in 2022, but the red trend, based on 2007-2022 data, better reflects variables such as El Niño and shows both the Latent Heat Tipping Point and the Seafloor Methane Tipping Point (at 1.35°C) getting crossed in 2024. 


Ominously, November 2023 temperature anomalies are forecast to be at the top end of the scale for a large part of the Arctic Ocean, as illustrated by the tropicaltidbits.com image below. 


Some developments could make things even worse and a huge temperature rise could unfold soon. The image below shows a polynomial trend added to NOAA globally averaged marine surface monthly mean methane data from April 2018 to November 2022, pointing at 1200 ppm CO₂e (carbon dioxide equivalent) getting crossed in 2027.

The Clouds Tipping Point, at 1200 ppm CO₂e, could be crossed and this on its own could result in a further rise of 8°C. As illustrated by the above image, this tipping point could be crossed as early as in 2027 due to forcing caused by the rise in methane alone. When further forcing is taken into account, this could happen even earlier than in 2027. 

On top of the February 28, 2023 daily average of 422.88 ppm for CO₂, methane can add 384.71 ppm CO₂e when using a 1-year GWP of 200 for NOAA's 1923.57 ppb November 2022 methane mean.

While methane at higher altitude can reach even higher levels than NOAA's marine surface data, adding NOAA's November 2022 mean to 422.88 ppm CO₂ would leave just 392.41 ppm CO₂e for further forcing, before the Clouds Tipping Point would get crossed, as the image on the right illustrates.

[ see the Extinction page ]
Further forcing comes from nitrous oxide and other greenhouse gases, while rises in other gases and further changes such as caused by sea ice loss and changes in aerosols can also speed up the temperature rise.

Changes in aerosols are discussed in earlier posts such as this post and this post. The upcoming temperature rise on land on the Northern Hemisphere could be so strong that much traffic, transport and industrial activity will grind to a halt, resulting in a reduction in cooling aerosols that are now masking the full wrath of global heating. These are mainly sulfates, but burning of fossil fuel and biomass also emits iron that helps photosynthesis of phytoplankton in oceans, as a 2022 study points out. 

Without these emissions, the temperature is projected to rise strongly, while there could be an additional temperature rise due to an increase in warming aerosols and gases as a result of more biomass and waste burning and forest fires.

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 an additional rise of 0.6°C due to an increase in warming aerosols by 2026, as discussed in this post and earlier posts.

The image on the right indicates that the rise from pre-industrial to 2020 could be as much as 2.29°C. Earth's energy imbalance has grown since 2020. Therefore, the rise up to now may be higher. 

Climate Tipping Points and further Events and Developments

The temperature could also be pushed up further due to reductions in the carbon sink on land. An earlier post mentions a study that found that the Amazon rainforest is no longer a sink, but has become a source, contributing to warming the planet instead; another study found that soil bacteria release CO₂ that was previously thought to remain trapped by iron; another study found that forest soil carbon does not increase with higher CO₂ levels; another study found that forests' long-term capacity to store carbon is dropping in regions with extreme annual fires; another earlier post discussed the Terrestrial Biosphere Temperature Tipping Point, coined in a study finding that at higher temperatures, respiration rates continue to rise in contrast to sharply declining rates of photosynthesis, which under business-as-usual emissions would nearly halve the land sink strength by as early as 2040.

This earlier post also discusses how CO₂ and heat taken up by oceans can be reduced. A 2021 study on oceans finds that, with increased stratification, heat from climate warming less effectively penetrates into the deep ocean, which contributes to further surface warming, while it also reduces the capability of the ocean to store carbon, exacerbating global surface warming. A 2022 study finds that ocean uptake of CO₂ from the atmosphere decreases as the Meridional Overturning Circulation slows down. An earlier analysis warns about growth of a layer of fresh water at the surface of the North Atlantic resulting in more ocean heat reaching the Arctic Ocean and the atmosphere over the Arctic, while a 2023 study finds that growth of a layer of fresh water decreases its alkalinity and thus its ability to take up CO₂, a feedback referred to as the Ocean Surface Tipping Point.

[ from Blue Ocean Event 2022? - click on images to enlarge ]

The above image depicts only one sequence of events, or one scenario out of many. Things may eventuate in different orders and occur simultaneously, i.e. instead of one domino tipping over the next one sequentially, many events may occur simultaneously and reinforce each other. Further events and developments could be added to the list, such as ocean stratification and stronger storms that can push large amounts of warm salty water into the Arctic Ocean.

While loss of Arctic sea ice and loss of Permafrost in Siberia and North America are often regarded as tipping points, Antarctic sea ice loss, and loss of the snow and ice cover on Greenland, on Antarctica and on mountaintops such as the Tibetan Plateau could also be seen as tipping points. Another five tipping points are: 
- The Latent Heat Tipping Point
- The Seafloor Methane Tipping Point

Extinction

Altogether, the rise from pre-industrial to 2026 could be more than 18.44°C, while 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.


This should act as a warning that near-term human extinction could occur sooner than most may think. Indeed, when asked what could cause humans to go extinct, many may mention:
  1. asteroid strikes
  2. rampant pestilence, diseases, epidemics and pandemics
  3. war, murder and violence
  4. ecosystems and vegetation collapse, famine
  5. dehydration
  6. plastic pollution, spread of poisonous and toxic substances
  7. nuclear accidents, nuclear war or waste leakage
  8. outbreaks of antibiotic-resistant bacteria
  9. emerging new or re-emerging ancient microbes
10. bio-weapons and biological experiments gone out of hand
11. infertility, genetic degeneration, loss of genetic diversity
12. madness, cults, depression and suicide
13. polar shifts, earthquakes, landslides and tsunamis
14. Artificial Intelligence gone rogue
15. hostile aliens breeding predatory animals

More recently, climate change threats are mentioned such as:
16. destructive storms, flooding, fires and more extreme weather
17. hydrogen sulfide gas released from oceans
18. depletion of the ozone layer
19. co-extinctions, i.e. extinction of species that humans depend on, resulting in our own demise.

There may be more threats, but I think the biggest threat is:
20. temperature rise
In the video below, Edge of Extinction: Destination Destruction, Guy McPherson gives his view on our predicament.




Conclusion

The dire situation we're in looks set to get even more dire, calling for comprehensive and effective action, as described in the Climate Plan and Transforming Society.


Links

• NSIDC - National Snow and Ice Data Center
https://www.nsidc.org

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

• Cryosphere Computing - by Nico Sun
https://cryospherecomputing.com

• Nullschool
https://earth.nullschool.net

• Climate Reanalyzer - sea ice based on NSIDC index V3
https://climatereanalyzer.org/clim/seaice

• NOAA - greenhouse gases - trends

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

• NOAA - Monthly temperature anomalies versus El Niño
https://www.ncei.noaa.gov/access/monitoring/monthly-report/global/202301/supplemental/page-4

• NOAA - Solar cycle progression

• NASA gistemp Monthly Mean Global Surface Temperature - Land Only

• NOAA - Annual Northern Hemisphere Land Temperature Anomalies 

• Tonga eruption increases chance of temporary surface temperature anomaly above 1.5 °C - by Stuart Jenkins et al. (2023)
https://www.nature.com/articles/s41558-022-01568-2



• Moistening Atmosphere
• Albedo, latent heat, insolation and more

• Latent Heat

• Blue Ocean Event

• Tropicaltidbits.com

• Methane keeps rising

• A huge temperature rise threatens to unfold soon

• The Clouds Feedback and the Clouds Tipping Point
https://arctic-news.blogspot.com/p/clouds-feedback.html

• Human Extinction by 2025?

• 2020: Hottest Year On Record

• The Importance of Methane in Climate Change

• The underappreciated role of anthropogenic sources in atmospheric soluble iron flux to the Southern Ocean - by Mingxu Liu et al. (2022)
https://www.nature.com/articles/s41612-022-00250-w

• How close are we to the temperature tipping point of the terrestrial biosphere? - by Katharyn Duffy et al. (2021)

• Overshoot or Omnicide? 

• Upper Ocean Temperatures Hit Record High in 2020 - by Lijing Cheng et al. (2021)

• Reduced CO₂ uptake and growing nutrient sequestration from slowing overturning circulation - by Yi Liu et al. (2022)
https://www.nature.com/articles/s41558-022-01555-7

• Cold freshwater lid on North Atlantic
• Long-Term Slowdown of Ocean Carbon Uptake by Alkalinity Dynamics - by Megumi Chikamoto et al. (2023) 
• Ocean Surface Tipping Point Could Accelerate Climate Change

• When Will We Die?

• Edge of Extinction: Destination Destruction - video by Guy McPherson




Wednesday, October 5, 2022

Methane keeps rising

WMO Report on Greenhouse Gases 

In 2020 and 2021, the global network of the World Meteorological Organization (WMO) detected the largest within-year increases (15 and 18 ppb, respectively) of atmospheric methane (CH₄) since systematic measurements began in the early 1980s. 

[ IPCC/WMO data through 2021 ]
The image on the right illustrates methane's rise, showing IPCC and, more recently, WMO data. Methane reached 1908 parts per billion (ppb) in 2021, 262% of the 1750 level, while carbon dioxide (CO₂) reached 415.7 parts per million (ppm) in 2021, 149% of the 1750 level, and nitrous oxide (N₂O) reached 334.5 ppb, 124% of the 1750 level. 

The WMO adds that analyses of measurements of the abundances of atmospheric CH₄ and its stable carbon isotope ratio ¹³C/¹²C (reported as δ¹³C(CH₄)) indicate that the increase in CH₄ since 2007 is associated with biogenic processes.

Methane's rise has been accelerating since 2007, which makes this a scary suggestion, as increasing decomposition of plant material as a result of climate change is a self-reinforcing feedback loop that is hard to stop.

Interestingly, a different explanation is pointed at in the 2019 analysis is shale gas a major driver of recent increase in global atmospheric methane?

Another explanation, discussed in an earlier post, is that there was a slowdown from 1984 to 2004 in the rise of methane as a result of rising temperatures increasing the water vapor in the atmosphere, resulting in more hydroxyl decomposing more methane in the atmosphere in the 1990s (compared to the 1980s). Accordingly, while the rise in methane concentration appeared to slow down over those years, methane emissions actually kept growing and continued to do so at accelerating pace, but since an increasingly large part of methane was decomposed by hydroxyl, this continuing rise in methane emissions was overlooked.

This could still mean that plant material is now getting decomposed at higher rates, but an even larger danger is that methane emissions started to increase more strongly from the early 2000s due in part to more methane eruptions from the seafloor of the Arctic Ocean. In other words, while hydroxyl kept increasing, seafloor methane emissions kept increasing even faster, to the extent that methane emissions increasingly started to overwhelm this growth in hydroxyl, resulting in a stronger rise in overall methane abundance in the atmosphere. 

Sadly, there are few measurements available for methane that could erupt from the seafloor of the Arctic Ocean. Moreover, WMO and NOAA data that are used to calculate global means are typically taken at marine surface level, which may be appropriate for carbon dioxide that is present more strongly at sea surface level, but methane is much lighter and will rise quickly and accumulate at higher altitude, as indicated by the satellite images further below. Moreover, the lack of measurements of methane over the Arctic Ocean and at higher altitudes makes it hard to determine from where the methane originated. Much methane could originate from the seafloor of the Arctic Ocean and rise to the Tropopause, while moving from there closer to the Equator, all largely without getting reported.  

What's happening in 2022?

So, what's happening in 2022? Well, it appears that the rise in methane keeps accelerating, as illustrated by the image below showing daily average methane measurements at Mauna Loa, Hawaii, since 2001.

The image below shows methane in situ measurements at Barrow, Alaska, indicating that methane is present in even higher abundance over the Arctic and that levels are rising fast over the Arctic. 


The image below, adapted from Copernicus, shows a forecast for October 27, 2022, 03 UTC at 500 hPa. High levels of methane show up over the Arctic. 


The MetOp-B satellite recorded a mean methane level of 1981 ppb at 293 mb on October 2, 2022 am, while plenty of methane was present over the Arctic Ocean at the three altitudes shown on compilation image below.
The MetOp-B satellite recorded a peak methane level of 2901 ppb at 293 mb on October 20, 2022 am, while plenty of methane was again present over the Arctic Ocean at the three altitudes shown on the compilation image below.

This supports the possibility that large amounts of methane are getting released from the Arctic Ocean, with even more to follow.

While the IPCC keeps hiding the potential for a huge rise in temperature by 2026, as discussed in an earlier post, a recently-published article points out that prudent risk management requires consideration of bad-to-worst-case scenarios. 

How bad could it be? A 2016 analysis warned that there could be a temperature rise of more than 10°C from pre-industral by 2026. An additional danger is that, as methane keeps rising, the clouds tipping point could be crossed even earlier than in 2026. Let's re-evaluate these dangers. 

The above 1981 ppb mean methane level translates into 396.2 ppm CO₂e at a 1-year GWP of 200. Destabilization of sediments at the seafloor of the Arctic Ocean could cause a large abrupt burst of methane to enter the atmosphere over the Arctic Ocean. A doubling of the mean methane level could push up the mean methane level to twice as much, to 792.4 ppm CO₂e, which is only 407.6 ppm CO₂ away from the 1200 ppm CO₂e clouds tipping point that on its own could push up the temperature by some 8°C globally. This gap of 407.6 ppm CO₂ could be more than covered by the current carbon dioxide level. The September 2022 CO₂ level at Mauna Loa was higher than that, i.e. 415.96 ppm. Since the CO₂ level at Mauna Loa in September typically is at its lowest point for the year, this implies that a large abrupt burst of methane could cause the the clouds tipping point to be instantly crossed due to methane and CO₂ alone.

Note that there are additional forcers, such as CFCs, while there are also further events and developments that could additionally speed up the temperature rise, as further discussed below. The scary situation therefore is that the clouds tipping point could be instantly crossed with a burst of methane that is far smaller in size than the methane already in the atmosphere. Such a burst of methane could be released at any time, as discussed in earlier posts such as this one

[ from earlier post ]
That's not even the worst-case scenario. In the above calculation, global mean methane levels are used. However, there is a possibility that low-lying clouds could at first break up and vanish abruptly at one specific point, due to a high methane peak, and that this could lead to break-up of neighboring clouds, propagating break-up across the globe and thus pushing up the temperature rise virtually instantly by some 8°C globally.

The MetOp satellite recorded a peak methane level of 3644 ppb and a mean level of 1944 ppb at 367 mb on November 21, 2021, pm, as discussed in an earlier post. This 3644 ppb translates into 728.8 ppm CO₂e, again at a 1-year GWP of 200. This is 471.2 ppm CO₂e away from the clouds tipping point and that 471.2 ppm CO₂e could be covered by the carbon dioxide, nitrous oxide and CFCs currently in the atmosphere.

How high could the temperature rise be by 2026? 

There are a number of scenarios that could cause the clouds tipping point to be crossed soon, e.g. if the rise in methane kept following a trend as depicted in the image below, showing WMO 2015-2021 global annual surface mean methane abundance, with a trend added.

[ click on images to enlarge ]
The trend points at a potential mean global abundance of methane of more than 700 ppm CO₂e by the end of 2026, implying that when including further forcers the clouds tipping point could be crossed in 2026. Furthermore, the trend points at 1200 ppm CO₂e getting crossed in 2028 due to the forcing of methane alone. 

Even without such an increase in methane, a huge temperature rise could eventuate by 2026, first of all due to a cataclysmic alignment of El Niño and sunspots.

We are currently in the depths of a persistent La Niña, as illustrated by the image on the right, adapted from NOAA, and this suppresses the temperature rise at the moment.

The next El Niño is already overdue, so the peak of the next El Niño may well coincide with a peak in sunspots which look set to reach a higher than expected maximum impact around July 2025. The rise in sunspots from May 2020 to July 2025 could make a difference of some 0.15°C, concluded an earlier post.

Moving from the bottom of the current La Niña to the peak of a strong El Niño could make a difference of more than half a degree Celsius, as indicated by the image below, adapted from NOAA


Therefore, the rise due to the combined impact of El Niño and sunspots could be 0.65°C by 2025. When adding this to the temperature rise that has already occurred and that, when measured from pre-industrial could be as high as 2.29°C, the total land-ocean global temperature rise could be as high as 2.94°C by 2025,  while the rise on land on the Northern Hemisphere could peak at more than 3°C above pre-industrial, noting that when there was a strong El Niño in February 2016, the land-only monthly anomaly from 1880-1920 was 2.95°C, as illustrated by the image below. 

[ from earlier post ]
Such a huge rise could cause heatwaves and droughts that could result in a huge peak in power demand, as everyone switches on their air conditioners, while at the same time rivers could either dry up or their water could become too hot to cool power plants. This could bring the grid down, which would mean that coal-fired power plants would stop emitting sulfates.

[ from Track Buckling Research ]
This could mean that equipment and appliances that need electricity such as heaters and air conditioners could stop working. Electric pumps could stop working, so there may no longer be water coming out of taps. The internet could stop working where routers require power from the grid.

Furthermore, the heat could cause asphalt and tarmac to melt and rail tracks to buckle, while airports could be closed, not only because the surface of the runway could get too hot, but also because the air could become too thin for planes to take off due to the heat.

In short, traffic, transport and industrial activities such as smelting, which are emitting a lot of sulfates as well at the moment, could grind to a halt at many places on the Northern Hemisphere. The result would be a large reduction in aerosols that are currently masking the full wrath of global warming (mainly sulfates). 

[ see the Extinction page ]
How much difference could it make? 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 ¾°C per W m⁻², this translates into an impact of -1.695°C. Since the IPCC's total for aerosols includes a net positive impact for warming aerosols such as black carbon, the impact of cooling aerosols only (without warming aerosols) will be even more negative.

This supports the 2016 analysis that warned that by 2026 there could be a 1.9°C temperature rise due to a decrease in cooling aerosols, while there could be an additional 0.6°C temperature rise due to an increase in warming aerosols and gases as a result of more biomass and waste burning and forest fires by 2026.

So, together with the upcoming El Niño and a peak in sunspots, that could result in a total rise by 2026 of 5.44°C above pre-industrial. There's more to come! Additionally, the 2016 analysis warned about further rises in temperature due to loss of Arctic sea ice and permafrost, and associated changes, as well as further rises due to gases, concluding that there could be a temperature rise by 2026 of more than 10°C compared to pre-industrial.

With a temperature rise of more than 10°C by 2026, the clouds tipping point will also be crossed, which would result in a total rise of more than 18°C by 2026. Keep in mind 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.


The situation is dire and 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

• WMO - More bad news for the planet: greenhouse gas levels hit new highs 

• WMO - Greenhouse Gas Bulletin 
https://public.wmo.int/en/greenhouse-gas-bulletin

• Ideas and perspectives: is shale gas a major driver of recent increase in global atmospheric methane? - by Robert Howarth

• NOAA - Global Monitoring Laboratory
https://gml.noaa.gov/dv/iadv

• Copernicus methane at 500 hPa, forecast for October 18, 2022, 03 UTC
https://atmosphere.copernicus.eu/charts/cams/methane-forecasts?facets=undefined&time=2022101800,3,2022101803&projection=classical_global&layer_name=composition_ch4_500hpa

• What the IPCC impacts report is hiding
https://arctic-news.blogspot.com/2022/02/what-the-ipcc-impacts-report-is-hiding.html

• Climate Endgame: Exploring catastrophic climate change scenarios - by Luke Kemp et al.
https://www.pnas.org/doi/full/10.1073/pnas.2108146119

Also discussed at:
https://www.facebook.com/groups/arcticnews/posts/10160138721434679

• The Clouds Feedback and the Clouds Tipping Point
https://arctic-news.blogspot.com/p/clouds-feedback.html

• Arctic Ocean invaded by hot, salty water

• Sunspots
https://arctic-news.blogspot.com/p/sunspots.html

• NOAA National Centers for Environmental Information, State of the Climate: Monthly Global Climate Report for September 2022, retrieved October 16, 2022
https://www.ncei.noaa.gov/access/monitoring/monthly-report/global/202209/supplemental/page-4

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

• Crossing 3C
https://arctic-news.blogspot.com/2022/09/crossing-3c.html

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

• Track Buckling Research
https://www.volpe.dot.gov/infrastructure-systems-and-technology/structures-and-dynamics/track-buckling-research

• Invisible ship tracks show large cloud sensitivity to aerosol - by Peter Manhausen et al. 

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