High Temperatures October 2020

September 2020 was the warmest September in the NASA record that goes back to 1880. In the image, September 2020 temperatures are compared to 1951-1980.

Global warming is accelerating

Similarly, Copernicus reports that September 2020 global surface air temperature was the highest September temperature on record. The image below shows temperatures averaged over the twelve-month period from October 2019 to September 2020.

Keep in mind that anomalies in the NASA image are compared to 1951-1980, while in the Copernicus image, anomalies are compared to the 1981-2010 average. Anomalies are even higher when compared to pre-industrial levels, as discussed further below.

The Copernicus image shows that the shape of the global anomaly over the past twelve months is very similar to the peak reached around 2016. This confirms that global warming is accelerating, because the peak around 2016 was reached under El Niño conditions, whereas current temperatures are reached under La Niña conditions and while sunspots are at a low, both of which are suppressing temperatures, as discussed in a recent post

What causes this acceleration of the temperature rise?

James Hansen and Makiko Sato confirm that global warming is accelerating and they explore whether this acceleration could be caused by fast feedbacks and short-term natural variability such as the sunspot solar cycle, which they give an amplitude of some 0.25 W/m². James Hansen and Makiko Sato conclude that global warming is accelerating due to a less negative atmospheric aerosol forcing.

Indeed, sunspots cannot explain this acceleration, because we’re currently in a sunspot low. 

El Niño/La Niña cannot explain this acceleration either, because we’re currently experiencing La Niña conditions, as also illustrated by above NOAA image
Further causes could be explored. As the image below shows, more than 90% of global warming currently goes into oceans. 
[ see also earlier post ]

The two images below shows that high sea surface temperature anomalies feature on the Northern Hemisphere on October 22, 2020, with anomalies (from 1981-2011) as high as 10.2°C or 18.3°F (off the coast of North America). This is the more remarkable since, at the same time, low sea surface temperatures show up over the mid-Pacific, associated with La Niña (image right). 


Stratification may cause oceans to take up less heat and the more heat will remain in the troposphere, the faster the temperature of the troposphere will rise, as discussed in an earlier post
As discussed under feedback #25 at the feedbacks page, the atmosphere can be expected to carry more water vapor as temperatures rise. Since water vapor is a potent greenhouse gas, more water vapor in the atmosphere will contribute to global warming. 
More evaporation also brings more heat into the atmosphere, as illustrated by the image on the right, and more heat will also be transferred to the atmosphere as the area of open water increases in the Arctic Ocean.
Further acceleration of the temperature rise

[ from earlier post ]

Further acceleration of global warming looks set to occur over the next few years as sunspot activity increases and as El Niño conditions will return. 

In 2019, Tiar Dani et al. analyzed a number of studies and forecasts pointing at the maximum in the upcoming Solar Cycle occurring in the year 2023 or 2024.

This analysis, discussed in a recent post, found some variation in intensity between forecasts, adding images including the one on the right, which is based on linear regression and suggests that the Solar Cycle 25 may be higher than the previous Solar Cycle 24. 


The need to rapidly transition to clean, renewable energy 

The international treaty banning nuclear weapons has now been ratified by 50 countries and the treaty will come into force on 22 January 2021, making it illegal to stockpile, produce and use nuclear weapons from January 22, 2021.

The treaty complements the Paris Agreement, the Montreal Protocol and further international agreements that politicians should abide by.

Clean, renewable energy – key to world peace

In the year 1900, there were more electric cars on U.S. roads than gasoline cars. Solar panels were used on a satellite, launched by the US back in 1958. William Thomson proposed using heat pumps for space heating in 1852. The first electricity-generating wind turbine was invented in 1888 in Cleveland, Ohio by Charles Brush.

What has been holding up the innovation in clean, renewable energy technologies such as batteries, solar panels, wind turbines and heat pumps? What stood in the way was the disastrous turn that history took into fossil fuel and nuclear power. Historically, fossil fuel has been a source of conflict that blocked the road to progress. The key to progress and world peace is a rapid transition to clean, renewable energy.

Fossil fuel and control over its supply is behind much of the conflict and violence, as well as pollution that has infested the world for more than a century. Instead of continuing to use fossil fuel, the world must rapidly transition to the use wind turbines, geothermal power, solar power, wave power, and similar ways to generate clean, renewable energy, in combination with hydrogen and batteries and other ways to store energy.

Abundance of local clean, renewable energy

This transition to clean, renewable energy will remove much cause for conflict. Clean, renewable energy is available in abundance LOCALLY around the world (unlike fossil fuel) and the use of clean, renewable energy in one place doesn’t exclude use of clean, renewable energy elsewhere.

Clean, renewable energy’s numerous benefits

This transition also comes with greater energy security and reliability, next to its numerous further benefits, e.g. it will make more land and water available for growing food and it will generate better and more jobs and investment opportunities, and improve our health, in addition to the reductions in greenhouse gases that come with this transition.

Clean, renewable energy is also cheaper

Importantly, it is also more economic to use clean, renewable energy, so the transition will more than pay for itself as we go. The more prices of solar panels, batteries, heat pumps, etc. keep falling, and the more urgency there is to act on climate change, the more sense it makes to transition to clean, renewable energy as soon as possible. Innovation has resulted in a huge drop in the cost of generating and storing clean, renewable electricity. In the Lazard 2019 analysis of the cost of energy and storage, the unsubsidized cost of solar PV (thin film utility scale) was $US32-42/MWh, i.e. already lower than the cost of fossil fuel and nuclear, which ranged from $US44-199/MWh (see image). A recent tender for solar panels in Portugal received an offer equivalent to a price of $US13/MWh. 

Aerosols
 

Yet, while the transition to clean, renewable energy makes sense from so many perspectives, while it is absolutely necessary, and while it will reduce temperatures, this transition will not immediately result in lower overall temperatures, for a number of reasons. Maximum warming occurs about one decade after a carbon dioxide emission, so the full warming wrath of the carbon dioxide emissions over the past ten years is still to come, as discussed at the extinction page. Even with dramatic cuts in emissions, temperatures will not fall as long as levels of greenhouse gases in the atmosphere remain high. Additionally, sulfate cooling loss will further increase temperatures, as the world progresses with the necessary transition to the use of clean, renewable electricity. So, additional action is needed! 

A rapid, steep temperature rise
The danger is that a rapid and steep temperature rise will be triggered by a combination of elements such as El Niño, sunspots, oceans taking up less heat and changes to aerosols such as further sulfate cooling loss. 
The potential for such a rapid, steep temperature rise is also illustrated by the image below, posted in February 2019 and showing a potential total rise of 18°C or 32.4°F from 1750 by the year 2026.

[ from earlier post ]

A rapid, steep temperature rise would be felt most strongly in the Arctic, causing albedo loss, emissions and transfer of heat from ocean to atmosphere that would all hit the Arctic most strongly, thus further speeding up the temperature rise, as also illustrated by the image below. 
As discussed in an earlier post, a rise of more than 5°C could happen within a decade, possible by 2026. Humans will likely go extinct with a 3°C rise and most life on Earth will disappear with a 5°C rise. 
[ from earlier post ]
Arctic Sea Ice
Meanwhile, temperatures in the Arctic have been very high, as illustrated by the image below showing air temperature in the Arctic up to October 12, 2020 (red line). 

For some time, Arctic sea ice exent has been at a record low for the time of year, as illustrated by the image below, showing the situation on October 20, 2020. 
For some time, sea ice area has also been at a record low for the time of year, as illustrated by the image below, showing the situation up to October 22, 2020.
Arctic sea ice volume has been very low, as illustrated by the image below showing volume up to September 30, 2020. 
As the image below shows, there was a lot of open water north of Greenland on October 23, 2020.

The image below, showing land outlines, is added for reference purposes. See also further images at this facebook post.
Temperature anomalies over the Arctic Ocean remain high. The image below shows a forecast for November 8, 2020 12Z. Very high temperature anomalies are visible over the Arctic Ocean, in particular over the East Siberian Arctic Shelf, while the Arctic as a whole shows an anomaly of 6.1°C compared to 1979-2000.

These high temperature anomalies reflect overheating of the Arctic Ocean with the sea ice no longer acting as a buffer to consume heat.

Furthermore, these high temperatures in October and November 2020 reduce the chances that sea ice will build up much thickness over the next few months, meaning there will be little or no buffer to consume incoming heat as temperatures start to rise again early next year. 

Without such a buffer, and with greater odds of high temperatures at the start of the melting season, the threat increases of destabilization of methane hydrates contained in sediments at the seafloor of the Arctic Ocean. 

Meanwhile, the temperature of the ocean on the Northern Hemisphere keeps increasing, as illustrated by the image below, from an earlier post


As the Arctic warms up faster than the rest of the world, the temperature difference between the North Pole and the Equator narrows, making the jet stream wavier, thus enabling warm air over the Pacific Arctic to move more easily into the Arctic, as discussed in many earlier posts such as this one, which featured a forecast for March 31, 2019, with a temperature anomaly for the Arctic of 7.7°C or 13.86°F and local anomalies approaching 30°C or 54°F higher than 1979-2000.

So, the odds are increasing that very high temperatures will hit the Arctic at the start of the melting season, further increasing the threat of destabilization of methane hydrates contained in sediments at the seafloor of the Arctic Ocean. 

The Methane Threat

On October 26, 2020 pm, the NetOp-1 satellite recorded methane levels as high as 2537 ppb. 

Where did such high levels originate? The animation shows areas solidly magenta-colored and indicating high methane levels to first appear over the East Siberian Arctic Shelf close to sea level, and to grow larger and cover more of the Arctic Ocean at higher altitudes. 

As discussed repeatedly in earlier posts such as this one and as illustrated by the image below, from a recent post, methane levels are rising most strongly at higher altitudes. 
[ from earlier post ]

As discussed in a 2017 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. Since little hydroxyl is present in the atmosphere over the Arctic, it is much harder for this methane to be broken down. 

What further makes the rise of methane at these high altitudes very worrying is that once methane does reach 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.

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

Links

• Copernicus – Surface air temperature for September 2020
https://climate.copernicus.eu/surface-air-temperature-september-2020

• NASA – Temperature anomalies September 2020
https://data.giss.nasa.gov/gistemp/maps/index.html

• September 2020 Global Temperature Update – by James Hansen
http://www.columbia.edu/~mhs119/Temperature/Emails/September2020.pdf

• Accelerated Global Warming (14 October 2020) – by James Hansen and Makiko Sato
http://www.columbia.edu/~jeh1/mailings/2020/20201014_AcceleratedWarming.pdf

• NOAA – Global monthly temperature anomalies, with ENSO status
https://www.ncdc.noaa.gov/sotc/global/202009/supplemental/page-4

• ENSO: Recent Evolution, Current Status and Predictions – NOAA, October 12, 2020
https://www.cpc.ncep.noaa.gov/products/analysis_monitoring/lanina/enso_evolution-status-fcsts-web.pdf

• Danish Meteorological Institute – Arctic temperature
http://ocean.dmi.dk/arctic/meant80n.uk.php

• Climate reanalyzer
https://climatereanalyzer.org

• Cryospherecomputing – by Nico Sun 

http://cryospherecomputing.tk

• Arctic sea ice extent – Vishop, Arctic Data archive System, National Institute of Polar Research, Japan 
https://ads.nipr.ac.jp/vishop/#/extent

• Portugal’s second solar PV tender sets new world record low price

• Lazard 2019 analysis of the cost of energy and storage 
https://www.lazard.com/perspective/lcoe2019

• UN Secretary-General’s Spokesman – on the occasion of the 50th ratification of the Treaty on the Prohibition of Nuclear Weapons 
https://www.un.org/sg/en/content/sg/statement/2020-10-24/un-secretary-generals-spokesman-the-occasion-of-the-50th-ratification-of-the-treaty-the-prohibition-of-nuclear-weapons

• Temperatures threaten to become unbearable
https://arctic-news.blogspot.com/2020/09/temperatures-threaten-to-become-unbearable.html 

• Methane Hydrates Tipping Point threatens to get crossed

https://arctic-news.blogspot.com/2017/04/10c-or-18f-warmer-by-2021.html

• A Global Temperature Rise Of More than Ten Degrees Celsius By 2026?

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