High temperatures persist
The image below, created with
NASA data while using a 1903-1924 custom base, illustrates that the temperature anomaly through July 2024 has been more than 1.5°C above this base for each of the past consecutive 13 months, and even more when compared to a pre-industrial base. The red line shows the trend (one-year Lowess Smoothing) associated with the rapid recent rise.
On August 19, 2024, the daily global air temperature was 16.9°C (62.42°F), an anomaly of +0.8°C (+1.44°F) versus 1991-2020, the highest temperature and anomaly on record for this day of the year, as illustrated by the image below, adapted from
Copernicus.
Copernicus has meanwhile upgraded the anomaly versus 1991-2020 to 0.81°C (1.458°F) for August 19, 2024. Climate Reanalyzer recorded an anomaly versus 1991-2020 of 0.82°C (1.476°F) for August 19, 2024, as illustrated by the image below.
Temperatures have been high for 14 consecutive months, i.e. about 0.8°C (± 0.3°C) above the 1991-2020 average and much more when compared to a pre-industrial base, with no sign of a return to earlier temperatures. On August 31, 2024, the temperature was 0.78°C above 1991-2020, the highest anomaly on record for that day of the year.
ENSO-neutral conditions are currently present and a transition to La Niña is expected by September-November 2024, as illustrated by the image below, adapted from
NOAA. The La Niña may be short-lived and a transition to the next El Niño may occur in the course of 2025.
The image below, adapted from
NOAA, illustrates that El Niño conditions were present from June 2023 through April 2024, and that ENSO-neutral started in May 2024.
The danger is that we could move into a new El Niño in 2025, while temperatures remain high due to
feedbacks and while
sunspots move toward the peak of this cycle, expected to occur in July 2025. This - in combination with further events and variables - could constitute a cataclysmic alignment that could result in runaway temperature rise by 2026, as an
earlier post concluded and as illustrated by the image below.
In a cataclysmic alignment, the next El Niño threatens to develop while sunspots are higher than expected and peak in July 2025.
As emissions keep rising, feedbacks threaten to grow in strength and strike with ever greater ferocity, further accelerating the temperature rise while extreme weather disasters hit the world more frequently over larger areas, with greater intensity and for longer periods.
Heatwaves, fires, famine, drought, floods, crop loss, loss of habitable land and corrupt politicians threaten violent conflicts to erupt around the world, industrial activity to grind to a halt and the temperature to rise above 3°C from pre-industrial, driving humans into extinction by 2026.
IPCC keeps downplaying the danger
Note that neither the 1903-1924 base, nor the 1991-2020 base, nor the 1901-2000 base in above images is pre-industrial. The IPCC keeps downplaying the danger, e.g. by claiming that we're still well below the 1.5°C threshold, but when using a genuinely
pre-industrial base, the temperature anomaly has for the past thirteen months also been above the 2°C threshold that politicians at the 2015 Paris Agreement pledged wouldn't be crossed.
The above image, from an
earlier post, shows that the February 2024 temperature was 1.76°C above 1885-1915, potentially 2.75°C above
pre-industrial (bright yellow inset right). The red line (a 6 months Lowess smoothing trend) highlights the steep rise that had already taken place by then.
Additionally, the IPCC refers to a "carbon budget" as if there was an amount of carbon to be divided among polluters and to be consumed for decades to come.
The image on the right illustrates the fallacy of offsets, net-zero and a "balance" between sources and sinks.
Instead, comprehensive and effective action is needed on multiple lines of action, simultaneously yet separately.
Indeed, action is needed to reduce concentrations of carbon both in oceans and in the atmosphere, while on land, the soil carbon content needs to increase, which can be achieved by methods such as pyrolysis of biowaste and adding the resulting biochar to the soil, which will reduce emissions, reduce fire hazards, sequester carbon, support the presence of moisture & nutrients in the soil and thus support the health & growth of vegetation, as discussed at the
Climate Plan group and the
biochar group.
The IPCC has not only failed to warn about the size of the temperature rise from pre-industrial, the IPCC has also failed to warn about developments contributing to such a rise and failed to point at the best ways to combat the rise.
As illustrated by the image below, adapted from
Climate Reanalyzer, the July 2024 temperature anomaly was huge over and around much of Antarctica.
As illustrated by the image below, also adapted from
Climate Reanalyzer, Antarctic temperatures were still increasing in early August, 2024.
The IPCC failed to warn about Antarctic snow and ice cover decline, and - importantly - the amplifying impact of Antarctic sea ice decline on the global temperature rise. This was addressed in an
earlier post as follows:
Sea ice loss results in less sunlight getting reflected back into space and instead getting absorbed by the ocean and the impact of Antarctic sea ice loss is even stronger than Arctic sea ice loss, as Antarctic sea ice is located closer to the Equator, as pointed out by Paul Beckwith in a video in an earlier post. A warmer Southern Ocean also comes with fewer bright clouds, further reducing albedo, as discussed here and here. For decades, there still were many lower clouds over the Southern Ocean, reflecting much sunlight back into space, but these lower clouds have been decreasing over time, further speeding up the amount of sunlight getting absorbed by the water of the Southern Ocean, and this 'pattern effect' could make a huge difference globally, as this study points out. Emissivity is a further factor; open oceans are less efficient than sea ice when it comes to emitting in the far-infrared region of the spectrum (feedback #23 on the feedbacks page).
Sea surface temperatures in the Northern Hemisphere
After an astonishing rise in 2023, sea surface temperature anomalies fell for six months in the Northern Hemisphere and then rose again for four months, threatening to cause dramatic sea ice loss over the next few months and destabilize sediments at the seafloor, resulting in huge amounts of methane erupting and abruptly entering the atmosphere.
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| [ image created with NOAA data, click on images to enlarge ] |
Deformed Jet Stream pushing more heat toward Arctic Ocean
As the Jet Stream gets more deformed due to polar amplification of the temperature rise, this can at times result in strong winds speeding up ocean currents that carry heat toward the Arctic Ocean.
The above image, adapted from
NOAA, illustrates the huge amount of heat present in the ocean around North America, with sea surface temperatures as high as 33.1°C (91.58°F) recorded on August 27, 2024.
Huge amounts of heat are carried along the path of the Gulf Stream, from the Gulf of Mexico through the North Atlantic to the Arctic Ocean.
Local peak temperatures can be even higher. A sea surface temperature of 35.9°C (96.5°F) was recorded by station 256 in the Gulf of Mexico on August 11, 2024, as illustrated by the image below, created with
cdip.ucsd.edu content.
The image by
Brian McNoldy below shows that ocean heat content in the Gulf of Mexico at record high on August 25, 2024.
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| [ click on images to enlarge ] |
The image on the right shows the July 2024 sea surface temperature anomaly (Northern Hemisphere view), created with a
Climate Reanalyzer image.
The image below shows a
deformed Jet Stream (at 250 hPa) with many circular wind patterns. Winds merge off the North American coast, reaching speeds as high as 374 km/h (232 mph, at green circle). Such strong winds can strongly cool the sea surface due to evaporation, while forming a
freshwater lid at the surface of the North Atlantic that enables more warm subsurface water to flow toward the Arctic Ocean. The image shows part of the Jet Stream moving all the way across the Arctic Ocean, speeding up ocean currents that melt the sea ice and cause further heating up of the water of the Arctic Ocean.
While slowing down of the Atlantic meridional overturning circulation (AMOC) can hold back the flow of ocean heat toward the Arctic Ocean, at the same time more heat will accumulate at the surface of the Atlantic Ocean. Higher sea surface temperatures come with greater stratification (image below, from
earlier post).
Meltwater and rain can contribute to formation of a
freshwater lid that expands at the surface of the North Atlantic. This, in combination with greater stratification (
above image), can enable more ocean heat to travel underneath this lid from the North Atlantic into the Arctic Ocean, and this can occur abruptly at times when a deformed Jet Stream causes storms that speed up ocean currents along this path. The image below illustrates a cold
freshwater lid forming at the surface of the North Atlantic. To a lesser extent (due to less meltwater), a lid can also form at the surface of the North Pacific along the path of the
Kuroshio Current.
Arctic sea ice
The image below, adapted from the
Danish Metereological Institute, shows that Arctic sea ice volume on August 31, 2024, was at a record low for the time of year, as it has been for most of the year.
Arctic sea ice has become very thin over the years. The combination image below, created with
Naval Research Laboratory images, shows a forecast for Arctic sea ice thickness on August 16, run the day before, for the years 2014, 2023 and 2024.
The image below shows sea ice disappearing over large parts of the Arctic Ocean including near the North Pole, with a NASA satellite image on the left showing the situation on August 27, 2024 and a University of Bremen images on the right showing sea ice concentration on August 26, 2024.
The screenshot below, from an
earlier post, further illustrates the danger.
High methane levels over Arctic
Meanwhile, peak methane levels as high as 2414 parts per billion (ppb) were recorded by the NOAA 21 satellite at 399 mb on August 13, 2024 AM, with a global mean of 1938 ppb.
By comparison, the NOAA 20 satellite recorded peak levels as high as 2336 ppb at 487 mb on August 13, 2024 AM, with a global mean of 1943 ppb.
As illustrated by the image below, high methane levels were recently recorded at the observatory in Barrow, Alaska.
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
• NASA - datasets and images
https://data.giss.nasa.gov• Copernicus - Climate Pulse
https://pulse.climate.copernicus.eu• Climate Reanalyzer
https://climatereanalyzer.org• 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
• Cataclysmic Alignment
• Nullschool.net
• Jet Stream
