The current onset of climate tipping points

Arctic ice melt
Arctic Ice Melt

 

As extreme temperatures, the rate of sea ice melt, the collapse of Greenland glaciers, the thawing of Siberian and Canadian permafrost and increased evaporation in the Arctic drive cold snow storms into Europe and North America, and as hurricanes and wild fires affect tropical and semi-tropical parts of the globe, it is becoming clear Earth is entering a shift in state of the atmosphere-ocean system associated with destructive climate tipping points. As Arctic permafrost is thawing an analogy with geological methane-release events such as the 56 million years-old Paleocene-Eocene boundary thermal maximum (PETM) event is becoming more likely.

As is well known to students of the history of the climate, once a temperature threshold is breached, abrupt weather events ensue amplified by feedbacks such as decreased reflectivity of the Earth surface and enhanced release of greenhouse gases, often within short time frames.

 


Figure 1. 1880-2018 annual mean temperatures and 5-years smoothing.
https://data.giss.nasa.gov/gistemp/graphs/customize.html

 

Such abrupt changes are occurring at present. As mean global temperature has exceeded 1.2 degrees Celsius above 1880 temperatures (Figure 1), sharp reductions occur in Arctic sea ice from 45 percent in 1985 to 21 percent in 2017i, when the ice cover was 8.5 percent lower than the average of 1981-2010ii.

As the ice melts the near-total reflection (high albedo) of solar radiation from the ice is replaced by absorption of infrared radiation by open water; The flow of ice-melt water from the Greenland glaciers creates a large pool of cold water in the North Atlantic Ocean. The cold water region south of Greenland slows-down to aborts northward flow of the thermohaline Atlantic Meridional Ocean Circulation (AMOC), leading to cooling of the North Atlantic and adjacent North America and Europeiii.

Rising temperature and evaporation over the warming Arctic Ocean results in build-up of masses of cold vapor-laden air, intermittently penetrating into lower latitudes through the weakened undulating boundary of the high-altitude polar vortex, which allows penetration of snow storms southward through Siberia and North Americaiv (Figure 2).

 


Figure 2. Arctic air temperatures in January 2018 in degrees Celsius relative to the average (Arctic sea – 3-9 degrees, yellow to red; Greenland and Siberia (-1 to -3 degrees C, blue to magenta) Credit: NSIDC courtesy NOAA/ESRL Physical Sciences Division

 

In 2006 the Greenland and Antarctic ice sheets experienced a combined mass loss of 475±158 Gt/yr (billion ton/year), equivalent to 1.3±0.4 mm/year sea level rise. The acceleration in ice sheet loss over the last 18 years was 21.9±1 Gt/year2 for Greenland and 14.5 ± 2 Gt/year2.

The slow-down to collapse of the northward flow of warm water from tropical regions, namely the Atlantic Meridional Ocean Circulation (AMOC), originating from the Gulf of Mexico, and further warming of the tropical ocean pools, produce in temperature polarities with cool northern ocean regions. This ensues in storms and hurricanes in regions such as the Caribbean islands. Warming of the west Pacific Ocean leads to cyclones such as have affected the Philippines, Fiji and Samoa,

Polar warming is leading to the release of large amounts of methane from frozen organic matter stored in the permafrost and from methane hydrates in lakes, the sea and sediments. This has already raised atmospheric methane levels during 1960-2017 from ~1600 parts per billion to 1860 ppb. The bubbling of methane is locally leading to collapse and cratering of the permafrost. The total mass of methane on land of ~2050 GtC (billion tons) and methane hydrates at sea of ~16,000 GtC (Global Carbon Project) is some 30 times greater than the >600 GtC which has been produced by anthropogenic emissions since the onset of the industrial age. Even a release of 10 percent of Arctic-stored carbon would raise atmospheric greenhouse levels by a factor of about three.

The current warming of Earth manifest in the Arctic Sea, the melting of polar ice sheets, penetration of snow storms into mid-latitudes, permafrost thaw, hurricanes and wildfires and the rise in extreme weather events, manifesting a shift in state of the atmosphere-ocean system, constitutes an existential threat to humanity and much of nature.

Apart from sharp reduction in carbon emissions, there appears to be one chance to save the biosphere as we know it, namely CO2 down-draw using every available method (cf. basalt dust application of soils, carbon cultivation of soils (biochar), CO2 removal by air streaming through basalt, extensive sea weed farms, ‘sodium trees’ sequestering CO2 using sodium hydroxide in pipe systems). This would require funds on the $trillions-scale currently allocated for the military and for wars, humanity’s choice being between ongoing wars and defense of the Planet.

 

 

Andrew Glikson

Andrew Glikson, an Earth and paleo-climate scientist, graduated at the University of Western Australia, conducted geological surveys of the oldest geological formations in Australia, South Africa, India and Canada; studied large asteroid impacts, including effects on the atmosphere and oceans and on mass extinction of species. Since 2005 he studied the relations between climate and human evolution and published  books on the subject.

 

Edited for Unlikely by dan raphael, Staff Reviewer
Last revised on Sunday, April 8, 2018 - 22:42