Climate Change = Extreme Weather = More Climate Change

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The last several decades of climate change, and climate change research, have indicated and repeatedly confirmed a rather depressing reality. When something changes in the earth’s climate system, it is possible that a negative feedback will result, in which climate change is attenuated. I.e., more CO2 could cause more plant growth, the plants “eat” the CO2, so a negative feedback reduces atmospheric levels of the greenhouse gas bringing everything back to normal. Or, when something changes in the earth’s climate system, we could get a positive feedback, where change in one direction (warming) causes more change in that direction. A developing and alarming example of this would be warming in the arctic causing less summer sea ice in the arctic which warms the arctic which causes less sea ice, etc. etc., with numerous widespread and dramatic effects on climate and weather.

ResearchBlogging.orgOver these decades of observation and research, we’ve discovered that negative feedbacks are rare, and when they occur, the are feeble. Yes, some plants do eat some of that extra CO2, bur hardly any. This makes sense. Adding antelopes to the savanna might cause there to be more lions to some extent, but the cap on lion density is not antelopes … it is other lions, staking out territories. After the first few dozen antelopes all you get is a lot of antelopes. Biological systems tend to optimize within some range. Plants can’t really be expected to use more water, more CO2, more other nutrients, just because they are there, beyond some range that they typically use in nature.

Well, we have a new positive feedback: Weather Weirding caused by climate change causes more climate change. Here’s how it works.

First, we warm the arctic. This causes the gradient of warm tropical air to cooler temperate and arctic air to reduce. The gradient causes atmospheric systems that include jet streams to form, but with a reduced gradient, the jet streams change their behavior. When the gradient is low enough (as it is now most of the time) the polar jet stream shifts from being a more or less simple circle around the earth to a very wavy circle, and the jet stream itself moves more slowly. For reasons that have to do with the math of the atmosphere, when the waviness reaches a certain point the waves themselves tend to stop moving, or move only slowly. So the jet stream is moving through these waves, but the position of the waves remains stable for days and days on end.

Where the wave dips towards the equator, an low pressure system forms in the “elbow” of the wave and sits there for days on end, causing cool conditions and a lot of precipitation. Flooding ensues. Where the wave dips up towards the pole, a high pressure system forms in the inverted elbow of the jet stream. This brings warm air north and that air tends to be dry (depending on where it is). This results in heat waves and drought conditions. The reality is more complex that I’ve indicated here, but you get the picture. Weather extremes of both cold and heat occur, and weather extremes of both wet and dry occur.

(For more information on these phenomena see: Why are we having such bad weather?, Linking Weather Extremes to Global Warming, and The Ice Cap is Melting and You Can Help.)

And now comes the newly identified “positive” feedback.

The research by scientists at Max Plank is published in nature (see citation below) but summarized on a web page from that institute:

When the carbon dioxide content of the atmosphere rises, the Earth not only heats up, but extreme weather events, such as lengthy droughts, heat waves, heavy rain and violent storms, may become more frequent. Whether these extreme climate events result in the release of more CO2 from terrestrial ecosystems and thus reinforce climate change has been one of the major unanswered questions in climate research. It has now been addressed by an international team of researchers working with Markus Reichstein, Director at the Max Planck Institute for Biogeochemistry in Jena. They have discovered that terrestrial ecosystems absorb approximately 11 billion tons less carbon dioxide every year as the result of the extreme climate events than they could if the events did not occur. That is equivalent to approximately a third of global CO2 emissions per year….that the consequences of weather extremes can be far-reaching. “As extreme climate events reduce the amount of carbon that the terrestrial ecosystems absorb and the carbon dioxide in the atmosphere therefore continues to increase, more extreme weather could result,” explains Markus Reichstein. “It would be a self-reinforcing effect.”

In particular drought (caused by extremes of heat long term, and lack of rainfall) cause plants to absorb less CO2. Heavy precipitation increases the flow of water containing carbonate holding materials into bodies of water where the CO2 out-gasses.

I would add to this the relationship between drought, fire, and dark snow in Greenland.

Climate change causes extreme weather which causes more of the same sort of climate change.

Bobby Magill also discusses this here: Can Extreme Weather Make Climate Change Worse?


Reichstein, Markus, Bahn, Michael, Ciais, Phillipe, & Et Al (2013). Climate extremes and the carbon cycle Nature DOI: 10.1038/nature12350

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6 thoughts on “Climate Change = Extreme Weather = More Climate Change

  1. Sailor, that was hoped for at one point but it does not seem to work that way. There are a number of reasons including that the vapor is concentrated in space not uniform, and not at high enough of an altitude to reflect enough heat … vapor is a green house gas and clouds reflect sunlight, so one can imagine the possible outcomes are complicated. I think, though, that the cloud situation has been largely settled and there isn’t much hope of a significant (or any?) negative feedback there.

  2. Clouds reflect in both directions… But they only reflect sunlight during the day, whereas they reflect IR back towards the ground day or night. That’s why overcast nights tend to be warmer than clear ones.

    There are a couple of whopping big negative feedbacks that are not in any doubt, but their effects are already factored in. They’re why nobody expects the Earth to turn into Venus… But they’re not enough to completely counteract the current forcings. Interestingly, you never see the “septics” talking about them…

  3. is it possiable for the climate change to affect major wheather and make rain act weird in my state it would rain for a a hour and it will rain hard then stop and be sunny again ive never seen this happen before and it seemed like insects are getting confused and mating with other insects of diffrent speices becaus the envirmant is changin and so is the weather very confusing so is it possiable for climate change to affect speices and dissrubt ther normal rontine oflife

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