The atmosphere is so unstable that a butterfly flapping its wings can, famously, change the course of weather patterns. The celebrated “butterfly effect” also means that the reliability of weather forecasts drops sharply beyond 10 days.

Beyond this, there are strong fluctuations in temperature, with increases tending to be followed by decreases, and vice-versa. The same pattern holds true over months, years and decades. “This natural tendency to return to a basic state is an expression of the atmosphere’s memory that is so strong that we are still feeling the effects of century-old fluctuations,” says McGill University physics professor Shaun Lovejoy. “While man-made atmospheric warming imposes an overall increasing trend in temperatures, the natural fluctuations around this trend follow the same long memory pattern.”

In a new paper published online in Geophysical Research Letters, Lovejoy shows how to directly harness the atmosphere’s elephantine memory to produce temperature forecasts that are somewhat more accurate than conventional numerical computer models. This new method, he says, could help improve notoriously poor seasonal forecasts, as well as producing better long-term climate projections.

Improvement on standard approach

To take advantage of the butterfly effect, Lovejoy’s approach treats the weather as random and uses historical data to force the forecast to reflect a realistic climate. This allows it to overcome limitations of the standard approach, in which imperfect representations of the weather push a computer model to be consistent with its model climate – rather than with the real climate. The new method also represents an improvement over other statistical forecasting techniques that exploit only the atmosphere’s short-term memory, Lovejoy asserts.

Lovejoy’s paper uses a simple version of his new method to show that the so-called pause in global warming since 1998 can be well explained with the help of historical atmospheric data. He also concludes that this method proves more accurate over this period than the standard computer models used, for example, by the International Panel on Climate Change.

Lovejoy’s model also predicts that if greenhouse gas emissions continue at the post 2000 rate, there is a 97.5% chance that the “pause” in global warming will be over before 2020.

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Lovejoy, S. (2015), “Using scaling for macroweather forecasting including the pause”, Geophys. Res. Lett., 42, doi:10.1002/2015GL065665

or (open access):

http://www.physics.mcgill.ca/~gang/eprints/eprintLovejoy/neweprint/Hindcast.pause.3.8.15.pdf

or:

http://onlinelibrary.wiley.com/doi/10.1002/2015GL065665/full