Climate ‘tipping points’ identified using millennia-old data
Historical climate change data can be used to determine the next “tipping points” where large and often irreversible changes can occur to the climate, scientists have found.
University of Birmingham researchers found that the current understanding of tipping points is lacking because such an event has not occurred in recent times.
Earth System models, routinely used for climate predictions, are taken from our understanding of the physical, chemical and biological processes that work together to shape our planet’s environment. But these models do not provide a complete picture because they fail to simulate known climate events from the past.
The new study finds that knowledge of climate reconstructions from thousands of years ago can be used to fine-tune Earth System models to provide a more accurate understanding of climate system thresholds.
Senior author Dr Peter Hopcroft, said: “Climate modelling is the only way we have to predict future climate change, but when models are developed, they are only evaluated with weather observations from the past 150 years or so. This means we have no way to verify their predictions of potential abrupt change – the risks of which are only likely to increase as the planet warms. Palaeoclimate records of abrupt climate changes from the deeper past allow us overcome this problem.”
In their study the team focused on one key example, the ‘greening’ and subsequent rapid desertification of the Sahara, which took place in the mid-Holocene period, around 6,000 years ago.
By feeding data from fossil pollen and sedimentary records into a typical climate model, they were able to show how the model could then predict the Sahara’s transformation into a savannah, which was marked by increased plant coverage, expansion of lakes and most importantly increased rainfall.
The results were then independently compared with studies of marine sediment records from the region, showing how the model accurately captured a very rapid return to the desert conditions over the Sahara.
“We now need to apply these methods to other models to test how universal the results might be,” added Hopcroft. “But by demonstrating how paleoclimate information can be used to improve the way models can simulate past abrupt climate change, we hope that we can begin to increase our confidence in future projections of abrupt events.”
While accurate, long-term climate modelling is still difficult to achieve, scientists are increasingly making use of artificial intelligence and machine learning to try and make their results as accurate as possible.
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