They discovered a global connection pattern of extreme rainfall – this could eventually improve weather forecasts and hence help to limit damages and protect people. Extreme rainfall events are on the rise due to human-caused climate change, which makes the study even more relevant. The researchers developed a new method rooted in complex systems science to analyze satellite data. The revealed extreme rainfall patterns are likely linked to giant airflows known as jetstreams that circle the globe high up in the atmosphere, forming huge waves between the Equator and the Poles.
Each year, extreme rainfall events cause devastation around the globe. For example, extreme rainfall has led to particularly severe flashfloods and mudslides in North India and Pakistan in recent years. "We unravel a global teleconnection pattern that governs the occurrence of extreme rainfall events, and identify specific types of atmospheric waves as their likely main cause. The gained insights into atmospheric dynamics and the relation to extreme rainfall events will help increase our capability to predict such events," says Niklas Boers from the Potsdam Institute for Climate Impact Research (PIK) and Imperial College London, lead-author of the new study.
Links between the Asian Monsoon and events for example in Europe
"The new technique applied to satellite data shows very surprising relationships between extreme rainfall events in different regions around the world," says co-author Brian Hoskins, chair of the Grantham Institute at Imperial College.
"For example, extreme events in the South Asian Summer Monsoon are, on average, linked to events in the East Asian, African, European and North American regions. Although rains in Europe do not cause the rain in Pakistan and India, they belong to the same atmospheric wave pattern, with the European rains being triggered first. This should provide a strong test for weather and climate models and gives promise of better predictions."
High-end mathematics and interdisciplinary science yield results with huge practical relevance
By breaking the globe into a grid, the team could see where events occurred and statistically determine their relations – even if the events did not occur at the same time. The researchers could thereby detect so far invisible patterns.
"This frontier interdisciplinary study, combining complex network theory and atmospheric science, yields breakthrough insights in studying extreme rainfall," says co-author Jürgen Kurths, also from PIK. "Complexity science can hence not only be applied to the spread of epidemics or to opinion formation in social networks, but also to improve our understanding of the atmosphere. Thus our high-end mathematical methods in fact produce results of tremendous practical relevance that can help to keep people safe in the face of climate change and other great challenges of our times."
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