Global warming incrementally boosts the intensity of extreme rainfall at higher altitudes, putting 2 billion people living in or downstream from mountains at greater risk of floods and landslides, researchers said Wednesday.
Each degree Celsius of warming increases the density of major downpours by 15 percent at elevations above 2,000 meters, they reported in the journal Nature.
On top of that, each additional 1,000 meters of altitude adds another 1 percent of rainfall.
A world, in other words, 3 degrees Celsius hotter than preindustrial levels will see the likelihood of potentially devastating deluges multiply by nearly half.
The findings underscore the vulnerability of infrastructure not designed to withstand extreme flooding events, the authors warned.
Earth's surface has already warmed 1.2 degrees Celsius, enough to amplify record-breaking downpours that put huge swathes of Pakistan under water last summer, and parts of California earlier this year.
On current policy trends, the planet will warm 2.8 degrees Celsius by century's end, according to the UN's IPCC climate science advisory panel.
The new study, based on data covering the last 70 years, and climate-model projections, found two main drivers behind the upsurge in extreme rainfall events at altitude in a warming world.
The first is simply more water: scientists have long known that every 1 degree Celsius increase boosts the amount of moisture in the atmosphere by 7 percent.
A girl walks in the pouring rain. /CFP
From snow to rain
Since the 1950s, heavy rainfall has become more frequent and intense across most parts of the world, according to the World Weather Attribution (WWA) consortium, which teases out the impact of climate change on specific extreme weather events, including heatwaves, droughts and tropical storms.
Extreme rainfall is more common and intense because of human-caused climate change in Europe, most of Asia, central and eastern North America, and parts of South America, Africa and Australia, the WWA has found.
The second factor uncovered by researchers was more surprising.
"This is first time that anyone has looked at whether those intense precipitation events fall as rain or snow," said lead author Mohammed Ombadi, a researcher at Lawrence Berkeley National Laboratory in California.
"Unlike snowfall, rainfall triggers runoff more rapidly, leading to a higher risk of flooding, landslide hazards and soil erosion."
Ombadi speculated that a higher rate of snow-turned-to-rain observed between 2,500 and 3,000 meters was due to precipitation at that altitude occurring at just below freezing point.
The mountainous regions and adjacent flood plains likely to experience the biggest impacts from extreme rainfall events are in and around the Himalayas and North America's Pacific mountain ranges, according to the study.
The findings focused only on the Northern Hemisphere due to a lack of observational data from below the equator.
The regions most affected should prepare "robust climate adaptation plans," the authors said.
"We need to consider this increase in rainfall extremes in the design and building of dams, highways, railroads and other infrastructure if we want to make sure they will remain sustainable in a warmer climate," said Ombadi.
High-risk areas will either need to be avoided altogether, or built up with engineering solutions that can protect the communities living there, he added.
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