October 5, 2020
News Release

Dust Dampens Albedo Effect, Spurs Snowmelt in the Heights of the Himalayas

Specks blowing in from Africa, Middle East exert enormous effect on climate

Himalayas

© S. Hanusch | Shutterstock.com

RICHLAND, Wash. — Dust blowing onto high mountains in the western Himalayas is a bigger factor than previously thought in hastening the melting of snow there, researchers show in a study published Oct. 5 in Nature Climate Change.

That’s because dust— lots of it in the Himalayas— absorbs sunlight, heating the snow that surrounds it.  

“It turns out that dust blowing hundreds of miles from parts of Africa and Asia and landing at very high elevations has a broad impact on the snow cycle in a region that is home to one of the largest masses of snow and ice on Earth,” said Yun Qian, atmospheric scientist at the U.S. Department of Energy’s Pacific Northwest National Laboratory.

Qian and Chandan Sarangi, formerly a postdoctoral associate at PNNL and now at the Indian Institute of Technology Madras in India, are corresponding authors of the study.

More than 700 million people in southeast Asia, as well as parts of China and India, depend on melting snow in the Himalayas for much of their freshwater needs in summer and early fall, driving the urgency of scientists ferreting out the factors that influence earlier snowmelt in the region.

In a study funded by NASA, scientists analyzed some of the most detailed satellite images ever taken of the Himalayas to measure aerosols, elevation, and surface characteristics such as the presence of dust or pollution on snow.

Of dust, soot, sun and snow: The albedo effect

Dark objects on or in snow absorb sunlight more effectively than pure white snow, whose reflectivity fends off sunlight so forcefully that snow can be blinding on a bright, sunny day. But snow near an object that absorbs sunlight— like snow on a dark-colored car where some of the roof is exposed— heats up and melts faster than pristine snow.

Scientists use the word “albedo” to discuss how well a surface reflects sunlight. Dirty snow has a low albedo, while pure snow has a high albedo. Dust and soot lower snow’s albedo, causing the snow to absorb more light, heating up and melting snow faster.

The albedo effect at high elevations is crucial to life for millions of people who rely on snowmelt for their drinking water. Darker, dirtier snow melts faster than pure snow, changing the timing and amount of snowmelt and affecting agriculture and other aspects of life.

Dust in Himalayas
Dust that blows in from Africa, the Middle East and Asia collects in snow high in the Himalayas, darkening the snow, absorbing sunlight and hastening snowmelt. Here, dust from Pakistan and India collects in the Himalayas. Photo courtesy of Jacques Descloitres | NASA
 

The powerful effect of dirty snow

The team found that dust plays a much larger role melting snow than soot and other forms of pollution, known as black carbon, at elevations above 4,500 meters. Below that, black carbon dominates.

It's a surprise for scientists, who note that far more studies have explored the role of black carbon than dust in snowmelt.

The dust blows into the western Himalayas from the west— from the Thar Desert in northwestern India, from Saudi Arabia and even from the Sahara in Africa. The dust comes in winds thousands of feet high, at what scientists call elevated aerosol layers.

While desert dust is natural, the scientists say that its prevalence in the Himalayas is not without human influence. Increasing temperatures have changed atmospheric circulation, affecting the winds that can carry dust hundreds or thousands of miles. Changing land-use patterns and increasing development have reduced vegetation, liberating dust that otherwise would have been tied to the land.

Qian was one of the first scientists to develop sophisticated modeling tools to analyze how impurities like dust and soot affect the rate at which snow melts. He did that early work more than a decade ago in the mountains of the U.S. West.

“It’s likely that these results translate to other high mountain chains, including the Rockies, Sierras and Cascades in North America and several mountain chains in Asia, such as the Caucuses and Urals,” Qian said.

Much of the data for the study comes from satellite images obtained by multiple NASA instruments, including NASA’s Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO), OMI (Ozone Monitoring Instrument), and MODIS (Moderate Resolution Imaging Spectroradiometer). These instruments can detect dust and other aerosols in the atmosphere, and measure snow coverage and albedo, from hundreds of miles above Earth. Equipped with data from these and other sources, the PNNL team did extensive computer modeling of the processes at work.

Dust with staying power

Dust particles usually stay in snow longer than black carbon, the scientists noted. Dust is usually a little bit bigger; it’s not as easily blown off the snow and it doesn’t fall through snow as easily. There’s also a lot more of it.

“The snow in the western Himalayas is receding rapidly. We need to understand why this is happening, and we need to understand the implications,” said Sarangi. “We’ve shown that dust can be a big contributor to the accelerated snowmelt. Hundreds of millions of people in the region rely on snow for their drinking water – we need to consider factors like dust seriously to understand what’s happening.”

Himalayas
The Himalayas contain one of biggest masses of snow and ice on Earth and provide drinking water for hundreds of millions of people. The timing of the annual snowmelt is key for life in the region— and scientists have found that this timing is affected by dust much more than previously thought. © S. Hanusch | Shutterstock.com

Qian notes that as the climate warms and snow lines move higher, scientists expect the role of dust to become even more pronounced in the Himalayas— a region that, aside from the Arctic and Antarctic regions, contains the biggest mass of snow and ice on the planet.

Additional PNNL authors of the paper are Ruby Leung and Duli Chand. Other authors include Karl Rittger of the University of Colorado Boulder, Kat Bormann of the Jet Propulsion Laboratory and Thomas Painter of the University of California, Los Angeles. Painter has been studying the phenomenon for decades, since noticing the effect of dust on snowmelt while climbing a peak in Colorado.

“This paper shows that dust, working together with increased black carbon and rising carbon dioxide levels, is a dominant driver of snowmelt in the Himalayas,” Painter said. “If we realize that increasing dust is a huge problem and that it’s driving much of the snow and glacier melt, we can take actions to reduce dust emissions and buy ourselves time to finally deal with carbon dioxide emissions.”

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Pacific Northwest National Laboratory draws on signature capabilities in chemistry, Earth sciences, and data analytics to advance scientific discovery and create solutions to the nation's toughest challenges in energy resiliency and national security. Founded in 1965, PNNL is operated by Battelle for the U.S. Department of Energy's Office of Science. DOE's Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit PNNL's News Center. Follow us on FacebookInstagramLinkedIn and Twitter.

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About PNNL

Pacific Northwest National Laboratory draws on its distinguishing strengths in chemistry, Earth sciences, biology and data science to advance scientific knowledge and address challenges in sustainable energy and national security. Founded in 1965, PNNL is operated by Battelle for the Department of Energy’s Office of Science, which is the single largest supporter of basic research in the physical sciences in the United States. DOE’s Office of Science is working to address some of the most pressing challenges of our time. For more information, visit https://www.energy.gov/science/. For more information on PNNL, visit PNNL's News Center. Follow us on Twitter, Facebook, LinkedIn and Instagram.

Published: October 5, 2020

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