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Laser Light Sheet Offers Insight into Snowflake Acceleration

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A winter wonderland calls to mind piles of fluffy, glistening snow. But to reach the ground, snowflakes are swept into the turbulent atmosphere, swirling through the air instead of plummeting directly to the ground.

The path of precipitation is complex but important to more than just skiers assessing the potential powder on their alpine vacation or school children hoping for a snow day. Determining snowflake fall speed is crucial for predicting weather patterns and measuring climate change.

In order to study the acceleration of snowflakes in atmospheric turbulence, researchers from the University of Utah deployed a tracking system comprised of a laser light sheet and a single-lens reflex (SLR) camera. They found that regardless of turbulence or snowflake type, acceleration follows a universal statistical pattern that can be described as an exponential distribution.
Researchers at the University of Utah found that snowflake accelerations follow a predictable pattern. Namely, an exponential frequency distribution with an exponent of three halves. Courtesy of Pezibear, Pixabay.
Researchers at the University of Utah found that snowflake accelerations follow a predictable pattern. Namely, an exponential frequency distribution with an exponent of three halves. Courtesy of Pezibear, Pixabay.

“Even in the tropics, precipitation often starts its lifetime as snow,” said author Timothy Garrett. “How fast precipitation falls greatly affects storm lifetimes and trajectories and the extent of cloud cover that may amplify or diminish climate change. Just small tweaks in model representations of snowflake fall speed can have important impacts on both storm forecasting and how fast climate can be expected to warm for a given level of elevated greenhouse gas concentrations.”

Set up in a ski area near Salt Lake City, the team battled an unprecedented 900 inches of snow. They simultaneously filmed snowfall and measured atmospheric turbulence. Using their experimental tracking system, they gathered information about snowflake mass, size, and density.

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“Generally, as expected, we find that low-density ‘fluffy’ snowflakes are most responsive to surrounding turbulent eddies,” said Garrett.
Field site near Salt Lake City where researchers battled 900 inches of snow to collect their data. Courtesy of the University of Utah.
Field site near Salt Lake City where researchers battled 900 inches of snow to collect their data. Courtesy of the University of Utah.

Despite the complexity of snowflake crystals, the team found that snowflake accelerations follow a predictable pattern. Namely, an exponential frequency distribution with an exponent of three halves. In analyzing their data, they also discovered that fluctuations in the terminal velocity frequency distribution followed the same pattern.

“Snowflakes are complicated, and turbulence is irregular. The simplicity of the problem is actually quite mysterious, particularly given there is this correspondence between the variability of terminal velocities – something ostensibly independent of turbulence – and accelerations of the snowflakes as they are locally buffeted by turbulence,” said Garrett.

Because size determines terminal velocity, a possible explanation is that the turbulence in clouds that influences snowflake size is related to the turbulence measured at the ground. Yet the factor of three halves remains a mystery.

The researchers will revisit their experiment this winter, using a mist of oil droplets to obtain a closer look at turbulence and its impact on snowflakes.

The research was published in Physics of Fluids (www.doi.org/10.1063/5.0173359).

Published: December 2023
Research & TechnologyImagingLaserslight sheetcamerassingle lens reflexatmosphericturbulencesnowflakessnowflakeaccelerationUniversity of Utahphysics of fluidsTechnology News

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