When an unexpected rainstorm leaves you soaking wet, it is an annoyance. When a drought leads to fires, crop failures, and water shortages, the significance of weather becomes vitally important.
If you could control the weather, would you?
Small amounts of rain can mean the difference between struggle and success. For nearly 80 years, an approach called cloud seeding has, in theory, given people the ability to get more rain and snow from storms and make hailstorms less severe. But only recently have scientists been able to peer into clouds and begin to understand how effective cloud seeding really is.
In this episode of “The Conversation Weekly,” we speak with three researchers about the simple yet murky science of cloud seeding, the economic effects it can have on agriculture, and research that may allow governments to use cloud seeding in more places.
Hard to gauge
Katja Friedrich, a professor of atmospheric and oceanic sciences at the University of Colorado, Boulder in the U.S., is a leading researcher on cloud seeding. “When we do cloud seeding, we are looking for clouds that have tiny super-cooled liquid droplets,” she explains. Silver iodide is very similar in structure to an ice crystal. When the droplets touch a particle of silver iodide, “they freeze, then they can start merging with other ice crystals, become snowflakes and fall out of the cloud.”
While the process is fairly straightforward, measuring its effectiveness in the real world is not, according to Friedrich. “The problem is that once we modify a cloud, it’s really difficult to say what would’ve happened if you hadn’t cloud-seeded.” It’s hard enough to predict weather without messing with it artificially.
In 2017, Friedrich’s research group had a breakthrough in measuring the effect of cloud seeding. “We flew some aircraft, released silver iodide, and generated these clouds that were like these six exact lines that were downstream of where the aircraft were seeding,” she says.
They then had a second aircraft fly through the clouds. “We could actually quantify how much snow we could produce by two hours of cloud seeding.” That effect, according to research on cloud seeding, is an increase in precipitation of somewhere around five to 20 percent or 30 percent, depending on conditions.
Measuring the effect on precipitation — whether rain or snow — directly may have taken complex science and a bit of luck, but in places that have been using cloud seeding for long periods of time, the economic benefits are shockingly clear.
Dean Bangsund is a researcher at North Dakota State University who studies the economics of agriculture. “We have a high amount of hail damage in North Dakota,” said Bangsund. For decades, the state government has been using cloud seeding to reduce hail damage, as cloud seeding leads to the formation of more pieces of smaller hail compared to fewer pieces of larger hail. “It doesn’t 100 percent eliminate hail; it’s designed to soften the impact.”
Every 10 years, the state of North Dakota does an analysis on the economic impacts of the cloud seeding program, measuring both reductions in hail damage and benefits from increased rain. Bangsund led the last report and says that for every dollar spent on the cloud seeding program, “we are looking at something that is anywhere from $8 or $9 in benefit on the really lowest scale, up to probably $20 of impact per acre.” With millions of acres of agricultural fields in the cloud seeding area, that is a massive economic benefit.
Both Freidrich and Bangsund emphasized that cloud seeding, while effective in some cases, cannot be used everywhere. There is also a lot of uncertainty in how much of an effect it has. One way to improve the effectiveness and applicability of cloud seeding is by improving the seed. Linda Zou is a professor of civil infrastructure and environmental engineering at Khalifa University in the United Arab Emirates.
Her work has focused on developing a replacement for silver iodide, and her lab has developed what she calls a nanopowder. “I start with table salt, which is sodium chloride,” says Zou. “This desirable-sized crystal is then coated with a thin nanomaterial layer of titanium dioxide.” When salt gets wet, it melts and forms a droplet that can efficiently merge with other droplets and fall from a cloud. Titanium dioxide attracts water. Put the two together, and you get a very effective cloud-seeding material.
From indoor experiments, Zou found that “with the nanopowders, there are 2.9 times the formation of larger-size water droplets.” These nanopowders can also form ice crystals at warmer temperatures and less humidity than silver iodide.
As Zou says, “if the material you are releasing is more reactive and can work in a much wider range of conditions, that means no matter when you decide to use it, the chance of success will be greater.”
This article was originally published on The Conversation by Daniel Merino and Nehal El-Hadi. Read the original article here.