Spray That Stays
When farmers spray their fields with pesticides or orange growers spray water on their crops to prevent frost damage, only about 2 percent of the spray sticks to the plants. The rest of the droplets either bounce right back off the leaves or get blown away by the wind. All that waste costs money and, in the case of pesticide application, contributes to pollution of waterways and exposes farmers unnecessarily to hazardous chemicals. But a team of MIT researchers has found a way to fix that.
A clever combination of inexpensive additives allowed the researchers, led by associate professor of mechanical engineering Kripa Varanasi and grad student Maher Damak, to drastically cut down on the amount of liquid that bounces off, potentially making it possible to use just one-tenth as much pesticide or other spray as would otherwise be needed.
Previous attempts to reduce this droplet bounce rate have relied on additives such as surfactants, soaplike chemicals that reduce the surface tension of the droplets and cause them to spread more. But tests have shown that this yields only a small improvement; the speedy droplets bounce off while the surface tension is still changing, and the surfactants cause the spray to form smaller droplets that are more easily blown away.
The new approach uses two different kinds of polymer additives, each added to a separate portion of the spray. One gives its part of the solution a negative electric charge; the other causes a positive charge. When two of the oppositely charged droplets meet on a leaf, they form a hydrophilic (water-attracting) “defect” that sticks to the surface and makes other droplets more likely to adhere.
The project was developed in collaboration with the MIT Tata Center for Technology and Design, which aims to develop technologies that can benefit communities in India and throughout the developing world. Spraying of pesticides there is typically done manually with tanks carried on farmers’ backs, and since the cost of pesticides can be a significant par of a farmer’s budget, reducing the amount that’s wasted could improve the overall economics of small-scale farming. It could also reduce soil and water pollution and spare farmers excessive exposure to the spray chemicals. And for those spraying water, limiting the waste of often-limited freshwater resources can be significant.
“We can use normal sprayers, with two tanks at a time, and add one material to one tank and the oppositely charged material to the other,” Damak says. The farmer “would do everything as usual, just adding our solutions.”
—David L. Chandler
www.technologyreview.com November/December 2016 MIT News 9