This is actually really important research as it can help researchers better understand how airborne diseases spread. "It's important to understand how the process of fluid breakup, or fluid fragmentation, happens," Lydia Bourouiba, head of MIT's Fluid Dynamics of Disease Transmission Laboratory said in a statement. "What is the physics of the breakup telling us in terms of droplet size distribution, and the resulting prediction of the downstream range of contamination?"
This isn't Bourouiba's first infectious rodeo, however. This research builds off of her earlier tests that show coughs and sneezes travel up to 200 times farther as these mucus balloons than if they were straight droplets. "What we saw was surprising in many ways," Bourouiba continued. "We expected to see droplets coming out fully formed from the respiratory tract. It turns out that's not the case at all. And this gives us a good baseline to expand our mechanistic understanding of violent expirations." That's all well and good, just be sure to cover your mouth first.
[Image: From the paper, "Visualization of sneeze ejecta: steps of fluid fragmentation leading to respiratory droplets," by B. E. Scharfman, A. H. Techet, J. W. M. Bush, L. Bourouiba.]