NIST researchers put masks under the microscope to see how well different fabrics filter out virus-filled droplets and aerosols
To understand how something works, it helps to see it up close. A team of NIST researchers took this approach when studying the fabric masks that people wear to slow the spread of COVID-19. Those masks work by blocking some of the virus-filled droplets and smaller particles, called aerosols, that an infected person exhales, and they also offer some protection to the wearer by filtering incoming air. The researchers wanted to know how well different fabrics filter out those particles and what makes some fabrics better filters than others.
“Their research indicates that that cotton fabrics tend to perform better than synthetics, with cotton flannels being particularly effective. After being exposed to the moisture in a person’s breath, cotton fabrics perform better still.”
Polyester is a synthetic material that, like many fabrics, is made up of individual fibers bundled into yarns then woven together. This image shows the cross-sectional shapes of the individual fibers. The researchers used images such as this one to measure the width of the individual fibers — a key variable that affects particle filtration.
The entire scale bar in this image is 125 micrometers, or millionths of a meter, wide — a bit wider than an average human hair.
This image shows the cross-section of a cotton flannel and its over/under weave. In addition to measuring the width of individual fibers, the researchers used images like this one to measure the thickness of the fabrics — another important variable that affects their ability to filter particles.
This image shows top-down views of cotton flannel (left) and polyester (right). The weave of the cotton flannel is hidden below a disorganized network of crisscrossing fibers. These raised fibers make flannel feel soft to the touch. In contrast, the fibers in this polyester are very organized and consistent.
This image shows the individual fibers in cotton flannel. When you breathe through a mask, the air flows around these fibers and the aerosols are pulled along for the ride. The aerosols can be very small, but they do have some mass. As the air bends and twists around the fibers, some of the aerosols can’t turn fast enough and smash into and stick to them. NIST researcher Chris Zangmeister likens this to the scene in Star Wars: The Empire Strikes Back when starfighters are streaking through the asteroid field. Only the smaller ships could turn fast enough. The Star Destroyer couldn’t make it through.
While cotton is best for the fabric masks that the general public uses, medical-grade masks are a different story. This false-color image shows a cross-section of one layer of an N95 respirator mask, including filtering material, shown in purple, and protective material around it. This layered structure then repeats for added protection. The filtering material is made by melting and then air-blowing polypropylene, a type of plastic, into a chaotic web. The fibers are far smaller and have much greater surface area than cotton fibers, which is one reason this is an especially effective filtering material.
N95 respirators get their name because they filter out 95% of particles that are 0.3 millionths of a meter in size. Their filtration performance is well known because there have long been standards for medical-grade masks. The first standards for fabric masks were recently released. The NIST studies described on this page and studies by other organizations contributed to the development of those standards, which will give people in nonmedical fields information on how well their masks work.
NIST scientists are still working to gain a better understanding of the filtration properties of mask fabrics. As people continue to wear fabric masks to limit the spread of COVID-19, or if the need should arise again in the future, these tiny details will help.
This article was originally published on NIST.gov