Face shape influences mask fit, suggests problems with double masking against COVID-19
Proper fit crucial for optimal mask protection
- Date:
- May 3, 2022
- Source:
- American Institute of Physics
- Summary:
- In a new study, researchers used principal component analysis along with fluid dynamics simulation models to show the crucial importance of proper fit for all types of masks and how face shape influences the most ideal fit. They modeled a moderate cough jet from a mouth of an adult male wearing a cloth mask over the nose and mouth with elastic bands wrapped around the ears and calculated the maximum volume flow rates through the front of mask and peripheral gaps at different material porosity levels.
- Share:
In its updated guidance at the start of 2022, the U.S. Centers for Disease Control and Prevention said loosely woven cloth masks offer the least protection against COVID-19, and N95 and KN95 masks offer the most protection. Still, after more than two years since the pandemic began, there is not a full understanding of mask characteristics for the most optimal protection.
In Physics of Fluids, published by AIP Publishing, researchers at Florida State University and Johns Hopkins University use principal component analysis (PCA) along with fluid dynamics simulation models to show the crucial importance of proper fit for all types of masks and how face shape influences the most ideal fit.
The study suggests double masking with improperly fitted masks may not significantly improve mask efficiency and produces a false sense of security.
More layers mean a less porous face covering, leading to more flow forced out of the perimeter gaps (sides, top, and bottom) in masks with a less secure fit. Double layers increase filtering efficiency only with good mask fit but could also lead to breathing difficulties.
The researchers modeled a moderate cough jet from a mouth of an adult male wearing a cloth mask over the nose and mouth with elastic bands wrapped around the ears. They calculated the maximum volume flow rates through the front of mask and peripheral gaps at different material porosity levels.
For a more realistic 3D face shape and size, the researchers used PCA that integrated 100 adult male and 100 adult female heads retrieved from head scan data at Basel University in Switzerland. PCA condenses large sets of variables while retaining most of information.
Their model showed how the slight asymmetry typical in all facial structures can affect proper mask fitting. For example, a mask can have a tighter fit on the left side of the face than on the right side.
"Facial asymmetry is almost imperceivable to the eye but is made obvious by the cough flow through the mask," said co-author Tomas Solano, from Florida State University. "For this particular case, the only unfiltered leakage observed is through the top. However, for different face shapes, leakage through the bottom and sides of the mask is also possible."
Creating "designer masks" customized to each person's face is not practical at scale. Still, PCA-based simulations can be used to design better masks for different populations by revealing general differences between male and female or child versus elderly facial structures and the associated air flow through masks.
Story Source:
Materials provided by American Institute of Physics. Note: Content may be edited for style and length.
Journal Reference:
- Tomas Solano, Chuanxin Ni, Rajat Mittal, Kourosh Shoele. Perimeter leakage of face masks and its effect on the mask's efficacy. Physics of Fluids, 2022; 34 (5): 051902 DOI: 10.1063/5.0086320
Cite This Page: