https://jamanetwork.com/journals/jama/fullarticle/2763852
Owing to the forward momentum of the cloud, pathogen-bearing droplets
are propelled much farther than if they were emitted in isolation
without a turbulent puff cloud trapping and carrying them forward. Given
various combinations of an individual patient’s physiology and
environmental conditions, such as humidity and temperature, the gas
cloud and its payload of pathogen-bearing droplets of all sizes can
travel 23 to 27 feet (7-8 m).3,4
Importantly, the range of all droplets, large and small, is extended
through their interaction with and trapping within the turbulent gas
cloud, compared with the commonly accepted dichotomized droplet model
that does not account for the possibility of a hot and moist gas cloud.
Moreover, throughout the trajectory, droplets of all sizes settle out or
evaporate at rates that depend not only on their size, but also on the
degree of turbulence and speed of the gas cloud, coupled with the
properties of the ambient environment (temperature, humidity, and
airflow).
Turbulent gas cloud dynamics should influence the design
and recommended use of surgical and other masks. These masks can be
used both for source control (ie, reducing spread from an infected
person) and for protection of the wearer (ie, preventing spread to an
unaffected person). The protective efficacy of N95 masks depends on
their ability to filter incoming air from aerosolized droplet nuclei.
However, these masks are only designed for a certain range of
environmental and local conditions and a limited duration of usage.9
Mask efficacy as source control depends on the ability of the mask to
trap or alter the high-momentum gas cloud emission with its pathogenic
payload. Peak exhalation speeds can reach up to 33 to 100 feet per
second (10-30 m/s), creating a cloud that can span approximately 23 to
27 feet (7-8 m). Protective and source control masks, as well as other
protective equipment, should have the ability to repeatedly withstand
the kind of high-momentum multiphase turbulent gas cloud that may be
ejected during a sneeze or a cough and the exposure from them. Currently
used surgical and N95 masks are not tested for these potential
characteristics of respiratory emissions.
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