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quadgram frequency
who has granted medrxiv78
medrxiv a license to78
a license to display78
license to display the78
display the preprint in78
granted medrxiv a license78
has granted medrxiv a78
to display the preprint78
is the author funder71
the copyright holder for70
copyright holder for this70
was not certified by58
which was not certified58
certified by peer review58
not certified by peer58
severe acute respiratory syndrome57
the preprint in perpetuity50
it is made available45
license it is made45
is made available under45
international license it is45
made available under a45
holder for this preprint42
the number of droplets40
the evolution of the38
for this preprint this37
preprint this version posted37
this preprint this version37
as a function of32
droplets and droplet nuclei28
in terms of the28
of respiratory droplets and28
this this version posted28
this version posted september28
holder for this this28
for this this version28
preprint the copyright holder28
the diameter of the27
of droplets in the27
the size of the26
temperature and relative humidity24
in the absence of23
no reuse allowed without23
airborne droplets and nuclei23
the total number of23
reuse allowed without permission23
acute respiratory syndrome coronavirus23
as shown in fig22
the volume of the21
is shown in fig20
droplets can move in20
on the other hand20
can be expressed as20
available under a perpetuity20
this version posted may19
the severe acute respiratory19
can move in indoor19
in the context of19
how far droplets can19
far droplets can move19
at the droplet surface19
the size distribution of18
heat and mass transfer18
under a is the18
available under a is18
this version posted july18
fall to the ground18
a is the author18
it is clear that17
in the range of17
as well as the17
out of the puff17
of airborne droplets and17
the transmission of covid16
the spread of the16
of the puff and16
infection prevention and control16
on coughing and sneezing16
as shown in figure16
evaporation and dispersion of16
carriage of respiratory droplets16
that remain within the16
move in indoor environments15
the effect of the15
size and the duration15
in the air for15
and the duration of15
the duration of air15
diameter of the droplet15
of the order of15
the size and the15
evolution of the droplet15
of the ejected droplets14
size distribution of droplets14
the droplet surface and14
is the density of14
evolution of the puff14
remain within the puff14
total number of droplets14
the use of a14
in the form of14
the droplet and the14
number of droplets in14
toward understanding the risk13
risk of secondary airborne13
for disease control and13
of secondary airborne infection13
aerosol and surface stability13
emission of respirable pathogens13
as compared with sars13
of the droplet is13
in the presence of13
the probability of infection13
time evolution of the13
clouds and respiratory pathogen13
and relative humidity on13
and respiratory pathogen emissions13
the risk of secondary13
revisiting the wells evaporation13
the evaporation and dispersion13
the trajectory of the13
surface stability of sars13
disease control and prevention13
and surface stability of13
understanding the risk of13
it is important to13
gas clouds and respiratory13
at the mm distance13
a wide range of13
turbulent gas clouds and13
of the droplet nuclei12
droplets that remain within12
is the diameter of12
the time evolution of12
velocity of the droplet12
the world health organization12
the droplet size distribution12
in the case of12
of severe acute respiratory12
is defined as the12
suspended in the air12
the motion of the12
infection control in health12
in the current study12
distance traveled by the12
ejected puff of air12
of the droplet cloud12
the effect of non12
a relative humidity of11
respiratory droplets and droplet11
for infection control in11
u r n a11
o u r n11
by the receiving host11
potential implications for reducing11
ventilation for infection control11
the mass fraction of11
a function of the11
p r o o11
r n a l11
reducing transmission of covid11
r o o f11
the use of masks11
of droplets and aerosols11
in the supporting information11
l p r e11
transmission of infectious agents11
implications for reducing transmission11
natural ventilation for infection11
the presence of non11
for reducing transmission of11
a l p r11
reduce the risk of11
n a l p11
j o u r11
a function of time10
of the droplet and10
the drying time of10
that the effect of10
droplet size distribution is10
of aerosol transmission of10
the distance traveled by10
prevent the spread of10
of water vapor in10
was found to be10
of the puff of10
of an infected person10
it should be noted10
the ejected puff of10
efficacy of face masks10
modes of transmission of10
transmission of the virus10
the initial droplet size10
volume of the puff10
in front of the10
the total mass of10
middle east respiratory syndrome10
distribution of the droplets10
at a distance of10
at a relative humidity10
droplets in the cloud10
in contrast to the10
centers for disease control10
the puff of air10
size distribution of the9
to talking and coughing9
the puff and the9
virus shedding in exhaled9
size in aerosolised pathogen9
of the severe acute9
to account for the9
with a diameter of9
of the droplets exhaled9
the inhomogeneous humidity field9
at the same time9
rapidly fall to the9
sites of origin of9
shedding in exhaled breath9
the rate of evaporation9
between the droplet and9
in aerosolised pathogen transmission9
should be noted that9
n u s c9
speech increase with voice9
particle size distribution of9
the mean number of9
superemission during human speech9
c r i p9
relative humidity on the9
in exhaled breath and9
mean number of droplets9
prevention and control of9
article is protected by9
of particle size in9
and efficacy of face9
u s c r9
has been shown to9
to become droplet nuclei9
and superemission during human9
a large number of9
aerosol emission and superemission9
m a n u9
particle size in aerosolised9
emission and superemission during9
can be used to9
respiratory virus shedding in9
exhaled breath and efficacy9
the role of particle9
that the use of9
the infection rate constant9
during human speech increase9
human speech increase with9
is protected by copyright9
increase with voice loudness9
this article is protected9
a n u s9
the spread of infection9
the survival of the9
r i p t9
of the droplets and9
for health workers treating9
van doremalen et al9
the effect of buoyancy9
breath and efficacy of9
temperature and high humidity9
pressure at the droplet9
water vapor in the9
the droplets exhaled by9
role of particle size9
s c r i9
due to talking and9
plays an important role9
and final sign off8
an order of magnitude8
airborne or droplet precautions8
from an infected person8
a droplet of diameter8
of hospitalized patients with8
the total volume of8
droplet and nuclei concentration8
particle deposition in a8
as will be seen8
droplets exhaled by sneeze8
the evaporation of droplets8
to be the same8
survival of the virus8
droplet precautions for health8
the droplet cloud is8
the radius of the8
air changes per hour8
the ratio of the8
the risk of transmission8
the velocity of the8
can be found in8
laden droplets and aerosols8
characterizations of particle size8
in addition to the8
away from the mouth8
at the mouth opening8
is given by where8
of the puff as8
dynamics and characterization of8
precautions for health workers8
the density of the8
droplets due to talking8
airborne transmission of sars8
immediately at the mouth8
of particle size distribution8
under different weather conditions8
exhaled droplets due to8
puff of air and8
or droplet precautions for8
the center of the8
the absence of gravity8
of the droplets are8
distribution of droplets in8
flow dynamics and characterization8
of the ejected puff8
of the droplet particle8
of face masks in8
airborne droplet and nuclei8
is taken to be8
of respiratory droplets from8
transmission of respiratory viruses8
with the use of8
are assumed to be8
the pareto distribution is8
the growth rate of8
the exhaled breath of8
nasal cavity under cyclic8
on which the droplet8
and relative humidity of8
the droplets expelled during7
and personal protective equipment7
implication for infection prevention7
respiratory specimens of infected7
falling out of the7
available under a author7
an important role in7
of healthy human subjects7
in the air and7
fragmentation leading to respiratory7
of fluid fragmentation leading7
transmission of influenza a7
the airborne droplets and7
east respiratory syndrome coronavirus7
of droplets within the7
load in upper respiratory7
and characterization of a7
specimens of infected patients7
droplets produced by coughing7
high temperature and high7
steps of fluid fragmentation7
study on transport characteristics7
and temperature of the7
findings of this study7
is the drag coefficient7
upper respiratory specimens of7
of the droplet size7
the surface of the7
size of the droplets7
under a author funder7
reported in the literature7
to reduce the risk7
leading to respiratory droplets7
use of a mask7
deposition in a human7
transport characteristics of saliva7
exhaled breath of healthy7
droplet and the surrounding7
is the mass fraction7
characterization of a cough7
the virus in the7
droplets generated by coughing7
in the indoor environment7
on transport characteristics of7
visualization of sneeze ejecta7
of influenza a virus7
by severe acute respiratory7
received number of droplets7
duguid and loudon roberts7
the volume fraction of7
the location of the7
fraction of water vapor7
ambient temperature and humidity7
and droplet size distributions7
dispersion of the virus7
is related to the7
from a human cough7
characteristics of saliva droplets7
of the droplets expelled7
the human nasal cavity7
the evaporation dynamics of7
and dispersion of respiratory7
due to entrainment and7
the analysis of the7
the shape of the7
vapor pressure at the7
size of the droplet7
is a function of7
the magnitude of the7
droplets in the exhaled7
use of face masks7
breath of healthy human7
fluid fragmentation leading to7
in the exhaled breath7
shown in figure s7
the presence of a7
taking into account the7
viral load in upper7
and control of epidemic7
advancement of the microkeratome7
in upper respiratory specimens7
time of a droplet6
linger in the air6
transmission of virus causing6
coughing in a calm6
from the point of6
for a spherical puff6
of droplets that remain6
a distance of m6
the drag coefficient of6
implications for ipc precaution6
evaporation of the droplets6
air jets and droplet6
range of droplet sizes6
entrainment of ambient air6
value of r m6
expiration air jets and6
in the number of6
small speech droplets and6
the propagation of the6
an increase in the6
the filtration efficiencies of6
aerosol transmission of influenza6
equipment contamination by severe6
the air temperature and6
the puff velocity decreases6
that the number of6
that there is no6
in an airliner cabin6
of transmission of virus6
d e d e6
the results of the6
are shown in fig6
can be taken to6
in a calm indoor6
a small amount of6
droplets with laser light6
of infectious agents in6
the difference in the6
saliva droplets produced by6
the virtual origin to6
fluid droplets with laser6
the computational fluid dynamics6
the effect of weather6
m and t e6
for ipc precaution recommendations6
is one of the6
the mass of the6
is consistent with the6
the evaporation of the6
the expansion of the6
with laser light scattering6
the same as that6
respiratory droplets from coughing6
droplet of diameter d6
we find that the6
by coughing in a6
of buoyancy is to6
hot and dry weather6
initial velocity of the6
to be the time6
radius of the droplet6
assessment of hospitalized patients6
e p t e6
a mask is worn6
mass fraction of water6
is clear that the6
close proximity to the6
the human respiratory tract6
is important to note6
of respiratory droplets in6
of the previous sections6
is the mass of6
the evaporation of water6
contamination by severe acute6
in hot and dry6
to the presence of6
characterization of expiration air6
of the puff is6
in a cough jet6
important to note that6
c e p t6
controversy around airborne versus6
droplet size distributions immediately6
on the droplet surface6
the ejected droplets are6
of a susceptible host6
from a symptomatic patient6
fate in indoor environments6
of expiration air jets6
concentration of airborne droplets6
is the volume of6
time it takes for6
from the virtual origin6
personal protective equipment contamination6
versus droplet transmission of6
the spread of droplets6
when a mask is6
the value of r6
can we prevent the6
yes yes yes yes6
of the cloud is6
evaporation time of the6
airborne versus droplet transmission6
air and water vapor6
fallen out of the6
size distributions immediately at6
around airborne versus droplet6
evaporated to become droplet6
d m a n6
the flow resistance of6
given by the puff6
term on the right6
and the number of6
be taken to be6
p t e d6
the airborne lifetime of6
the latent heat of6
at the time of6
of droplet size distribution6
over a wide range6
a c c e6
the fact that the6
the initial velocity of6
distributions immediately at the6
jets and droplet size6
of small speech droplets6
in a human nasal6
droplet transmission of respiratory6
produced by coughing in6
of saliva droplets produced6
the context of covid6
we prevent the spread6
contagion and air hygiene6
flow resistance of the6
a human nasal cavity6
is not sufficient to6
a calm indoor environment6
the temperature of the6
be emphasized that the6
or can we prevent6
used to calculate the6
protect against droplet infection6
by an infected person6
that the value of6
be the same as6
surgical masks and n6
of virus causing covid6
analysis of the previous6
growth rate of the6
the droplets and the6
are more likely to6
protective equipment contamination by6
at the end of6
mean time for a6
number of droplet nuclei6
by the puff model6
droplet fate in indoor6
to obtain the following6
airborne contagion and air6
e d m a6
be seen in section6
on the transmission of6
t e d m6
transition time t tr6
aerosol transmission of infectious6
c c e p6
the spread of respiratory6
there has been a6
of air and the6
dispersion of respiratory droplets6
the evaporation and settling6
virological assessment of hospitalized6
the deposition of the6
protection against droplet infection6
to note that the6
on the basis of6
for small values of6
will be seen in6
it is seen that6
droplets are assumed to6
the mean time for6
droplet and aerosol transmission6
of the exhaled droplets6
droplets expelled from the6
droplet nuclei within the6
the same as the6
oral fluid droplets with6
have fallen out of6
in the transmission of6
within the puff and6
of the number of6
effect of buoyancy is6
the ambient temperature and6
the value of the5
of airborne transmission of5
size from water evaporation5
results of this study5
volunteers were asked to5
as the number of5
droplets by turbulence in5
the edge of the5
drying time of a5
it is necessary to5
in the order of5
in the air are5
some of the droplets5
we assume that the5
the distance between the5
and their potential importance5
human respiratory tract during5
present simple and transparent5
be found in the5
droplets expelled during expiratory5
efficacy of homemade masks5
droplet size distribution and5
transparent algebraic equations that5
by the infected host5
their potential importance in5
the source and sink5
capture the essential physics5
of the survival of5
for the effect of5
the outer borders of5
size distribution and sites5
of the initial droplet5
as predicted by the5
the risk of transmitting5
the strength of the5
from the human respiratory5
the findings of this5
droplets and their potential5
of exhaled droplet nuclei5
declare that they have5
are summarized in table5
equations that capture the5
due to the presence5
transmission of the severe5
reduce the transmission of5
the tx and rx5
physics of virus transmission5
wearing a surgical mask5
the viability of the5
be performed in a5
at each time step5
in the breathing zone5
as discussed in section5
dry air and water5
the data that support5
the transmission of the5
of the virus in5
of temperature and relative5
we observe that the5
head and neck surgery5
review of aerosol transmission5
is similar to the5
potential importance in sars5
vapor in the air5
of the human cough5
the upper bound of5
speech droplets and their5
that support the findings5
deposition in human airways5
the nature of the5
time can be estimated5
motion of the puff5
the form of droplets5
can be written as5
remain in the air5
in the upper respiratory5
of droplets expelled from5
speed of km h5
are given in table5
the filtration efficiency of5
trajectory of the droplets5
the centers for disease5
the advancement of the5
tract during expiratory activities5
of the initial ejected5
airborne transmission of the5
the maximum horizontal distance5
normal and pareto distributions5
remain suspended in the5
is given by the5
the fit of the5
hospitalized patients with covid5
and transparent algebraic equations5
across all droplet sizes5
for the decrease in5
an ecological study of5
the formation of droplets5
also be noted that5
defined in terms of5
the final droplet size5
droplets were predicted to5
where h is the5
droplet nuclei in a5
is the dynamic viscosity5
on the viability of5
of expiratory droplets by5
human nasal cavity under5
the mouth and nose5
the settling velocity of5
or rapidly fall to5
of the aerosol particle5
of the infected person5
enhanced spread of expiratory5
borders of the mask5
due to the settling5
of the initial diameter5
for the evolution of5
is assumed to be5
that capture the essential5
infection state of the5
with an increase in5
the droplets in the5
the evaporation time of5
generated oral fluid droplets5
larger than that of5
can be found elsewhere5
study of droplet infections5
expiratory droplets by turbulence5
be determined by the5
simple and transparent algebraic5
outer borders of the5
long periods of time5
both droplets and aerosols5
the dynamic viscosity of5
as far as m5
when the inhomogeneous humidity5
of the initial velocity5
of this study are5
of origin of droplets5
density of the droplet5
of middle east respiratory5
of the imi system5
time of the droplet5
the frequency of the5
at the point of5
the volume of air5
support the findings of5
on the droplet size5
traveled by the puff5
play a major role5
for the spread of5
in the present work5
m from the face5
spread of expiratory droplets5
world should face the5
to the naked eye5
which corresponds to the5
by turbulence in a5
transmission of infectious diseases5
the number of viral5
on the surface of5
it should also be5
that they have no5
the rate of change5
air temperature and rh5
should also be noted5
origin of droplets expelled5
transmission of the sars5
droplets with initial radii5
airborne lifetime of small5
the world should face5
used in this study5
will fall to the5
on the diffusion of5
d is the droplet5
turbulence in a cough5
and sites of origin5
is the number of5
a balanced salt solution5
of the human face5
this study are available5
the time it takes5
vapor at the droplet5
is presented in fig5
of the puff are5
a few hundreds of5
the direction of the5
droplet evaporation and dispersion5
under the influence of5
from the mouth opening5
reduce the number of5
of water and air5
in human exhaled breath5
capillary bridge of mucus5
the initial diameter of5
which was not peer5
the received number of5
the efficacy of homemade5
expelled from the human5
this is because the5
the drop size distribution5
the risk of infection5
propagation of the cloud5
the entire range of5
the transmission of respiratory5
are shown in table5
respiratory droplets and dropletnuclei5
for coughing and speaking5
the transmission of infectious5
and n respirators are5
the volume flow rate5
data that support the5
the results of this5
health workers treating covid5
of droplets and a5
spread of the disease5
the puff can be5
computational fluid dynamics simulations5
to be smaller than5
distribution and sites of5
lifetime of small speech5
in cold and humid5
the droplets and particles5
the central part of5
of the total mass5
should face the reality5
the fluid dynamics of5
ecological study of droplet5
in the respiratory tract5
is the latent heat5
origin of the droplets5
be taken into account5
of bourouiba et al5
pulled into the sink5
the lower respiratory tract5
m from the person5
droplets within the puff5
ambient temperature and relative5
respiratory tract during expiratory5
the droplets can be5
air temperature and relative5
the inertia of the5
of droplets generated by5
using computational fluid dynamics5
algebraic equations that capture5
of the ambient air5
the spread of covid5
is followed by the5
of the virus to5
assumed to be the5
as given by where5
one of the most5
of the droplets is5
and the risk of5
beyond the outer borders5
are in the range5
simple model for the4
is not any acting4
aerosols in human exhaled4
ac on and windows4
pe q pe v4
stages when the puff4
of disease transmission by4
the end of the4
n u and b4
on and windows closed4
would they protect in4
dispersion of droplet nuclei4
a transition time t4
the different models of4
velocity has dropped to4
v v p dt4
environment is at ambient4
that there was a4
in the nasal cavity4
of the respiratory tract4
masks for aerosol infection4
the initial droplet diameter4
financial interests or personal4
to be transmitted through4
in the wind direction4
the sites of origin4
droplets in the aerosol4
buoyancy of the puff4
the puff of exhaled4
droplet size distributions at4
the size and concentration4
a function of droplet4
mass of the droplet4
work reported in this4
are moving at velocities4
the puff continues to4
s e and the4
put together the different4
inhalation by the receiving4
the size of droplets4
is smaller than the4
strong effect on the4
was nasal passage model4
t lim and t4
units the puff has4
diseases such as influenza4
airborne spread of expiratory4
buoyancy and air drag4
shows the evolution of4
is seen that the4
cluster of pneumonia associated4
by the world health4
more than a few4
of water vapor at4
at the onset of4
the difference between the4
expiratory droplet nuclei between4
temperature difference between the4
rate of the droplets4
of the respiratory droplets4
is the gravitational acceleration4
droplet transmission to humans4
familial cluster of pneumonia4
the droplet spreading distance4
the development of a4
time for a droplet4
simple negative pressure mask4
acceleration due to gravity4
v on which the4
does it take for4
the point of ejection4
away from the source4
forces acting on the4
count probability is a4
airborne droplet transmission to4
that could have appeared4
that the evaporation of4
concentration of droplets generated4
the initially ejected droplets4
of this study was4
less than a second4
of droplets when the4
wind speed of km4
influenza among health care4
as a result the4
airflow and contaminant transport4
the form of a4
the puff remains coherent4
together the different models4
person of a respiratory4
vivo measurements of inhalability4
the infection state of4
transition time can be4
consider the evolution of4
it is possible to4
the authors declare that4
for t t lim4
and droplet evolution described4
a negative pressure mask4
if we ignore the4
medrxiv preprint figure s4
of the exhaled air4
when an infected person4
relationships that could have4
chances of the survival4
interests or personal relationships4
spread of the virus4
an infected person of4
still fluid settling velocity4
the results show that4
reported in this paper4
higher than that of4
c d is the4
shows the evolution starting4
from the surrounding air4
final droplet size distribution4
in accordance with the4
most of the virus4
the local fluid velocity4
from the pareto distribution4
the airborne droplet and4
d is the drag4
smaller than d e4
first term on the4
cannot decrease below of4
on the order of4
the temperature difference between4
is warmer than the4
assessing the effectiveness of4
part of the human4
prone acute respiratory infections4
theoretical framework can be4
effectiveness of face masks4
from the respiratory tract4
of droplets and the4
of drag and the4
effects of drag and4
droplets in microfluidic devices4
a familial cluster of4
samplers in calm air4
s s s e4
can be obtained for4
visible to the naked4
limit of the imi4
the effect of brownian4
s e and t4
to the mm distance4
the efficacy of facemasks4
of a droplet and4
the droplet diameter at4
the vertical motion of4
of the tx and4
controlled comparison in patients4
in close proximity to4
authors declare that they4
separate the two different4
particles in calm air4
was estimated to be4
the chances of the4
contaminant transport in an4
airborne for many minutes4
droplets of various sizes4
expelled during expiratory activities4
the acceleration due to4
of the third term4
viruses in the environment4
in a recent study4
the presence of the4
of symptomatic seasonal influenza4
number of viral copies4
pneumonia associated with the4
median evaporation time of4
aerosol particles in calm4
and the sites of4
the number of the4
edge of the mask4
time regimes of t4
is dictated by the4
in this study to4
number of emitted virions4
acute respiratory infections in4
humidity reduce the transmission4
preventing influenza among health4
the output of the4
initial droplet size and4
exited droplets whose initial4
relative humidity of the4
of a droplet is4
size distribution is modeled4
the initial size of4
different time regimes of4
are shown in figure4
decrease below of the4
infectious virus in exhaled4
characterized by its initial4
we are interested in4
droplets and nuclei that4
influence the work reported4
can be rewritten as4
the droplet nuclei cloud4
droplets expelled by a4
obtained by taking the4
for preventing influenza among4
velocities and ejection angles4
which the puff is4
filtration efficiencies of different4
and later within the4
of origin of the4
latent heat of vaporization4
to the pressure drop4
and nuclei that remain4
the period of breathing4
dv v v p4
total number of droplet4
the number and size4
the concentration of virus4
particle transport and deposition4
the facemasks have been4
the efficacy of the4
not any acting force4
center for disease control4
high humidity reduce the4
in the size regime4
current pandemic may not4
the floor within a4
recognition of aerosol transmission4
influenza cases from a4
size that is dictated4
in the development of4
velocity and temperature of4
in the direction of4
there is not any4
no known competing financial4
spread of respiratory droplets4
the droplet size spectrum4
probability is a probability4
measurements of inhalability of4
fall out of the4
cotton masks in blocking4
of masks and other4
for the volume of4
is the thermal conductivity4
effect of surgical masks4
cough with and without4
the formation of aerosol4
the puff model is4
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droplet nuclei containing the3
dispersion of exhaled droplet3
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median evaporation time was3
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framework to capture the3
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data and velocity history3
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disease transmission via drops3
detection of airborne viruses3
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initial droplet size distribution3
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guidelines for environmental infection3
particles in a human3
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aspiration and filtration efficiencies3
assisted lasik flap creation3
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fluid dynamics simulations of3
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on the analysis of3
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since most of the3
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droplet nuclei of size3
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humidity field induced by3
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distribution of the droplet3
at the location of3
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greater than m s3
also shows that the3
investigate the effect of3
trapped by the mask3
order of magnitude higher3
the airborne diameters of3
of environmental factors on3
parameters such as the3
pressure mask technique to3
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direction in which these3
droplets and aerosols generated3
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dispersion of airborne sputum3
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of a continuum of3
through respiratory droplets is3
up to m s3
coronavirus survival on surfaces3
and the ambient air3
is the sherwood number3
of the virus is3
is the volume fraction3
assumed that the air3
can be obtained by3
in airborne transmission of3
from to m s3
being taken over by3
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on the effect of3
the cross section of3
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a major role in3
design of the work3
effect of gravity is3
particles in the air3
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acute respiratory diseases in3
velocity of m s3
the ground due to3
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has a strong effect3
droplets generated during speech3
the reynolds number re3
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during sneezing or coughing3
to of its initial3
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within the cloud have3
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hospital ward with three3
the surgical mask worn3
cold and dry conditions3
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d p is the3
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other personal protective equipment3
aerobiology and its role3
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this paper is to3
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droplet nuclei as a3
spread of the exhaled3
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total mass of liquid3
increases the probability of3
insertion of ventilation tube3
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for each droplet size3
transport of inertial particles3
the cistern tank was3
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myringotomy with ventilation tube3
distance traveled by a3
left side was nasal3
face and the mask3
is of utmost importance3
the emission strength of3
droplets with a diameter3
droplets are slowed down3
maximum distance traversed was3
to the public health3
association between ambient temperature3
myringotomy with insertion of3
the left of the3
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rate of the droplet3
a droplet can travel3
evaluation of the filtration3
before being taken over3
during coughing and sneezing3
size becomes smaller than3
hygroscopic growth of the3
the settling of large3
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in the proximity of3
the mass flux of3
the number of covid3
if the environment is3
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asymptomatic contact in germany3
are trapped by the3
masks in the covid3
droplets expelled during coughing3
to make the physics3
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particle sizing and detection3
considering a uniform gap3
the dry air and3
droplets falling out of3
droplets when the capillary3
derivation of the probability3
the minimum droplet size3
airborne infectious disease and3
a higher risk of3
particle inhalation and deposition3
two orders of magnitude3
in the large droplets3
the rapid spread of3
inhalation and deposition in3
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nuclei in a two3
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the reproductive number of3
volume fraction of non3
the inhalation flow rate3
interdependence of evaporation and3
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of oral fluid droplets3
effect of brownian force3
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results indicate that the3
cover the entire size3
number per unit volume3
droplet size from water3
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as a random process3
the cumulative number of3
estimates of airborne virion3
of infectious respiratory diseases3
emission rates while speaking3
fraction of the droplets3
number of droplets expelled3
between the droplets and3
traveled by the droplets3
activities the size and3
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mask fitted with suction3
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droplet evaporation to determine3
which these droplets are3
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distance recommended by the3
contributions to the conception3
the settling times of3
have a ballistic trajectory3
diseases in health care3
respiratory droplets that are3
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the derivation of the3
droplet nuclei after evaporation3
environmental infection control in3
early transmission dynamics in3
the dominant route for3
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ignore the effects of3
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mm from the mouth3
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reduce the probability of3
time scale problem of3
dispersal during nasoendoscopy and3
motion of the droplet3
masks and common fabric3
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a better understanding of3
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the first step of3
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the size range of3
the suppression of pulmonary3
small amount of non3
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airborne virion emission rates3
spread of the covid3
to the left of3
expelled by a sneeze3
travellers at points of3
forward motion of the3
figure c shows the3
droplets of diameter d3
the viscosity of air3
rapid and efficient manner3
it can be seen3
flow rate of the3
assess the spread of3
are plotted in fig3
of fuel droplet heating3
on the environmental conditions3
advanced models of fuel3
to determine whether droplets3
s to m s3
phase change and deposition3
number of infected persons3
were solved using the3
video s shows the3
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setting of an operating3
lower size detection limit3
the likelihood of the3
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the environment is contaminated3
the capillary bridge of3
the position of the3
assumed to be in3
have been associated with3
droplets expelled during singing3
united states a familial3
the design of the3
relative to the initial3