Transition from saliva droplets to solid aerosols in the context of COVID-19 spreading

Stiti, Mehdi; Castanet, Guillaume; Corber, Andrew; Aldén, Marcus; Berrocal, Edouard

doi:10.1016/j.envres.2021.112072

Cited by 34 publications

(36 citation statements)

References 41 publications

(58 reference statements)

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“…For a droplet of pure water, we may assume the vapor pressure at the droplet surface p v,p is the vapor pressure corresponding to the droplet temperature p v,p = p sat (T p ), as we considered the air film around the droplet to be fully-saturated. Accurate modeling of the evaporation of saliva can be rather complex, and thus most studies simplify the saliva as an ideal solution of dissolved inorganic salts [9,47,58]. This simplification allows for the estimation of the vapor pressure using Raoult's law,…”

Section: Mass Equationmentioning

confidence: 99%

“…As the droplet's water content evaporates, it may transition from a saliva droplet to a solid residue, featuring a unique behavior; regardless of its initial diameter and the ambient conditions, the final diameter is set to be roughly 20% of the initial droplet diameter [47,48]. This aerosol might remain stable for hours and would nearly suspend in the ambient air due to its small mass [49].…”

Section: Introductionmentioning

confidence: 99%

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Dispersion of Airborne Respiratory Saliva Droplets by Indoor Wake Flows

Avni¹,

Dagan²

2022

Preprint

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A new analysis of the interaction between vortical wake structures and exhaled saliva droplets is conducted in the presented study. We demonstrate how wake flows may alter the droplet and aerosol dispersion, exceeding previously reported settling distances. A dipolar vortex is used to model the wake flow, self-propelling through a cloud of micron-sized evaporating saliva droplets, which are tracked using a Lagrangian method. The droplet's spatial location, velocity, diameter, and temperature are traced, while coupled to their local flow field thereof. Contrary to previous studies of droplet dispersion by vortical flows, a vortex viscous decay model is included. This proves to be essential for accurately predicting the dispersion and settling distances of droplets and aerosols. The non-volatile saliva components are also considered, allowing for properly capturing the dropletaerosol transition while predicting the equilibrium diameter of post evaporation residual aerosols. Moreover, the model is verified with previously published results, yielding an accurate prediction of the droplet's evaporationfalling curves. Using this model, our theoretical analysis reveals non-intuitive interactions between wake flows, droplet relaxation time, gravity, and mass transfer rates. The underlying physical mechanism responsible for the increased dispersion is studied, where aerosols originating from saliva droplets entrap within the vortical structure and subsequently translate to distances two orders of magnitude larger than the size of the vortex. Thus, a new mechanism enhancing the transmission of airborne pathogens is suggested, offering a new outlook on the spreading of airborne-carried pathogens.

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Section: Mass Equationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dispersion of Airborne Respiratory Saliva Droplets by Indoor Wake Flows

Avni¹,

Dagan²

2022

Preprint

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“…The outbreak of SARS, MERS, and the Novel Coronavirus SARS-CoV-2 illustrates that virus transmission and infection are very complex problems. Droplet aerosol is one of the crucial ways for most microorganisms (including viruses, bacteria and fungi) to spread in the air [1][2][3][4]. People usually release droplet aerosols by coughing or breathing, and then the droplet aerosols spread through the air until they are inhaled into the body or deposited on surfaces [5,6].…”

Section: Introductionmentioning

confidence: 99%

Numerical Modeling of Droplet Aerosol Coagulation, Condensation/Evaporation and Deposition Processes

et al. 2022

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The differentially weighted operator-splitting Monte Carlo (DWOSMC) method is further developed to describe the droplet aerosol dynamic behaviors, including coagulation, deposition, condensation, and evaporation processes. It is first proposed that the droplet aerosols will experience firstly condensation and then evaporation, and this phenomenon is first implemented into the Monte Carlo method and sectional method with considering coagulation, deposition, and condensation/evaporation processes in both single-component and two-component aerosol particle systems. It is found that the calculated results of the DWOSMC method agree well with both the analytical solutions and the sectional method. The further developed DWOSMC method can predict the variation of particle number density, total particle volume, mean particle diameter, particle size distributions, and the component-related particle volume densities in both single component and two-component droplet aerosol systems considering coagulation, deposition, and condensation/evaporation processes.

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“…This phenomenon is marked by various characteristics that occur in the environment, such as, for example, relative humidity (RH) and ambient temperature among others, Ugarte-Anero et al [1], Wang et al [10] and Sen et al [11]. Stiti et al [12] shows that a droplet of an initial diameter of 21 µm in 2 seconds could become an aerosol when a temperature above 20ºC and an RH below 80% occurs. Studies such as Xie et al [13], Liu et al [14] and Ugarte-Anero et al [1] state that at higher relative humidity the evaporation time of these is longer.…”

Section: Introductionmentioning

confidence: 99%

“…This phenomenon depends on many factors; the speed at which it is generated, whether we are in a closed or open place, anyhow there is a high-speed wind or a soft breeze, regardless there is ventilation, etc. Stiti [12] has found that a particular 80 µm becomes solid waste before reaching the ground when the person exhaling it has a height of 1.6 meters from the mouth to the ground. CFD studies such as Dbouk et al [15] and Li et al[16] warn that with an external wind greater than 1.1 m/s can reach up to 6 meters away.…”

Section: Introductionmentioning

confidence: 99%

Computational characterization of the behavior of a saliva droplet in a social environment

Fernández-Gámiz

Ugarte-Anero

Portal-Porras

et al. 2022

Preprint

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The conduct of respiratory droplets is the basis of the study to reduce the spread of a virus in society. The pandemic suffered in early 2020 due to COVID-19 shows the lack of research on the evaporation and fate of droplets exhaled in the environment. The current study, attempts to provide solution through computational fluid dynamics techniques based on a multiphase state with the help of Eulerian - Lagrangian techniques to the activity of respiratory droplets. A numerical study has shown how the behavior of droplets of pure water exhaled in the environment after a sneeze or cough have a dynamic equal to the experimental curve of Wells. The droplets of saliva have been introduced as a saline solution. Considering the mass transferred and the turbulence created, the results has showed that the ambient temperature and relative humidity are parameters that significantly affect the evaporation process, and therefore to the fate. Evaporation time tends to be of a higher value when the temperature affecting the environment is lower. With constant parameters of particle diameter and ambient temperature, an increase in relative humidity increases the evaporation time. A larger particle diameter is consequently transported at a greater distance, since the opposite force it affects is the weight. Finally, a neural network based model is presented to predict particle evaporation time.

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Transition from saliva droplets to solid aerosols in the context of COVID-19 spreading

Cited by 34 publications

References 41 publications

Dispersion of Airborne Respiratory Saliva Droplets by Indoor Wake Flows

Dispersion of Airborne Respiratory Saliva Droplets by Indoor Wake Flows

Numerical Modeling of Droplet Aerosol Coagulation, Condensation/Evaporation and Deposition Processes

Computational characterization of the behavior of a saliva droplet in a social environment

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