Sneezing and asymptomatic virus transmission

Busco, Giacomo; Yang, Se Ro; Seo, Joseph; Hassan, Yassin A.

doi:10.1063/5.0019090

Cited by 171 publications

(187 citation statements)

References 25 publications

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“…Computational fluid dynamics has been used in many studies to investigate aerosol transport in outdoor conditions, 14 indoor conditions such as hospitals, 6,15 and even inside the human airway system with good agreement with the experimental data. 16,17 During the COVID-19 pandemic, significant efforts have been made to develop computational fluid dynamics models of the human sneeze, 18 investigate mask mechanics, 19 and study aerosol transport and air flow in different environments and conditions such as aircrafts, 20 vehicular cabins, 1 urinals and toilets, 21,22 public spaces, 23 and indoor spaces. 24,25 Despite these efforts, to the authors’ knowledge, no studies have investigated aerosol transport in a classroom environment although classroom sizes, the air conditioning layout, and aerosol source distribution are characteristically different than hospital care units and other indoor spaces discussed in the literature.…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of aerosol transport in a classroom with relevance to COVID-19

et al. 2020

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The present study investigates aerosol transport and surface deposition in a realistic classroom environment using computational fluid-particle dynamics simulations. Effects of particle size, aerosol source location, glass barriers, and windows are explored. While aerosol transport in air exhibits some stochasticity, it is found that a significant fraction (24%–50%) of particles smaller than 15 µ m exit the system within 15 min through the air conditioning system. Particles larger than 20 µ m almost entirely deposit on the ground, desks, and nearby surfaces in the room. Source location strongly influences the trajectory and deposition distribution of the exhaled aerosol particles and affects the effectiveness of mitigation measures such as glass barriers. Glass barriers are found to reduce the aerosol transmission of 1 µ m particles from the source individual to others separated by at least 2.4 m by ∼92%. By opening windows, the particle exit fraction can be increased by ∼38% compared to the case with closed windows and reduces aerosol deposition on people in the room. On average, ∼69% of 1 µ m particles exit the system when the windows are open.

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Section: Introductionmentioning

confidence: 99%

Numerical investigation of aerosol transport in a classroom with relevance to COVID-19

et al. 2020

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“…However, such direct numerical simulations are highly nontrivial, too. It has been attempted with Euler-Lagrangian approaches with Reynolds-averaged Navier-Stokes (RANS) approximations for a single droplet [46], for multiple droplets [47][48][49] and large eddy simulations (LES) [50], which however are insufficient to properly resolve the small scales of the mixing process, which are crucial for the droplet evaporation. Also temperature and humidity fields are not fully coupled, which however determine the evaporation rate and thus the lifetime of the droplets and are essential to properly describe their collective effects.…”

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confidence: 99%

Extended lifetime of respiratory droplets in a turbulent vapour puff and its implications on airborne disease transmission

Chong

Hori

et al. 2020

Preprint

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To mitigate the COVID-19 pandemic, it is key to slow down the spreading of the life-threatening coronavirus (SARS-CoV-2). This spreading mainly occurs through virus-laden droplets expelled at speaking, screaming, shouting, singing, coughing, sneezing, or even breathing [1-7]. To reduce infections through such respiratory droplets, authorities all over the world have introduced the so-called "2-meter distance rule" or "6-foot rule". However, there is increasing empirical evidence, e.g. through the analysis of super-spreading events [6, 8-11], that airborne transmission of the coronavirus over much larger distances plays a major role [1-3, 7, 12-15], with tremendous implications for the risk assessment of coronavirus transmission. It is key to better and fundamentally understand the environmental ambient conditions under which airborne transmission of the coronavirus is likely to occur, in order to be able to control and adapt them. Here we employ direct numerical simulations of a typical respiratory aerosol in a turbulent jet of the respiratory event within a Lagrangian-Eulerian approach [16-18] with 5000 droplets, coupled to the ambient velocity, temperature, and humidity fields to allow for exchange of mass and heat [19] and to realistically account for the droplet evaporation under different ambient conditions. We found that for an ambient relative humidity of 50% the lifetime of the smallest droplets of our study with initial diameter of 10 μm gets extended by a factor of more than 30 as compared to what is suggested by the classical picture of Wells [20, 21], due to collective effects during droplet evaporation and the role of the respiratory humidity [22], while the larger droplets basically behave ballistically. With increasing ambient relative humidity the extension of the lifetimes of the small droplets further increases and goes up to 150 times for 90% relative humidity, implying more than two meters advection range of the respiratory droplets within one second. Smaller droplets live even longer and travel further. Our results may explain why COVID-19 superspreading events can occur for large ambient relative humidity such as in cooled-down meat-processing plants [10] or in pubs with poor ventilation. We anticipate our tool and approach to be starting points for larger parameter studies and for optimizing ventilation and indoor humidity controlling concepts, which in the upcoming autumn and winter both will be key in mitigating the COVID-19 pandemic.

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“…Small droplets were diluted in the air with million particles which may cause diseases within 6 m in theory. Moreover, in Busco et al (2020) research work, the sneezing zone which may contain virus carriers like droplets or aerosols was modeled by using CFD method. It was proved in this investigation that the biomechanics of sneezing can be predicted by the signal generated from contractions or relaxations of head muscles; Dbouk and Drikakis (2020a) analyzed the effect of the wind speed on the transmission of coughing droplets and found 2 m social distance may not sufficiently prevent pathogen transmission.…”

Section: Introductionmentioning

confidence: 99%

The role of computational fluid dynamics tools on investigation of pathogen transmission: Prevention and control

Peng

Chen

Liu

2020

Science of The Total Environment

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Transmission mechanics of infectious pathogen in various environments are of great complexity and has always been attracting many researchers' attention. As a cost-effective and powerful method, Computational Fluid Dynamics (CFD) plays an important role in numerically solving environmental fluid mechanics. Besides, with the development of computer science, an increasing number of researchers start to analyze pathogen transmission by using CFD methods. Inspired by the impact of COVID-19, this review summarizes research works of pathogen transmission based on CFD methods with different models and algorithms. Defining the pathogen as the particle or gaseous in CFD simulation is a common method and epidemic models are used in some investigations to rise the authenticity of calculation. Although it is not so difficult to describe the physical characteristics of pathogens, how to describe the biological characteristics of it is still a big challenge in the CFD simulation. A series of investigations which analyzed pathogen transmission in different environments (hospital, teaching building, etc) demonstrated the effect of airflow on pathogen transmission and emphasized the importance of reasonable ventilation. Finally, this review presented three advanced methods: LBM method, Porous Media method, and Web-based forecasting method. Although CFD methods mentioned in this review may not alleviate the current pandemic situation, it helps researchers realize the transmission mechanisms of pathogens like viruses and bacteria and provides guidelines for reducing infection risk in epidemic or pandemic situations.

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Sneezing and asymptomatic virus transmission

Cited by 171 publications

References 25 publications

Numerical investigation of aerosol transport in a classroom with relevance to COVID-19

Numerical investigation of aerosol transport in a classroom with relevance to COVID-19

Extended lifetime of respiratory droplets in a turbulent vapour puff and its implications on airborne disease transmission

The role of computational fluid dynamics tools on investigation of pathogen transmission: Prevention and control

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