Colliding respiratory jets as a mechanism of air exchange and pathogen transport during conversations

Giri, Arghyanir; Biswas, Neelakash; Chase, Danielle L.; Xue, Nan; Abkarian, Manouk; Mendez, Simon; Saha, Sandeep; Stone, Howard A.

doi:10.1017/jfm.2021.915

Cited by 11 publications

(30 citation statements)

References 37 publications

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“…We therefore do not Flow E13-7 incorporate the thermodynamics of evaporation in this study, and treat small droplets and droplet nuclei as interchangeable; we refer to both as 'aerosols'. This is consistent with Abkarian et al (2020), Yang et al (2020) and Giri et al (2022), who have not considered effects of droplet evaporation in their speechflow simulation/modelling. The resulting governing equations, namely the Boussinesq-Navier-Stokes equations, the continuity equation and the scalar transport equations, are solved using the finite volume DNS solver, Megha-5 (for further details, see appendix A).…”

Section: Computational Set-up and Parameters Of Simulationsupporting

confidence: 88%

“…It is worth noting that our grid resolution is better than that used in the DNS of studies on cough flows by Chong et al (2021) and Rosti et al (2021) when adjusted for Reynolds number, since our Reynolds number is much lower than that used in these studies (see table S1 (supplementary material)). While the DNS of conversation by Giri et al (2022) uses a grid size of 2 mm which is smaller than ours, in view of the above discussion, we see our grid size of 256 × 128 × 128 to be adequate. This exercise serves us well in reducing the computational cost, and enables us to report results from a large number of simulations (nearly 25).…”

Section: Grid Resolution and Validationmentioning

confidence: 68%

“…A recent study by Poydenot et al. (2021) estimates to be as high as , and we have included this value in ‘set 3’, with and same as those in set 2. Incidentally, the parameters in set 3 are the same as used by Giri et al. (2022) for estimating the probability of infection when the speaker is a ‘super-titerer’ (i.e. a person who has very high viral load in their saliva).…”

Section: Discussionmentioning

confidence: 99%

“…The other factors that influence the risk of infection are the duration of speech as discussed in § 3.3 and the measure of total viral exposure used in calculating the probability of infection. For example, the method used by Giri et al. (2022), which is essentially the same as that proposed by Yang et al. (2020), considers only the inhaled virions and therefore results in probabilities lower than our estimates, which also include viral exposure to eyes and mouth. Furthermore, the results presented here are relevant for poorly ventilated spaces whereas a cross-ventilation can make a difference in the number of ingested virions.…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, N II,i /max(N II,i ) is significantly reduced for y s /L s > 0.3, implying that for a given separation distance between two people, the viral load during a short conversation can be expected to be low if the condition y s L s /3 is satisfied. Giri et al (2022) found the 'critical' vertical separation for a maximum exposure to infected aerosols during a conversation to be 2y s /(L s tan(𝛼)) ≈ 0.83 (where 𝛼 is the jet half-angle), which translates into y s /L s ≈ 0.087, using 𝛼 = 11.8 • (Giri et al, 2022). They did this exercise for L s = 1 m. This value is somewhat smaller than the y s /L s ≈ 0.12 that we obtained for maximum aerosol exposure to person 2 for L s = 1.2 m (figure 6b).…”

Section: Viral Exposure and Infection Probability For Cases I And Iimentioning

confidence: 99%

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Virus transmission by aerosol transport during short conversations

Singhal

Ravichandran

Govindarajan

et al. 2022

Flow

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The SARS-CoV-2 is transmitted not only through coughing, but also through breathing, speaking or singing. We perform direct numerical simulations of the turbulent transport of potentially infectious aerosols in short conversations, involving repetitive phrases separated by quiescent intervals. We estimate that buoyancy effects due to droplet evaporation are small, and neglect them. A two-way conversation is shown to significantly reduce the aerosol exposure compared with a relative monologue by one person and relative silence of the other. This is because of the ‘cancelling’ effect produced by the two interacting speech jets. Unequal conversation is shown to significantly increase the infection risk to the person who talks less. Interestingly, a small height difference is worse for infection spread, due to reduced interference between the speech jets, than two faces at the same level. For small axial separation, speech jets show large oscillations and reach the other person intermittently. We suggest a range of lateral separations between two people to minimize transmission risk. A realistic estimate of the infection probability is provided by including exposure through the eyes and mouth, in addition to the more common method of using inhaled virions alone. We expect that our results will provide useful inputs to epidemiological models and to disease management.

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Section: Computational Set-up and Parameters Of Simulationsupporting

confidence: 88%

Section: Grid Resolution and Validationmentioning

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Viral Exposure and Infection Probability For Cases I And Iimentioning

confidence: 99%

See 3 more Smart Citations

Virus transmission by aerosol transport during short conversations

Singhal

Ravichandran

Govindarajan

et al. 2022

Flow

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From Microscopic Droplets to Macroscopic Crowds: Crossing the Scales in Models of Short‐Range Respiratory Disease Transmission, with Application to COVID‐19

2023

Self Cite

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Short‐range exposure to airborne virus‐laden respiratory droplets is an effective transmission route of respiratory diseases, as exemplified by Coronavirus Disease 2019 (COVID‐19). In order to assess the risks associated with this pathway in daily‐life settings involving tens to hundreds of individuals, the chasm needs to be bridged between fluid dynamical simulations and population‐scale epidemiological models. This is achieved by simulating droplet trajectories at the microscale in numerous ambient flows, coarse‐graining their results into spatio‐temporal maps of viral concentration around the emitter, and coupling these maps to field‐data about pedestrian crowds in different scenarios (streets, train stations, markets, queues, and street cafés). At the individual scale, the results highlight the paramount importance of the velocity of the ambient air flow relative to the emitter's motion. This aerodynamic effect, which disperses infectious aerosols, prevails over all other environmental variables. At the crowd's scale, the method yields a ranking of the scenarios by the risks of new infections, dominated by the street cafés and then the outdoor market. While the effect of light winds on the qualitative ranking is fairly marginal, even the most modest air flows dramatically lower the quantitative rates of new infections.

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The onset of turbulence in decelerating diverging channel flows

Sarath

Manu

2023

J. Fluid Mech.

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This work investigates the stability and transition to turbulence in a diverging channel subjected to a time-varying trapezoidal-shaped inflow boundary condition. Numerical simulations are performed for different deceleration rates and Reynolds numbers while maintaining a constant acceleration rate. The flow transition begins with two-dimensional primary instability with the formation of inflectional velocity profiles, followed by local separation and the emergence of an array of shear layer vortices. We divide simulation cases systematically into three categories based on the onset of secondary instability and the generation of streamwise vorticity. At low and medium Reynolds numbers (type I), the spanwise vortex rolls formed by inflectional instability remain two-dimensional and diffuse at the channel centre without exhibiting further instabilities. At high Reynolds numbers and deceleration rates (type II), the rolled shear layer exhibits secondary instability during the zero mean inflow phase, followed by local incipient turbulent structure formation. The streamwise vorticity that develops over the shear layer structures causes oscillations with a spanwise wavelength similar to those associated with the elliptic instability in a counter-rotating vortex pair. Using the Lamb–Oseen approximation of vortices in conjunction with the dynamic mode decomposition algorithm of the three-dimensional flow field, we captured successfully the characteristics of the secondary instability. The third category (type III) is characterized by periodic unsteady separation, secondary instability, and merging of shear layer vortices, which occurs when Reynolds numbers are high and deceleration rates are low.

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Colliding respiratory jets as a mechanism of air exchange and pathogen transport during conversations

Cited by 11 publications

References 37 publications

Virus transmission by aerosol transport during short conversations

Virus transmission by aerosol transport during short conversations

From Microscopic Droplets to Macroscopic Crowds: Crossing the Scales in Models of Short‐Range Respiratory Disease Transmission, with Application to COVID‐19

The onset of turbulence in decelerating diverging channel flows

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