Abstract
We study the spreading of viruses, such as SARS-CoV-2, by airborne aerosols, via a new first-passage-time problem for Lagrangian tracers that are advected by a turbulent flow: By direct numerical simulations of the three-dimensional (3D) incompressible, Navier-Stokes equation, we obtain the time $t_R$ at which a tracer, initially at the origin of a sphere of radius $R$, crosses the surface of the sphere \textit{for the first time}. We obtain the probability distribution function $\mathcal{P}(R,t_R)$ and show that it displays two qualitatively different behaviors: (a) for $R \ll L_{\rm I}$, $\mathcal{P}(R,t_R)$ has a power-law tail $\sim t_R^{-\alpha}$, with the exponent $\alpha = 4$ and $L_{\rm I}$ the integral scale of the turbulent flow; (b) for $l_{\rm I} \lesssim R $, the tail of $\mathcal{P}(R,t_R)$ decays exponentially. We develop models that allow us to obtain these asymptotic behaviors analytically. We show how to use $\mathcal{P}(R,t_R)$ to develop social-distancing guidelines for the mitigation of the spreading of airborne aerosols with viruses such as SARS-CoV-2.
Highlights
By 1 June 2020 (14:31 GMT) the COVID-19 coronavirus pandemic had affected 213 countries and territories and 2 international conveyances; the numbers of cases and deaths were, respectively, 6 300 444 and 374 527 [1]
If tR is the time at which a tracer, initially at the origin of a sphere of radius R, crosses the surface of the sphere for the first time, what is the probability distribution function (PDF) P (R, tR)? The answer to this question is of central importance in both fundamental nonequilibrium statistical mechanics [19,20,21,22,23] and in understanding the dispersal of tracers by a turbulent flow, a problem whose significance cannot be overemphasized, for it is of relevance to the advection of (a) airborne viruses, as Published by the American Physical Society
To obtain the statistical properties of Lagrangian tracers, which are advected by this turbulent flow, we seed the flow with Np independent identical tracer particles
Summary
By 1 June 2020 (14:31 GMT) the COVID-19 coronavirus pandemic had affected 213 countries and territories and 2 international conveyances; the numbers of cases and deaths were, respectively, 6 300 444 and 374 527 [1]. (2) Second, transmission of this virus can occur because of airborne aerosols, such as (a) a cloud of fine droplets, with diameters smaller than 5 μm, emitted by an infected person while speaking loudly [6], or (b) the SARS-CoV-2 RNA on fine, suspended particulate matter [7] These aerosols may remain suspended in the air for a long time. We can study the spread of viruses, such as SARS-CoV-2, via the airborne-aerosol route, by considering the advection of such tracers by turbulent fluid flows. To calculate the time it takes for an aerosol particle to reach the distance R for the first time and to calculate the probability distribution function (PDF) of the first-passage time of a tracer in a turbulent flow If tR is the time at which a tracer, initially at the origin of a sphere of radius R, crosses the surface of the sphere for the first time, what is the probability distribution function (PDF) P (R, tR)? The answer to this question is of central importance in both fundamental nonequilibrium statistical mechanics [19,20,21,22,23] and in understanding the dispersal of tracers by a turbulent flow, a problem whose significance cannot be overemphasized, for it is of relevance to the advection of (a) airborne viruses, as
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