How a table modulates the risk of airborne transmission between facing individuals

TL;DR

This study uses high-fidelity simulations to analyze how a table influences airborne transmission risks between facing individuals, revealing that table proximity can both restrict particle spread and increase concentration, affecting transmission dynamics.

Contribution

The paper introduces a detailed simulation-based analysis of how tables modulate airborne transmission, highlighting the role of table distance in flow dynamics and particle deposition.

Findings

Table proximity restricts forward particle spread.

Close tables increase particle concentration and transmission risk.

Tables act as filters, affecting particle size distribution.

Abstract

Airborne transmission has been recognized as an important route of transmission for SARS-CoV-2, the virus responsible for the COVID-19 pandemic. While coughing and sneezing are spectacular sources of production of infected aerosols with far-reaching airflows, the prevalence of asymptomatic transmissions highlighted the importance of social activities. Gathering around a table, a common scenario of human interactions, not only fixes a typical distance between static interlocutors, but influences airborne transmission, by serving both as a flow diverter and a surface for droplet deposition. Here, we use high-fidelity large-eddy simulations to characterize short-range airborne transmission when two people face each other at a typical table. We show that compared to the natural distance travelled by free buoyant puffs and jets, the distance between the table and the emission constitutes a new length scale that modifies downward exhaled flows, common during nose breathing, speech, and laughter. When the table is close to the emitter, its main effect is to restrict the forward spread of emitted particles. However, if the distance between individuals is too short, particles reaching the recipient become more concentrated, rising transmission risks. Additionally, simulations of forceful exhalations, like laughter, demonstrate that the table acts as a filter that collects medium-sized particles that would have remained in the free jet otherwise, but can in that case be involved in the fomite transmission route. The table introduces a cut-off size for particles that depends on the inertia of the exhaled material, thereby modifying the size distribution of particles suspended in the air.