Speech can produce jet-like transport relevant to asymptomatic spreading of virus

TL;DR

This study investigates how speech generates jet-like flows that can transport aerosols over distances relevant to virus transmission, highlighting the role of phonetic features in spreading risk.

Contribution

It provides a detailed analysis of airflow during speech, revealing jet-like transport mechanisms influenced by phonetics, which were previously underexplored in disease transmission.

Findings

Speech can produce jet-like flows capable of transporting aerosols over 2 meters.

Plosive sounds like 'P' generate directed, jet-like air flows.

Transport distances vary with speech features, affecting disease spread understanding.

Abstract

Many scientific reports document that asymptomatic and presymptomatic individuals contribute to the spread of COVID-19, probably during conversations in social interactions. Droplet emission occurs during speech, yet few studies document the flow to provide the transport mechanism. This lack of understanding prevents informed public health guidance for risk reduction and mitigation strategies, e.g. the "six-foot rule". Here we analyze flows during breathing and speaking, including phonetic features, using order-of-magnitudes estimates, numerical simulations, and laboratory experiments. We document the spatio-temporal structure of the expelled air flow. Phonetic characteristics of plosive sounds like 'P' lead to enhanced directed transport, including jet-like flows that entrain the surrounding air. We highlight three distinct temporal scaling laws for the transport distance of exhaled material including (i) transport over a short distance ($<$ 0.5 m) in a fraction of a second, with large angular variations due to the complexity of speech, (ii) a longer distance, approximately 1 m, where directed transport is driven by individual vortical puffs corresponding to plosive sounds, and (iii) a distance out to about 2 m, or even further, where sequential plosives in a sentence, corresponding effectively to a train of puffs, create conical, jet-like flows. The latter dictates the long-time transport in a conversation. We believe that this work will inform thinking about the role of ventilation, aerosol transport in disease transmission for humans and other animals, and yield a better understanding of linguistic aerodynamics, i.e., aerophonetics.