期刊
INTERNATIONAL JOURNAL OF MULTIPHASE FLOW
卷 132, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijmultiphaseflow.2020.103439
关键词
Airborne transmission; Sneezing; Coughing; Droplet evaporation; Droplet nuclei; Aerosol inhalation; Filtration efficiency of mask
类别
资金
- Office of Naval Research (ONR), Multidisciplinary University Research Initia-tives (MURI) Program [N00014-16-1-2617]
- UF Informatics Institute
- French ANR
- ERS Advanced Grant TRUFLOW
- PRIN project [2017RSH3JY]
- NSF [CBET 2029548]
- Clarkson IGNITE Fellowship
- Smith Family Foundation
- Massachusetts Institute of Technology (MIT) Policy Lab
- MIT Reed Fund
- Esther and Harold E. Edgerton Career Development chair at MIT
- National Science Foundation [1546990, 2026225]
- Div Of Chem, Bioeng, Env, & Transp Sys
- Directorate For Engineering [2026225, 1546990] Funding Source: National Science Foundation
The COVID-19 pandemic has strikingly demonstrated how important it is to develop fundamental knowledge related to the generation, transport and inhalation of pathogen-laden droplets and their subsequent possible fate as airborne particles, or aerosols, in the context of human to human transmission. It is also increasingly clear that airborne transmission is an important contributor to rapid spreading of the disease. In this paper, we discuss the processes of droplet generation by exhalation, their potential transformation into airborne particles by evaporation, transport over long distances by the exhaled puff and by ambient air turbulence, and their final inhalation by the receiving host as interconnected multiphase flow processes. A simple model for the time evolution of droplet/aerosol concentration is presented based on a theoretical analysis of the relevant physical processes. The modeling framework along with detailed experiments and simulations can be used to study a wide variety of scenarios involving breathing, talking, coughing and sneezing and in a number of environmental conditions, as humid or dry atmosphere, confined or open environment. Although a number of questions remain open on the physics of evaporation and coupling with persistence of the virus, it is clear that with a more reliable understanding of the underlying flow physics of virus transmission one can set the foundation for an improved methodology in designing case-specific social distancing and infection control guidelines. (C) 2020 Elsevier Ltd. All rights reserved.
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