Introduction
As airborne transmission of expiratory droplets is one of the important pathways for viral respiratory diseases including the recent pandemic COVID-19 to infect healthy people, it is extremely important to explore and understand the detailed mechanisms of virus spread through airborne expiratory droplets. To reduce the risk of exposure to viral respiratory diseases, the World Health Organization recommends main measures, namely hand hygiene, social distancing, and wearing masks. Among the recommended measures, there is a hot debate about social distancing related to the exposure risk, especially in indoor environments. Through expiratory activities, airborne virus-laden droplets may spread over long distances, such as tens of meters in indoor environments, and remain in the air for a long time, making it an important route of exposure. Unfortunately, the scientific evidence on many public health policies regarding social distancing is still fragmentary. The public has only a rudimentary understanding of airborne transmission of viral respiratory diseases and proper social distancing. To address the concern of "whether the usual social distance is sufficient to avoid airborne infection of expiratory droplets in indoor environments", this project will use systematic, multidisciplinary experimental, theoretical and modelling approaches. The spatiotemporal variations of size distributions, velocity vector fields and airborne dynamics of expiratory droplets generated from people infected with Influenza A or B, and the quantities of influenza virus at different distances from the test subjects will be firstly measured using a suite of the state-of-the-art instruments and methods. Bacteriophage phi 6 will then be used as a surrogate of coronavirus and other human pathogenic enveloped viruses to investigate the survivability and number of viruses in size-resolved droplets at different time and locations from the release point under different environmental conditions (e.g. temperature and relative humidity) with the aid of cultivation method and RT-qPCR technique. Lastly, a versatile model of whole-range airborne transmission will be developed and validated with experimental data to predict the airborne transmission of virus-laden expiratory droplets and the risk of exposure to viable viruses. Different from previous models, more parameters will be integrated, especially including survivability and number of viruses in size-resolved droplets at various distances and time, and impact of droplet concentration on the drag force on droplets under different environmental conditions, into the model for more realistic simulations. The outcomes of the project will be the knowledge necessary to determine proper social distancing in various indoor environments, which will contribute to the control of respiratory infectious diseases.
Related Publications
- Li, X., Chen, Z., Tu, J., Yu, H., Tang, Y.* and Qin, C.* (2024). Impact of impinging jet ventilation on thermal comfort and aerosol transmission: A numerical investigation in a densely-occupied classroom with solar effect. Journal of Building Engineering.
- Qin, C., Cai, S.S., Lyu, X.* and Lu, W.-Z.* (2024). Cross transmission of normal breathing-released contaminants in a general hospital ward with impinging jet supply: A numerical study. Journal of Building Engineering, 92.