Evaluating a Transparent Coating on a Face Shield for Repelling Airborne Respiratory Droplets

Overview

Journal Phys Fluids (1994)

Publisher American Institute of Physics

Date 2021 Nov 22

PMID 34803361

Citations 2

Authors

Bibek Kumar

Sanghamitro Chatterjee

Amit Agrawal

Rajneesh Bhardwaj

Affiliations

Soon will be listed here.

Abstract

A face shield is an important personal protective equipment to avoid the airborne transmission of COVID-19. We assess a transparent coating on a face shield that repels airborne respiratory droplets to mitigate the spread of COVID-19. The surface of the available face shield is hydrophilic and exhibits high contact angle hysteresis. The impacting droplets stick on it, resulting in an enhanced risk of fomite transmission of the disease. Further, it may get wetted in the rain, and moisture may condense on it in the presence of large humidity, which may blur the user's vision. Therefore, the present study aims to improve the effectiveness of a face shield. Our measurements demonstrate that the face shield, coated by silica nanoparticles solution, becomes superhydrophobic and results in a nominal hysteresis to the underlying surface. We employ high-speed visualization to record the impact dynamics of microliter droplets with a varying impact velocity and angle of attack on coated and non-coated surfaces. While the droplet on non-coated surface sticks to it, in the coated surface the droplets bounce off and roll down the surface, for a wide range of Weber number. We develop an analytical model and present a regime map of the bouncing and non-bouncing events, parametrized with respect to the wettability, hysteresis of the surface, and the Weber number. The present measurements provide the fundamental insights of the bouncing droplet impact dynamics and show that the coated face shield is potentially more effective in suppressing the airborne and fomite transmission.

Citing Articles

Improving Indoor Air Ventilation by a Ceiling Fan to Mitigate Aerosols Transmission.

Mallah S, Behera S, Sharma A, Agrawal A, Bhardwaj R Trans Indian Natl Acad Eng. 2023; 8(1):171-182.

PMID: 36742163 PMC: 9887580. DOI: 10.1007/s41403-023-00387-x.

Development and evaluation of a fluidic facemask for airborne transmission mitigation.

Keisar D, Garzozi A, Shoham M, Greenblatt D Exp Therm Fluid Sci. 2022; 141:110777.

PMID: 36158451 PMC: 9482797. DOI: 10.1016/j.expthermflusci.2022.110777.

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