Majid Rezaei scite author profile

Airborne transmission is considered as an important route for the spread of infectious diseases, such as SARS-CoV-2, and is primarily determined by the droplet sedimentation time, i.e., the time droplets spend in air before reaching the ground. Evaporation increases the sedimentation time by reducing the droplet mass. In fact, small droplets can, depending on their solute content, almost completely evaporate during their descent to the ground and remain airborne as so-called droplet nuclei for a long time. Considering that viruses possibly remain infectious in aerosols for hours, droplet nuclei formation can substantially increase the infectious viral air load. Accordingly, the physical-chemical factors that control droplet evaporation and sedimentation times and play important roles in determining the infection risk from airborne respiratory droplets are reviewed in this article.

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The surface charge density effect on the electro-osmotic flow in a nanochannel: a molecular dynamics study

Rezaei

2014

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Molecular dynamics study of an electro-kinetic fluid transport in a charged nanochannel based on the role of the stern layer

Rezaei

Azimian

Toghraie

2015

Physica A: Statistical Mechanics and its Applications

102

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Viscous interfacial layer formation causes electroosmotic mobility reversal in monovalent electrolytes

Rezaei

Azimian

Pishevar

et al. 2018

Phys. Chem. Chem. Phys.

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We study the ion density, shear viscosity and electroosmotic mobility of an aqueous monovalent electrolyte at a charged solid surface using molecular dynamics simulations. Upon increasing the surface charge density, ions are displaced first from the diffuse layer to the outer Helmholtz layer, increasing its viscosity, and subsequently to the hydrodynamically stagnant inner Helmholtz layer. The ion redistribution causes both charge inversion and reversal of the electroosmotic mobility. Because of the surface-charge dependent interfacial hydrodynamic properties, however, the charge density of mobility reversal differs from the charge density of charge inversion, depending on the salt concentration and the chemical details of the ions and the surface. Mobility reversal cannot be described by an effective slip boundary condition alone - the spatial dependence of the viscosity is essential.

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Majid Rezaei

Airborne virus transmission via respiratory droplets: Effects of droplet evaporation and sedimentation

The surface charge density effect on the electro-osmotic flow in a nanochannel: a molecular dynamics study

Molecular dynamics study of an electro-kinetic fluid transport in a charged nanochannel based on the role of the stern layer

Viscous interfacial layer formation causes electroosmotic mobility reversal in monovalent electrolytes

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