Characterizations of particle size distribution of the droplets exhaled by sneeze

Han, Zhizhong; Weng, W.G.; Huang, Qin

doi:10.1098/rsif.2013.0560

Cited by 340 publications

(375 citation statements)

References 54 publications

(105 reference statements)

Supporting

Mentioning

357

Contrasting

Unclassified

Order By: Relevance

“…The number density, velocity and size distributions of droplets ejected by expiratory events have important implications for transmission, and numerous studies have attempted to measure these characteristics (Duguid 1946;Wells 1955;Morawska et al 2009;Xie et al 2009;Han, Weng & Huang 2013;Bourouiba, Dehandschoewercker & Bush 2014;Scharfman et al 2016;Asadi et al 2019). A single sneeze can generate O(10 4 ) or more droplets, with velocities upwards of 20 m s −1 (Han et al 2013). Coughing generates 10-100 times fewer droplets than sneezing, with velocities of approximately 10 m s −1 , but even talking can generate approximately 50 particles per second (Asadi et al 2019).…”

Section: Droplet Characteristicsmentioning

confidence: 99%

The flow physics of COVID-19

2020

View full text Add to dashboard Cite

Section: Droplet Characteristicsmentioning

confidence: 99%

The flow physics of COVID-19

2020

View full text Add to dashboard Cite

“…From another point of view, several research groups found that aerosol particles exhaled by humans are composed of small droplets of airway-lining fluid (Fiegel et al, 2006;Han, Weng & Huang, 2013), and some of these exhaled droplets contain pathogens, such as influenza viruses (Fabian et al, 2008;Milton, Fabian, Cowling, Grantham & McDevitt, 2013), tuberculosis bacteria (Turner & Bothamley, 2014), and severe acute respiratory syndrome viruses (World Health Organization (WHO), 2009). However, the concentrations of overall culturable bioaerosols in exhaled air from humans were not adequately measured in these reference studies.…”

Section: Introductionmentioning

confidence: 99%

Effects of human activities on concentrations of culturable bioaerosols in indoor air environments

Heo

Lim

Kim

et al. 2017

Journal of Aerosol Science

View full text Add to dashboard Cite

A B S T R A C TWe studied the effects of human activity on concentrations of fungal and bacterial bioaerosols in indoor air environments. We conducted measurement experiments for concentrations of bioaerosols and aerosol particles in test chambers with people performing various activities inside. We found that the number of people and human activities had positive correlations with the concentrations of bacterial bioaerosols. However, the concentration of fungal bioaerosols was not influenced by human presence or activities. The findings regarding the concentrations of fungal and bacterial bioaerosols and the effects of human presence and activities will be useful for studying control methods against bioaerosols.

show abstract

“…By adjusting the initial ethanol concentration, samples with two constant octanol/water (OCT/W) ratios of 1/99 and 5/95 were selected for detection, and are presented in Figure 4A. [46] It is also possible for chemical identification from such small volume of highly diluted solution. When the OCT/W ratio is 5/95, the profile of the volume of analyte solution in the range of 0.73-0.45 shows weak fluorescence intensity with a minimum volume of analyte solution of ≈9 µL.…”

Section: Minimal Volume Of Analyte Solution For the Spinning Ouzo Dromentioning

confidence: 99%

“…Such volume required for the sample solution is even smaller than a typical size of a drop from sneezing or coughing. [46] It is also possible for chemical identification from such small volume of highly diluted solution. Figure 4C,D shows the FTIR spectra and corresponding profiles of IR absorbance at 1709 cm −1 of octanol nanodroplets produced by ternary OCT/W/E drops with different initial volumes of nonanoic acid aqueous solutions (10 −5 m).…”

Section: Minimal Volume Of Analyte Solution For the Spinning Ouzo Dromentioning

confidence: 99%

One‐Step Nanoextraction and Ultrafast Microanalysis Based on Nanodroplet Formation in an Evaporating Ternary Liquid Microfilm

Qian

Yamada

Wei

et al. 2019

Adv Materials Technologies

View full text Add to dashboard Cite

in chemical analysis workflow is sample pretreatment to extract the analytes before detection. The recent development of dispersive liquid-liquid microextraction (DLLME) has stimulated progress for extracting and preconcentrating trace hydrophobic analytes from aqueous solutions both rapidly and efficiently. [4][5][6] DLLME is based on spontaneous emulsification upon mixing of a water-insoluble extractant, a dispersive solvent, and an analyte aqueous solution. [7,8] The hydrophobic analyte could be rapidly extracted into extractant nanodroplets because of the higher solubility of the analyte in the extractant than in water. The large surface area of nanodroplets enhances the transfer of the analyte from the surrounding solution to the droplets. Relying on the combination of DLLME and various detection techniques, such as inductively coupled plasma optical emission spectrometry or fluorescence spectrometry, trace chemical analysis has been achieved for diverse applications. [9][10][11] However, these existing approaches require significant improvement due to their time-consuming nature, their requirement for specialized equipment in droplet separation and for large volumes of the analyte solution. [12,13] Many studies have focused on concentrating compounds from a single sessile drop evaporation. [14][15][16][17] A common issue comes from the coffee stain effect that leads to uncontrolled deposition of the analyte on the substrate rather than into a focused spot. Although an evaporating drop can shrink isotropically on superhydrophobic surfaces, micro/nanoscale structures on these surfaces can influence solute deposition, in particular at the final stage of evaporation when the drop size becomes comparable with the structures. [18] Supersensitive detection can be achieved for the materials deposited on highly ordered nanostructures on the substrate by using the plasmonic effect. [19] However, these nanostructures are difficult to fabricate for fast and high throughput analysis. Recent work on drop evaporation of ternary liquid mixtures shows advantageous features that may lead to unpinned drop for solute concentrating. [20,21] Selective evaporation of the volatile co-solvent (ethanol) in the mixture leads to oversaturation of oil and consequently spontaneously formation of tiny droplets. This phenomenon of Preconcentration is key for detection from an extremely low concentration solution, but requires separation steps from a large volume of samples using extracting solvents. Here, a simple approach is presented for ultrafast and sensitive microanalysis from a tiny volume of aqueous solutions. In this approach, liquid-liquid nanoextraction in an evaporating thin liquid film on a spinning substrate is coupled with quantitative analysis in one step. The approach is exemplified using a liquid mixture comprising a target compound to be analyzed in water, mixed with extractant oil and co-solvent ethanol. With rapid evaporation of ethanol, nanodroplets of oil form spontaneously in the film. The compounds are highly conce...

show abstract

Characterizations of particle size distribution of the droplets exhaled by sneeze

Cited by 340 publications

References 54 publications

The flow physics of COVID-19

The flow physics of COVID-19

Effects of human activities on concentrations of culturable bioaerosols in indoor air environments

One‐Step Nanoextraction and Ultrafast Microanalysis Based on Nanodroplet Formation in an Evaporating Ternary Liquid Microfilm

Contact Info

Product

Resources

About