Standard

Evaporation dynamics of a sessile droplet on glass surfaces with fluoropolymer coatings : Focusing on the final stage of thin droplet evaporation. / Gatapova, Elizaveta Ya; Shonina, Anna M.; Safonov, Alexey I. и др.

в: Soft Matter, Том 14, № 10, 01.01.2018, стр. 1811-1821.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

APA

Vancouver

Gatapova EY, Shonina AM, Safonov AI, Sulyaeva VS, Kabov OA. Evaporation dynamics of a sessile droplet on glass surfaces with fluoropolymer coatings: Focusing on the final stage of thin droplet evaporation. Soft Matter. 2018 янв. 1;14(10):1811-1821. doi: 10.1039/c7sm02192e

Author

Gatapova, Elizaveta Ya ; Shonina, Anna M. ; Safonov, Alexey I. и др. / Evaporation dynamics of a sessile droplet on glass surfaces with fluoropolymer coatings : Focusing on the final stage of thin droplet evaporation. в: Soft Matter. 2018 ; Том 14, № 10. стр. 1811-1821.

BibTeX

@article{5e1c7a9e98f84427b175736089b59695,
title = "Evaporation dynamics of a sessile droplet on glass surfaces with fluoropolymer coatings: Focusing on the final stage of thin droplet evaporation",
abstract = "The evaporation dynamics of a water droplet with an initial volume of 2 μl from glass surfaces with fluoropolymer coatings are investigated using the shadow technique and an optical microscope. The droplet profile for a contact angle of less than 5° is constructed using an image-analyzing interference technique, and evaporation dynamics are investigated at the final stage. We coated the glass slides with a thin film of a fluoropolymer by the hot-wire chemical vapor deposition method at different deposition modes depending on the deposition pressure and the temperature of the activating wire. The resulting surfaces have different structures affecting the wetting properties. Droplet evaporation from a constant contact radius mode in the early stage of evaporation was found followed by the mode where both contact angle and contact radius simultaneously vary in time (final stage) regardless of wettability of the coated surfaces. We found that depinning occurs at small contact angles of 2.2-4.7° for all samples, which are smaller than the measured receding contact angles. This is explained by imbibition of the liquid into the developed surface of the {"}soft{"} coating that leads to formation of thin droplets completely wetting the surface. The final stage, which is little discussed in the literature, is also recorded. We have singled out a substage where the contact line velocity is abruptly increasing for all coated and uncoated surfaces. The critical droplet height corresponding to the transition to this substage is about 2 μm with R/h = 107. The duration of this substage is the same for all coated and uncoated surfaces. Droplets observed at this substage for all the tested surfaces are axisymmetric. The specific evaporation rate clearly demonstrates an abrupt increase at the final substage of the droplet evaporation. The classical R2 law is justified for the complete wetting situation where the droplet is disappearing in an axisymmetric manner.",
keywords = "CONTACT LINE REGION, LIQUID DROPLETS, WATER, ANGLE, IMBIBITION, FLUID, CAPILLARITY, WETTABILITY, TRANSITION, PRESSURE",
author = "Gatapova, {Elizaveta Ya} and Shonina, {Anna M.} and Safonov, {Alexey I.} and Sulyaeva, {Veronica S.} and Kabov, {Oleg A.}",
year = "2018",
month = jan,
day = "1",
doi = "10.1039/c7sm02192e",
language = "English",
volume = "14",
pages = "1811--1821",
journal = "Soft Matter",
issn = "1744-683X",
publisher = "Royal Society of Chemistry",
number = "10",

}

RIS

TY - JOUR

T1 - Evaporation dynamics of a sessile droplet on glass surfaces with fluoropolymer coatings

T2 - Focusing on the final stage of thin droplet evaporation

AU - Gatapova, Elizaveta Ya

AU - Shonina, Anna M.

AU - Safonov, Alexey I.

AU - Sulyaeva, Veronica S.

AU - Kabov, Oleg A.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - The evaporation dynamics of a water droplet with an initial volume of 2 μl from glass surfaces with fluoropolymer coatings are investigated using the shadow technique and an optical microscope. The droplet profile for a contact angle of less than 5° is constructed using an image-analyzing interference technique, and evaporation dynamics are investigated at the final stage. We coated the glass slides with a thin film of a fluoropolymer by the hot-wire chemical vapor deposition method at different deposition modes depending on the deposition pressure and the temperature of the activating wire. The resulting surfaces have different structures affecting the wetting properties. Droplet evaporation from a constant contact radius mode in the early stage of evaporation was found followed by the mode where both contact angle and contact radius simultaneously vary in time (final stage) regardless of wettability of the coated surfaces. We found that depinning occurs at small contact angles of 2.2-4.7° for all samples, which are smaller than the measured receding contact angles. This is explained by imbibition of the liquid into the developed surface of the "soft" coating that leads to formation of thin droplets completely wetting the surface. The final stage, which is little discussed in the literature, is also recorded. We have singled out a substage where the contact line velocity is abruptly increasing for all coated and uncoated surfaces. The critical droplet height corresponding to the transition to this substage is about 2 μm with R/h = 107. The duration of this substage is the same for all coated and uncoated surfaces. Droplets observed at this substage for all the tested surfaces are axisymmetric. The specific evaporation rate clearly demonstrates an abrupt increase at the final substage of the droplet evaporation. The classical R2 law is justified for the complete wetting situation where the droplet is disappearing in an axisymmetric manner.

AB - The evaporation dynamics of a water droplet with an initial volume of 2 μl from glass surfaces with fluoropolymer coatings are investigated using the shadow technique and an optical microscope. The droplet profile for a contact angle of less than 5° is constructed using an image-analyzing interference technique, and evaporation dynamics are investigated at the final stage. We coated the glass slides with a thin film of a fluoropolymer by the hot-wire chemical vapor deposition method at different deposition modes depending on the deposition pressure and the temperature of the activating wire. The resulting surfaces have different structures affecting the wetting properties. Droplet evaporation from a constant contact radius mode in the early stage of evaporation was found followed by the mode where both contact angle and contact radius simultaneously vary in time (final stage) regardless of wettability of the coated surfaces. We found that depinning occurs at small contact angles of 2.2-4.7° for all samples, which are smaller than the measured receding contact angles. This is explained by imbibition of the liquid into the developed surface of the "soft" coating that leads to formation of thin droplets completely wetting the surface. The final stage, which is little discussed in the literature, is also recorded. We have singled out a substage where the contact line velocity is abruptly increasing for all coated and uncoated surfaces. The critical droplet height corresponding to the transition to this substage is about 2 μm with R/h = 107. The duration of this substage is the same for all coated and uncoated surfaces. Droplets observed at this substage for all the tested surfaces are axisymmetric. The specific evaporation rate clearly demonstrates an abrupt increase at the final substage of the droplet evaporation. The classical R2 law is justified for the complete wetting situation where the droplet is disappearing in an axisymmetric manner.

KW - CONTACT LINE REGION

KW - LIQUID DROPLETS

KW - WATER

KW - ANGLE

KW - IMBIBITION

KW - FLUID

KW - CAPILLARITY

KW - WETTABILITY

KW - TRANSITION

KW - PRESSURE

UR - http://www.scopus.com/inward/record.url?scp=85043402362&partnerID=8YFLogxK

U2 - 10.1039/c7sm02192e

DO - 10.1039/c7sm02192e

M3 - Article

C2 - 29442108

AN - SCOPUS:85043402362

VL - 14

SP - 1811

EP - 1821

JO - Soft Matter

JF - Soft Matter

SN - 1744-683X

IS - 10

ER -

ID: 10421668