Analysis of capillary filling in nanochannels with electroviscous effects
Files
File version
Author(s)
Yang, Chun
Nguyen, Nam-Trung
Griffith University Author(s)
Primary Supervisor
Other Supervisors
Editor(s)
Date
Size
261122 bytes
File type(s)
application/pdf
Location
License
Abstract
Capillary filling is the key phenomenon in planar chromatography techniques such as paper chromatography and thin layer chromatography. Recent advances in micro/nanotechnologies allow the fabrication of nanoscale structures that can replace the traditional stationary phases such as paper, silica gel, alumina, or cellulose. Thus, understanding capillary filling in a nanochannel helps to advance the development of planar chromatography based on fabricated nanochannels. This paper reports an analysis of the capillary filling process in a nanochannel with consideration of electroviscous effect. In larger scale channels, where the thickness of electrical double layer (EDL) is much smaller than the characteristic length, the formation of the EDL plays an insignificant role in fluid flow. However, in nanochannels, where the EDL thickness is comparable to the characteristic length, its formation contributes to the increase in apparent viscosity of the flow. The results show that the filling process follows the Washburn's equation, where the filled column is proportional to the square root of time, but with a higher apparent viscosity. It is shown that the electroviscous effect is most significant if the ratio between the channel height (h) and the Debye length (? -1) reaches an optimum value (i.e. ?h 蠴). The apparent viscosity is higher with higher zeta potential and lower ion mobility.
Journal Title
Microfluidics and Nanofluidics
Conference Title
Book Title
Edition
Volume
7
Issue
4
Thesis Type
Degree Program
School
Publisher link
Patent number
Funder(s)
Grant identifier(s)
Rights Statement
Rights Statement
© 2009 Springer Berlin Heidelberg. This is an electronic version of an article published in Microfluidics and Nanofluidics, Volume 7, Issue 4, pp 519-530, 2009. Microfluidics and Nanofluidics is available online at: http://link.springer.com/ with the open URL of your article.
Item Access Status
Note
Access the data
Related item(s)
Subject
Mechanical engineering
Engineering practice and education not elsewhere classified
Nanotechnology