Difference between revisions of "Spatially extended FCS for visualizing and quantifying high-speed multiphase flows in microchannels"

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== Summary==
 
== Summary==
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This article describes a method for measuring the flow velocity inside multi-phase microfluidic channels using using fluorescence imaging.  Multiphase microfluidics, such as droplet microfluidics, has expanded into an important field.  This paper surmises that it would be useful to understand the properties of flows inside such channels.
 
This article describes a method for measuring the flow velocity inside multi-phase microfluidic channels using using fluorescence imaging.  Multiphase microfluidics, such as droplet microfluidics, has expanded into an important field.  This paper surmises that it would be useful to understand the properties of flows inside such channels.
  
A sample microfluidic channel with an approximate depth of 20 microns and a width of 50-75 microns was placed under a confocal microscope.  Fluorescently-labeled particles were then flowed through the channels.  The flow was recorded using a high speed camera.
 
  
The resulting frames were stacked together into a kymograph.  A kymograph is a graphical representation of spatial position over time, where one axis represents timeThis is shown in figure 2 below.
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A sample microfluidic channel with an approximate depth of 20 microns and a width of 50-75 microns was placed under a confocal microscopeFluorescently-labeled particles were then flowed through the channels.  The flow was recorded using a high speed camera. A diagram of the experimental setup is shown below in figure 1:
  
The authors then calculated the auto-correlation of the kymograph to give the flow velocity of the particles. This method works for flows of up to 1cm/s
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[[Image:Caspar_Summary7_Pic1.JPG]]
  
  
[[Image:Caspar_Summary7_Pic1.JPG]]
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The resulting frames were stacked together into a kymograph. A kymograph is a graphical representation of spatial position over time, where one axis represents time.  The kymograph's gray levels were inverted to make the particles stand out in front of a black background.  This is shown below in figure 2:
  
 
[[Image:Caspar_Summary7_Pic2.JPG]]
 
[[Image:Caspar_Summary7_Pic2.JPG]]
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Finally the authors calculated the auto-correlation of the kymograph to give the flow velocity of the particles.  This method works for flows of up to 1cm/s. 
  
 
[[Image:Caspar_Summary7_Pic3.JPG]]
 
[[Image:Caspar_Summary7_Pic3.JPG]]

Revision as of 19:26, 8 November 2010

Original entry: Caspar Floryan, APPHY 225, Fall 2010

Reference

Spatially extended FCS for visualizing and quantifying high-speed multiphase flows in microchannels S.M. Hashmi, M. Loewenberg and E.R. Dufresne, Optics Express, 15 6528 (2007)

Keywords

Microfluidic Flow Kymograph Imaging

Summary

This article describes a method for measuring the flow velocity inside multi-phase microfluidic channels using using fluorescence imaging. Multiphase microfluidics, such as droplet microfluidics, has expanded into an important field. This paper surmises that it would be useful to understand the properties of flows inside such channels.


A sample microfluidic channel with an approximate depth of 20 microns and a width of 50-75 microns was placed under a confocal microscope. Fluorescently-labeled particles were then flowed through the channels. The flow was recorded using a high speed camera. A diagram of the experimental setup is shown below in figure 1:

Caspar Summary7 Pic1.JPG


The resulting frames were stacked together into a kymograph. A kymograph is a graphical representation of spatial position over time, where one axis represents time. The kymograph's gray levels were inverted to make the particles stand out in front of a black background. This is shown below in figure 2:

Caspar Summary7 Pic2.JPG


Finally the authors calculated the auto-correlation of the kymograph to give the flow velocity of the particles. This method works for flows of up to 1cm/s.

Caspar Summary7 Pic3.JPG