Difference between revisions of "Surface Morphology of Drying Latex Films: Multiple Ring Formation"

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==Summary==
 
==Summary==
 
[[Image:Shmuylovich fig1a.jpg|center|thumb|upright=3.5|Rings formed by the evaporation of a solution containing 0.88 um particles. The drop volume is written below each image, while the outer ring diameter is written above.]]
 
[[Image:Shmuylovich fig1a.jpg|center|thumb|upright=3.5|Rings formed by the evaporation of a solution containing 0.88 um particles. The drop volume is written below each image, while the outer ring diameter is written above.]]
The experiment was simple: a small drop of a monodisperse solution of particles (either 0.008% (w/w) solution of 0.88 um diameter particles, or 0.01% solution of 3.15 um particles) was placed on a glass microscope slide. The drying process was then captured on camera. As the solution evaporated it formed concentric rings of particle arrays.
 
 
[[Image:Shmuylovich fig4a.jpg|thumb|The "pinning" and "un-pinning" of the contact line of the solution with 0.88 um particles. Insets show two histograms: one of the distances traversed between "sticking events", and one of the time between pinning events.]]
 
[[Image:Shmuylovich fig4a.jpg|thumb|The "pinning" and "un-pinning" of the contact line of the solution with 0.88 um particles. Insets show two histograms: one of the distances traversed between "sticking events", and one of the time between pinning events.]]
 +
The experiment was simple: a small drop of a monodisperse solution of particles (either 0.008% (w/w) solution of 0.88 um diameter particles, or 0.01% solution of 3.15 um particles) was placed on a glass microscope slide. The drying process was then captured on camera. As the solution evaporated it formed concentric rings of particle arrays.
 +
  
 
It was observed that a larger drops size produced more rings that covered a wider area. Using solutions of larger particles decreased the number of rings, but did not have a significant effect on the diameter of the outer rings. Studying the dynamics of the contact line during liquid evaporation revealed that the motion is not continuous. Rather, the contact line became "pinned" and unable to move for periods of time, with different parts of the same ring being able to be pinned and unpinned at the same time.
 
It was observed that a larger drops size produced more rings that covered a wider area. Using solutions of larger particles decreased the number of rings, but did not have a significant effect on the diameter of the outer rings. Studying the dynamics of the contact line during liquid evaporation revealed that the motion is not continuous. Rather, the contact line became "pinned" and unable to move for periods of time, with different parts of the same ring being able to be pinned and unpinned at the same time.

Revision as of 02:10, 5 December 2009

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Reference

Surface morphology of drying latex films: multiple ring formation

Shmuylovich L, Shen AQ, Stone HA

Langmuir 18: 3441-3445 (2002)

Summary

Rings formed by the evaporation of a solution containing 0.88 um particles. The drop volume is written below each image, while the outer ring diameter is written above.
The "pinning" and "un-pinning" of the contact line of the solution with 0.88 um particles. Insets show two histograms: one of the distances traversed between "sticking events", and one of the time between pinning events.

The experiment was simple: a small drop of a monodisperse solution of particles (either 0.008% (w/w) solution of 0.88 um diameter particles, or 0.01% solution of 3.15 um particles) was placed on a glass microscope slide. The drying process was then captured on camera. As the solution evaporated it formed concentric rings of particle arrays.


It was observed that a larger drops size produced more rings that covered a wider area. Using solutions of larger particles decreased the number of rings, but did not have a significant effect on the diameter of the outer rings. Studying the dynamics of the contact line during liquid evaporation revealed that the motion is not continuous. Rather, the contact line became "pinned" and unable to move for periods of time, with different parts of the same ring being able to be pinned and unpinned at the same time.

Soft Matter Aspects

Two-dimensional hexagonal crystaline formed by 3.15 um particles.

The formation of ordered arrays by evaporating solutions of particles has many applications in material science. This paper presented data that explored the effects on contact line behavior of varying sizes of drops or particles. It also presents a model to explain the observed contact line pinning. In brief, the contact line (the edge of the evaporating drop) moves until it runs into a particle (in fact, the higher rate of evaporation at the contact creates a convective flow that results in an outward flux of particles). A particle at the contact line "pins" the contact line, leading to an even greater evaporation rate and an even greater flux of particles towards the edge. The result of this is a concentrated array of particles that is left behind after the contact line continues to recede. These arrays take on the form of a 2D hexagonal crystaline structure.