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View Preprint: Fluidic Assembly and Packing of Microspheres in Confined Channels

Citation: Vanapalli, Siva A., Iacovella, Christopher R., Sung, Kyung Eun, Mukhija, Deshpremy, Millunchick, Joanna M., Burns, Mark A., Glotzer, Sharon C. and Solomon, Michael J. (2008) Fluidic Assembly and Packing of Microspheres in Confined Channels.
Collection: Lab for Computational Nanoscience and Soft Matter Simulation (2006 - Present)  

Title Fluidic Assembly and Packing of Microspheres in Confined Channels
Abstract/Summary We study fluidic assembly and packing of spherical particles in rectilinear microchannels that are terminated by a flow constriction. First, we introduce a method for active assembly of particles in the confined microchannels by triggering a local constriction in the fluid channel using a partially closed membrane valve. This microfluidic valve allows active, on-demand particle assembly as opposed to previous passive assembly methods based on terminal channels and weirs. Second, we study the three-dimensional assembly and packing of particles against a weir in confined rectilinear microchannels. The packings result in achiral particle chains with alternating (zigzag) structure. This structure is characterized by a single, repeated bond angle whose components projected into the frame of the channel are quantified by confocal microscopy and image processing. Brownian dynamics simulation of the packing comprehensively delineates the range of bond angles possible in narrow, rectilinear microchannels as well as the complex dependence of these angles on the relative dimensions of the channel and particles. The simulations of the three-dimensional packings are accurately modeled by a compact theory based on trigonometric relationships. The experimentally measured bond angles show excellent agreement with the simulations, thereby validating the functional dependence of the achiral packing bond angles on channel dimensions. This functional relationship is immediately useful for the design of anisotropic particles by microfluidic synthesis.
Keyword(s) Photonic Crystals
Colloidal Particles
Flow Lithography
Building-Blocks
Shape
Fabrication
Anisotropy
Microparticles
Date 2008-04-22
Research Fields, Courses and Disciplines 250000 Chemical Sciences
240000 Physical Sciences
250600 Theoretical and Computational Chemistry
250500 Macromolecular Chemistry
291400 Materials Engineering
290600 Chemical Engineering
Author(s) Vanapalli, Siva A.
Iacovella, Christopher R.
Sung, Kyung Eun
Mukhija, Deshpremy
Millunchick, Joanna M.
Burns, Mark A.
Glotzer, Sharon C.
Solomon, Michael J.
Copyright Agreement on
Additional Notes Langmuir, 24 (7), 3661 -3670, 2008
 
Related Links
Link Description
http://pubs.acs.org/cgi-bin/abstract.cgi/langd5/2008/24/i07/abs/la703840w.html   Langmuir, 24 (7), 3661 -3670, 2008  
http://matdl.org/repository/view/matdl:884   Packing in rectilinear channels  
http://matdl.org/repository/view/matdl:885   Bond angle of particles in small, rectilinear channels  
 
 
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Created: Tue, 22 Apr 2008, 14:58:26 EST by Chris Iacovella. Detailed History


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