Flat polymer ribbons and other shapes by electrospinning

In addition to round nanofibers, electrospinning a polymer solution can produce thin fibers with a variety of cross‐sectional shapes. Branched fibers, flat ribbons, ribbons with other shapes, and fibers that were split longitudinally from larger fibers were observed. The transverse dimensions of the...

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Published inJournal of polymer science. Part B, Polymer physics Vol. 39; no. 21; pp. 2598 - 2606
Main Authors Koombhongse, Sureeporn, Liu, Wenxia, Reneker, Darrell H.
Format Journal Article
LanguageEnglish
Published New York John Wiley & Sons, Inc 01.11.2001
Wiley
Subjects
Applied sciences
branched fibers
electrospinning
Exact sciences and technology
fibers
fluid mechanics
Forms of application and semi-finished materials
jets
Miscellaneous
nanofibers
nanotechnology
polymer fibers
Polymer industry, paints, wood
polymer solutions
ribbon
Technology of polymers
Hydroxyethyl methacrylate polymer
Solvent spinning
Manufacturing process
Morphology
Vinylidene fluoride polymer
Styrene polymer
Experimental study
Microstrip
Non circular cross section
Etherimide polymer
Nanostructured materials
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Summary:In addition to round nanofibers, electrospinning a polymer solution can produce thin fibers with a variety of cross‐sectional shapes. Branched fibers, flat ribbons, ribbons with other shapes, and fibers that were split longitudinally from larger fibers were observed. The transverse dimensions of these asymmetric fibers were typically 1 or 2 μm, measured in the widest direction. A correlation of the branches and bends, observed in high‐frame‐rate videography of the electrified jets of polymer solutions from which the ribbons and branched fibers were produced, suggest that these phenomena occur at scales ranging from around 1 mm to 1 μm. The observation of fibers with these cross‐sectional shapes from a number of different kinds of polymers and solvents indicates that fluid mechanical effects, electrical charge carried with the jet, and evaporation of the solvent all contributed to the formation of the fibers. The influence of a skin on the jets of polymer solutions accounts for a number of the observations. The observed shapes can be used as guides for the extension of mathematical or computer‐generated models for the electrospinning process. © 2001 John Wiley & Sons, Inc. J Polym Sci Part B: Polym Phys 39: 2598–2606, 2001
Bibliography:National Science Foundation - No. DMI-9813098; No. CTS-9900949
U.S. Army Soldier Systems Command
Coalescence Research Consortium of the University of Akron
ArticleID:POLB10015
U.S. Army Research Office
istex:E990732D5B067AEF045ADCA6129AC38F25EF68CA
ark:/67375/WNG-V891X457-X
ISSN:0887-6266
1099-0488
DOI:10.1002/polb.10015