Simulation of electrostatic field in electrospinning of polymer nanofibers

Y. Li; X. Zhang; E. Trudick; G.G. Chase

Nanoscale Systems: Mathematical Modeling, Theory and Applications (2015)

  • Volume: 4, Issue: 1
  • ISSN: 2299-3290

Abstract

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Electrospinning is a popular process for fabricating submicron diameter gibers. The process applies a strong electric gield to launch a polymer jet that elongates to create the gine gibers. The jet dries as the solvent evaporates and the dried giber collects on a grounded surface. Most of electrospinning literatures focus the polymer solution compositions and the properties of the produced gibers. Less attention is applied to the electrostatic gield geometries and operating conditions. Through computer simulations and laboratory experiments thiswork shows that by applying the grounded voltage to different regions of the collector surface, the electric gield can be moved spatially to direct the electrospinning jets towards select locations of the grounded surface.

How to cite

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Y. Li, et al. "Simulation of electrostatic field in electrospinning of polymer nanofibers." Nanoscale Systems: Mathematical Modeling, Theory and Applications 4.1 (2015): null. <http://eudml.org/doc/276429>.

@article{Y2015,
abstract = {Electrospinning is a popular process for fabricating submicron diameter gibers. The process applies a strong electric gield to launch a polymer jet that elongates to create the gine gibers. The jet dries as the solvent evaporates and the dried giber collects on a grounded surface. Most of electrospinning literatures focus the polymer solution compositions and the properties of the produced gibers. Less attention is applied to the electrostatic gield geometries and operating conditions. Through computer simulations and laboratory experiments thiswork shows that by applying the grounded voltage to different regions of the collector surface, the electric gield can be moved spatially to direct the electrospinning jets towards select locations of the grounded surface.},
author = {Y. Li, X. Zhang, E. Trudick, G.G. Chase},
journal = {Nanoscale Systems: Mathematical Modeling, Theory and Applications},
keywords = {Electrospinning; Electrostatic field; Simulation; FlexPDE},
language = {eng},
number = {1},
pages = {null},
title = {Simulation of electrostatic field in electrospinning of polymer nanofibers},
url = {http://eudml.org/doc/276429},
volume = {4},
year = {2015},
}

TY - JOUR
AU - Y. Li
AU - X. Zhang
AU - E. Trudick
AU - G.G. Chase
TI - Simulation of electrostatic field in electrospinning of polymer nanofibers
JO - Nanoscale Systems: Mathematical Modeling, Theory and Applications
PY - 2015
VL - 4
IS - 1
SP - null
AB - Electrospinning is a popular process for fabricating submicron diameter gibers. The process applies a strong electric gield to launch a polymer jet that elongates to create the gine gibers. The jet dries as the solvent evaporates and the dried giber collects on a grounded surface. Most of electrospinning literatures focus the polymer solution compositions and the properties of the produced gibers. Less attention is applied to the electrostatic gield geometries and operating conditions. Through computer simulations and laboratory experiments thiswork shows that by applying the grounded voltage to different regions of the collector surface, the electric gield can be moved spatially to direct the electrospinning jets towards select locations of the grounded surface.
LA - eng
KW - Electrospinning; Electrostatic field; Simulation; FlexPDE
UR - http://eudml.org/doc/276429
ER -

References

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  1. [1] D.H. Reneker, A.L. Yarin, Hao Fong, and S. Koombhongse. Bending instability of electrically charged liquid jets of polymer solutions in electrospinning. J. Appl.Phys., 87 (9), 4531-4531 (2000). [Crossref] 
  2. [2] C.J. Thompson, G.G. Chase, A.L. Yarin, D.H. Reneker. Effects of parameters on nanofiber diameter determined from electrospinning model. Polymer, 48 (23), 6913-6922 (2007). [Crossref][WoS] 
  3. [3] S. Rafiei, S. Maghsoodloo, B. Noroozi, V. Mottaghitalab, A. K. Haghi. Mathematical modeling in electrospinning process of nanofibers: a detailed review. Cellulose Chem. and Technol., 47 (5-6), 323-338 (2013). 
  4. [4] W.M. Edwards. Polyamide-acids, compositions thereof, and process for their preparation. US Patent 3179614 (1965). 
  5. [5] R.S. Irwin, C.E. Smullen. Formation of polypyromellitimide filaments. US Patent 3415782 (1968). 
  6. [6] P. Katta, M. Alessandro, R. D. Ramsier, and G. G. Chase. Continuous Electrospinning of Aligned Polymer Nanofibers onto a Wire Drum Collector. Nano Letter, 4 (11), 2215-2218 (2004). 4, No. 
  7. [7] Z. Zhong, J.Y. Howe, D.H. Reneker.Molecular scale imaging and observation of electron beam-induced changes of polyvinylidene fluoride molecules in electrospun nanofibers. Polymer, 54 (15), 3745-3756 (2013). [Crossref] 
  8. [8] A. L. Yarin, S. Koombhongse, D.H. Reneker. Bending instability in electrospinning of nanofibers. J. Appl. Phys., 89 (5), 3018- 3026 (2001). [Crossref] 
  9. [9] K. Arayanarakul, N. Choktaweesap, D. Aht-ong, C. Meechaisue, P. Supaphol. Effects of poly(ethylene glycol), inorganic salt, sodium dodecyl sulfate, and solvent system on electrospinning of poly(ethylene oxide). Macromol. Mater. Eng., 291 (6), 581–591(2006). [Crossref] 
  10. [10] L.S.Carnell, E.J. Siochi, N.M. Holloway, R.M. Stephens, C. Rhim, L.E. Niklason R.L.Clark. Alignedmats from electrospun single fibers. Macromolecules, 41 (14), 5345-5349 (2008). [Crossref][WoS] 
  11. [11] H. Pan, L. Li, L. Hu, X. Cui. Continuous aligned polymer fibers produced by a modified electrospinning method. Polymer, 47 (14), 4901-4904 (2006). [Crossref] 
  12. [12] Y.Wu, L.A. Carnell, R.L. Clark. Control of electrospun mat width through the use of parallel auxiliary electrodes. Polymer, 48 (19), 5653-5661 (2007). [WoS][Crossref] 
  13. [13] M.L. ArrasMatthias, C. Grasl, H. Bergmeister, H. Schima, Electrospinning of aligned fibers with adjustable orientation using auxiliary electrodes. Sci. Technol. Adv. Mater., 13 (3), 035008 1-8 (2012). [WoS][Crossref] 
  14. [14] J.S. Varabhas, G.G. Chase, D.H. Reneker. New Methods to Electrospin Nanofibers. Journal of Engineered Fibers and Fabrics, 6 (3), 32-38 (2011). 
  15. [15] W.E. Teo, S. Ramakrishna. A review on electrospinning design and nanofibre assemblies. Nanotechnology, 17 (14), 89-106 (2006). [Crossref] 
  16. [16] H. Niu, X. Wang, T. Lin. Needleless Electrospinning: Developments and Performances. Nanofibers – Production, Properties and Functional Applications. InTech, Croatia, pp. 18-34 (2011). 
  17. [17] G. Viswanadam, G.G. Chase. Modified electric fields to control the direction of electrospinning jets. Polymer, 54 (4), 1397- 1404 (2013). [Crossref][WoS] 
  18. [18] H. Shin, Y. Li, A. Paynter, K. Nartetamrongsutt, G. G. Chase. Vertical rod method for electrospinning polymer fibers. Polymer, 65, 26-33 (2015). [Crossref] 
  19. [19] R. F. Graf. Modern Dictionary of Electronics (7th ed). Butterworth-Heinemann, United Kingdom, pp. 292 (1999). 
  20. [20] Halliday D, Resnick R. Fundamentals of physics. Wiley, New York, pp.449-459 (1974). 
  21. [21] John S Rigden, Macmillan. Encyclopedia of Physics. Simon & Schuster, New York, pp.353 (1996). 
  22. [22] S.K. Doss, R.J. Gelinas, R.G. Nelson, J. P. Ziagos. Adaptive Forward-Inverse Modeling of Reservoir Fluids Away from Wellbore. SciTech Connect, Washington, D.C. pp. 9 (1999). 
  23. [23] FlexPDE manual Version 6.33. PDE Solutions Inc., Spokane Valley, Washington, pp. 58 (2013). 

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