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Reliability testing of PEDOT : PSS capacitors integrated into textile fabrics

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Warianty tytułu
PL
Badanie niezawodności kondensatorów PEDOT : PSS wbudowanych w tkaniny
Języki publikacji
EN
Abstrakty
EN
Textile-based capacitors have been made from polyethylene dioxythiophene, polystyrene sulphonate (PEDOT:PSS) as the electrolyte and pure stainless steel filament yarns as the electrodes. The capacitor is well integrated into the textile structure, small in size and of light weight. Although they experience a self-discharge, the reliability of the PEDOT:PSS capacitors has been investigated by repeating up to 14 cycles of charging and discharging. Initially, the voltage output turns out to be higher with increasing number of cycles. However, after the fifth cycle, degradation of the cell starts occurring and a decreasing behaviour in the voltage output is observed. One can roughly say that these capacitors could be used up to 10–15 cycles.
PL
Kondensatory tekstylne wytwarza się z mieszaniny poli(3,4-dioksyetylenotiofenu) z polistyrenem sulfonowanym (PEDOT: PSS), pełniącej rolę elektrolitu oraz włókien ciągłych z czystej stali nierdzewnej, pełniących funkcję elektrod. Kondensatory tego typu są dobrze zintegrowane ze strukturą tkaniny, są lekkie i mają niewielkie rozmiary. Chociaż kondensatory PEDOT:PSS ulegają samorozładowaniu, przeprowadzono badania ich niezawodności powtarzając 14 cykli ładowania i rozładowywania Początkowo napięcie wyjściowe zwiększało się wraz ze wzrostem liczby cykli. Jednakże po piątym cyklu, dochodziło do degradacji ogniwa i obserwowano zmniejszanie się napięcia wyjściowego. Można orientacyjnie powiedzieć, że omawiane kondensatory nadają się do użytku przez maksymalnie 10–15 cykli.
Rocznik
Strony
447--451
Opis fizyczny
Bibliogr. 30 poz., rys., tab.
Twórcy
autor
  • Department of Textiles Ghent University Technologiepark 907, 9052 Zwijnaarde, Belgium Department of Textiles Moi University Eldoret, Kenya
autor
  • Department of Electronics and Information Systems Ghent University Sint Pietersnieuwstraat 41, 9000 Ghent, Belgium
autor
  • Department of Textiles Ghent University Technologiepark 907, 9052 Zwijnaarde, Belgium
  • Department of Textiles Ghent University Technologiepark 907, 9052 Zwijnaarde, Belgium
Bibliografia
  • 1. Bhattacharya R, de Kok MM, Zhou J. Rechargeable electronic textile battery. Applied Physics Letters 2009; 95: 22.
  • 2. Cao Lihui, Li Yinglin. The Development and Application of Smart Garment Materials. Materials and Manufacturing Technology, Pts 1 and 2. X. Yi and L. Mi. Stafa-Zurich. Trans Tech Publications Ltd 2010; 129-131: 472-475.
  • 3. Gu JF, Gorgutsa S and Skorobogatiy M. Soft capacitor fibers for electronic textiles. Applied Physics Letters 2010; 97: 13.
  • 4. Horng Ying-Ying, Lu Yi-Chen, Hsu Yu-Kuei, et al. Flexible supercapacitor based on polyaniline nanowires/carbon cloth with both high gravimetric and area-normalized capacitance. Journal of Power Sources 2010; 195(13): 4418-4422.
  • 5. Hu L, La Mantia F, Wu Hui, Xie X, James M and Cui Y. Lithium-Ion Textile Batteries with Large Areal Mass Loading. Advanced energy material 2011;1(6): 1012-1017.
  • 6. Irwin Michael D, Roberson David A, Olivas Richard I, Wicker R B and MacDonald E. Conductive Polymer-Coated Threads as Electrical Interconnects in e-Textiles. Fibers and Polymers 2011; 12(7): 904-910.
  • 7. Jost K, Perez CR, McDonough JK, Presser V, Heon M, Dion G, Gogotsi Y. Carbon coated textiles for flexible energy storage. Energy &Environmental Science 2011; 4(12): 5060-5067.
  • 8. Kaltenbrunner M, Kettlgruber G, Siket C, Schwodiauer R, Bauer S. Arrays of Ultracompliant Electrochemical Dry Gel Cells for Stretchable Electronics. Advanced Materials 2010; 22(18): 2065-2067.
  • 9. Kayacan O, Bulgun E, Sahin O. Implementation of Steel-based Fabric Panels in a Heated Garment Design. Textile Research Journal 2009; 79(16): 1427-1437.
  • 10. Kazani I. Study of screen-printed electroconductive textile materials. PhD dissertation, Gent university 2012.
  • 11. Kazani I, Hertleer C, De Mey G, Guxho G, Van Langenhove L. Dry cleaning of electroconductive layers screen printed on flexible substrates. Textile Research Journal 2013; 83(14): 1541-1548.
  • 12. Kazani I, Hertleer C, De Mey G, Schwarz A, Guxho G, Van Langenhove L. Electrical Conductive Textiles Obtained by Screen Printing. Fibres & Textiles in Eastern Europe 2012; 20(1): 57-63.
  • 13. Laforgue A. All-textile flexible supercapacitors using electrospun poly(3,4-ethylenedioxythiophene) nanofibers. Journal of Power Sources 2011; 196(1): 559-564.
  • 14. Lee Hyo Joong, Lee Joowok, and Park Su-Moon. Electrochemistry of Conductive Polymers. 45. Nanoscale Conductivity of PEDOT and PEDOT:PSS Composite Films Studied by Current-Sensing AFM. Journal of Physical Chemistry B 2010; 114(8): 2660-2666.
  • 15. Li GC, Pickup PG. Ion transport in poly(3,4-ethylenedioxythiophene)-poly(styrene-4-sulfonate) composites. Physical Chemistry Chemical Physics 2000; 2(6): 1255-1260.
  • 16. Liu Y, Gorgutsa S, Clara S, Skorobogatiy M. Flexible, solid electrolyte-based lithium battery composed of LiFePO4 cathode and Li4Ti5O10 anode for applications in smart textiles. Journal of the Electrochemical Society 2012; 159(4): A349-A356.
  • 17. Meng CZ, Liu C, Chen L, Hu C, Fan S. Highly Flexible and All-Solid-State Paper like Polymer Supercapacitors. Nano Letters 2010; 10(10):4025-4031.
  • 18. Muller Christian, Hamedi M, Karlsson R, Jansson R, Marcilla R, Hedhammar M and Inganas O. Woven Electrochemical Transistors on Silk Fibers. Advanced Materials 2011; 23(7): 898-901.
  • 19. Nishide, H. and Oyaizu K. Materials science - Toward flexible batteries. Science 2008; 319(5864): 737-738.
  • 20. Nyholm L, Nystrom G, Mihranyan A and Stromme M. Toward Flexible Polymer and Paper-Based Energy Storage Devices. Advanced Materials 2011; 23(33): 3751-3769.
  • 21. Odhiambo S, Heertleer C, Schwarz A, Van Langenhove L, De Mey G. Discharge characteristics of PEDOT: PSS textile batteries; comparison of silver coated yarn electrodes devices and pure stainless steel filament yarn electrodes devices. Textile Research Journal 2013; Accepted.
  • 22. Ouyang J, Xu QF, Chu CW, Yang Y, Li G, Shinar J. On the mechanism of conductivity enhancement in poly (3,4-ethylenedioxythiophene):poly(styrene sulfonate) film through solvent treatment. Polymer 2004; 45(25): 8443-8450.
  • 23. Rattfalt L, Linden M, Hult P, Berglin L, Ask P. Electrical characteristics of conductive yarns and textile electrodes for medical applications. Medical & Biological Engineering & Computing 2007; 45(12): 1251-1257.
  • 24. Rogers JA, Someya T, Huang Y. Materials and Mechanics for Stretchable Electronics. Science 2010; 327(5973): 1603-1607.
  • 25. Schwarz A, Cuny L, Hertleer C, Ghekiere F, Kazani I, De Clercq G, De Mey G, Van Langenhove L. Electrical circuit model of elastic and conductive yarns produced by hollow spindle spinning. Materials Technology 2011; 26(3): 121-127.
  • 26. Schwarz A, Hakuzimana J, Kaczynska A, Banaszczyk J, Westbroek P, McAdams E, Moody G, Chronis Y, Priniotakis G, De Mey G, Tseles D, Van Langenhove L. Gold coated para-aramid yarns through electroless deposition. Surface & Coatings Technology 2010; 204(9-10):1412-1418.
  • 27. Schwarz A, Hakuzimana J, Westbroek P, De Mey G, Priniotakis G, Nyokong T, Van Langenhove L. A study on the morphology of thin copper films on para-aramid yarns and their influence on the yarn's electro-conductive and mechanical properties. Textile Research Journal 2012; 82(15): 1587-1596.
  • 28. Stead L, Goulev P, Evans C, Mamdani E. The Emotional Wardrobe. Personal and Ubiquitous Computing 2004; 8(3-4): 282-290.
  • 29. Tao Xuyuan, Koncar V, Dufour C. Geometry Pattern for the Wire Organic Electrochemical Textile Transistor. Journal of the Electrochemical Society 2011; 158(5): H572-H577.
  • 30. Van Langenhove L, Hertleer C. Smart clothing: a new life. International journal of clothing science and technology 2004; 16: 63-72.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-27c8720c-b7ae-4478-b009-cdb4960bee67
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