Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (08): 99-106.doi: 10.13475/j.fzxb.20230403901

• Fiber Materials • Previous Articles     Next Articles

Preparation and properties of poly(3,4-ethylene supported dioxythiophene)/polystyrene sulfonic acid based composite conductive fibers

WU Fan1,2,3(), LIANG Fengyu1, XIAO Yiting1, YANG Zhibo4, WANG Wenting1, FAN Wei1,2,3   

  1. 1. School of Textile Science and Engineering, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
    2. Key Laboratory of Functional Textile Material and Product, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
    3. Institute of Flexible Electronics and Intelligent Textile, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
    4. School of Electronics and Information, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
  • Received:2023-04-17 Revised:2023-10-31 Online:2024-08-15 Published:2024-08-21

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Abstract:

Objective Intelligent textiles with excellent serviceability and electrical performance require the use of high-performance conductive fibers. Wet-spun conductive fibers have great potential in various smart and functional yarns and fabrics. The doping of conductive fillers into fibers is an efficient way to improve fiber conductivity. However, the effect of conductive fillers dispersed into the coagulation bath on the electrical properties of wet-spun fibers was not sufficiently investigated. This research aims to study the effect of doping method and doping ratio of conductive fillers on the electrical properties of poly (3,4-ethylene supported dioxythiophene):polystyrene sulfonic acid(PEDOT:PSS)-based fibers.

Method Graphene and silver nanowires (Ag NWs) were used as conductive fillers, PEDOT:PSS was used as the matrix, deionized water was used as the solvent, isopropanol and dimethyl sulfoxide were used as coagulation bath to fabricate wet-spun PEDOT:PSS based composite fibers. Conductive fillers were directly mixed into the spinning solution or only dispersed into the coagulation bath. In addition, polyurethane (PU) encapsulated composite fiber was fabricated by the immersion method.

Results The wet-spun composite fibers showed uniform diameter. Based on the bidirectional diffusion of spinning liquid and coagulators, the graphene and Ag NWs dispersed in the coagulation bath were closely adsorbed onto the surface of the PEDOT:PSS fiber. The PEDOT:PSS fiber doped with Ag NWs into spinning solution (sample 4) demonstrated the highest electrical conductivity (577.98±157.33) S/cm, and PEDOT:PSS-based composite fiber (sample 7) fabricated by graphene and Ag NWs dispersed into the coagulation bath showed the second-highest conductivity (421.19±75.14) S/cm. Considering the cost in real production, composite fibers (sample 7) fabricated in the coagulation bath with conductive fillers were considered more feasible. The strain and stress of the composite fiber were 1.23% and 37 MPa, respectively. The resistance of the composite fiber showed gradual increasing during the tensile loading process. When the strain reaches 0.75%, the gauge factor (GF) of composite fiber was 0.18 and was increased to 3.12 until it breaks at 1.23%. The static contact angle of composite fiber was 62.9°. The electric conductivity of polyurethane (PU) encapsulated composite fibers illustrated a decrease by 10.7% compared with that of composite fiber, but demonstrated ability to withstand cyclic three-point bending 6 000 times after which the resistance change of the fiber was below 0.12%. After water washing, the resistance of the PU encapsulated composite fiber was increased. After three times of water washing (about 30 min), the conductivity of encapsulated fiber stabilizes and remained at 260 S/cm.

Conclusion In this work, PEDOT:PSS based composite fiber with high conductivity and good stability are prepared by the wet spinning method. By adjusting the doping ratio and methods of graphene and silver nanowires into PEDOT:PSS, the conductivity of composite fibers is improved. Dispersing conductive fillers into the coagulation bath is found to be more feasible to fabricate high-performance conductive composite fibers. The resulting composite fibers show promise for small strain sensing and the surface of composite fiber is hydrophilic. The PU-encapsulated composite fibers exhibit good bending resistance as well as the water washing resistance. After three times of water washing, the electrical performance of PU-encapsulated composite fiber becomes stable. The proposed methods provide a new approach for wet-spun conductive composite fibers to achieve high electric conductivity and good stability simultaneously.

Key words: conductive fiber, poly(3,4-ethylene supported dioxythiophene): polystyrene sulfonic acid, graphene, silver nanowire, wet spinning, conductive property

CLC Number: 

  • TQ342.8

Fig.1

Illustration of double diffusion process between spinning solution and coagulation bath"

Fig.2

SEM images of graphene(a) and silver nanowires(b)"

Fig.3

SEM images of different composite fibers. (a) Sample 1; (b) Sample 2; (c) Sample 3; (d) Sample 4; (e) Sample 5; (f) Sample 6; (g) Sample 7; (h) Sample 7(high-magnification)"

Fig.4

EDS pattern of sample 7"

Fig.5

Current-voltage curves of PEDOT:PSS-based composite fiber (sample 7) fabricated by graphene and silver nanowires dispersed into coagulation bath"

Tab.1

Comparison of conductivity of each samples"

试样编号 电导率/(S·cm-1)
1 344.15±151.85
2 245.32±89.65
3 291.15±71.85
4 577.98±157.33
5 345.08±75.83
6 284.50±25.90
7 421.19±75.14

Fig.6

Tensile property and electrical property under strain of PEDOT:PSS-based composite fiber (sample 7) fabricated by graphene and Ag NWs dispersed into coagulation bath. (a) Stress-strain curve; (b) Change of electric resistance under strain"

Fig.7

Hydrophobic performance of PEDOT:PSS-based composite fiber (sample 7) fabricated by graphene and Ag NWs dispersed into coagulation bath and electrical performance of PU encapsulated composite fiber. (a) Static contact angle; (b) Current-voltage curves before and after package treatment; (c) Change of electric resistance after package treatment"

Fig.8

Water washing performance of PEDOT:PSS-based composite fiber (sample 7) fabricated by graphene and Ag NWs dispersed into coagulation bath after package treatment. (a) Current-voltage curves; (b) Change of conductivity"

[1] 刘旭华, 苗锦雷, 曲丽君, 等. 用于可穿戴智能纺织品的复合导电纤维研究进展[J]. 复合材料学报, 2021, 38(1): 67-83.
LIU Xuhua, MIAO Jinlei, QU Lijun, et al. Research progress of composite conductive fibers for wearable smart textiles[J]. Acta Materiae Compositae Sinica, 2021, 38(1): 67-83.
[2] 张文枭, 左杏薇, 曲丽君, 等. 基于导电纤维的柔性电子器件研究进展[J]. 复合材料学报, 2023, 40(2): 688-709.
ZHANG Wenxiao, ZUO Xingwei, QU Lijun, et al. Research progress of flexible electronic devices based on conductive fiber[J]. Acta Materiae Compositae Sinica, 2023, 40(2): 688-709.
[3] CHATTERJEE Kony, TABOR Jordan, GHOSH Tushar K. Electrically conductive coatings for fiber-based e-textiles[J]. Fibers, 2019. DOI:10.3390/fib7060051.
[4] BYUNGWOO Choi, JAEHONG Lee, HEETAK Han, et al. A highly conductive fiber with waterproof and self-cleaning properties for textile electronics[J]. ACS Applied Materials & Interfaces, 2018, 10(42): 36094-36101.
[5] 周歆如, 胡铖烨, 范梦晶, 等. 双针头连续水浴静电纺的电场模拟及其纳米纤维包芯纱结构[J]. 纺织学报, 2023, 44(2): 27-33.
ZHOU Xinru, HU Chengye, FAN Mengjing, et al. Electric field simulation of two-needle continuous water bath electrospinning and structure of nanofiber core-spun yarn[J]. Journal of Textile Research, 2023, 44(2): 27-33.
[6] WANG Xiaoxiong, YU Guifeng, ZHANG Jun, et al. Conductive polymer ultrafine fibers via electrospinning: preparation, physical properties and applications[J]. Progress in Materials Science, 2021. DOI:10.1016/j.pmatsci.2020.100704.
[7] KIM Seung-woo, KWON Sung-nam, NA Seok-in. Stretchable and electrically conductive polyurethane-silver/graphene composite fibers prepared by wet-spinning process[J]. Composites Part B: Engineering, 2019, 165(15): 573-581.
[8] WANG Yaqun, DING Yu, GUO Xuelin, et al. Conductive polymers for stretchable supercapacitors[J]. Nano Research, 2019, 12(9): 1978-1987.
doi: 10.1007/s12274-019-2296-9
[9] 庞雅莉, 孟佳意, 李昕, 等. 石墨烯纤维的湿法纺丝制备及其性能[J]. 纺织学报, 2020, 41(9): 1-7.
PANG Yali, MENG Jiayi, LI Xin, et al. Preparation of graphene fibers by wet spinning and fiber characterization[J]. Journal of Textile Research, 2020, 41(9): 1-7.
[10] 蒲海红, 贺芃鑫, 宋柏青, 等. 纤维素/碳纳米管复合纤维的制备及其功能化应用[J]. 纺织学报, 2023, 44(1): 79-86.
PU Haihong, HE Pengxin, SONG Baiqing, et al. Preparation of cellulose/carbon nanotube composite fiber and its functional applications[J]. Journal of Textile Research, 2023, 44(1): 79-86.
[11] TSEGHAI Granch Berhe, MENGISTIE Desalegn Alemu, MALENGIER Benny, et al. PEDOT:PSS-based conductive textiles and their applications[J]. Sensors, 2020. DOI:10.3390/s20071881.
[12] RUBENUBEN Sarabia-riquelme, MARYAM Shah, JOSEPH W Brill, et al. Effect of drawing on the electrical, thermoelectrical, and mechanical properties of wet-spun PEDOT:PSS fibers[J]. ACS Applied Polymer Materials, 2019, 1(8): 2157-2167.
[13] LI Mufang, ZENG Fanjia, LUO Mengying, et al. Synergistically improving flexibility and thermoelectric performance of composite yarn by continuous ultrathin PEDOT:PSS/DMSO/ionic liquid coating[J]. ACS Applied Materials & Interfaces, 2021, 13(42): 50430-50440.
[14] IZARRA Ambroise De, PARK Seongjin, LEE Jinhee, et al. Ionic liquid designed for PEDOT:PSS conductivity enhancement[J]. Journal of the American Chemical Society, 2018, 140(16): 5375-5384.
doi: 10.1021/jacs.7b10306 pmid: 29633844
[15] ZHANG Jizhen, SEYEDI Neyedin Shayan, QIN Si, et al. Fast and scalable wet-spinning of highly conductive PEDOT:PSS fibers enables versatile applications[J]. Journal of Materials Chemistry A, 2019, 7(11): 6401-6410.
doi: 10.1039/c9ta00022d
[16] FENG Danyang, WANG Peng, WANG Mingxu, et al. A facile route toward continuous wet-spinning of PEDOT: PSS fibers with enhanced strength and electroconductivity[J]. Fibers and Polymers, 2021, 22: 1491-1495.
[17] JIN Jo Young, YOUNG Kim Soo, HUN Hyun Jeong, et al. Fibrillary gelation and dedoping of PEDOT:PSS fibers for interdigitated organic electrochemical transistors and circuits[J]. npj Flexible Electronics, 2022(1): 330-340.
[18] 刘玲, 周彬, 周红涛. PEDOT/PSS质量分数对纺丝液流变性能及导电纤维可纺性的影响[J]. 塑料工业, 2022, 50(2): 174-178.
LIU Ling, ZHOU Bin, ZHOU Hongtao. Effect of mass fraction of PEDOT/PSS on rheological properties of spinning fluid and spinnability of conducting fibers[J]. Plastic Industry, 2022, 50(2): 174-178.
[19] LIU Siqi, LI Hui, HE Chaobin. Simultaneous enhancement of electrical conductivity and seebeck coefficient in organic thermoelectric SWNT/PEDOT:PSS nanocomposites[J]. Carbon, 2019, 149: 25-32.
doi: 10.1016/j.carbon.2019.04.007
[20] GAO Qiang, WANG Mingxu, KANG Xinyuan, et al. Continuous wet-spinning of flexible and water-stable conductive PEDOT:PSS/PVA composite fibers for wearable sensors[J]. Composites Communications, 2020, 17: 134-140.
[21] JALILI Rouhollah, RAZAL Joselito M, WALLACE Gordon G. Wet-spinning of PEDOT:PSS/functionalized-SWNTs composite: a facile route toward production of strong and highly conducting multifunctional fibers[J]. Scientific Reports, 2013.DOI:10.1038/srep03438.
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