PEDOT:PSS-Based Conductive Textiles and Their Applications

Tseghai, Granch Berhe; Mengistie, Desalegn Alemu; Malengier, Benny; Fante, Kinde Anlay; Langenhove, Lieva Van

doi:10.3390/s20071881

Cited by 141 publications

(94 citation statements)

References 104 publications

(111 reference statements)

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“…Silver-nanoparticle ink edges over copper nanoparticles due to their low rate of oxide formation [ 21 ]. Very few investigations have been observed for flexible antennas based on copper-based nanoparticles [ 22 ]. Besides nanoparticles, electro-textile materials like Ni/Ag-plated, Flectron (copper-coated nylon fabric), and nonwoven conductive fabrics (NWCFs) are generally used in flexible antennas.…”

Section: Materials For Flexible Antennasmentioning

confidence: 99%

Flexible Antennas: A Review

et al. 2020

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The field of flexible antennas is witnessing an exponential growth due to the demand for wearable devices, Internet of Things (IoT) framework, point of care devices, personalized medicine platform, 5G technology, wireless sensor networks, and communication devices with a smaller form factor to name a few. The choice of non-rigid antennas is application specific and depends on the type of substrate, materials used, processing techniques, antenna performance, and the surrounding environment. There are numerous design innovations, new materials and material properties, intriguing fabrication methods, and niche applications. This review article focuses on the need for flexible antennas, materials, and processes used for fabricating the antennas, various material properties influencing antenna performance, and specific biomedical applications accompanied by the design considerations. After a comprehensive treatment of the above-mentioned topics, the article will focus on inherent challenges and future prospects of flexible antennas. Finally, an insight into the application of flexible antenna on future wireless solutions is discussed.

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Section: Materials For Flexible Antennasmentioning

confidence: 99%

Flexible Antennas: A Review

et al. 2020

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“…In this work, we have added polydimethylsiloxane-b-polyethylene oxide (PDMS) which compensates for the stiffness from PEDOT:PSS. Moreover, we have utilized a different conductive polymer composite of PEDOT:PSS, because of its acceptable electrical conductivity and flexibility [8,9], and PDMS, due to its biocompatibility and extensibility [10]. The result should be a single fabric that senses both strain and moisture.…”

Section: Introductionmentioning

confidence: 99%

PEDOT:PSS/PDMS-Coated Cotton Fabric for Strain and Moisture Sensors

Tseghai

Malengier

Fante

et al. 2021

International Conference on the Challenges, Opportunities, Innovations and Applications in Electronic Textiles

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In this work, we have successfully developed a flexible, lightweight, and washable strain and moisture sensor textile fabric by printing poly(3,4-ethylenedioxythiophene) polystyrene sulfonate/polydimethylsiloxane-b-polyethylene oxide (PEDOT:PSS/PDMS) conductive polymer composite on knitted cotton fabric. A 60.2 kΩ/sq surface resistance has been obtained at a 30% ratio of PDMS to PEDOT:PSS at 0.012 g/cm2 solid add-on. The coated fabric was washed at 30 °C for 30 min in the presence of a standard detergent. It was observed that there was a 5.3% increase in surface resistance, i.e., 63.4 kΩ/sq. After coating, the fabric could still be stretched up to the infliction elongation of the fabric, i.e., 40%, with a significant change in surface resistance that makes it usable as a strain sensor. In addition, the conductive fabric showed a drop in surface resistance with an increase of the moisture regain up to 150%.

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“…PEDOT:PSS is attractive because of its high optical transparency, electrical conductivity, mechanical durability, electrochemical performance, and compatibility with roll-to-roll (R2R) processing. [15,22] It has been reported that the optoelectronic properties of PEDOT:PSS TCEs can be further enhanced by incorporating Ag metal mesh/stripes, giving rise to better device performance in organic devices, such as OSCs, organic light-emitting diodes, and even SCs. Moreover, the PEDOT:PSS/Ag hybrid TCE can produce more efficient stripe-shaped devices due to the underlying Ag sub-metal electrodes.…”

Section: Introductionmentioning

confidence: 99%

Scalable, All‐Printed Photocapacitor Fibers and Modules based on Metal‐Embedded Flexible Transparent Conductive Electrodes for Self‐Charging Wearable Applications

Jin

Ovhal

Lee

et al. 2020

Advanced Energy Materials

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of a lightweight, flexible, self-charging device with stable and sustainable power output. To tackle this issue, researchers are committed to assembling a flexible, uninterruptible, self-charging system by integrating various flexible energy-harvesting and energy-storage devices, giving rise to novel photocapacitor-integrated devices. Individually, the device application of flexible, fabric/stripe-type photovoltaic (PV) cells and supercapacitors in futuristic textile circuits has been extensively explored. These fiber/stripe-based devices can be easily integrated and woven together into garments with orderly patterns, such as stripes or mosaics, without compromising the wearing comfort and aesthetic design of the garment itself. [5-7] For flexible energy-harvesting devices, researchers have developed highly efficient and flexible PV cells, such as dyesensitized, [5] organic, [8] and perovskite [9] solar cells, which are environmentally benign. Compared to dye-sensitized and perovskite solar cells, organic solar cells (OSCs) exhibit superior device flexibility and higher power conversion efficiency (PCE) retention under extreme mechanical deformation/ distortion. They have these benefits because they are based on organic polymers, which are non-brittle in nature. Additionally, OSCs are low-cost, printable, reproducible, and lightweight, rendering them compatible with futuristic wearable textile applications. [1,3,5,10-13] However, conventional film-based OSCs exhibit flexibility only in a direction perpendicular to the film and are not compatible with the weaving process for wearable electronic applications. By virtue of their diverse fabrication techniques and structural designs, the dimensions of flexible OSC devices can be tuned from 2D (film) to 1D (fibers/stripes) by further scaling down the y-axis of the conventional film-based device. 1D fiber/ stripe-shaped devices that are fully compatible with the weaving process can then be obtained. Stripe-shaped OSCs have inherent advantages over planar OSCs, such as incredibly high mechanical flexibility, which means they can conform to arbitrary shapes like the human body. [14] Furthermore, after the weaving process, the relative shadowed active area is less for stripe-shaped device structures as compared with fiber-shaped geometries. On another note, flexible supercapacitors (F-SCs) have been used as energy storage systems in futuristic smart electronics The popularity of wearable smart electronic gadgets, such as smartphones, smartwatches, and medical sensors, is inhibited by their limited operation lifetime due to the lack of a sustainable self-charging power supply. This constraint can be overcome by developing a flexible, self-charging photocapacitor that can synchronously harvest and store energy. Here, ultrathin, all-printed, and metal-embedded transparent conducting electrodes (ME-TCEs) are designed for the fabrication of large-area, flexible organic solar cells (F-OSCs) and flexible supercapacitors (F-SCs). Stripe-shaped F-OSCs (SF-OSCs) and F-SCs (SF-SCs) ...

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PEDOT:PSS-Based Conductive Textiles and Their Applications

Cited by 141 publications

References 104 publications

Flexible Antennas: A Review

Flexible Antennas: A Review

PEDOT:PSS/PDMS-Coated Cotton Fabric for Strain and Moisture Sensors

Scalable, All‐Printed Photocapacitor Fibers and Modules based on Metal‐Embedded Flexible Transparent Conductive Electrodes for Self‐Charging Wearable Applications

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