Click Electroless Plating and Sonoplating of Polyester with Copper Nanoparticles Producing Conductive Fabric

Moazzenchi, Bahareh; Montazer, Majid

doi:10.1007/s12221-020-9664-7

Cited by 22 publications

(15 citation statements)

References 32 publications

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“…Recently, different authors have studied electroless plating processes without addition of stabilising and sensitising agents. Thus, Moazzenchi and Montazer [ 78 ] reported a simple click electroless Cu plating and sonoplating of polyester fabric for E-textile applications; Karami et al [ 65 ] electroless Ag plated surface of reduced GO (rGO) coated cotton fabric for textile-based super-capacitor electrode applications; Takuoka et al [ 66 ] electroless Ni-P plated PET textile with the assistance of supercritical CO 2 (scCO 2 ); Ali et al [ 6 ] focused on metallization of cotton fabrics by using the shorter route of modified electroless Cu plating method, which is also Pd, Sn and formaldehyde free; Lu et al [ 73 ] studied an efficient catalyst-free process for the electroless Cu plated bamboo fabric initially-modified with MPTMS ethanol solution.…”

Section: Fabrication Techniques For Tailoring Of Conductive Textilesmentioning

confidence: 99%

Metallisation of Textiles and Protection of Conductive Layers: An Overview of Application Techniques

Ojstršek

Plohl

Gorgieva

et al. 2021

Sensors

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The rapid growth in wearable technology has recently stimulated the development of conductive textiles for broad application purposes, i.e., wearable electronics, heat generators, sensors, electromagnetic interference (EMI) shielding, optoelectronic and photonics. Textile material, which was always considered just as the interface between the wearer and the environment, now plays a more active role in different sectors, such as sport, healthcare, security, entertainment, military, and technical sectors, etc. This expansion in applied development of e-textiles is governed by a vast amount of research work conducted by increasingly interdisciplinary teams and presented systematic review highlights and assesses, in a comprehensive manner, recent research in the field of conductive textiles and their potential application for wearable electronics (so called e-textiles), as well as development of advanced application techniques to obtain conductivity, with emphasis on metal-containing coatings. Furthermore, an overview of protective compounds was provided, which are suitable for the protection of metallized textile surfaces against corrosion, mechanical forces, abrasion, and other external factors, influencing negatively on the adhesion and durability of the conductive layers during textiles’ lifetime (wear and care). The challenges, drawbacks and further opportunities in these fields are also discussed critically.

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Section: Fabrication Techniques For Tailoring Of Conductive Textilesmentioning

confidence: 99%

Metallisation of Textiles and Protection of Conductive Layers: An Overview of Application Techniques

Ojstršek

Plohl

Gorgieva

et al. 2021

Sensors

View full text Add to dashboard Cite

show abstract

“…So far, e-textiles Nanomaterials 2022, 12, 2039 2 of 47 have been proposed to be utilized in different areas, i.e., healthcare [7,8], sensing [9,10], defense [11,12], sports [13,14], personal protection [15,16], fashion [17,18], energy [19,20], thermal management [21,22], magnetic shielding [23,24], communication [25,26], etc. The incorporation of metal nanoparticles (silver [27,28], gold [29,30], copper [31,32], zinc oxide [33,34], gallium [35,36], platinum [37,38], aluminum [39,40], nickel [41,42], cobalt [43,44], tin [45,46], etc. ), carbon nanomaterials (carbon nanotube [47,48], graphene [49,50], carbon black [51,52], activated carbon [53,…”

Section: Introductionmentioning

confidence: 99%

Advances in the Robustness of Wearable Electronic Textiles: Strategies, Stability, Washability and Perspective

Sadi

Kumpikaitė

2022

Nanomaterials

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Flexible electronic textiles are the future of wearable technology with a diverse application potential inspired by the Internet of Things (IoT) to improve all aspects of wearer life by replacing traditional bulky, rigid, and uncomfortable wearable electronics. The inherently prominent characteristics exhibited by textile substrates make them ideal candidates for designing user-friendly wearable electronic textiles for high-end variant applications. Textile substrates (fiber, yarn, fabric, and garment) combined with nanostructured electroactive materials provide a universal pathway for the researcher to construct advanced wearable electronics compatible with the human body and other circumstances. However, e-textiles are found to be vulnerable to physical deformation induced during repeated wash and wear. Thus, e-textiles need to be robust enough to withstand such challenges involved in designing a reliable product and require more attention for substantial advancement in stability and washability. As a step toward reliable devices, we present this comprehensive review of the state-of-the-art advances in substrate geometries, modification, fabrication, and standardized washing strategies to predict a roadmap toward sustainability. Furthermore, current challenges, opportunities, and future aspects of durable e-textiles development are envisioned to provide a conclusive pathway for researchers to conduct advanced studies.

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“…Conductive fabrics, which are used in the smart textile area, have broad applications, such as sensors, − photovoltaic devices, , heating textiles, , devices for electrotherapy, , wireless communication, , wearable computers, actuators, and electrostatic discharge clothing . Another application of smart textiles can be found in various wearable electrodes, heat storage, , and thermoregulated clothing. , Base fabric materials, including cotton, wool, polyester, and nylon, are used as substrates for fabricating conductive fabrics. − These substrates can be made conductive by coating or implanting the fibers or the fabric with conductive materials such as gold, , copper, titanium, nickel, and silver . Conductive polymers, − carbon black, , carbon nanotubes, − graphite, and graphene , are other conductive materials used to manufacture conductive fabrics.…”

Section: Introductionmentioning

confidence: 99%

Review on PEDOT:PSS-Based Conductive Fabric

et al. 2022

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This article reviews conductive fabrics made with the conductive polymer poly (3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), their fabrication techniques, and their applications. PEDOT:PSS has attracted interest in smart textile technology due to its relatively high electrical conductivity, water dispersibility, ease of manufacturing, environmental stability, and commercial availability. Several methods apply PEDOT:PSS to textiles. They include polymerization of the monomer, coating, dyeing, and printing methods. In addition, several studies have shown the conductivity of fabrics with the addition of PEDOT:PSS. The electrical properties of conductive textiles with a certain sheet resistance can be reduced by several orders of magnitude using PEDOT:PSS and polar solvents as secondary dopants. In addition, several studies have shown that the flexibility and durability of textiles coated with PEDOT:PSS can be improved by creating a composite with other polymers, such as polyurethane, which has high flexibility and extensibility. This improvement is due to the stronger bonding of PEDOT:PSS to the fabrics. Sensors, actuators, antennas, interconnectors, energy harvesting, and storage devices have been developed with PEDOT:PSS-based conductive fabrics.

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Click Electroless Plating and Sonoplating of Polyester with Copper Nanoparticles Producing Conductive Fabric

Cited by 22 publications

References 32 publications

Metallisation of Textiles and Protection of Conductive Layers: An Overview of Application Techniques

Metallisation of Textiles and Protection of Conductive Layers: An Overview of Application Techniques

Advances in the Robustness of Wearable Electronic Textiles: Strategies, Stability, Washability and Perspective

Review on PEDOT:PSS-Based Conductive Fabric

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