Flexible Textile Strain Sensor Based on Copper-Coated Lyocell Type Cellulose Fabric

“…No major differences are found, except for isolated adsorbed siloxane-clusters possibly build up during prehydrolysis of the solution. By deposition of silver, no continuous layer, but additional small isolated clusters are formed on the fiber surface [18].…”

Section: Layer Morphology and Compositionmentioning

confidence: 99%

Tunable colors and conductivity by electroless growth of Cu/Cu2O particles on sol-gel modified cellulose

et al. 2020

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Development of colored surfaces by formation of nano-structured aggregates is a widely used strategy in nature to color lightweight structures (e.g. butterflies) without the use of dye pigments. The deposition of nanoscale particles mimics nature in it's approach coloring surfaces. This work presents sol-gel modification of cellulose surfaces used to form a template for growth of Cu/Cu 2 O core-shell particles with defined size-distributions. Besides improving the adhesion of the deposited particulate material, the sol-gel matrix serves as a template for the control of particle sizes of the Cu/Cu 2 O structures, and as a consequence of particle size variation the surface color is tunable. As an example, red color was achieved with an average particle size of 35 nm, and shifts gradually to blue appearance when particles have grown to 80 nm on the sol-gel modified fabric. The copper concentration on representative fabrics is kept low to avoid modifying the textile characteristics and were all in the range of 150-170 mg per g of cellulose material. As a result of copper deposition on the surface of the material, the cellulose fabric also became electrically conductive. Remarkably, the electrical conductivity was found to be dependent on the average particle sizes of the deposits and thus related to the change in observed color. The generation of color by growth of nano-sized particles on sol-gel templates provides a highly promising approach to stain surfaces by physical effects without use of synthetic colorants, which opens a new strategy to improve environmental profile of coloration.

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“…Even in such a traditional area such as clothing, the modern lifestyle and new technologies are changing the aim and perception of textile materials, from simple protection to wearables with new functionalities and added value. Recently, researchers have shown an increased interest in flexible, electrically conductive textiles, which, in combination with different electronic components and circuit boards on the textile surface, represent electronic textile systems (so called e-textiles), with applications in photodynamic therapy, electronic sensors, flexible batteries, heating fabrics and light emitting displays [1][2][3]. Several approaches/techniques have been proposed in the literature about how conductivity can be implemented into flexible surfaces, (i) fabrics are weaved or knitted from conductive yarns, (ii) surfaces are sewn or embroidered with conductive threads, and (iii) those specially treated to impart conductivity, i.e., by chemical coating, surface metallization (e.g., copper (Cu), silver (Ag) or nickel (Ni) nanoparticles (NPs)), deposition of conductive fillers (carbon black or carbon nanotubes) and coating of conductive polymers (e.g., polyaniline, polypyrrole or poly-3,4-ethylenedioxythiophene), achieving Some examples of these novel products are flexible heaters, panels and actuators, electrostatic discharge clothing, high-performance sportswear and embedded healthmonitoring devices (recording data related to body temperature, heartbeat, moisture, etc.…”

Section: Introductionmentioning

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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Flexible Textile Strain Sensor Based on Copper-Coated Lyocell Type Cellulose Fabric

Cited by 23 publications

References 47 publications

Bio-Based Polymers for Engineered Green Materials

Bio-Based Polymers for Engineered Green Materials

Tunable colors and conductivity by electroless growth of Cu/Cu2O particles on sol-gel modified cellulose

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

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