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

Landsiedel, Justus; Root, Waleri; Schramm, Christian; Menzel, A.; Witzleben, Steffen; Bechtold, Thomas; Pham, Tung

doi:10.1007/s12274-020-2907-5

Cited by 12 publications

(3 citation statements)

References 23 publications

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“…Recently, some approaches have been applied to color fabrics with structural color materials. − Among them, the most commonly applied method is forming a close-packed photonic crystal (PC) − structure or an amorphous photonic structure (APS) − on the surface of fabrics using polystyrene (PS), SiO 2 , and other low-refractive-index spheres ( n < 1.6) as a building block. Large-area structural colored fabrics were prepared by assembling PS spheres into ordered PCs on the surface of fabrics .…”

Section: Introductionmentioning

confidence: 99%

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres

Han

Zhang

et al. 2021

ACS Appl. Mater. Interfaces

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Compared with conventional textile coloring with dyes and pigments, structural colored fabrics have attracted broad attention due to the advantages of eco-friendliness, brilliant colors, and anti-fading properties. The most investigated structural color on fabrics is originated from a band gap of multilayered photonic crystals or amorphous photonic structures. However, limited by the nature of the color generation mechanism and a multilayered structure, it is challenging to achieve structural colored fabrics with brilliant noniridescent colors and high fastness. Here, we propose an alternative strategy for coloring a fabric based on the scattering of Cu2O single-crystal spheres. The disordered Cu2O thin layers (<0.6 μm) on the surface of fabrics were prepared by a spraying method, which can generate vivid noniridescent structural color due to the strong Mie scattering of Cu2O single-crystal spheres. Importantly, the great mechanical stability of the structural color was realized by firmly binding Cu2O spheres to the fabric using a commercial binder. The structural color can be tuned by changing the diameter of Cu2O spheres. Furthermore, complex patterns can be easily obtained by spray coating Cu2O spheres with different particle sizes using a mask. According to color fastness test standards, the dry rubbing, wet rubbing, and light fastness of the structural color on fabric can reach level 5, level 4, and level 6, respectively, which is sufficient to resist rubbing, photobleaching, washing, rinsing, kneading, stretching, and other external mechanical forces. This coloring method may carve a practical avenue in textile coloring and has potentials in other practical applications of structural color.

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Section: Introductionmentioning

confidence: 99%

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres

Han

Zhang

et al. 2021

ACS Appl. Mater. Interfaces

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“…The mass load increased as P A increased to reach the maximum (≈18 mg cm −2 ) at D S = 2 mm, which is substantially higher than those reported in previous studies. [ 24,25 ] The penetration depth also increased as P A increased where the deep penetration (>600 µm) into fabrics occurred with P A ≥ 70 kPa at D S = 2 mm. The high mass load and deep penetration resulted in sufficiently low electrical resistance (<2.6 Ω) at the optimal condition.…”

Section: Resultsmentioning

confidence: 99%

A Programmable Dual‐Regime Spray for Large‐Scale and Custom‐Designed Electronic Textiles

et al. 2022

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Increasing demand for wearable healthcare synergistically advances the field of electronic textiles, or e‐textiles, allowing for ambulatory monitoring of vital health signals. Despite great promise, the pragmatic deployment of e‐textiles in clinical practice remains challenged due to the lack of a method in producing custom‐designed e‐textiles at high spatial resolution across a large area. To this end, a programmable dual‐regime spray that enables the direct custom writing of functional nanoparticles into arbitrary fabrics at sub‐millimeter resolution over meter scale is employed. The resulting e‐textiles retain the intrinsic fabric properties in terms of mechanical flexibility, water‐vapor permeability, and comfort against multiple uses and laundry cycles. The e‐textiles tightly fit various body sizes and shapes to support the high‐fidelity recording of physiological and electrophysiological signals on the skin under ambulatory conditions. Pilot field tests in a remote health‐monitoring setting with a large animal, such as a horse, demonstrate the scalability and utility of the e‐textiles beyond conventional devices. This approach will be suitable for the rapid prototyping of custom e‐textiles tailored to meet various clinical needs.

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“…In this case, a power output of 5.5·10 −11 Watt can be realized at the consumer. An optimization of the assembly with an increased number of junctions, an optimized geometry and the use of copper-coated textiles that show even lower electrical resistivity [ 20 ], will directly lead to a higher energy output. This becomes clear when comparing the textile-foil-based assembly with the foil-based assembly, which offers a current flow of 385 nA and a power output of 14.7·10 −11 Watt.…”

Section: Resultsmentioning

confidence: 99%

Multi-Point Flexible Temperature Sensor Array and Thermoelectric Generator Made from Copper-Coated Textiles

Landsiedel

Root

Aguiló-Aguayo

et al. 2021

Sensors

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The integration of electrical functionality into flexible textile structures requires the development of new concepts for flexible conductive material. Conductive and flexible thin films can be generated on non-conductive textile materials by electroless metal deposition. By electroless copper deposition on lyocell-type cellulose fabrics, thin conductive layers with a thickness of approximately 260 nm were prepared. The total copper content of a textile fabric was analyzed to be 147 mg per g of fabric, so that the textile character of the material remains unchanged, which includes, for example, the flexibility and bendability. The flexible material could be used to manufacture a thermoelectric sensor array and generator. This approach enables the formation of a sensor textile with a large number of individual sensors and, at the same time, a reduction in the number of electrical connections, since the conductive textile serves as a common conductive line for all sensors. In combination with aluminum, thermoelectric coefficients of 3–4 µV/K were obtained, which are comparable with copper/aluminum foil and bulk material. Thermoelectric generators, consisting of six junctions using the same material combinations, led to electric output voltages of 0.4 mV for both setups at a temperature difference of 71 K. The results demonstrate the potential of electroless deposition for the production of thin-film-coated flexible textiles, and represent a key technology to achieve the direct integration of electrical sensors and conductors in non-conductive material.

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

Cited by 12 publications

References 23 publications

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres

A Programmable Dual‐Regime Spray for Large‐Scale and Custom‐Designed Electronic Textiles

Multi-Point Flexible Temperature Sensor Array and Thermoelectric Generator Made from Copper-Coated Textiles

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

Cited by 12 publications

References 23 publications

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu2O Spheres

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu2O Spheres

A Programmable Dual‐Regime Spray for Large‐Scale and Custom‐Designed Electronic Textiles

Multi-Point Flexible Temperature Sensor Array and Thermoelectric Generator Made from Copper-Coated Textiles

Contact Info

Product

Resources

About

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres

Structural Colored Fabrics with Brilliant Colors, Low Angle Dependence, and High Color Fastness Based on the Mie Scattering of Cu₂O Spheres