High‐Performance Flexible Transparent Electrode with an Embedded Metal Mesh Fabricated by Cost‐Effective Solution Process

Khan, Arshad; Lee, Sang Eon; Jang, Taehee; Xiong, Ze; Zhang, Cuiping; Tang, Jinyao; Guo, L. Jay; Li, Wen‐Di

doi:10.1002/smll.201600309

Cited by 187 publications

(236 citation statements)

References 73 publications

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“…Recently, uniform metal mesh structures prepared with nano-patterning lithography techniques such as photolithography, 29 nano-imprint lithography, [30][31][32] grain boundary lithography, 33 colloid sphere lithography, 34,35 AAO template lithography, 36 and electroplating lithography 37 have also attracted great interest as another alternative to ITO because their optical transmittance and electrical conductivity can easily be tuned by controlling the line width, line pitch, and film thickness. However, these approaches produce classical two-dimensional metal mesh structures with the typical trade-off between optical transmittance and electrical conductivity: wider and denser structures have high electrical conductivity, but at the price of reduced optical transmittance and vice versa.…”

Section: Introductionmentioning

confidence: 99%

A three-dimensional metal grid mesh as a practical alternative to ITO

et al. 2016

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The development of a practical alternative to indium tin oxide (ITO) is one of the most important issues in flexible optoelectronics. In spite of recent progress in this field, existing approaches to prepare transparent electrodes do not satisfy all of their essential requirements. Here, we present a new substrate-embedded tall (∼350 nm) and thin (∼30 nm) three-dimensional (3D) metal grid mesh structure with a large area, which is prepared via secondary sputtering. This structure satisfies most of the essential requirements of transparent electrodes for practical applications in future opto-electronics: excellent optoelectronic performance (a sheet resistance of 9.8 Ω□(-1) with a transmittance of 85.2%), high stretchability (no significant change in resistance for applied strains <15%), a sub-micrometer mesh period, a flat surface (a root mean square roughness of approximately 5 nm), no haze (approximately 0.5%), and strong adhesion to polymer substrates (it survives attempted detachment with 3M Scotch tape). Such outstanding properties are attributed to the unique substrate-embedded 3D structure of the electrode, which can be obtained with a high aspect ratio and in high resolution over large areas with a simple process. As a demonstration of its suitability for practical applications, our transparent electrode was successfully tested in a flexible touch screen panel. We believe that our approach opens up new practical applications in wearable electronics.

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Section: Introductionmentioning

confidence: 99%

A three-dimensional metal grid mesh as a practical alternative to ITO

et al. 2016

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“…Metal micro- and nano-mesh electrodes have attracted considerable attention recently because the thickness, spacing, and line-widths of metal patterns can be easily modified to obtain desirable optical and electrical properties with the benefit of air-processable conditions. These metal meshes have been fabricated by various methods such as pattern-masked evaporation2021, nanoimprint lithography172223, inkjet24, flexographic25, transfer2627 and gravure-offset printing1228. However, these electrodes also suffer from high surface roughness, resulting in the possibility of electrical short-circuits between the TCEs and the top electrode.…”

mentioning

confidence: 99%

Ultra-Smooth, Fully Solution-Processed Large-Area Transparent Conducting Electrodes for Organic Devices

Jin

Ginting

et al. 2016

Sci Rep

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A novel approach for the fabrication of ultra-smooth and highly bendable substrates consisting of metal grid-conducting polymers that are fully embedded into transparent substrates (ME-TCEs) was successfully demonstrated. The fully printed ME-TCEs exhibited ultra-smooth surfaces (surface roughness ~1.0 nm), were highly transparent (~90% transmittance at a wavelength of 550 nm), highly conductive (sheet resistance ~4 Ω ◻−1), and relatively stable under ambient air (retaining ~96% initial resistance up to 30 days). The ME-TCE substrates were used to fabricate flexible organic solar cells and organic light-emitting diodes exhibiting devices efficiencies comparable to devices fabricated on ITO/glass substrates. Additionally, the flexibility of the organic devices did not degrade their performance even after being bent to a bending radius of ~1 mm. Our findings suggest that ME-TCEs are a promising alternative to indium tin oxide and show potential for application toward large-area optoelectronic devices via fully printing processes.

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“…The transmittance of fully filled Cu metal-mesh including polyethylene terephthalate (PET) substrate is about 88.1% while 90% for only a Ag seed layer. [14,18,29] Although Cu metal-mesh TCF has a reddish color, which has some disadvantages for practical device applications, a thin nickel layer of about 10-20 nm on top of copper would be electroplated to eliminate the reddish color, as shown in Figure S11 (Supporting Information). In parallel, sheet resistance from only a seed layer to fully filling Cu in the microgrooves varied from 50.8 to 0.29 Ω □ −1 .…”

Section: Resultsmentioning

confidence: 99%

“…The relationship between the sheet resistance and transparency was calculated by using the equation below [10,29,30] The relationship between the sheet resistance and transparency was calculated by using the equation below [10,29,30] …”

Section: Resultsmentioning

confidence: 99%

Printable High‐Aspect Ratio and High‐Resolution Cu Grid Flexible Transparent Conductive Film with Figure of Merit over 80 000

Chen

Nie

Guo

et al. 2019

Adv Elect Materials

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Figure of merit (FOM), the ratio of electrical conductance to optical transparency, is an important metric to evaluate transparent conductive film (TCF). The conductivity of commonly used flexible TCF such as indium tin oxide is generally limited and their FOM is lower than 300. In this study, a high‐performance copper (Cu) metal‐mesh TCF with the highest FOM ever reported, up to 8 × 104, is fabricated through an additive manufacturing process of blading a silver seed layer and selective electroplating of Cu. With this strategy, Cu metallic lines completely constrained in roll‐to‐roll imprinted microgrooves achieve high aspect ratio of 2 with 4 µm width and 8 µm depth, which has very clean and smooth edges. This embedded Cu metal mesh exhibits an ultralow sheet resistance down to 0.03 Ω □−1 at 86% optical transmittance. It is demonstrated that the Cu metal mesh has remarkable mechanical flexibility, high environmental stability at high temperature and humidity, and durability over repeated heating cycles. The Cu metal mesh is employed as a flexible transparent heater to attach to the windshield of a car, showing rapid heating at low voltage and effective removal of snow.

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High‐Performance Flexible Transparent Electrode with an Embedded Metal Mesh Fabricated by Cost‐Effective Solution Process

Cited by 187 publications

References 73 publications

A three-dimensional metal grid mesh as a practical alternative to ITO

A three-dimensional metal grid mesh as a practical alternative to ITO

Ultra-Smooth, Fully Solution-Processed Large-Area Transparent Conducting Electrodes for Organic Devices

Printable High‐Aspect Ratio and High‐Resolution Cu Grid Flexible Transparent Conductive Film with Figure of Merit over 80 000

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