Reduced Graphene Oxide Micromesh Electrodes for Large Area, Flexible, Organic Photovoltaic Devices

Flexible and semitransparent organic solar cells (OSCs) have been regarded as the most promising photovoltaic devices for the application of OSCs in wearable energy resources and building‐integrated photovoltaics. Therefore, the flexible and semitransparent OSCs have developed rapidly in recent years through the synergistic efforts in developing novel flexible bottom or top transparent electrodes, designing and synthesizing high performance photoactive layer and low temperature processed electrode buffer layer materials, and device architecture engineering. To date, the highest power conversion efficiencies have reached over 10% of the flexible OSCs and 7.7% with average visible transmittance of 37% for the semitransparent OSCs. Here, a comprehensive overview of recent research progresses and perspectives on the related materials and devices of the flexible and semitransparent OSCs is provided.

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Section: Wwwadvenergymatdementioning

confidence: 99%

Flexible and Semitransparent Organic Solar Cells

Cui

et al. 2017

Advanced Energy Materials

608

449

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“…In this context carbon is usually viewed in a negative light with most industries and nations trying to reduce their "carbon footprint" [5,6]. For these reasons increasing research focus has been placed on developing carbon materials for novel renewable applications [7,8]. Solar collectors and thermal energy storage components are two key subsystems in most solar thermal applications [9].…”

Section: Introductionmentioning

confidence: 99%

The use of graphite foams for simultaneous collection and storage of concentrated solar energy

Badenhorst

Fox

Mutalib

2016

Carbon

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Graphite foams of varying composition and density were prepared using a low cost, local pitch material and expandable graphite for use in solar energy capture. The foams have a high degree of graphitization but exhibit a fine mosaic texture. A small oxidative treatment (6% mass loss) was necessary to fully open the foam pores. As the density is reduced a large decrease in the foam surface area was observed. Despite this, an increase in solar energy capture efficiency was measured due to increased circulation through the foam. By varying foam geometry and the concentration ratio it was demonstrated that the receiver size can be reduced by 75% at the same efficiency.The foam with the lowest density was used to test the thermal performance of a simultaneous energy capture and storage concept using a phase change material. The melting time of the phase change material is reduced by 46% whilst only reducing the energy storage density by 18%. In addition it was found that the foam composite resulted in more ideal phase transition behaviour due to the elimination of incongruent melting. The composite can effectively capture, store and discharge thermal energy, at a constant temperature, without any additional requirements.

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“…Thicker layers afford high conductivity, but this increase comes at the expense of optical transmittance and vice versa, thus frequently affecting the performance of optoelectronic devices12. It is possible to improve the conductivity of TCEs through the use of metallic materials such as metal nanowires (NWs) and metal nano-mesh/micro-mesh materials1314. Recently, metal NWs, such as silver NWs, copper NWs, and gold NWs, have shown promise as alternative TCEs due to their high conductivities, transparency, and excellent flexibility151617.…”

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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Reduced Graphene Oxide Micromesh Electrodes for Large Area, Flexible, Organic Photovoltaic Devices

Cited by 122 publications

References 78 publications

Flexible and Semitransparent Organic Solar Cells

Flexible and Semitransparent Organic Solar Cells

The use of graphite foams for simultaneous collection and storage of concentrated solar energy

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

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