Anti‐reflection and hydrophobic characteristics of M‐PDMS based moth‐eye nano‐patterns on protection glass of photovoltaic systems

Shin, Ju Hyeon; Han, Ke; Lee, Heon

doi:10.1002/pip.1051

Cited by 51 publications

(32 citation statements)

References 20 publications

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“…Only breakthrough technologies are led by the university or research institutes . The core technology projects are also led by private industry targeting earlier commercialization.…”

Section: Level and Share Of The Public Support In The Three Targeted mentioning

confidence: 99%

Solar energy support in the Asia–Pacific region

Avril

Mansilla

Lemaire

2012

Progress in Photovoltaics

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“…Only breakthrough technologies are led by the university or research institutes . The core technology projects are also led by private industry targeting earlier commercialization.…”

Section: Level and Share Of The Public Support In The Three Targeted mentioning

confidence: 99%

Solar energy support in the Asia–Pacific region

Avril

Mansilla

Lemaire

2012

Progress in Photovoltaics

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“…5 For these reasons, numerous studies have been conducted to reduce the accumulation of dust on the cover glass as well as to increase the efficiency of the solar cell module itself. [6][7][8] For example, micro shell arrays on flexible polydimethylsiloxane have shown super-hydrophobicity with low hysteresis, leading to a significant self-cleaning effect. 6 Moth-eye patterns on the protective glass have been used to decrease the reflection of incident light and have demonstrated desirable hydrophobicity with improved performance in photovoltaic systems.…”

Section: Introductionmentioning

confidence: 99%

Improvement of the self-cleaning capabilities and transparency of cover glasses for solar cell applications by modification with atmospheric pressure plasma

et al. 2016

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Using a cover glass is indispensable for protecting solar cells in photovoltaic systems. Herein, the surface of the cover glass was modified by atmospheric pressure plasma to enhance the self-cleaning effect without degrading the transmittance. A lower surface energy was achieved by depositing fluorocarbon polymers, and a micro-nano multi-scale morphology was built on the cover glass within 50 s. These two properties led to an increase in the hydrophobicity, which enhanced the self-cleaning effect of the surface. The morphology of the surface also helped to improve the transparency by reducing reflections. Both the enhanced self-cleaning effect and the improved transparency induced by the atmospheric pressure plasma treatment were confirmed by analyzing the total conversion efficiency of a solar cell by outdoor field testing.

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“…A layer of protective glass is an essential material in solar power systems because the solar cell module is often used outdoors. The protective glass is intended to protect the solar cell modules from external forces such as physical shock, acid rain, and humidity, to name a few . However, one disadvantage of using a protective glass layer is that it decreases the incident light that reaches the solar cell as a result of the loss of reflected light at the surface of the protective glass.…”

Section: Introductionmentioning

confidence: 99%

Nanosized patterned protective glass exhibiting high transmittance and self-cleaning effects for photovoltaic systems

Kim

Shin

Cho

et al. 2014

Phys. Status Solidi A

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As a result of the rising concerns surrounding environmental pollution, green energy technologies are beginning to replace conventional power generation technology based on fossil fuels. In particular, photovoltaic systems which convert solar energy into electricity without generating carbon dioxide have been widely used around the world as a result of their conversion energy being exceptionally high. In this investigation, we fabricated anti‐reflection and light‐scattering patterns on the protective glass of solar cell modules. The path length and quantity of incident light reaching the solar cell module could be increased by incorporating anti‐reflection and light‐scattering patterns. These patterns were fabricated on the surface of the protective glass using nanoimprint lithography (NIL) and inductively coupled plasma (ICP) processes. The amount of light reflected off the patterned protective glass decreased by up to 4% when the fabricated anti‐reflection patterns were implemented. Additionally, the surface of the patterned glass was superhydrophobic as a result of the self‐assembled monolayer (SAM) coating employed in this study. The lithium ion battery comprised of the solar module using patterned glass as a protective layer could be charged approximately 14% higher than the lithium ion battery comprised of the solar module using conventional textured glass as a protective layer.

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Anti‐reflection and hydrophobic characteristics of M‐PDMS based moth‐eye nano‐patterns on protection glass of photovoltaic systems

Cited by 51 publications

References 20 publications

Solar energy support in the Asia–Pacific region

Solar energy support in the Asia–Pacific region

Improvement of the self-cleaning capabilities and transparency of cover glasses for solar cell applications by modification with atmospheric pressure plasma

Nanosized patterned protective glass exhibiting high transmittance and self-cleaning effects for photovoltaic systems

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