Recent Applications of Antireflection Coatings in Solar Cells

Ji, Chunxue; Liu, Wen; Bao, Yidi; Chen, Xiaoling; Yang, Guiqiang; Wei, Bo; Yang, Fuhua; Wang, Xiaodong

doi:10.3390/photonics9120906

Cited by 27 publications

(14 citation statements)

References 96 publications

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“…To reduce reflection for solar cells and photodiodes, antireflection coatings (ARCs) [52][53][54] and surface texturing techniques [55][56][57][58][59][60][61] are designed. By carefully engineering the refractive index of the surface, the reflection can be minimized, allowing more light, particularly in the wavelength range of interest, to pass into the semiconductor material and be absorbed, resulting in higher device performance and new applications.…”

Section: Reduced Light Transmission Into Solar Cells and Photodiodesmentioning

confidence: 99%

Bridging the gap between surface physics and photonics

Laukkanen,

Punkkinen,

Kuzmin

et al. 2024

Rep. Prog. Phys.

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Use and performance criteria of photonic devices increase in various application areas such as information and communication, lighting, and photovoltaics. In many current and future photonic devices, surfaces of a semiconductor crystal are a weak part causing significant photo-electric losses and malfunctions in applications. These surface challenges, many of which arise from material defects at semiconductor surfaces, include signal attenuation in waveguides, light absorption in light emitting diodes, non-radiative recombination of carriers in solar cells, leakage (dark) current of photodiodes, and light reflection at solar cell interfaces for instance. To reduce harmful surface effects, the optical and electrical passivation of devices has been developed for several decades, especially with the methods of semiconductor technology. Because atomic scale control and knowledge of surface-related phenomena have become relevant to increase the performance of different devices, it might be useful to enhance the bridging of surface physics to photonics. Toward that target, we review some evolving research subjects with open questions and possible solutions, which hopefully provide example connecting points between photonic device passivation and surface physics. One question is related to the properties of the wet chemically cleaned semiconductor surfaces which are typically utilized in device manufacturing processes, but which appear to be different from crystalline surfaces studied in ultrahigh vacuum by physicists. In devices, a defective semiconductor surface often lies at an embedded interface formed by a thin metal or insulator film grown on the semiconductor crystal, which makes the measurements of its atomic and electronic structures difficult. To understand these interface properties, it is essential to combine quantum mechanical simulation methods. This review also covers metal-semiconductor interfaces which are included in most photonic devices to transmit electric carriers to the semiconductor structure. Low-resistive and passivated contacts with an ultrathin tunnelling barrier are an emergent solution to control electrical losses in photonic devices.

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Section: Reduced Light Transmission Into Solar Cells and Photodiodesmentioning

confidence: 99%

Bridging the gap between surface physics and photonics

Laukkanen,

Punkkinen,

Kuzmin

et al. 2024

Rep. Prog. Phys.

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“…Currently, multilayer composite thin-film coating is the most common approach to achieving AR. 10,11 However, the stability of the multilayer structures may be insufficient for hightemperature applications. With the development of photonics technology, interfaces can be designed with periodic subwavelength-scale structures, such as pillars, holes, pyramids, and cones.…”

Section: Introductionmentioning

confidence: 99%

“…Currently, multilayer composite thin-film coating is the most common approach to achieving AR. , However, the stability of the multilayer structures may be insufficient for high-temperature applications. With the development of photonics technology, interfaces can be designed with periodic subwavelength-scale structures, such as pillars, holes, pyramids, and cones. − The refractive index on both sides of the interface can gradually change using relief structures, avoiding light loss or reflection caused by abrupt refractive index changes without increasing the influence of diffraction.…”

Section: Introductionmentioning

confidence: 99%

Periodic Al₂O₃ Nanohole Arrays on MgO (100) for a Low-Reflectivity External Cavity Fabry–Pérot Interferometer

Li,

Lei,

Liu

et al. 2024

ACS Appl. Nano Mater.

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Based on nanoimprint lithography and dry etching of stacked three-layer masks, we successfully prepared large-area periodic Al 2 O 3 nanohole arrays on MgO (100) substrates. At 1550 nm, the nanohole arrays increased the interface transmittance of MgO (100) from 93.2% to above 98.8%. Postannealing at 700 °C, the interface transmittance decreased only to 97.8%. Compared with typical multilayer antireflection coating, it is simpler and easier to prepare. Nanoholes are arranged in a square lattice. The radius is 250 nm, the period is 350 nm, and the height is 200 nm. During the etching process, we eliminated the serious impact of shrinking the round hole into a gear hole caused by microloading. The processed nanohole is an inverted truncated cone with a verticality of 83.7°. In addition, the potential of Al 2 O 3 nanohole arrays to interfere with interface reflections was effectively verified using spectrophotometry and the self-built low-reflectivity external cavity Fabry−Peŕot interference platform. This research provides us with important solutions for developing Fabry−Peŕot optical fiber devices with a higher demodulation accuracy.

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“…The existing research on ARL is divided into two main categories, namely, membrane structure and micronano-optical structure [11,12]. Wang et al theoretically and experimentally concluded that the experimental porous SiO 2 and MgF 2 double-layer anti-reflection can improve the short-circuit current density of siliconbased stacked cells, and the ARL has good anti-reflection properties in the range of 400-1200 nm [13].…”

Section: Introductionmentioning

confidence: 99%

New multilayer film photonic crystal grating multilayer anti-reflection layer for visible-near-infrared solar cells

Chenghao,

Jun,

Yapeng

et al. 2024

Eng. Res. Express

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In this paper, a new anti-reflection layer(ARL) is designed by the finite element method, which is made of parabolic air slots with periodic distribution etched on a multilayer film structure with optimized thickness. The effective transmissivity in the 400-1450nm band is formulated in conjunction with the AM1.5 solar spectrum, and the effects of the air slot depth (H), depth-to-width ratio, and the size of period (T) on the transmissivity of the ARL are investigated separately. By optimizing the structural parameters, a new type of ARL with H=310nm and T=105nm acting in the 400-1450 nm waveband was obtained. The transmissivity of this stacked structure ARL is improved and the stability of the transmission effect in the full waveband is enhanced compared to the conventional membrane structure and the emerging micro-nano-optical structure. The effective transmissivity of this multilayer film photonic crystal grating ARL is calculated to be 98.43% in the operating full waveband (400-1450nm) of the Si-0.86eVPbS double-junction solar cell. The transmissivity is higher than 93.83% of multilayer film ARL and 97.13% of TiO2 grating ARL.

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Recent Applications of Antireflection Coatings in Solar Cells

Cited by 27 publications

References 96 publications

Bridging the gap between surface physics and photonics

Bridging the gap between surface physics and photonics

Periodic Al₂O₃ Nanohole Arrays on MgO (100) for a Low-Reflectivity External Cavity Fabry–Pérot Interferometer

New multilayer film photonic crystal grating multilayer anti-reflection layer for visible-near-infrared solar cells

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Recent Applications of Antireflection Coatings in Solar Cells

Cited by 27 publications

References 96 publications

Bridging the gap between surface physics and photonics

Bridging the gap between surface physics and photonics

Periodic Al2O3 Nanohole Arrays on MgO (100) for a Low-Reflectivity External Cavity Fabry–Pérot Interferometer

New multilayer film photonic crystal grating multilayer anti-reflection layer for visible-near-infrared solar cells

Contact Info

Product

Resources

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Periodic Al₂O₃ Nanohole Arrays on MgO (100) for a Low-Reflectivity External Cavity Fabry–Pérot Interferometer