Lithography-Free, Large-Area Spatially Segmented Disordered Structure for Light Harvesting in Photovoltaic Modules

Ko, Joo Hwan; Kim, Sohee; Kim, Min Seok; Heo, Se‐Yeon; Yoo, Young Jin; Kim, Yeong Jae; Lee, Heon; Song, Young Min

doi:10.1021/acsami.2c12131

Cited by 5 publications

(3 citation statements)

References 59 publications

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“…The aluminum nanoparticles were then produced on an Ultra High Vacuum electron beam evaporator (AJA International). In agreement with previous studies ( 20 , 34 – 36 ), we find that three parameters play a critical role in the geometry of the self-assembled monolayer: the temperature of the substrate, the pressure in the chamber, and the rate of growth. We chose these parameters compromising between the desired higher saturation of colors and the lower requirements for fabrication that ensures the versatility of the proposed architecture and the viability of a transition to industrial-scale production.…”

Section: Methodssupporting

confidence: 92%

Ultralight plasmonic structural color paint

et al. 2023

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All present commercial colors are based on pigments. While such traditional pigment-based colorants offer a commercial platform for large-volume and angle insensitiveness, they are limited by their instability in atmosphere, color fading, and severe environmental toxicity. Commercial exploitation of artificial structural coloration has fallen short due to the lack of design ideas and impractical nanofabrication techniques. Here, we present a self-assembled subwavelength plasmonic cavity that overcomes these challenges while offering a tailorable platform for rendering angle and polarization-independent vivid structural colors. Fabricated through large-scale techniques, we produce stand-alone paints ready to be used on any substrate. The platform offers full coloration with a single layer of pigment, surface density of 0.4 g/m 2 , making it the lightest paint in the world.

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Section: Methodssupporting

confidence: 92%

Ultralight plasmonic structural color paint

et al. 2023

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“…Aside from the vibrational energies, photogenerated energies (often in form of solar energies) are also ubiquitous in nature. The existing devices for photoenergy harvesting or conversion are mostly in planar configurations, such as solar cells, ,, photoelectrochemical water splitting (PEC) cells, − devices for artificial photosynthesis, photocatalytic CO 2 reductions cells, , and so on. Due to the angle-dependent optical properties of 2D structures (e.g., absorption, reflection, transmittance, scattering, and other forms of optical interactions), planar devices are not able to take full use of solar energies (e.g., shadowing caused by low incident angles of lights).…”

Section: Structure-induced Functionalitiesmentioning

confidence: 99%

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Bo,

Xu,

Yang

et al. 2023

Chem. Rev.

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Architected flexible electronic devices with rationally designed 3D geometries have found essential applications in biology, medicine, therapeutics, sensing/imaging, energy, robotics, and daily healthcare. Mechanically-guided 3D assembly methods, exploiting mechanics principles of materials and structures to transform planar electronic devices fabricated using mature semiconductor techniques into 3D architected ones, are promising routes to such architected flexible electronic devices. Here, we comprehensively review mechanically-guided 3D assembly methods for architected flexible electronics. Mainstream methods of mechanically-guided 3D assembly are classified and discussed on the basis of their fundamental deformation modes (i.e., rolling, folding, curving, and buckling). Diverse 3D interconnects and device forms are then summarized, which correspond to the two key components of an architected flexible electronic device. Afterward, structure-induced functionalities are highlighted to provide guidelines for function-driven structural designs of flexible electronics, followed by a collective summary of their resulting applications. Finally, conclusions and outlooks are given, covering routes to achieve extreme deformations and dimensions, inverse design methods, and encapsulation strategies of architected 3D flexible electronics, as well as perspectives on future applications.

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“…Coatings also offer opportunities to leverage the structure–property relations of a wide range of optical surface structures. To date, improvements in solar cell performance have been demonstrated through nanoparticles surface coatings, nanostructured diffraction and diffuse layers, nanotexturing, geometric optical structure, among many others. − …”

Section: Introductionmentioning

confidence: 99%

Fluorescent Waveguide Lattices for Enhanced Light Harvesting and Solar Cell Performance

Ding

Hosein

2023

ACS Appl. Energy Mater.

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We present the properties and performance of fluorescent waveguide lattices as coatings for solar cells, designed to address the significant mismatch between the solar cell’s spectral response range and the solar spectrum. Using arrays of microscale visible light optical beams transmitted through photoreactive polymer resins comprising acrylate and silicone monomers and fluorescein o,o′-dimethacrylate comonomer, we photopolymerize well-structured films with single and multiple waveguide lattices. The materials exhibited bright green-yellow fluorescence emission through down-conversion of blue-UV excitation and light redirection from the dye emission and waveguide lattice structure. This enables the films to collect a broader spectrum of light, spanning UV–vis–NIR over an exceptionally wide angular range of ±70°. When employed as encapsulant coatings on commercial silicon solar cells, the polymer waveguide lattices exhibited significant enhancements in solar cell current density. Below 400 nm, the primary mode of enhancement is through down-conversion and light redirection from the dye emission and collection by the waveguides. Above 400 nm, the primary modes of enhancement were a combination of down-conversion, wide-angle light collection, and light redirection from the dye emission and collection by the waveguides. Waveguide lattices with higher dye concentrations produced more well-defined structures better suited for current generation in encapsulated solar cells. Under standard AM 1.5 G irradiation, we observed nominal average current density increases of 0.7 and 1.87 mA/cm2 for single waveguide lattices and two intersecting lattices, respectively, across the full ±70° range and reveal optimal dye concentrations and suitable lattice structures for solar cell performance. Our findings demonstrate the significant potential of incorporating down-converting fluorescent dyes in polymer waveguide lattices for improving the current spectral and angular response of solar cell technologies toward increasing clean energy in the energy grid.

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Lithography-Free, Large-Area Spatially Segmented Disordered Structure for Light Harvesting in Photovoltaic Modules

Cited by 5 publications

References 59 publications

Ultralight plasmonic structural color paint

Ultralight plasmonic structural color paint

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Fluorescent Waveguide Lattices for Enhanced Light Harvesting and Solar Cell Performance

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