Multifunctional Inverted Nanocone Arrays for Non‐Wetting, Self‐Cleaning Transparent Surface with High Mechanical Robustness

Kim, Jeong-Gil; Choi, Hyeongrak; Park, Kyoo Chul; Cohen, Robert E.; McKinley, Gareth H.; Barbastathis, George

doi:10.1002/smll.201303051

Cited by 78 publications

(59 citation statements)

References 49 publications

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“…59 Using another technique, Kim et al demonstrated an inverted nanocone array in polyurethane acrylate (PUA) which had good optical and mechanical properties, as well as non-wetting and self-cleaning behavior. 68 The same research group has also demonstrated improved transmission as well as superhydrophobicity in nanotextured glass surfaces. 69 Another technique is using an electrodynamic screen (EDS) to clean dust off reflectors.…”

Section: Reflector Degradationmentioning

confidence: 97%

Concentrating Solar Power

et al. 2015

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Concentrating solar power (CSP) is a reliable and wellknown form of solar power. Nine solar trough plants producing more than 400 megawatts (MW) of electricity have been operating reliably in the California Mojave Desert since the 1980s. With a renewed sense of urgency to commercialize renewable energy sources, the U.S. Department of Energy (DOE) is ramping up its CSP research, development, and deployment efforts. These efforts, which are leveraging both industry partners and the national laboratories, are directed toward the development of parabolic trough, dish/engine, and power tower CSP systems.

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Section: Reflector Degradationmentioning

confidence: 97%

Concentrating Solar Power

et al. 2015

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“…Taking seeded silicon as a starting point for a high-Zn surface (Figure 3a), this initial morphology is 'pore-like,' i.e., holes in a continuous metallic top surface, with a dense structure. Such morphologies are highly similar to those that have recently been utilized for controlling optical properties and wetting in polymer systems, whereby the geometry was shown to give superior mechanical robustness due to the lack of buckling deformation under loading 36 . By employing BCP templating, the ZnO rod spacing was increased (Figure 3b-d), leading to distribution of the pores until, with the sparsest 235 K-23 K template (Figure 3d), the individual ZnO imprints were resolved.…”

Section: Results and Discussion Bmg Structural Tuning By Zno Growth Cmentioning

confidence: 57%

Multiscale patterning of a metallic glass using sacrificial imprint lithography

et al. 2015

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Bulk metallic glasses (BMGs) have been developed as a means to achieve durable multiscale, nanotextured surfaces with desirable properties dictated by topography for a multitude of applications. One barrier to this achievement is the lack of a bridging technique between macroscale thermoplastic forming and nanoimprint lithography, which arises from the difficulty and cost of generating controlled nanostructures on complex geometries using conventional top-down approaches. This difficulty is compounded by the necessary destruction of any resulting reentrant structures during rigid demolding. We have developed a generalized method to overcome this limitation by sacrificial template imprinting using zinc oxide (ZnO) nanostructures. It is established that such structures can be grown inexpensively and quickly with tunable morphologies on a wide variety of substrates out of solution, which we exploit to generate the nanoscale portion of the multiscale pattern through this bottom-up approach. In this way, we achieve metallic structures that simultaneously demonstrate features from the macroscale down to the nanoscale, requiring only the top-down fabrication of macro/microstructured molds. Upon detachment of the formed part from the multiscale molds, the ZnO remains embedded in the surface and can be removed by etching in mild conditions to both regenerate the mold and render the surface of the BMGs nanoporous. The ability to pattern metallic surfaces in a single step on length scales from centimeters down to nanometers is a critical step toward fabricating devices with complex shapes that rely on multiscale topography for their intended functions, such as biomedical and electrochemical applications.

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“…Подробное описание параметров текстуры поверх-ности было представлено МакКинли с сотрудниками [81,82]. Авторы рассматривают идеализированную поверхность со сферическими выступами (волокна-ми, рис.…”

Section: условия стабильности супергидрофобного состоянияunclassified