AI Article Synopsis
- - Researchers are exploring how the structure of silicon at the nanoscale affects its optical properties, which has applications in optics, energy harvesting, and various industries like anti-reflective coatings.
- - This study focuses on creating silicon photonic crystals by controlling etching techniques to form ordered arrays of inverted silicon nanopyramids and nanopillars, achieving uniformity and reproducibility in the patterns.
- - Experimental results show that the reflection characteristics of these nanostructures depend on their aspect ratio and spacing, with visible-light scattering patterns being modifiable through the arranged nanostructures, indicating potential uses in optics, electronics, and energy applications.
Article Abstract
Searching for the relationship between the nanostructure and optical properties has always been exciting the researchers in the field of optics (linear optics as well as non-linear optics), energy harvesting (anti-reflective Si solar cells, perovskite solar cells, ..., etc.), and industry (anti-reflection coating on car windows, sunglasses, etc.). In this work, we present an approach for nanostructuring the silicon substrate to silicon photonic crystals. By precisely controlling the etching time and etching path after using nanoimprint lithography, ordered arrays of inverted Si nanopyramids and Si nanopillars with good homogeneity, uniform surface roughness, high reproducibility of pattern transfer, and a controllable aspect ratio are prepared. Experimental investigation of the optical properties indicates that the reflections of these Si nanostructures are mainly determined by the aspect ratio as well as the period of nanostructures. Furthermore, we have experimentally observed visible-light scattering (V-LS) patterns on inverted Si nanopyramids and Si nanopillars, and their corresponding patterns can be precisely controlled by the patterned nanostructures. The V-LS pattern, background, and "ghost peaks" on the angle-resolved scattering results are caused by constructive interference, destructive interference, and the interference situation between both. This controllable nanopatterning on crystalline Si substrates with precisely tunable optical properties shows great potential for applications in many fields, for example, optics, electronics, and energy.
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| http://dx.doi.org/10.1021/acsami.1c16182 | DOI Listing |
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