Roughness Suppression in Electrochemical Nanoimprinting of Si for Applications in Silicon Photonics

Abstract: Metal‐assisted electrochemical nanoimprinting (Mac‐Imprint) scales the fabrication of micro‐ and nanoscale 3D freeform geometries in silicon and holds the promise to enable novel chip‐scale optics operating at the near‐infrared spectrum. However, Mac‐Imprint of silicon concomitantly generates mesoscale roughness (e.g., protrusion size ≈45 nm) creating prohibitive levels of light scattering. This arises from the requirement to coat stamps with nanoporous gold catalyst that, while sustaining etchant diffusion, i… Show more

“…Advances in in situ analysis to more precisely determine reaction species would certainly benefit the MacEtch community. The recent development of two-dimensional materials, 193,205,207,213 oxides, 25 and nitrides 209,214 as catalysts, one-pot MacEtch, 66,82 and MacImprint 36,215 techniques are promising developments on these issues. By the same token, the advantages of MacEtch have the potential to greatly innovate mainstay nanofabrication techniques, by improving processing throughput, reducing fabrication complexity, avoiding surface damage, and lowering costs.…”

Metal-assisted chemical etching beyond Si: applications to III–V compounds and wide-bandgap semiconductors

“…Advances in in situ analysis to more precisely determine reaction species would certainly benefit the MacEtch community. The recent development of two-dimensional materials, 193,205,207,213 oxides, 25 and nitrides 209,214 as catalysts, one-pot MacEtch, 66,82 and MacImprint 36,215 techniques are promising developments on these issues. By the same token, the advantages of MacEtch have the potential to greatly innovate mainstay nanofabrication techniques, by improving processing throughput, reducing fabrication complexity, avoiding surface damage, and lowering costs.…”

Metal-assisted chemical etching beyond Si: applications to III–V compounds and wide-bandgap semiconductors

“…In contrast, MacEtch allows to fabricate hierarchical features [45,46] with very sharp profile. MacEtch has been successfully demonstrated in combination with electron beam [47,48], UV [44,[49][50][51], flow-enabled self-assembly [52], tip-based [53], electrochemical nanoimprint [54] and chemisorption-assisted transfer printing [55] lithography. We recently reported a new method of MacEtch in gas phase (gas-MacEtch) [45], which combines the extremely high aspect ratio capability of this technique with the use of gas reactants to reduce the nanostructures stiction due to capillary effects during drying after wet etching [56].…”

High aspect ratio arrays of Si nano-pillars using displacement Talbot lithography and gas-MacEtch

“…Nanostructured high refractive index materials offer a powerful means for tailoring the optical characteristics of planar optical components used in flat-optics, [1] metamaterials, [2] integrated photonics, [3][4][5] and transformation optics. [6,7] For many planar optical devices ranging from diffractive elements [8] and metalenses, [9][10][11] to optical cloaks, [7] waveguide-based devices, [3,4,12,13] and more, an ideal design solution is to engineer a sub-wavelength spacing between the dielectric elements, or in other words to construct a sub-wavelength grating (SWG) metama-demonstrated in infrared glass-ceramics and nanocomposites by local modification with laser, [25] thermal, [23,24] or photothermal treatments, [26] with an achievable index contrast up to Δn = 0.1.…”

Digital and Gradient Refractive Index Planar Optics by Nanoimprinting Mesoporous Silicon