Real- and Q-space travelling: multi-dimensional distribution maps of crystal-lattice strain (epsilon(044)) and tilt of suspended monolithic silicon nanowire structures

Silicon nanowire-based sensors find many applications in micro- and nano-electromechanical systems, thanks to their unique characteristics of flexibility and strength that emerge at the nanoscale. This work is the first study of this class of micro- and nano-fabricated silicon-based structures adopting the scanning X-ray diffraction microscopy technique for mapping the in-plane crystalline strain (epsilon(044)) and tilt of a device which includes pillars with suspended nanowires on a substrate. It is shown how the micro- and nanostructures of this new type of nanowire system are influenced by critical steps of the fabrication process, such as electron-beam lithography and deep reactive ion etching. X-ray analysis performed on the 044 reflection shows a very low level of lattice strain (

Real- and Q-space travelling: multi-dimensional distribution maps of crystal-lattice strain (epsilon(044)) and tilt of suspended monolithic silicon nanowire structures

System and method for removing scalloping and tapering effects in high aspect ratio through-silicon vias of wafers

Monolithic Fabrication of Silicon Nanowires Bridging Thick Silicon Structures

Superplastic behavior of silica nanowires obtained by direct patterning of silsesquioxane-based precursors

System and method for removing scalloping and tapering effects in high aspect ratio through-silicon vias of wafers

Monolithic Fabrication of Silicon Nanowires Bridging Thick Silicon Structures

Superplastic behavior of silica nanowires obtained by direct patterning of silsesquioxane-based precursors