Ties between Microsystems Technology and Nano-Engineering

Our research is centered on the engineering of structures at the mesoscopic length scale. Patterns between the micrometer and nanometer bridge molecules and biological cells to microelectronics and microsystems, and further to the macroworld, and vice versa. Standard photo-resist based lithography and micro/nano-fabrication methods, however, reach limits when applied to advanced micro- and nano-electromechanical systems (MEMS/NEMS). New alternative nanopatterning methods, such as local vacuum deposition through nanostencils, scanning probe methods, as well as nanostrucuturing with focused ion beam (FIB), are therefore being further developed in our lab. Some of our research activities, which cover the mesoscopic length scale that can bridge the “Top-Down” engineering methods and the “Bottom-Up” self-organization strategies, will be presented in this talk.

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Ties between Microsystems Technology and Nano-Engineering

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Thermomechanical nanocutting of 2D materials using thermal scanning probe lithography

Nanomechanical bio-sensing for fast and reliable detection of viability and susceptibility of microorganisms

Thermal scanning probe lithography-a review