Title :
Sub-nanometer displacement sensing for the Nanogate - a tunable nanometer gap
Author :
Ma, Hongshen ; White, James ; Paradiso, Joseph ; Slocum, Alexander
Author_Institution :
Responsive Environments Group, MIT Media Lab., Cambridge, MA, USA
Abstract :
We have developed a sub-nanometer level displacement sensing system for a MEMS device called the Nanogate. The Nanogate is a tunable nanometer gap between ultra smooth surfaces of silicon and Pyrex. The separation between the surfaces can be as small as a few nanometers to as large as one micron. The Nanogate was created as a valve for precisely controlling very small gas and liquid flows, but it is also envisioned as a device where the variable gap can be used to filter particles and molecules by size. One advantage of our system is that the displacement measurement does not directly measure the capacitance of the nanometer gap hence does not depend on the dielectric properties of the material flowing in the gap. Our results show our capacitive sensor with a noise floor of 1.2Å RMS and long-term drift of 2.5nm.
Keywords :
capacitive sensors; displacement measurement; flow control; microfluidics; nanotechnology; 2.5 nm; MEMS device; Nanogate; bioMEMS; capacitance measurement; capacitive sensing; capacitive sensor; dielectric properties; displacement measurement; flow control; gas flow; liquid flow; microfluidics; nanoscale sensing; noise floor; sub-nanometer level displacement sensing system; tunable nanometer gap; ultra smooth surface; Capacitance measurement; Dielectric measurements; Displacement measurement; Filters; Fluid flow; Microelectromechanical devices; Nanoscale devices; Silicon; Size control; Valves;
Conference_Titel :
Sensors, 2003. Proceedings of IEEE
Print_ISBN :
0-7803-8133-5
DOI :
10.1109/ICSENS.2003.1278893
