Nanoelectromechanical Membranes for Multimode Mass Spectrometry

Author: Li, Jarvis

Year: 2014

Degree: Senior thesis (Major)

Advisors: Roukes, Michael Lee; Hung, Peter S.

Committee Members: Stone, Edward C.; Libbrecht, Kenneth George; Filippone, Bradley W.; Frautschi, Steven C.; Tombrello, Thomas A.; Politzer, Hugh David; Adhikari, Rana

Option: Physics

DOI: 10.7907/R6T2-MP04

Abstract

Nanoelectromechanical systems (NEMS) represent the next wave in miniaturizing various electrical and mechanical devices used in a variety of fields, such as physics, biology, and engineering. In particular, NEMS devices have high surface area to volume ratios, low power consumption, low mass, and extremely small footprints. These properties allow NEMS to explore more fundamental regimes of matter. Current NEMS mass spectrometry advancements have only utilized doubly-clamped beams and cantilevers. However to expand the measurement capabilities of NEMS mass spectrometry, we utilize a circular membrane geometry in order to build upon the existing measurements in 1 spatial dimension to measure mass spatially in 2-dimensions. Furthermore, membranes should provide a larger potential mass dynamic range. For this experiment, we utilize circular piezoelectric membranes of aluminum nitride and molybdenum stacks. For mass deposition, we utilize a technique known as matrix-assisted laser desorption/ionization (MALDI), which focuses a pulsed UV laser onto the desired sample embedded in a corresponding matrix. The energy causes a plume of particles to desorb off the sample and towards the device. As a particle lands on the device, we are able to deduce its mass from the shift in its resonant frequency. In particular we need to measure the first three resonant frequencies, since the frequency shifts also depend on the location the particle landed on the device. Here we show the viability of our detection setup, mass deposition setup, and our mass deposition results.

Files