Open AccessDevelopment of MEMS photoacoustic spectroscopy
Author(s) -
A. P. L. Robinson,
Matt Eichenfield,
Benjamin Griffin,
Heidi Z. Harvey,
Gregory N. Nielson,
Murat Okandan,
Eric Langlois,
Paul R. Resnick,
Michael Shaw,
Ian Young,
Richard C. Givler,
Charles M. Reinke
Publication year - 2014
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/1200669
Subject(s) - photoacoustic spectroscopy , microelectromechanical systems , calibration , reliability (semiconductor) , photoacoustic imaging in biomedicine , spectroscopy , computer science , optical fiber , materials science , nanotechnology , optics , physics , telecommunications , power (physics) , quantum mechanics
After years in the field, many materials suffer degradation, off-gassing, and chemical changes causing build-up of measurable chemical atmospheres. Stand-alone embedded chemical sensors are typically limited in specificity, require electrical lines, and/or calibration drift makes data reliability questionable. Along with size, these "Achilles’ heels" have prevented incorporation of gas sensing into sealed, hazardous locations which would highly benefit from in-situ analysis. We report on development of an all-optical, mid-IR, fiber-optic based MEMS Photoacoustic Spectroscopy solution to address these limitations. Concurrent modeling and computational simulation are used to guide hardware design and implementation.
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