Title :
High resolution optical characterization of cantilever arrays and multiple air-gap cavities for scanning probe microscopy, communication, analytics and sensing
Author :
Scholz, T. ; Depski, T. ; Römer, F. ; Irmer, S. ; Viereck, V. ; Bartels, M. ; Barth, W. ; Hillmer, H.
Author_Institution :
Inst. of Microstruct. Technol. & Anal., Kassel Univ.
Abstract :
We present an ultra-precise optical methodology to investigate complex nano- and microscale structures fabricated by micromachining. This method is applied for micromachined tunable multiple air-gap GaInAsP microresonators as well as for Si cantilever arrays which are fabricated commercially. These different devices are applied in scanning probe microscopy, analytics, sensing and high bit-rate communication. A detailed comparison of experimental studies with results of theoretical model calculations is performed on the basis of line-shape-fits to provide precise geometric and compositional parameters. We obtain an excellent agreement between experimental and theoretical data
Keywords :
gallium arsenide; gallium compounds; indium compounds; micro-optics; microcavities; micromachining; optical tuning; scanning electron microscopy; silicon; GaInAsP; Si; Si cantilever arrays; bit-rate optical communication; complex microscale structures; complex nano-scale structures; high resolution optical characterization; micromachined tunable microresonators; multiple air-gap cavity; scanning probe microscopy; ultra-precise optical methodology; Air gaps; Composite materials; Mechanical factors; Optical arrays; Optical filters; Optical microscopy; Optical sensors; Process control; Scanning probe microscopy; Solid modeling;
Conference_Titel :
Optical MEMS and Their Applications Conference, 2005. IEEE/LEOS International Conference on
Conference_Location :
Oulu
Print_ISBN :
0-7803-9278-7
DOI :
10.1109/OMEMS.2005.1540109
