Title :
Anodic bonding of optical fibers to silicon for integrating MEMS based optical pressure and temperature sensors onto optical fibers
Author :
Saran, A. ; Abeysinghe, D.C. ; Deshmukh, P. ; Flenniken, R. ; Boyd, J.T.
Author_Institution :
Opto-Electron. Lab., Cincinnati Univ., OH, USA
Abstract :
In this paper we present novel anodic bonding of optical fibers to silicon wafers of conventional thickness. In this technique we use an ultra-thin silicon layer as an intermediate stress reducing layer. Anodic bonding of optical fibers to silicon enables integration of optical pressure sensors and temperature sensors for harsh and biomedical environments onto optical fibers by non-adhesive means. Non-adhesive integration of MEMS sensors onto optical fibers will lead to creation of new class of devices. Results include tensile bond strength test that indicate maximum average tensile strength of the fiber-to-thick silicon bonds is 4.29 MPa corresponding to bonding at 400/spl deg/C and ANSYS simulation which verify the role of ultra thin silicon as a stress reducing layer.
Keywords :
biosensors; bonding processes; elemental semiconductors; integrated optics; internal stresses; microsensors; optical fibres; optical sensors; pressure sensors; semiconductor thin films; silicon; tensile strength; 400 degC; ANSYS simulation; Si; anodic bonding; biomedical environments o; fiber-thick silicon bonds; integrating MEMS; intermediate stress reducing layer; nonadhesive; optical fibers; optical pressure sensors; temperature sensors; tensile bond strength; ultra-thin silicon layer; Biomedical optical imaging; Integrated optics; Micromechanical devices; Optical fiber sensors; Optical fibers; Optical sensors; Silicon; Temperature sensors; Tensile stress; Wafer bonding;
Conference_Titel :
TRANSDUCERS, Solid-State Sensors, Actuators and Microsystems, 12th International Conference on, 2003
Conference_Location :
Boston, MA, USA
Print_ISBN :
0-7803-7731-1
DOI :
10.1109/SENSOR.2003.1215379
