Title :
Gas tightness of cavities sealed by silicon wafer bonding
Author :
Mack, S. ; Baumann, H. ; Gösele, U.
Author_Institution :
Max-Planck-Inst. of Microstructure Phys., Halle, Germany
Abstract :
The hermetic sealing of cavities formed by low temperature silicon direct bonding (SDB) and anodic bonding (AB) of plain and structured silicon surfaces is quantitatively investigated: Gas leakage rates along the bonding interface are determined for pressure sensor test structures by monitoring the pressure increase after a 700 h storage in a 6 bar hydrogen atmosphere. Corresponding leakage rates under atmospheric conditions as small as 10-14 (mbar 1)/s could be determined by this method. In the case of AB and of hydrophilic SDB with plain bonding surfaces, no measurable gas leakage is observed. For SDB however, only 6 nm deep grooves on one bonding surface do already cause a considerable gas leakage. For AB grooves with a depth of up to ca. 50 nm are still perfectly sealed. Here, the electrostatic pressure leads to a surface conformation through mainly elastic deformation of the bonding surfaces
Keywords :
elemental semiconductors; leak detection; microsensors; pressure sensors; seals (stoppers); semiconductor device packaging; semiconductor device testing; silicon; wafer bonding; 50 nm; 6 bar; 6 nm; 700 h; H2; Si; Si wafer bonding; anodic bonding; bonding surfaces; cavities; direct bonding; elastic deformation; electrostatic pressure; gas leakage rates; gas tightness; hermetic sealing; hydrophilic SDB; leakage rates; low temperature silicon; plain bonding surfaces; pressure sensor; test structures; Atmosphere; Gas detectors; Glass; Hydrogen storage; Micromechanical devices; Silicon; Temperature; Testing; Voltage; Wafer bonding;
Conference_Titel :
Micro Electro Mechanical Systems, 1997. MEMS '97, Proceedings, IEEE., Tenth Annual International Workshop on
Conference_Location :
Nagoya
Print_ISBN :
0-7803-3744-1
DOI :
10.1109/MEMSYS.1997.581908
