Title :
Nanometer-thin titania films with SAM-level stiction and superior wear resistance for reliable MEMS performance
Author :
Ashurst, R. ; Jang, Young Jae ; Magagnin, L. ; Carraro, C. ; Sung, M.M. ; Maboudian, Roya
Author_Institution :
California Univ., Berkeley, CA, USA
Abstract :
Most MEMS devices involving contacting surfaces suffer from stiction and wear. While the development of self-assembled monolayer (SAM)-based processes has virtually eliminated stiction, wear remains a serious reliability issue. In this paper, the use of titania ultra-thin films as a means to reduce both stiction and wear is reported. Atomic layer deposition (ALD) is used for the film growth in order to ensure a uniform and conformal coating, effectively encapsulating the released polysilicon microelectromechanical systems (MEMS) devices. The application of 10-nm thin titania coating is shown to result in improved reliability of test microdevices. To further improve reliability, a vapor phase SAM coating is applied to TiO2 encapsulated micromachines. Results on the tribological properties of both TiO2-and SAM coated TiO2-encapsulated microdevices are presented.
Keywords :
micromechanical devices; monolayers; nanostructured materials; reliability; self-assembly; stiction; thin films; titanium compounds; vapour deposited coatings; wear resistance; 10 nm; MEMS devices; Si; TiO2; microdevices; microelectromechanical systems; nanometer titania ultrathin films; polysilicon; reliability; self-assembled monolayer; stiction; thin titania coating; tribological properties; vapor phase SAM coating; wear resistance; Atomic layer deposition; Biological materials; Coatings; Friction; Micromechanical devices; Optical films; Optical materials; Silicon; Surface contamination; Testing;
Conference_Titel :
Micro Electro Mechanical Systems, 2004. 17th IEEE International Conference on. (MEMS)
Print_ISBN :
0-7803-8265-X
DOI :
10.1109/MEMS.2004.1290545
