AbstractThis paper presents a new method for wafer level vacuum packaging of MEMS devices using anodic bonding together with vertical feedthroughs formed on an SOI cap wafer, eliminating the need for any sealing material or any complex via-refill or trench-refill vertical feedthrough steps. The packaging yield is experimentally verified to be above 95%, and the cavity pressure is characterized to be as low as 1 mTorr with the help of a thin-film getter. The shear strength of several packages is measured to be above 15MPa
This paper reports a novel and inherently simple fabrication process, so-called advanced MEMS (aMEMS...
This paper presents a novel and inherently simple all-silicon fabrication and hermetic packaging met...
Vacuum and hermetic packaging is a critical requirement for optimal performance of many micro-electr...
This paper presents a new method for wafer level vacuum packaging of MEMS devices using anodic bondi...
AbstractThis paper presents a new method for wafer level vacuum packaging of MEMS devices using anod...
This paper presents a novel, inherently simple and low-cost fabrication and hermetic packaging metho...
A wafer-level packaging method for SOI-MEMS structures that are desired to be encapsulated in a herm...
A wafer-level vacuum package with silicon bumps and electrical feedthroughs on the cap wafer is deve...
IEEEThis paper introduces a novel, inherently simple, and all-silicon wafer-level fabrication and he...
In this paper the authors report about the six inch wafer level vacuum packaging of electro-statical...
A low-cost, hermetic wafer-level packaging solution with negligible parasitics suitable for MEMS res...
In this paper, a high performance wafer-level vacuum packaging technology based on GSG triple-layer ...
Results of wafer level packaging for micro-electro-mechanical systems based on low temperature melti...
Silicon-glass anodic bonding, commonly used for MEMS packaging, offers many advantages. However, out...
A novel vacuum (< 20 mTorr) encapsulation technology for the packaging of micro-electromechanical sy...
This paper reports a novel and inherently simple fabrication process, so-called advanced MEMS (aMEMS...
This paper presents a novel and inherently simple all-silicon fabrication and hermetic packaging met...
Vacuum and hermetic packaging is a critical requirement for optimal performance of many micro-electr...
This paper presents a new method for wafer level vacuum packaging of MEMS devices using anodic bondi...
AbstractThis paper presents a new method for wafer level vacuum packaging of MEMS devices using anod...
This paper presents a novel, inherently simple and low-cost fabrication and hermetic packaging metho...
A wafer-level packaging method for SOI-MEMS structures that are desired to be encapsulated in a herm...
A wafer-level vacuum package with silicon bumps and electrical feedthroughs on the cap wafer is deve...
IEEEThis paper introduces a novel, inherently simple, and all-silicon wafer-level fabrication and he...
In this paper the authors report about the six inch wafer level vacuum packaging of electro-statical...
A low-cost, hermetic wafer-level packaging solution with negligible parasitics suitable for MEMS res...
In this paper, a high performance wafer-level vacuum packaging technology based on GSG triple-layer ...
Results of wafer level packaging for micro-electro-mechanical systems based on low temperature melti...
Silicon-glass anodic bonding, commonly used for MEMS packaging, offers many advantages. However, out...
A novel vacuum (< 20 mTorr) encapsulation technology for the packaging of micro-electromechanical sy...
This paper reports a novel and inherently simple fabrication process, so-called advanced MEMS (aMEMS...
This paper presents a novel and inherently simple all-silicon fabrication and hermetic packaging met...
Vacuum and hermetic packaging is a critical requirement for optimal performance of many micro-electr...