| Patent application number | Description | Published |
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| 20090200619 | SYSTEMS AND METHODS FOR MEMS DEVICE FABRICATION - Systems and methods for MEMS device fabrication. A layer of photoresist is formed on a substrate. A first region of the substrate is exposed to a radiation source through a photomask. The first region of exposed photoresist is developed with a developer solution in order to etch the exposed regions to a first depth. A second region is exposed to radiation through a second photomask. The second photomask defines areas in which a bump feature is intended on the substrate. The second region is developed with the developer solution, preparing the first and second exposed regions for a layer of metal. A layer of metal is deposited on the substrate, such that the metal attaches to both the substrate and any remaining photoresist on the substrate. The remaining photoresist and its attached metal is dissolved away leaving an interconnect pattern and at least one bump feature. | 08-13-2009 |
| 20090212386 | MEMS DEVICE AND METHOD OF MAKING SAME - A MEMS device includes a P-N device formed on a silicon pin, which is connected to a silicon sub-assembly, and where the P-N device is formed on a silicon substrate that is used to make the silicon pin before it is embedded into a first glass wafer. In one embodiment, forming the P-N device includes selectively diffusing an impurity into the silicon pin and configuring the P-N device to operate as a temperature sensor. | 08-27-2009 |
| 20100019364 | SAW DEBRIS REDUCTION IN MEMS DEVICES - An improved MEMS device and method of making. Channels are formed in a first substrate around a plurality of MEMS device areas previously formed on the first substrate. Then, a plurality of seal rings are applied around the plurality of MEMS device areas and over at least a portion of the formed channels. A second substrate is attached to the first substrate, then the seal ring surrounded MEMS device areas are separated from each other. The channels include first and second cross-sectional areas. The first cross-sectional area is sized to keep saw debris particles from entering the MEMS device area. | 01-28-2010 |
| 20100181652 | SYSTEMS AND METHODS FOR STICTION REDUCTION IN MEMS DEVICES - Systems and methods for reducing stiction between elements of a microelectromechanical systems (MEMS) device during anodic bonding. The MEMS device includes a substrate cover with an optional conductor on its interior surface and the cover is anchored to a first portion of a sensing element. The MEMS device further includes a second portion of the sensing element separated from the substrate cover with a space and an antistiction element disposed between the second portion and cover. The antistiction element can be formed of a material type with high electrostatic resistance, to prevent stiction between MEMS device elements during anodic bonding. | 07-22-2010 |
| 20100320595 | HYBRID HERMETIC INTERFACE CHIP - A hermetically sealed MEMS device package comprises a MEMS device platform, a hermetic interface chip, and an outer seal ring. The MEMS device platform includes a MEMS device surrounded by a continuous outer boundary wall with a top surface. The hermetic interface chip includes a glass substrate and at least one silicon mesa. The glass substrate includes at least one hole and has a lower surface with an inner portion surrounded by an outer portion. The at least one silicon mesa is bonded to the inner portion of the lower surface of the glass substrate, such that the at least one silicon mesa is aligned with the at least one hole in the glass substrate. The outer seal ring bonds the outer portion of the lower surface of the glass substrate to the top surface of the continuous outer boundary wall of the MEMS device platform. | 12-23-2010 |
| 20110187464 | APPARATUS AND METHODS FOR ALKALI VAPOR CELLS - Apparatus and methods for alkali vapor cells are provided. In one embodiment, a vapor cell for a Chip-Scale Atomic Clocks (CSAC) comprises a silicon wafer having defined within a first chamber, a second chamber, and a pathway connecting the first chamber to the second chamber; a first glass wafer anodically-bonded to a first surface of the silicon wafer; a second glass wafer anodically-bonded to an opposing second surface of the silicon wafer, wherein the first chamber defines an optical path through the vapor cell; and an alkali metal material deposited into the second chamber. The pathway connecting the first chamber to the second chamber is configured with a geometry that is at least partially inhibitive to alkali metal vapor flow. | 08-04-2011 |
| 20110187465 | DESIGN AND PROCESSES FOR STABILIZING A VCSEL IN A CHIP-SCALE ATOMIC CLOCK - A method to construct a chip-scale atomic clock is provided. The method comprises providing a scaffolding for components in a chip-scale atomic clock. The components include a laser and at least one other component. The method also includes operationally positioning the components on the scaffolding so that an emitting surface of the laser is non-parallel to partially reflective surfaces of the at least one other component. | 08-04-2011 |
| 20110187466 | CHIP-SCALE ATOMIC CLOCK WITH TWO THERMAL ZONES - A chip-scale atomic clock comprises a physics package and a laser die located in a first thermal zone of the physics package. A quarter wave plate is mounted in the physics package and is in optical communication with the laser die. A vapor cell is mounted in the physics package and is in optical communication with the quarter wave plate. The vapor cell is located in a second thermal zone that is independent from the first thermal zone. An optical detector is mounted in the physics package and is in optical communication with the vapor cell. The first thermal zone provides a first operation temperature at a first stability point associated with the laser die, and the second thermal zone provides a second operation temperature at a second stability point associated with the vapor cell. | 08-04-2011 |
| 20110188524 | DESIGNS AND PROCESSES FOR THERMALLY STABILIZING A VERTICAL CAVITY SURFACE EMITTING LASER (VCSEL) IN A CHIP-SCALE ATOMIC CLOCK - Designs and processes for thermally stabilizing a vertical cavity surface emitting laser (vcsel) in a chip-scale atomic clock are provided. In one embodiment, a Chip-Scale Atomic Clock includes: a vertical cavity surface emitting laser (vcsel); a heater block coupled to a base of the vcsel; a photo detector; a vapor cell, wherein the vapor cell includes a chamber that defines at least part of an optical path for laser light between the vcsel and the photo detector; and an iso-thermal cage surrounding the vcsel on all sides, the iso-thermal cage coupled to the heater block via a thermally conductive path. | 08-04-2011 |
| 20110189429 | FABRICATION TECHNIQUES TO ENHANCE PRESSURE UNIFORMITY IN ANODICALLY BONDED VAPOR CELLS - A method of fabricating vapor cells comprises forming a plurality of vapor cell dies in a first wafer having an interior surface region and a perimeter, and forming a plurality of interconnected vent channels in the first wafer. The vent channels provide at least one pathway for gas from each vapor cell die to travel outside of the perimeter of the first wafer. The method further comprises anodically bonding a second wafer to one side of the first wafer, and anodically bonding a third wafer to an opposing side of the first wafer. The vent channels allow gas toward the interior surface region of the first wafer to be in substantially continuous pressure-equilibrium with gas outside of the perimeter of the first wafer during the anodic bonding of the second and third wafers to the first wafer. | 08-04-2011 |
