Abstract: A method for fabrication of single crystal silicon micromechanical resonators using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, a capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; viewing windows are opened in the active layer of the resonator wafer; masking the single crystal silicon semiconductor material active layer of the resonator wafer with photoresist material; a single crystal silicon resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist material is subsequently dry stripped.

Abstract: Alternative methods of constructing a vertically offset structure are disclosed. An embodiment includes forming a flexible layer having first and second end portions, an intermediate portion coupling the first and second portions, and upper and lower surfaces. The distance between the upper and lower surfaces at the intermediate portion is less than the distance between the upper and lower surfaces at the first and second end portions. The first end portion is bonded to a base member. The second end portion of the flexible layer is deflected until the second end portion contacts the base member. The second end portion is bonded to the base member.

Abstract: A method for fabrication of single crystal silicon micromechanical resonators using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, a capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; viewing windows are opened in the active layer of the resonator wafer; masking the single crystal silicon semiconductor material active layer of the resonator wafer with photoresist material; a single crystal silicon resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist material is subsequently dry stripped.

Abstract: Alternative methods of constructing a vertically offset structure are disclosed. An embodiment includes forming a flexible layer having first and second end portions, an intermediate portion coupling the first and second portions, and upper and lower surfaces. The distance between the upper and lower surfaces at the intermediate portion is less than the distance between the upper and lower surfaces at the first and second end portions. The first end portion is bonded to a base member. The second end portion of the flexible layer is deflected until the second end portion contacts the base member. The second end portion is bonded to the base member.

Abstract: The present invention provides systems and methods for pre-filter in a VHF receiver using Micro-Electro-Mechanical Systems (MEMS) filters. The system includes an antenna, and first and second Micro-Electro-Mechanical Systems (MEMS) filters. The first MEMS filter filters a signal received by the antenna based on a first pre-defined bandwidth, and the second MEMS filter filters the signal filtered by the first MEMS filter based on a second bandwidth. The system also includes an analog to digital converter that converts the signal filtered by the second MEMS filter into a digital signal, a down converter that down converts the digital signal produced by the A to D converter, and a digital signal processor that processes the down converted digital signal produced by the down converter. The first and second MEMS filters or the down converter are adjustable based on a received tuning signal.

Abstract: A method for forming a vibrating micromechanical structure having a single crystal silicon (SCS) micromechanical resonator formed using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; windows are opened in the active layer of the resonator wafer; masking the active layer of the resonator wafer with photoresist; a SCS resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist is subsequently dry stripped. A patterned SCS cover is bonded to the resonator wafer resulting in hermetically sealed chip scale wafer level vacuum packaged devices.

Abstract: A method for forming a vibrating micromechanical structure having a single crystal silicon (SCS) micromechanical resonator formed using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; windows are opened in the active layer of the resonator wafer; masking the active layer of the resonator wafer with photoresist; a SCS resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist is subsequently dry stripped. A patterned SCS cover is bonded to the resonator wafer resulting in hermetically sealed chip scale wafer level vacuum packaged devices.

Abstract: A method for fabrication of single crystal silicon micromechanical resonators using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, a capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; viewing windows are opened in the active layer of the resonator wafer; masking the single crystal silicon semiconductor material active layer of the resonator wafer with photoresist material; a single crystal silicon resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist material is subsequently dry stripped.

Abstract: A method for forming a vibrating micromechanical structure having a single crystal silicon (SCS) micromechanical resonator formed using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; windows are opened in the active layer of the resonator wafer; masking the active layer of the resonator wafer with photoresist; a SCS resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist is subsequently dry stripped. A patterned SCS cover is bonded to the resonator wafer resulting in hermetically sealed chip scale wafer level vacuum packaged devices.

Abstract: A method for forming a vibrating micromechanical structure having a single crystal silicon (SCS) micromechanical resonator formed using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; windows are opened in the active layer of the resonator wafer; masking the active layer of the resonator wafer with photoresist; a SCS resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist is subsequently dry stripped. A patterned SCS cover is bonded to the resonator wafer resulting in hermetically sealed chip scale wafer level vacuum packaged devices.

Abstract: A method for fabrication of single crystal silicon micromechanical resonators using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, a capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; viewing windows are opened in the active layer of the resonator wafer; masking the single crystal silicon semiconductor material active layer of the resonator wafer with photoresist material; a single crystal silicon resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist material is subsequently dry stripped.

Abstract: A method for forming a vibrating micromechanical structure having a single crystal silicon (SCS) micromechanical resonator formed using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; windows are opened in the active layer of the resonator wafer; masking the active layer of the resonator wafer with photoresist; a SCS resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist is subsequently dry stripped. A patterned SCS cover is bonded to the resonator wafer resulting in hermetically sealed chip scale wafer level vacuum packaged devices.

Abstract: A method for fabrication of single crystal silicon micromechanical resonators using a two-wafer process, including either a Silicon-on-insulator (SOI) or insulating base and resonator wafers, wherein resonator anchors, a capacitive air gap, isolation trenches, and alignment marks are micromachined in an active layer of the base wafer; the active layer of the resonator wafer is bonded directly to the active layer of the base wafer; the handle and dielectric layers of the resonator wafer are removed; viewing windows are opened in the active layer of the resonator wafer; masking the single crystal silicon semiconductor material active layer of the resonator wafer with photoresist material; a single crystal silicon resonator is machined in the active layer of the resonator wafer using silicon dry etch micromachining technology; and the photoresist material is subsequently dry stripped.

Abstract: An hermetic, gas filled or vacuum package device and method of making a vacuum package device. The device includes a device layer having one or more Micro Electro-Mechanical Systems (MEMS) devices. The device layer includes one or more electrical leads coupled to the one or more MEMS devices. The device also includes a first wafer having one or more silicon pins, wherein a first surface of the first wafer is bonded to a first surface of the device layer in such a manner that the one or more silicon pins are in electrical communication with the electrical leads. A second wafer, which may also have one or more silicon pins, is bonded to a second surface of the device layer. The first and second wafers are formed of borosilicate glass and the device layer is formed of silicon.

Abstract: An hermetic, gas filled or vacuum package device and method of making a vacuum package device. The device includes a device layer having one or more Micro Electro-Mechanical Systems (MEMS) devices. The device layer includes one or more electrical leads coupled to the one or more MEMS devices. The device also includes a first wafer having one or more silicon pins, wherein a first surface of the first wafer is bonded to a first surface of the device layer in such a manner that the one or more silicon pins are in electrical communication with the electrical leads. A second wafer, which may also have one or more silicon pins, is bonded to a second surface of the device layer. The first and second wafers are formed of borosilicate glass and the device layer is formed of silicon.

Abstract: A continuous flow, steady state fluid delivery and recovery system for a process chamber and processes requiring supercritical fluid and desired additives including co-solvents, for conducting repetitive batch processing operations in an automated environment, for such processes as supercritical carbon dioxide cleaning and processing of semiconductor wafers. The system provides for steady-state operation of fluid flow and byproducts recovery while the process chamber is brought rapidly and repeatedly on and off line as in batch operations and for various process steps.

Abstract: A pressure vessel for use in production processes requiring elevating and ranging of temperatures and pressures during the process cycle, readily adaptable to production line operation, suitable for wafer processing in the semiconductor industry and for other industries and processes. The pressure vessel is configured within an open support frame with a stationary, preferably inverted, orientation. The cover or closing plate is vertically movable towards the mouth of the pressure vessel and functions as the platform by which the object under process is transferred into the vessel. The moving and locking mechanism for the cover is isolated and shielded from the process environment.

Abstract: A dry process for the cleaning of precision surfaces such as of semiconductor wafers, by using process materials such as carbon dioxide and useful additives such as cosolvents and surfactants, where the process materials are applied exclusively in gaseous and supercritical states. Soak and agitation steps are applied to the wafer, including a rapid decompression of the process chamber after a soak period at higher supercritical pressure, to mechanically weaken break up the polymers and other materials sought to be removed, combined with a supercritical fluid flush to carry away the loose debris.

Abstract: A continuous flow, steady state fluid delivery and recovery system for a process chamber and processes requiring supercritical fluid and desired additives including co-solvents, for conducting repetitive batch processing operations in an automated environment, for such processes as supercritical carbon dioxide cleaning and processing of semiconductor wafers. The system provides for steady-state operation of fluid flow and byproducts recovery while the process chamber is brought rapidly and repeatedly on and off line as in batch operations and for various process steps.

Abstract: An apparatus and method for drying a microelectronic structure on wafer substrate using supercritical phase gas techniques and a unique pressure vessel locking mechanism. There is lid and a base with an open cavity to contain at least one microelectronic structure on wafer substrate. Clamping the lid to the base uses locking clamp rings with open jaws large to partially enclose the edge of the vessel. The clamp rings are supported symmetrically about the sides of the vessel. The rings are adjusted between an open position where the rings are clear of the vessel and a locking position where the jaws partially enclose the vessel. The jaws and the vessel share a tapered cam plate and roller system configured to bring the rings into vertically compressive locking engagement on the pressure vessel when the rings are moved into locking position. Mechanical interlocks provide security against back pressure opening the rings.