Entries |
Document | Title | Date |
20080233673 | METHOD FOR FABRICATING MEMS-RESONATOR - The present invention is an etching mask used for fabricating of the MEMS resonator including an oscillator which both edges are fixed to a base substance and vibrates to a vibrating direction, and an electrode which is fixed to a base substance by vibration is impossible in parallel for the oscillator, and is placed every one or more at the both sides of the oscillator. The etching mask includes a mask pattern | 09-25-2008 |
20080280387 | Layout design and fabrication of SDA micro motor for low driving voltage and high lifetime application - Provided is a new design and fabrication of scratch drive actuator (SDA) micro rotary motor with low driving voltage and high lifetime characteristics. To substantially reduce the driving voltage from 30˜150 V | 11-13-2008 |
20080293178 | Process For Manufacturing Micromechanical Devices Containing a Getter Material and Devices So Manufactured - A process is provided for manufacturing micromechanical devices formed by joining two parts together by direct bonding. One of the parts ( | 11-27-2008 |
20080299695 | MICROCHANNELS FOR BioMEMS DEVICES - A method is disclosed for making a MEMS device wherein anhydrous HF exposed silicon nitride is used as a temporary adhesion layer allowing the transfer of a layer from a Carrier Wafer to a Device Wafer. | 12-04-2008 |
20090053846 | Methods of Making Electromechanical Three-Trace Junction Devices - Methods of producing an electromechanical circuit element are described. A lower structure having lower support structures and a lower electrically conductive element is provided. A nanotube ribbon (or other electromechanically responsive element) is formed on an upper surface of the lower structure so as to contact the lower support structures. An upper structure is provided over the nanotube ribbon. The upper structure includes upper support structures and an upper electrically conductive element. In some arrangements, the upper and lower electrically conductive elements are in vertical alignment, but in some arrangements they are not. | 02-26-2009 |
20090068781 | METHOD OF MANUFACTURE FOR MICROELECTROMECHANICAL DEVICES - A method of manufacturing a microelectromechanical device includes forming at least two conductive layers on a substrate. An isolation layer is formed between the two conductive layers. The conductive layers are electrically coupled together and then the isolation layer is removed to form a gap between the conductive layers. The electrical coupling of the layers mitigates or eliminates the effects of electrostatic charge build up on the device during the removal process. | 03-12-2009 |
20090068782 | Nano-elastic memory device and method of manufacturing the same - A nano-elastic memory device and a method of manufacturing the same. The nano-elastic memory device may include a substrate, a plurality of lower electrodes arranged in parallel on the substrate, a support unit formed of an insulating material to a desired or predetermined thickness on the substrate having cavities that expose the lower electrodes, a nano-elastic body extending perpendicular from a surface of the lower electrodes in the cavities, and a plurality of upper electrodes formed on the support unit and perpendicularly crossing the lower electrodes over the nano-elastic bodies. | 03-12-2009 |
20090142872 | Fabrication of capacitive micromachined ultrasonic transducers by local oxidation - Fabrication methods for capacitive micromachined ultrasonic transducers (CMUTS) with independent and precise gap and post thickness control are provided. The fabrication methods are based on local oxidation or local oxidation of silicon (LOCOS) to grow oxide posts. The process steps enable low surface roughness to be maintained to allow for direct wafer bonding of the membrane. In addition, methods for fabricating a step in a substrate are provided with reduced or minimal over-etch time by utilizing the nonlinearity of oxide growth. The fabrication methods of the present invention produce CMUTs with unmatched uniformity, low parasitic capacitance, and high breakdown voltage. | 06-04-2009 |
20090170231 | METHOD OF PRODUCING MECHANICAL COMPONENTS OF MEMS OR NEMS STRUCTURES MADE OF MONOCRYSTALLINE SILICON - The invention concerns a method of producing at least one mechanical component of a MEMS or NEMS structure from a monocrystalline silicon substrate, comprising the steps of:
| 07-02-2009 |
20090181487 | Method of making microminiature moving device - A microminiature moving device has disposed on a single-crystal silicon substrate movable elements such as a movable rod and a movable comb electrode that are displaceable in parallel to the substrate surface and stationary parts that are fixedly secured to the single-crystal silicon substrate with an insulating layer sandwiched between. Depressions are formed in the surface regions of the single-crystal silicon substrate where no stationary parts are present and the movable parts are positioned above the depressions. The depressions form gaps large enough to prevent foreign bodies from causing shorts and malfunctioning of the movable parts. | 07-16-2009 |
20090181488 | MEMS thermal actuator and method of manufacture - A separated MEMS thermal actuator is disclosed which is largely insensitive to creep in the cantilevered beams of the thermal actuator. In the separated MEMS thermal actuator, a inlaid cantilevered drive beam formed in the same plane, but separated from a passive beam by a small gap. Because the inlaid cantilevered drive beam and the passive beam are not directly coupled, any changes in the quiescent position of the inlaid cantilevered drive beam may not be transmitted to the passive beam, if the magnitude of the changes are less than the size of the gap. | 07-16-2009 |
20090191660 | Method for manufacturing a sensor device - A motion sensor in the form of an angular rate sensor and a method of making a sensor are provided and includes a support substrate and a silicon sensing ring supported by the substrate and having a flexive resonance. Drive electrodes apply electrostatic force on the ring to cause the ring to resonate. Sensing electrodes sense a change in capacitance indicative of vibration modes of resonance of the ring so as to sense motion. A plurality of silicon support rings connect the substrate to the ring. The support rings are located at an angle to substantially match a modulus of elasticity of the silicon, such as about 22.5 degrees and 67.5 degrees, with respect to the crystalline orientation of the silicon. | 07-30-2009 |
20090239325 | METHOD OF FABRICATING A INTEGRATED PRESSURE SENSOR - A method of fabricating a pressure sensor ( | 09-24-2009 |
20090275162 | CMOS-COMPATIBLE BULK-MICROMACHINING PROCESS FOR SINGLE-CRYSTAL MEMS/NEMS DEVICES - A process producing a single-crystalline device fabricated on a single-sided polished wafer employing processing from only the front-side and having a significant separation between the device and substrate is provided. In one embodiment, a method comprises an upper layer and a lower substrate. A device is formed in the upper layer, defined by gaps. The gaps are filled with at least one material that has etch characteristics different from those of the device and the substrate. At least a top portion of the gap material is removed from the upper layer. The gap material is etched so that a portion of the gap-material remains on the sidewalls of the surrounding upper layer. The material beneath the device is then etched, excluding an insulating layer beneath the device, releasing the device from the substrate. The insulating material beneath the device is then etched, the etch being selective to the insulating material and the gap material. | 11-05-2009 |
20090280594 | THREE-AXIS ACCELEROMETERS AND FABRICATION METHODS - Disclosed are MEMS accelerometers and methods for fabricating same. An exemplary accelerometer comprises a substrate, and a proof mass that is a portion of the substrate and which is separated from the substrate surrounding it by a gap. An electrically-conductive anchor is coupled to the proof mass, and a plurality of electrically-conductive suspension anus that are separated from the proof mass extend from the anchor and are coupled to the substrate surrounding the proof mass. A plurality of sense and actuation electrodes are separated from the proof mass by gaps and are coupled to processing electronics. Capacitive sensing is used to derive electrical signals caused by forces exerted on the proof mass, and the electrical signals are processed by the processing electronics to produce x-, y- and z-direction acceleration data. Electrostatic actuation is used to induce movements of the mass for force balance operation, or self-test and self-calibration. The fabrication methods use deep reactive ion etch bulk micromachining and surface micromachining to form the proof mass, suspension arms and electrodes. The anchor, suspension arms and electrodes are made in the same process steps from the same electrically conductive material, which is different from the substrate material. | 11-12-2009 |
20090311818 | ANODIC BONDING METHOD AND METHOD OF PRODUCING ACCELERATION SENSOR - An anodic bonding apparatus includes a first electrode and a second electrode. The first electrode has a first surface, and the second electrode has a second surface facing the first surface. The first surface includes a first central area; a first substrate placing area for placing a laminated substrate; and a first peripheral area surrounding the first substrate placing area. The second surface includes a second central area corresponding to the first central area; a second substrate placing area surrounding the second central area; and a second peripheral area corresponding to the first peripheral area and surrounding the second substrate placing area. Further, the second electrode includes a curved portion curved toward the first electrode, so that a distance between the first central area and the second central area becomes smaller than a distance between the first peripheral area and the second peripheral area. | 12-17-2009 |
20090317931 | METHOD OF FABRICATING AN ELECTROMECHANICAL DEVICE INCLUDING AT LEAST ONE ACTIVE ELEMENT - The invention relates to a method of fabricating an electromechanical device including an active element, wherein the method comprises the following steps: | 12-24-2009 |
20090325335 | HETEROGENEOUS SUBSTRATE INCLUDING A SACRIFICIAL LAYER, AND A METHOD OF FABRICATING IT - The invention relates to a method of making a component from a heterogeneous substrate comprising first and second portions in at least one monocrystalline material, and a sacrificial layer constituted by at least one stack of at least one layer of monocrystalline Si situated between two layers of monocrystalline SiGe, the stack being disposed between said first and second portions of monocrystalline material, wherein the method consists in etching said stack by making:
| 12-31-2009 |
20100029031 | METHOD OF FABRICATING A MEMS/NEMS ELECTROMECHANICAL COMPONENT - The invention relates to a method of fabricating and electromechanical device on at least one substrate, the device including at least one active element and wherein the method comprises:
| 02-04-2010 |
20100093125 | METHOD FOR TEMPERATURE COMPENSATION IN MEMS RESONATORS WITH ISOLATED REGIONS OF DISTINCT MATERIAL - MEMS resonators containing a first material and a second material to tailor the resonator's temperature coefficient of frequency (TCF). The first material has a different Young's modulus temperature coefficient than the second material. In one embodiment, the first material has a negative Young's modulus temperature coefficient and the second material has a positive Young's modulus temperature coefficient. In one such embodiment, the first material is a semiconductor and the second material is a dielectric. In a further embodiment, the quantity and location of the second material in the resonator is tailored to meet the resonator TCF specifications for a particular application. In an embodiment, the second material is isolated to a region of the resonator proximate to a point of maximum stress within the resonator. In a particular embodiment, the resonator includes a first material with a trench containing the second material. | 04-15-2010 |
20100173436 | METHOD OF MAKING BIOMEMS DEVICES - A MEMS device is manufactured by first forming a self-aligned monolayer (SAM) on a carrier wafer. Next, a first polymer layer is formed on the self-aligned monolayer. The first polymer layer is patterned form a microchannel cover, which is then bonded to a patterned second polymer layer on a device wafer to form microchannels. The carrier wafer is then released from the first polymer layer. | 07-08-2010 |
20100190285 | MICROELETROMECHANICAL SYSTEMS HAVING STORED CHARGE AND METHODS FOR FABRICATING AND USING SAME - Many inventions are disclosed. Some aspects are directed to MEMS, and/or methods for use with and/or for fabricating MEMS, that supply, store, and/or trap charge on a mechanical structure disposed in a chamber. Various structures may be disposed in the chamber and employed in supplying, storing and/or trapping charge on the mechanical structure. In some aspects, a breakable link, a thermionic electron source and/or a movable mechanical structure are employed. The breakable link may comprise a fuse. In one embodiment, the movable mechanical structure is driven to resonate. In some aspects, the electrical charge enables a transducer to convert vibrational energy to electrical energy, which may be used to power circuit(s), device(s) and/or other purpose(s). In some aspects, the electrical charge is employed in changing the resonant frequency of a mechanical structure and/or generating an electrostatic force, which may be repulsive. | 07-29-2010 |
20100273286 | Method Of Fabricating An Integrated CMOS-MEMS Device - An embodiment of a method is provided that includes providing a substrate having a frontside and a backside. A CMOS device is formed on the substrate. A MEMS device is also formed on the substrate. Forming the MEMS device includes forming a MEMS mechanical structure on the frontside of the substrate. The MEMS mechanical structure is then released. A protective layer is formed on the frontside of the substrate. The protective layer is disposed on the released MEMS mechanical structure (e.g., protects the MEMS structure). The backside of the substrate is processed while the protective layer is disposed on the MEMS mechanical structure. | 10-28-2010 |
20100304517 | MEMS DEVICE AND FABRICATION METHOD OF THE SAME - A microelectromechanical systems (MEMS) device includes a frame, an actuator formed on the same layer as the frame and connected to the frame to be capable of performing a relative motion with respect to the frame, and at least one stopper restricting a displacement of the actuator in a direction along the height of the actuator. The MEMS device is fabricated by bonding a second substrate to a first substrate, forming the frame and the actuator by partially removing the first substrate, and forming the at least one stopper by partially removing the second substrate. | 12-02-2010 |
20100317137 | METHOD FOR RELEASING THE SUSPENDED STRUCTURE OF A NEMS AND/OR NEMS COMPONENT - A method for making a microelectronic device comprising at least one electromechanical component provided with a mobile structure,
| 12-16-2010 |
20110027929 | METHOD OF FABRICATING MICRO-ELECTROMECHANICAL SYSTEM MICROPHONE STRUCTURE - A method of fabricating a micro-electromechanical system microphone structure is disclosed. First, a substrate defining a MEMS region and a logic region is provided, and a surface of the substrate has a dielectric layer thereon. Next, at least one metal interconnect layer is formed on the dielectric layer in the logic region, and at least one micro-machined metal mesh is simultaneously formed in the dielectric layer of the MEMS region. Therefore, the thickness of the MEMS microphone structure can be effectively reduced. | 02-03-2011 |
20110039365 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE - A method for fabricating a semiconductor device includes: the step (a) of forming a vibrating film on a predetermined region of each of a plurality of chips included in a semiconductor wafer; the step (b) of forming, on the semiconductor wafer, an intermediate film containing a sacrifice layer located on the vibrating film of each of the chips; and the step (c) of forming a fixed film on the intermediate film. This method further includes, after the step (c), the step (d) of subjecting the semiconductor wafer to blade dicing to separate the chips, and the step (e) of removing, by etching, the sacrifice layer to provide a cavity between the vibrating film and the fixed film. | 02-17-2011 |
20110059565 | METHOD AND APPARATUS FOR MEMS OSCILLATOR - A resonator includes a CMOS substrate having a first electrode and a second electrode. The CMOS substrate is configured to provide one or more control signals to the first electrode. The resonator also includes a resonator structure including a silicon material layer. The resonator structure is coupled to the CMOS substrate and configured to resonate in response to the one or more control signals. | 03-10-2011 |
20110059566 | Forming a Micro Electro Mechanical System - A method of forming a micro-electro mechanical system (MEMS), includes (1) removing material from a first wafer to define a first movable portion corresponding to an x-y accelerometer and a second movable portion corresponding to a z accelerometer, where each movable portion comprises at least one flexure member and at least one proof mass, each proof mass and flexure member being formed by the selective removal of material from a top side and a bottom side of first wafer; (2) bonding the first wafer to a second wafer comprising an electronic circuit, such that a gap is defined between the first wafer and the second wafer. The thickness of the at least one flexure member of the first movable portion is independent of a thickness of the at least one flexure member of the second movable portion and a thickness of the proof mass of the first movable portion is independent of a thickness of the at least one proof mass of the second movable portion. | 03-10-2011 |
20110070675 | METHOD FOR MANUFACTURING MICROMECHANICAL COMPONENTS - The present invention relates to a method for manufacturing an acceleration sensor. In the method, thin SOI-wafer structures are used, in which grooves are etched, the walls of which are oxidized. A thick layer of electrode material, covering all other material, is grown on top of the structures, after which the surface is ground and polished chemo-mechanically, thin release holes are etched in the structure, structural patterns are formed, and finally etching using a hydrofluoric acid solution is performed to release the structures intended to move and to open a capacitive gap. | 03-24-2011 |
20110081740 | Low Stress Photo-Sensitive Resin with Sponge-Like Structure and Devices Manufactured Employing Same - System and method for forming a structure including a MEMS device structure. In order to prevent warpage of a substrate arising from curing process for a sacrificial material (such as a photoresist), and from subsequent high temperature process steps, an improved sacrificial material comprises (i) a polymer and (ii) a foaming agent or special function group. The structure can be formed by forming a trench in a substrate and filling the trench with a sacrificial material. The sacrificial material includes (i) a polymer and (ii) a foaming agent or special function group. After further process steps are completed, the sacrificial material is removed from the trench. | 04-07-2011 |
20110086455 | GYROSCOPE - To provide a compact and high performance gyroscope. | 04-14-2011 |
20110104844 | METHOD FOR FABRICATING MICRO-ELECTRO-MECHANICAL SYSTEM (MEMS) DEVICE - A method for fabricating MEMS device includes providing a substrate having a first side and a second side. Then, a structural dielectric layer is formed over the substrate at the first side, wherein a structural conductive layer is embedded in the structural dielectric layer. A multi-stage patterning process is performed on the substrate from the second side, wherein a plurality of regions of the substrate with different levels is formed and a portion of the structural dielectric layer is exposed. An isotropic etching process is performed from the second side of the substrate or from the both side of the substrate to etch the structural dielectric layer, wherein a remaining portion of the structural dielectric layer comprises the structural conductive layer and a dielectric portion enclosed by the structural conductive layer. | 05-05-2011 |
20110104845 | PRODUCTION METHOD OF MEMS SENSOR - Production method for a MEMS sensor including a substrate, a lower thin film, opposed to a surface of the substrate at an interval, having a plurality of lower through-holes formed to pass through the lower thin film in the thickness direction thereof, an upper thin film, opposed to the lower thin film at an interval on the side opposite to the substrate, having a plurality of upper through-holes formed to pass through the upper thin film in the thickness direction thereof, and a plurality of protrusions irregularly provided on a region of the surface of the substrate opposed to the lower thin film. | 05-05-2011 |
20110111545 | LOW TEMPERATURE CERAMIC MICROELECTROMECHANICAL STRUCTURES - A method of providing microelectromechanical structures (MEMS) that are compatible with silicon CMOS electronics is provided. The method providing for processes and manufacturing sequences limiting the maximum exposure of an integrated circuit upon which the MEMS is manufactured to below 350° C., and potentially to below 250° C., thereby allowing direct manufacturing of the MEMS devices onto electronics, such as Si CMOS circuits. The method further providing for the provisioning of MEMS devices with multiple non-conductive structural layers such as silicon carbide separated with small lateral gaps. Such silicon carbide structures offering enhanced material properties, increased environmental and chemical resilience whilst also allowing novel designs to be implemented taking advantage of the non-conductive material of the structural layer. The use of silicon carbide being beneficial within the formation of MEMS elements such as motors, gears, rotors, translation drives, etc where increased hardness reduces wear of such elements during operation. | 05-12-2011 |
20110117689 | SEMICONDUCTOR SENSOR AND MANUFACTURING METHOD OF SENSOR BODY FOR SEMICONDUCTOR SENSOR - A semiconductor sensor of which the thickness may be reduced and a method of manufacturing a sensor body for the semiconductor sensor are provided. A total length L | 05-19-2011 |
20110136283 | Process for fabricating MEMS devices - A process for fabricating a MEMS device with movable comb teeth and stationary comb teeth. A single mask is used to define, during a series of processing steps, the location and width of both movable comb teeth and stationary comb teeth so as to assure self alignment of the comb teeth. MEMS devices are fabricated from a single multi-layer semi-conductor structure of semiconductor material and insulator material. In a preferred embodiment the process is employed to provide a MEMS mirror device having a movable structure, a movable frame, a first set of two torsional members, a first set of at least four comb drives, an outer fixed frame structure, a second set of two torsional members, and a second set of at least four comb drives. | 06-09-2011 |
20110159626 | Micro-Electro-Mechanical Device And Method Of Manufacturing The Same - The present invention improves mechanical strength of a micro-electro-mechanical device (MEMS) having a movable portion to improve reliability. In a micro-electro-mechanical device (MEMS) having a movable portion, a portion which has been a hollow portion in the case of a conventional structure is filled with a filler material. As the filler material, a block copolymer that is highly flexible is used, for example. By filling the hollow portion, mechanical strength improves. Besides, warpage of an upper portion of a structure body in the manufacture process is prevented, whereby yield improves. A micro-electro-mechanical device thus manufactured is highly reliable. | 06-30-2011 |
20110165717 | METHOD FOR FORMING MICRO-ELECTRO-MECHANICAL SYSTEM (MEMS) PACKAGE - A method for forming a micro-electro-mechanical systems (MEMS) package includes following steps. A plurality of MEMS units are formed on a substrate, and each of the MEMS units includes at least a MEMS sensing element and a first chamber over the MEMS sensing element. The MEMS units include electric connection pads. A plurality of covering units are formed correspondingly over the MEMS units. Each of the covering units provides a second chamber over the MEMS sensing element opposite to the first chamber. The covering units are adhered to the MEMS units by an adhesive material. The MEMS units are diced into singulated units. | 07-07-2011 |
20110223702 | MANUFACTURING METHOD OF MEMS DEVICE, AND SUBSTRATE USED THEREFOR - A method for manufacturing a MEMS device, includes: preparing a substrate provided with a first substrate in which a cavity is formed, and a second substrate that is bonded to a side of the first substrate on which the cavity is formed and includes a slit to delimit a movable portion in a position corresponding to the cavity, the second substrate, including a first surface thereof facing the first substrate, being provided with a thermally-oxidized film selectively formed on the first surface in a position corresponding to the movable portion; forming a first electrode layer on a second surface opposite to the first surface on which the thermally-oxidized film for the movable portion is formed; forming a sacrifice layer on the first electrode layer and the second substrate; forming a second electrode layer on the sacrifice layer; and removing the sacrifice layer and the thermally-oxidized film after the second electrode layer is formed. | 09-15-2011 |
20110230000 | MEMS DEVICE MANUFACTURING METHOD - A MEMS device manufacturing method including a break start point forming step of forming a break start point in a substrate along the areas corresponding to a plurality of crossing streets set on the substrate before forming a plurality of MEMS devices on the substrate, a device forming step of forming the MEMS devices in a plurality of areas partitioned by the areas corresponding to the crossing streets on the front side of the substrate after performing the break start point forming step, and a substrate breaking step of applying an external force to the substrate after performing the device forming step to thereby break the substrate along the areas corresponding to the crossing streets where the break start point is formed, thus dividing the substrate into the individual MEMS devices. | 09-22-2011 |
20110281389 | Micromachine and Method for Manufacturing the Same - A structure which prevents thinning and disconnection of a wiring is provided, in a micromachine (MEMS structure body) formed with a surface micromachining technology. A wiring (upper auxiliary wiring) over a sacrificial layer is electrically connected to a different wiring (upper connection wiring) over the sacrificial layer, so that thinning, disconnection, and the like of the wiring formed over the sacrificial layer at a step portion generated due to the thickness of the sacrificial layer can be prevented. The wiring over the sacrificial layer is formed of the same conductive film as an upper driving electrode which is a movable electrode and is thus thin. However, the different wiring is formed over a structural layer, which is formed by a CVD method and has a rounded step, and has a thickness of 200 nm to 1 μm, whereby thinning, disconnection, and the like of the wiring can be further prevented. | 11-17-2011 |
20110300658 | METHODS OF CREATING A MICRO ELECTRO-MECHANICAL SYSTEMS ACCELEROMETER USING A SINGLE DOUBLE SILICON-ON-INSULATOR WAFER - Methods for creating a microelectromechanical systems (MEMS) device using a single double, silicon-on-insulator (SOI) wafer. The double SOI wafer includes at least a base layer of silicon, a first layer of silicon, and a second layer of silicon, the layers of silicon are separated by an oxide layer. A stationary electrode with rigid support beams is formed into the second layer of silicon. A proof mass and at least one spring are formed into the first layer of silicon. The proof mass is separated from the stationary electrode by a first gap and the proof mass is separated from the base silicon layer by a second gap. | 12-08-2011 |
20120021550 | METHOD FOR FABRICATING A FIXED STRUCTURE DEFINING A VOLUME RECEIVING A MOVABLE ELEMENT IN PARTICULAR OF A MEMS - The fabrication of a semiconductor fixed structure defining a volume, for example of a MEMS micro electro-mechanical system includes, determining thicknesses beforehand depending on the functional distances associated with elements. At least one element is formed on a substrate by thermal oxidation of the substrate so as to form an oxide layer followed by selective etching of the oxide layer so as to define the volume in an etched portion by baring the underlying substrate so as to define the element in an unetched portion, and later oxidation of the substrate so as to form an oxide layer, in order to obtain the elements at the functional distances. | 01-26-2012 |
20120034724 | METHOD AND APPARATUS FOR MEMS OSCILLATOR - A resonator includes a CMOS substrate having a first electrode and a second electrode. The CMOS substrate is configured to provide one or more control signals to the first electrode. The resonator also includes a resonator structure including a silicon material layer. The resonator structure is coupled to the CMOS substrate and configured to resonate in response to the one or more control signals. | 02-09-2012 |
20120107992 | METHOD OF PRODUCING LAYERED WAFER STRUCTURE HAVING ANTI-STICTION BUMPS | 05-03-2012 |
20120107993 | METHOD OF MAKING A MICRO-ELECTRO-MECHANICAL-SYSTEMS (MEMS) DEVICE - A method of forming a MEMS device includes forming a sacrificial layer over a substrate. The method further includes forming a metal layer over the sacrificial layer and forming a protection layer overlying the metal layer. The method further includes etching the protection layer and the metal layer to form a structure having a remaining portion of the protection layer formed over a remaining portion of the metal layer. The method further includes etching the sacrificial layer to form a movable portion of the MEMS device, wherein the remaining portion of the protection layer protects the remaining portion of the metal layer during the etching of the sacrificial layer to form the movable portion of the MEMS device. | 05-03-2012 |
20120115269 | SACRAFICIAL LAYERS MADE FROM AEROGEL FOR MICROELECTROMECHANICAL SYSTEMS (MEMS) DEVICE FABRIACTION PROCESSES - Systems and methods for processing sacrificial layers in MEMS device fabrication are provided. In one embodiment, a method comprises: applying a patterned layer of Aerogel material onto a substrate to form an Aerogel sacrificial layer; applying at least one non-sacrificial silicon layer over the Aerogel sacrificial layer, wherein the non-sacrificial silicon layer is coupled to the substrate through one or more gaps provided in the patterned layer of Aerogel material; and removing the Aerogel sacrificial layer by exposing the Aerogel sacrificial layer to a removal liquid. | 05-10-2012 |
20120122259 | METHOD OF MANUFACTURING MEMS DEVICES PROVIDING AIR GAP CONTROL - Methods and apparatus are provided for controlling a depth of a cavity between two layers of a light modulating device. A method of making a light modulating device includes providing a substrate, forming a sacrificial layer over at least a portion of the substrate, forming a reflective layer over at least a portion of the sacrificial layer, and forming one or more flexure controllers over the substrate, the flexure controllers configured so as to operably support the reflective layer and to form cavities, upon removal of the sacrificial layer, of a depth measurably different than the thickness of the sacrificial layer, wherein the depth is measured perpendicular to the substrate. | 05-17-2012 |
20120129291 | METHOD FOR PRODUCING A MICROMECHANICAL COMPONENT - A method for producing a micromechanical component is described. The method includes providing a substrate having a layer system including an insulating material situated on the substrate, a conductive layer section and a protective layer structure connected to the conductive layer section, which borders a section of the insulating material. The method furthermore includes carrying out an isotropic etching process for removing a part of the insulating material, the conductive layer section and the protective layer structure preventing the removal of the bordered section of the insulating material; and a structural element being developed, which includes the conductive layer section, the protective layer structure and the bordered section of the insulating material. | 05-24-2012 |
20120156820 | COMPOSITE SACRIFICIAL STRUCTURE FOR RELIABLY CREATING A CONTACT GAP IN A MEMS SWITCH - The present Disclosure provides for fabrication devices and methods for manufacturing a micro-electromechanical system (MEMS) switch on a substrate. The MEMS fabrication device may have a first and second sacrificial layer that form the mold of an actuation member. The actuation member is formed over the first and second sacrificial layers to manufacture a MEMS switch from the MEMS fabrication device. | 06-21-2012 |
20120164774 | Methods of Manufacture MEMS Devices - Micro-electromechanical system (MEMS) devices and methods of manufacture thereof are disclosed. In one embodiment, a MEMS device includes a first semiconductive material and at least one trench disposed in the first semiconductive material, the at least one trench having a sidewall. An insulating material layer is disposed over an upper portion of the sidewall of the at least one trench in the first semiconductive material and over a portion of a top surface of the first semiconductive material proximate the sidewall. A second semiconductive material or a conductive material is disposed within the at least one trench and at least over the insulating material layer disposed over the portion of the top surface of the first semiconductive material proximate the sidewall. | 06-28-2012 |
20120171798 | DAMASCENE PROCESS FOR USE IN FABRICATING SEMICONDUCTOR STRUCTURES HAVING MICRO/NANO GAPS - In fabricating a microelectromechanical structure (MEMS), a method of forming a narrow gap in the MEMS includes a) depositing a layer of sacrificial material on the surface of a supporting substrate, b) photoresist masking and at least partially etching the sacrificial material to form at least one blade of sacrificial material, c) depositing a structural layer over the sacrificial layer, and d) removing the sacrificial layer including the blade of the sacrificial material with a narrow gap remaining in the structural layer where the blade of sacrificial material was removed. | 07-05-2012 |
20120264249 | METHOD FOR ETCHED CAVITY DEVICES - MEMS devices ( | 10-18-2012 |
20120270352 | FABRICATING MEMS COMPOSITE TRANSDUCER INCLUDING COMPLIANT MEMBRANE - A method of fabricating a MEMS composite transducer includes providing a substrate having a first surface and a second surface opposite the first surface. A transducing material is deposited over the first surface of the substrate. The transducing material is patterned by retaining transducing material in a first region and removing transducing material in a second region. A polymer layer is deposited over the first region and the second region. The polymer layer is patterned by retaining polymer in a third region and removing polymer in a fourth region. A first portion of the third region is coincident with a portion of the first region and a second portion of the third region is coincident with a portion of the second region. A cavity is etched from the second surface to the first surface of the substrate. An outer boundary of the cavity at the first surface of the substrate intersects the first region where transducing material is retained, so that a first portion of the transducing material is anchored to the first surface of the substrate and a second portion of the transducing material extends over at least a portion of the cavity. | 10-25-2012 |
20120270353 | COUPLING PIEZOELECTRIC MATERIAL GENERATED STRESSES TO DEVICES FORMED IN INTEGRATED CIRCUITS - A coupling structure for coupling piezoelectric material generated stresses to an actuated device of an integrated circuit includes a rigid stiffener structure formed around a piezoelectric (PE) material and the actuated device, the actuated device comprising a piezoresistive (PR) material that has an electrical resistance dependent upon an applied pressure thereto; and a soft buffer structure formed around the PE material and PR material, the buffer structure disposed between the PE and PR materials and the stiffener structure, wherein the stiffener structure clamps both the PE and PR materials to a substrate over which the PE and PR materials are formed, and wherein the soft buffer structure permits the PE material freedom to move relative to the PR material, thereby coupling stress generated by an applied voltage to the PE material to the PR material so as change the electrical resistance of the PR material. | 10-25-2012 |
20120276674 | Three-Axis Accelerometers and Fabrication Methods - MEMS accelerometers have a substrate, and a proof mass portion thereof which is separated from the substrate surrounding it by a gap. An electrically-conductive anchor is coupled to the proof mass, and a plurality of electrically-conductive suspension anus that are separated from the proof mass extend from the anchor and are coupled to the substrate surrounding the proof mass. A plurality of sense and actuation electrodes are separated from the proof mass by gaps and are coupled to processing electronics. The fabrication methods use deep reactive ion etch bulk micromachining and surface micromachining to form the proof mass, suspension arms and electrodes. The anchor, suspension arms and electrodes are made in the same process steps from the same electrically conductive material, which is different from the substrate material. | 11-01-2012 |
20130023081 | METHOD FOR FABRICATING INTEGRATED CIRCUIT - A method for fabricating integrated circuit is provided. First, a first interconnect structure including a plurality of first dielectric layers and a plurality of first conductive patterns stacked therewith alternately is formed on a MEMS region of a conductive substrate. Next, an interlayer is formed on the first interconnect structure and covering the first conductive patterns. Next, a poly silicon mask layer corresponding to the first conductive patterns is formed on the interlayer and exposing a portion of the media layer. Next, the portion of the interlayer exposed by the poly silicon mask layer and a portion of the first dielectric layer corresponding thereto are removed to form a plurality of openings. Then, a portion of the conductive substrate in the MEMS region is removed. | 01-24-2013 |
20130071964 | METHOD OF MANUFACTURING AN ELECTROMECHANICAL TRANSDUCER - Provided is a method of manufacturing an electromechanical transducer having a reduced variation in a breakdown strength caused by a variation in flatness of an insulating layer. In the method of manufacturing the electromechanical transducer, a first insulating layer is formed on a first substrate, a barrier wall is formed by removing a part of the first insulating layer, and a second insulating layer is formed on a region of the first substrate after the part of the first insulating layer has been removed. Next, a gap is formed by bonding a second substrate on the barrier wall, and a vibration film that is opposed to the second insulating layer via the gap is formed from the second substrate. In the forming of the barrier wall, a height on a gap side in a direction vertical to the first substrate becomes lower than a height of a center portion. | 03-21-2013 |
20130095593 | GAS SENSOR AND MANUFACTURING METHOD THEREOF - A gas sensor manufacturing method comprises the following steps: providing a SOI substrate, including an oxide layer, a device layer, and a carrier, wherein the oxide layer is disposed between the device layer and the carrier; etching the device layer to form an integrated circuit region, an outer region, a trench and at least one conducting line; coating or imprinted a sensing material on the integrated circuit region; and etching the carrier and the oxide layer to form a cavity up to the gap so as to form a film structure which is suspended in the cavity by the cantilevered connecting arm. | 04-18-2013 |
20130102100 | Method for Making Micro-Electro-Mechanical System Device - The present invention discloses a method for making a MEMS device, comprising: providing a zero-layer substrate; forming a MEMS device region on the substrate, wherein the MEMS device region is provided with a first sacrificial region to separate a suspension structure of the MEMS device from another part of the MEMS device; removing the first sacrificial region by etching; and micromachining the zero-layer substrate. | 04-25-2013 |
20130115729 | Lithographic fabrication process for a pressure sensor - Lithographic fabrication of a pressure sensor ( | 05-09-2013 |
20130122627 | INTEGRATED SEMICONDUCTOR DEVICES WITH SINGLE CRYSTALLINE BEAM, METHODS OF MANUFACTURE AND DESIGN STRUCTURE - Bulk acoustic wave filters and/or bulk acoustic resonators integrated with CMOS devices, methods of manufacture and design structure are provided. The method includes forming a single crystalline beam from a silicon layer on an insulator. The method further includes providing a coating of insulator material over the single crystalline beam. The method further includes forming a via through the insulator material exposing a wafer underlying the insulator. The insulator material remains over the single crystalline beam. The method further includes providing a sacrificial material in the via and over the insulator material. The method further includes providing a lid on the sacrificial material. The method further includes venting, through the lid, the sacrificial material and a portion of the wafer under the single crystalline beam to form an upper cavity above the single crystalline beam and a lower cavity in the wafer, below the single crystalline beam. | 05-16-2013 |
20130130424 | PROCESS FOR MINIMIZING CHIPPING WHEN SEPARATING MEMS DIES ON A WAFER - A method for separating a plurality of dies on a Micro-Electro-Mechanical System (MEMS) wafer comprising scribing a notch on a first side of the wafer between at least two of the plurality of dies on a first surface and depositing a metal on the first surface of the plurality of dies. The method further comprises scribing a second side of the wafer between at least two of the plurality of dies from a second surface thereof through the notch. The first side and second side are substantially parallel and opposite each other and the first surface and the second surface are substantially parallel and opposite each other. In a process in accordance with the present invention, a method to minimize chipping of the bonding portion of a MEMs device during sawing of the wafer is provided, which minimally affects the process steps associated with separating the die on a wafer. | 05-23-2013 |
20130143347 | METHODS AND DEVICES FOR FABRICATING TRI-LAYER BEAMS - Methods and devices for fabricating tri-layer beams are provided. In particular, disclosed are methods and structures that can be used for fabricating multilayer structures through the deposition and patterning of at least an insulation layer, a first metal layer, a beam oxide layer, a second metal layer, and an insulation balance layer. | 06-06-2013 |
20130178008 | METHOD OF MAKING SEMICONDUCTOR DEVICE - A semiconductor device includes a sensor portion, a cap portion, and an ion-implanted layer. The sensor portion has a sensor structure at a surface portion of a surface. The cap portion has first and second surfaces opposite to each other and includes a through electrode. The surface of the sensor portion is joined to the first surface of the cap portion such that the sensor structure is sealed between the sensor portion and the cap portion. The ion-implanted layer is located on the second surface of the cap portion. The through electrode extends from the first surface to the second surface and is exposed through the ion-implanted layer. | 07-11-2013 |
20130273682 | GRAPHENE PRESSURE SENSORS - Semiconductor nano pressure sensor devices having graphene membrane suspended over open cavities formed in a semiconductor substrate. A suspended graphene membrane serves as an active electro-mechanical membrane for sensing pressure, which can be made very thin, from about one atomic layer to about 10 atomic layers in thickness, to improve the sensitivity and reliability of a semiconductor pressure sensor device. | 10-17-2013 |
20130302933 | METHOD FOR FABRICATING MEMS DEVICE WITH PROTECTION RINGS - A microelectromechanical system (MEMS) device and a method for fabricating the same are described. The method of the present invention includes the following steps. A substrate is provided, including a circuit region and a MEMS region separated from each other. An interconnection structure is formed on the substrate in the circuit region, and simultaneously a plurality of dielectric layers and a first electrode are formed on the substrate in the MEMS region. The first electrode includes at least two metal layers and a protection ring. The metal layers and the protection ring are formed in the dielectric layers. The protection ring connects two adjacent metal layers, so as to define an enclosed space between the two adjacent metal layers. A second electrode is formed on the first electrode. The dielectric layers outside the enclosed space in the MEMS region are removed to form a cavity between the electrodes. | 11-14-2013 |
20130330870 | Micro-Electromechanical System Devices - Micro-electromechanical system (MEMS) devices and methods of manufacture thereof are disclosed. In one embodiment, a MEMS device includes a semiconductive layer disposed over a substrate. A trench is disposed in the semiconductive layer, the trench with a first sidewall and an opposite second sidewall. A first insulating material layer is disposed over an upper portion of the first sidewall, and a conductive material disposed within the trench. An air gap is disposed between the conductive material and the semiconductive layer. | 12-12-2013 |
20140017842 | METHODS FOR FORMING A SEALED LIQUID METAL DROP - Methods for forming an enclosed liquid metal (LM) drop inside a sealed cavity by formation of LM components as solid LM component layers and reaction of the solid LM component layers to form the LM drop. In some embodiments, the cavity has boundaries defined by layers or features of a microelectronics (e.g. VLSI-CMOS) or MEMS technology. In such embodiments, the methods comprise implementing an initial microelectronics or MEMS process to form the layers or features and the cavity, sequential or side by side formation of solid LM component layers in the cavity, sealing of the cavity to provide a closed space and reaction of the solid LM components to form a LM alloy in the general shape of a drop. In some embodiments, nanometric reaction barriers may be inserted between the solid LM component layers to lower the LM eutectic formation temperature. | 01-16-2014 |
20140024160 | Triple-Axis MEMS Accelerometer - An integrated circuit structure includes a triple-axis accelerometer, which further includes a proof-mass formed of a semiconductor material; a first spring formed of the semiconductor material and connected to the proof-mass, wherein the first spring is configured to allow the proof-mass to move in a first direction in a plane; and a second spring formed of the semiconductor material and connected to the proof-mass. The second spring is configured to allow the proof-mass to move in a second direction in the plane and perpendicular to the first direction. The triple-axis accelerometer further includes a conductive capacitor plate including a portion directly over, and spaced apart from, the proof-mass, wherein the conductive capacitor plate and the proof-mass form a capacitor; an anchor electrode contacting a semiconductor region; and a transition region connecting the anchor electrode and the conductive capacitor plate, wherein the transition region is slanted. | 01-23-2014 |
20140057382 | METHODS FOR FABRICATING MEMS STRUCTURES BY ETCHING SACRIFICIAL FEATURES EMBEDDED IN GLASS - In an embodiment a method of fabricating a MEMS structure is provided. The method includes fabricating a working structure in a doped layer proximate a first surface of a silicon substrate. The first surface of the silicon substrate is bonded to a first planar glass structure having a first one or more sacrificial features embedded therein. The method also includes etching to remove a bulk of the silicon substrate, wherein the bulk is reverse of the first surface on the silicon substrate, wherein etching removes the bulk and leaves the working structure bonded to the first planar glass structure. The method also includes etching to remove the first one or more sacrificial features from the first planar glass structure. | 02-27-2014 |
20140065751 | Method For Manufacturing Three-Dimensionally Shaped Comb-Tooth Electret Electrode - A method for manufacturing a three-dimensionally shaped comb-tooth electret electrode, provided with positive ions, includes: forming a three-dimensional movable comb-tooth electrode and a three-dimensional fixed comb-tooth electrode from an Si substrate; contacting a vapor including ions thereto, and forming an oxide layer including ions upon surfaces of the comb-tooth electrodes with heat applied thereto; and applying a voltage between the movable electrode and the fixed electrode with heat applied thereto, and thereby causing the ions included in the oxide layer to shift to a surface of the oxide layer; wherein, the voltage between the movable electrode and the fixed electrode is changed, so that the operation of each of the comb-teeth of the movable electrode being alternatingly pulled in against two opposed comb-teeth of the fixed electrode is repeated, and the pulling in voltage and the pulled-in state release voltage are gradually increased. | 03-06-2014 |
20140113396 | ESD PROTECTION FOR MEMS RESONATOR DEVICES - Disclosed herein are MEMS resonator device designs and fabrication techniques that provide protection against electrostatic charge imbalances. In one aspect, a MEMS resonator device includes a substrate, an electrode including a first microstructure supported by the substrate, a resonant element including a second microstructure spaced from the first microstructure by a gap for resonant displacement of the second microstructure within the gap during operation, and a disabled shunt coupled to the electrode or the resonant element. The disabled shunt is disabled to enable the resonant displacement but otherwise configured to protect against damage from an electrostatic charge imbalance before the operation of the MEMS resonator device. | 04-24-2014 |
20140162391 | METHOD FOR PRODUCING OSCILLATOR - A method for producing an oscillator includes: (a) forming a first layer on a substrate; (b) ion implanting a first impurity into a first region of the first layer; (c) forming a first electrode having a tapered plane on a side surface thereof by patterning the first layer; (d) forming a sacrificial layer on the first electrode and on the tapered plane of the first electrode; (e) forming a second electrode on the substrate and the sacrificial layer; and (f) removing the sacrificial layer. The step (b) is performed so that the concentration of the first impurity monotonically decreases from the upper surface side to the lower surface side in a region located at a depth of more than 10 nm from the upper surface of the first electrode. | 06-12-2014 |
20140162392 | PRODUCTION METHOD FOR A SUSPENDED STRUCTURE COMPONENT AND A TRANSISTOR CO-INTEGRATED ON A SAME SUBSTRATE - A method of forming a microelectronic device comprising, on a same substrate, at least one electro-mechanical component provided with a suspended structure and at least one transistor, the method comprising a step of release of the suspended structure from the electromechanical component after having formed metal interconnection levels of components. | 06-12-2014 |
20140186986 | HYBRID MEMS BUMP DESIGN TO PREVENT IN-PROCESS AND IN-USE STICTION - A micro-electro-mechanical systems (MEMS) device and method for forming a MEMS device is provided. A proof mass is suspended a distance above a surface of a substrate by a fulcrum. A pair of sensing plates are positioned on the substrate on opposing sides of the fulcrum. Metal bumps are associated with each sensing plate and positioned near a respective distal end of the proof mass. Each metal bump extends from the surface of the substrate and generally inhibits charge-induced stiction associated with the proof mass. Oxide bumps are associated with each of the pair of sensing plates and positioned between the respective sensing plate and the fulcrum. Each oxide bump extends from the first surface of the substrate a greater distance than the metal bumps and acts as a shock absorber by preventing the distal ends of the proof mass from contacting the metal bumps during shock loading. | 07-03-2014 |
20140248730 | MEMS Device and Method of Formation Thereof - The present disclosure provides a method including providing a first substrate; and forming a microelectromechanical system (MEMS) device on a first surface of the first substrate. A bond pad is formed on at least one bonding site on the first surface of the first substrate. The bonding site is recessed from the first surface. Thus, a top surface of the bond pad may lie below the plane of the top surface of the substrate. A device with recessed connective element(s) (e.g., bond pad) is also described. In further embodiments, a protective layer is formed on the recessed connective element during dicing of a substrate. | 09-04-2014 |
20140248731 | APPARATUS INTEGRATING MICROELECTROMECHANICAL SYSTEM DEVICE WITH CIRCUIT CHIP AND METHODS FOR FABRICATING THE SAME - One embodiment discloses an apparatus integrating a microelectromechanical system device with a circuit chip which includes a circuit chip, a microelectromechanical system device, a sealing ring, and a lid. The circuit chip comprises a substrate and a plurality of metal bonding areas. The substrate has an active surface with electrical circuit area, and the metal bonding areas are disposed on the active surface and electrically connected to the electrical circuits. The microelectromechanical system device comprises a plurality of bases and at least one sensing element. The bases are connected to at least one of the metal bonding areas. The at least one sensing element is elastically connected to the bases. The sealing ring surrounds the bases, and is connected to at least one of the metal bonding areas. The lid is opposite to the active surface of the circuit chip, and is connected to the sealing ring to have a hermetic chamber which seals the sensing element and the active surface of the circuit chip. | 09-04-2014 |
20140248732 | LIQUID CRYSTAL DISPLAY DEVICE HAVING TOUCH SENSOR EMBEDDED THEREIN, METHOD OF DRIVING THE SAME AND METHOD OF FABRICATING THE SAME - A liquid crystal display device having a touch sensor embedded therein is disclosed. The present invention includes a liquid crystal layer between first and second substrates, a pixel on the second substrate to apply a horizontal electric field to the liquid crystal layer, a touch sensor on the second substrate, the touch sensor detecting a touch by forming a touch capacitor with a touch object for touching the first substrate, and a readout line outputting a sensing signal from the touch sensor. The touch sensor includes a sensing electrode on the second substrate to form the sensing capacitor with the touch object, first and second sensor gate lines, a first sensor thin film transistor supplying a sensing driving voltage to the sensing electrode in response to a control of the first sensor gate line, and a second sensor thin film transistor supplying electric charges of the sensing electrode as the sensing signal in response to a control of the second sensor gate line. | 09-04-2014 |
20140287547 | INHIBITING PROPAGATION OF SURFACE CRACKS IN A MEMS DEVICE - A microelectromechanical systems (MEMS) device ( | 09-25-2014 |
20140287548 | MEMS Device with Release Aperture - The present disclosure provides a method of fabricating a micro-electro-mechanical systems (MEMS) device. In an embodiment, a method includes providing a substrate including a first sacrificial layer, forming a micro-electro-mechanical systems (MEMS) structure above the first sacrificial layer, and forming a release aperture at substantially a same level above the first sacrificial layer as the MEMS structure. The method further includes forming a second sacrificial layer above the MEMS structure and within the release aperture, and forming a first cap over the second sacrificial layer and the MEMS structure, wherein a leg of the first cap is disposed between the MEMS structure and the release aperture. The method further includes removing the first sacrificial layer, removing the second sacrificial layer through the release aperture, and plugging the release aperture. A MEMS device formed by such a method is also provided. | 09-25-2014 |
20140295606 | METHOD FOR PRODUCING A DEVICE COMPRISING CAVITIES FORMED BETWEEN A SUSPENDED ELEMENT RESTING ON INSULATING PADS SEMI-BURIED IN A SUBSTRATE AND THIS SUBSTRATE - A method for producing a device including plural cavities defined between a substrate in at least one given semiconductor material and a membrane resting on a top of insulating posts projecting from the substrate, the method allowing a height of the cavity or cavities to be adapted independently of a height of the insulating posts and allowing cavities of different heights to be formed. | 10-02-2014 |
20140357006 | METHOD FOR MAKING A SUSPENDED PART OF A MICROELECTRONIC AND/OR NANOELECTRONIC STRUCTURE IN A MONOLITHIC PART OF A SUBSTRATE - Method for making at least one first suspended part of a microelectronic or nanoelectronic structure from a monolithic part of a first substrate, the method comprising the following steps:
| 12-04-2014 |
20140357007 | METHOD OF FORMING A BOND RING FOR A FIRST AND SECOND SUBSTRATE - One method includes providing a first substrate; the first substrate may include a first MEMS device and a second MEMS device. A second substrate is also provided. The first substrate is bonded to the second substrate. The bonding may include forming a first bond ring around the first MEMS device and forming a second bond ring around the second MEMS device, wherein the second bond ring also encircles the first bond ring. In an embodiment, the eutectic point of the materials of the second bond ring is not reached during the bonding. | 12-04-2014 |
20140370638 | MEMS STRUCTURE WITH IMPROVED SHIELDING AND METHOD - A method for fabricating an integrated MEMS-CMOS device. The method can include providing a substrate member having a surface region and forming a CMOS IC layer having at least one CMOS device overlying the surface region. A bottom isolation layer can be formed overlying the CMOS IC layer and a shielding layer and a top isolation layer can be formed overlying a portion of bottom isolation layer. The bottom isolation layer can include an isolation region between the top isolation layer and the shielding layer. A MEMS layer overlying the top isolation layer, the shielding layer, and the bottom isolation layer, and can be etched to form at least one MEMS structure having at least one movable structure and at least one anchored structure. | 12-18-2014 |
20140370639 | MICRO ELECTRO MECHANICAL SYSTEM, SEMICONDUCTOR DEVICE, AND MANUFACTURING METHOD THEREOF - The present invention provides a MEMS and a sensor having the MEMS which can be formed without a process of etching a sacrifice layer. The MEMS and the sensor having the MEMS are formed by forming an interspace using a spacer layer. In the MEMS in which an interspace is formed using a spacer layer, a process for forming a sacrifice layer and an etching process of the sacrifice layer are not required. As a result, there is no restriction on the etching time, and thus the yield can be improved. | 12-18-2014 |
20150011035 | METHOD FOR FABRICATING AN INTEGRATED DEVICE - A method for fabricating an integrated device includes the following steps. First, a multi-layered structure is formed on a substrate, wherein the multi-layered structure is embedded in a lower isolation layer. Then, a bottom conductive pattern and a top conductive pattern are formed on a top surface of the lower isolation layer, wherein the top conductive pattern is on a top surface of the bottom conductive pattern. Afterwards, portions of the top conductive pattern are removed to expose portions of the bottom conductive pattern. Subsequently, an upper isolation layer is deposited on the lower isolation layer so that the upper isolation layer can be in direct contact with the portions of the bottom conductive pattern. Finally, portions of the lower isolation layer and the upper isolation layer are removed so as to expose portions of the substrate. | 01-08-2015 |
20150024534 | TWO DEGREE OF FREEDOM DITHERING PLATFORM FOR MEMS SENSOR CALIBRATION - Systems and methods for two degree of freedom dithering for micro-electromechanical system (MEMS) sensor calibration are provided. In one embodiment, a method for a device comprises forming a MEMS sensor layer, the MEMS sensor layer comprising a MEMS sensor and an in-plane rotator to rotate the MEMS sensor in the plane of the MEMS sensor layer. Further, the method comprises forming a first and second rotor layer and bonding the first rotor layer to a top surface and the second rotor layer to the bottom surface of the MEMS sensor layer, such that a first and second rotor portion of the first and second rotor layers connect to the MEMS sensor. Also, the method comprises separating the first and second rotor portions from the first and second rotor layers, wherein the first and second rotor portions and the MEMS sensor rotate about an in-plane axis of the MEMS sensor layer. | 01-22-2015 |
20150031159 | MEMS Devices and Methods of Forming the Same - A device includes a substrate, a routing conductive line over the substrate, a dielectric layer over the routing conductive line, and an etch stop layer over the dielectric layer. A Micro-Electro-Mechanical System (MEMS) device has a portion over the etch stop layer. A contact plug penetrates through the etch stop layer and the dielectric layer. The contact plug connects the portion of the MEMS device to the routing conductive line. An escort ring is disposed over the etch stop layer and under the MEMS device, wherein the escort ring encircles the contact plug. | 01-29-2015 |
20150118779 | STRAIN AND PRESSURE SENSING DEVICE, MICROPHONE, METHOD FOR MANUFACTURING STRAIN AND PRESSURE SENSING DEVICE, AND METHOD FOR MANUFACTURING MICROPHONE - According to one embodiment, a strain and pressure sensing device includes a semiconductor circuit unit and a sensing unit. The semiconductor circuit unit includes a semiconductor substrate and a transistor. The transistor is provided on a semiconductor substrate. The sensing unit is provided on the semiconductor circuit unit, and has space and non-space portions. The non-space portion is juxtaposed with the space portion. The sensing unit further includes a movable beam, a strain sensing element unit, and first and second buried interconnects. The movable beam has fixed and movable portions, and includes first and second interconnect layers. The fixed portion is fixed to the non-space portion. The movable portion is separated from the transistor and extends from the fixed portion into the space portion. The strain sensing element unit is fixed to the movable portion. The first and second buried interconnects are provided in the non-space portion. | 04-30-2015 |
20150140717 | METHOD FOR MANUFACTURING A STRUCTURED SURFACE - A method is described for manufacturing a micromechanical structure, in which a structured surface is created in a substrate by an etching method in a first method step, and residues are at least partially removed from the structured surface in a second method step. In the second method step, an ambient pressure for the substrate which is lower than 60 Pa is set and a substrate temperature which is higher than 150° C. is set. | 05-21-2015 |
20150318190 | BAW Gyroscope with Bottom Electrode - A bulk acoustic wave gyroscope has a primary member in a member plane, and an electrode layer in an electrode plane spaced from the member plane. The electrode layer has a first portion that is electrically isolated from a second portion. The first portion, however, is mechanically coupled with the second portion and faces the primary member (e.g., to actuate or sense movement of the primary member). For support, the second portion of the electrode is directly coupled with structure in the member plane. | 11-05-2015 |
20150336793 | METHOD OF MANUFACTURING A MEMS STRUCTURE - A method for creating MEMS structures comprises depositing and patterning a first mask on a wafer in order to define desired first areas to be etched in a first trench etching and desired second areas to be etched in a second trench etching. A first intermediate mask is deposited and patterned on top of the first mask. Recession trenches are etched on parts of the wafer. After the first intermediate mask is removed, first trenches are etched with further etching the recession trenches. The first trenches and the recession trenches are filled with a deposit layer. Part of the deposit layer is removed on second areas. A remainder is left on certain areas, to function as a second mask. A third mask is deposited. The third mask defines the final structure. The parts of the wafer on the second areas are etched in the second trench etching. The masks are then removed. | 11-26-2015 |
20150336794 | METHOD OF MANUFACTURING A MEMS STRUCTURE AND USE OF THE METHOD - A method creates MEMS structures by selectively etching a silicon wafer that is patterned by using a masking layer. The method comprises depositing and patterning a first mask on a silicon wafer to define desired first areas on the wafer to be etched. First trenches are etched on parts of the wafer not covered by the first mask. The first trenches are filled with a deposit layer. A part of the deposit layer is removed on desired second areas to be etched and a remainder is left on areas to function as a second mask to define final structures. Parts of the wafer on the desired second areas is etched, and the second mask is removed. A gyroscope or accelerator can be manufactured by dimensioning the structures. | 11-26-2015 |
20150340405 | INTEGRATED PIEZOELECTRIC RESONATOR AND ADDITIONAL ACTIVE CIRCUIT - A semiconductor device comprises a semiconductor wafer; a piezoelectric resonator formed on the wafer, and an active circuit also formed on the wafer. The active circuit (e.g., a frequency divider) is electrically connected to the piezoelectric resonator. | 11-26-2015 |
20150353350 | METHOD FOR MAKING SUSPENDED ELEMENTS WITH DIFFERENT THICKNESSES FOR A MEMS AND NEMS STRUCTURE - Method for making a N/MEMS device including a structure provided with an active part having a first suspended element and a second suspended element with different thicknesses, the method comprising the following steps of:
| 12-10-2015 |
20150368099 | ETCH RELEASE RESIDUE REMOVAL USING ANHYDROUS SOLUTION - A method of making a microelectromechanical systems (MEMS) device includes etching away a sacrificial material layer to release a mechanical element of the MEMS device. The MEMS device is formed at least partially on the sacrificial material layer, and the etching leaves a residue in proximity to the mechanical element. The residue is exposed to an anhydrous solution to remove the residue. The residue may be an ammonium fluorosilicate-based residue, and the anhydrous solution may include acetic acid, isopropyl alcohol, acetone, or any anhydrous solution that can effectively dissolve the ammonium fluorosilicate-based residue. | 12-24-2015 |
20150372028 | DISPLAY DEVICE INTEGRATED WITH TOUCH SCREEN PANEL AND METHOD FOR FABRICATING THE SAME - Disclosed is a display device integrated with a touch screen panel and a method for fabricating the same. The display includes: a TFT positioned at each pixel region; a first electrode spaced from one of a source electrode or a drain electrode of the TFT; a second electrode facing the first electrode; a TFT protective layer positioned on the TFT and has a first contact hole; a touch signal line positioned between a first touch connection pattern, which is made of the same material as the first electrode, and a second touch connection pattern made of the same material as the second electrode, and transfers a touch driving signal to the second touch connection pattern; a first connection pattern made of the same material as the second electrode; and a first electrode protective layer positioned on the first electrode and the touch signal line. | 12-24-2015 |
20160008849 | ULTRASONIC TRANSDUCER, METHOD OF PRODUCING SAME, AND ULTRASONIC PROBE USING SAME | 01-14-2016 |
20160016792 | MICROSTRUCTURE AND ELECTRONIC DEVICE - A method of manufacturing microstructures, such as MEMS or NEMS devices, including forming a protective layer on a surface of a moveable component of the microstructure. For example, a silicide layer may be formed on a portion of at least four different surfaces of a poly-silicon mass that is moveable with respect to a substrate of the microstructure. The process may be self-aligning. | 01-21-2016 |
20160023895 | Method for Producing a Micromechanical Component, and Corresponding Micromechanical Component - A method for producing a micromechanical component includes providing a substrate with a monocrystalline starting layer which is exposed in structured regions. The structured regions have an upper face and lateral flanks, wherein a catalyst layer, which is suitable for promoting a silicon epitaxial growth of the exposed upper face of the structured monocrystalline starting layer, is provided on the upper face, and no catalyst layers are provided on the flanks. The method also includes carrying out a selective epitaxial growth process on the upper face of the monocrystalline starting layer using the catalyst layer in a reactive gas atmosphere in order to form a micromechanical functional layer. | 01-28-2016 |
20160046482 | MEMS Devices and Methods of Forming the Same - A device includes a substrate, a routing conductive line over the substrate, a dielectric layer over the routing conductive line, and an etch stop layer over the dielectric layer. A Micro-Electro-Mechanical System (MEMS) device has a portion over the etch stop layer. A contact plug penetrates through the etch stop layer and the dielectric layer. The contact plug connects the portion of the MEMS device to the routing conductive line. An escort ring is disposed over the etch stop layer and under the MEMS device, wherein the escort ring encircles the contact plug. | 02-18-2016 |
20160115016 | FILM INDUCED INTERFACE ROUGHENING AND METHOD OF PRODUCING THE SAME - Various embodiments provide for a method for roughening a surface of a MEMs device or the surface of a CMOS surface. A first material can be deposited in a thin layer over a surface made of a second material. After heating, the first and second materials, they can partially melt and interdiffuse, forming an alloy. The first material can then be removed and the alloy is removed at the same time. The surface of the second material that is left behind has then been roughened due to the interdiffusion of the first and second materials. | 04-28-2016 |
20160130140 | METHOD FOR MANUFACTURING A PROTECTIVE LAYER AGAINST HF ETCHING, SEMICONDUCTOR DEVICE PROVIDED WITH THE PROTECTIVE LAYER AND METHOD FOR MANUFACTURING THE SEMICONDUCTOR DEVICE - A method for manufacturing a protective layer for protecting an intermediate structural layer against etching with hydrofluoric acid, the intermediate structural layer being made of a material that can be etched or damaged by hydrofluoric acid, the method comprising the steps of: forming a first layer of aluminium oxide, by atomic layer deposition, on the intermediate structural layer; performing a thermal crystallization process on the first layer of aluminium oxide, forming a first intermediate protective layer; forming a second layer of aluminium oxide, by atomic layer deposition, above the first intermediate protective layer; and performing a thermal crystallization process on the second layer of aluminium oxide, forming a second intermediate protective layer and thereby completing the formation of the protective layer. The method for forming the protective layer can be used, for example, during the manufacturing steps of an inertial sensor such as a gyroscope or an accelerometer. | 05-12-2016 |
20160251214 | Apparatus and Method of Forming a MEMS Device with Etch Channels | 09-01-2016 |
20180022600 | CMOS COMPATIBLE CAPACITIVE ABSOLUTE PRESSURE SENSORS | 01-25-2018 |