Patent application number | Description | Published |
20080231931 | MEMS CAVITY-COATING LAYERS AND METHODS - Devices, methods, and systems comprising a MEMS device, for example, an interferometric modulator, that comprises a cavity in which a layer coats multiple surfaces. The layer is conformal or non-conformal. In some embodiments, the layer is formed by atomic layer deposition (ALD). Preferably, the layer comprises a dielectric material. In some embodiments, the MEMS device also exhibits improved characteristics, such as improved electrical insulation between moving electrodes, reduced stiction, and/or improved mechanical properties. | 09-25-2008 |
20080239449 | ELECTRODE AND INTERCONNECT MATERIALS FOR MEMS DEVICES - A microelectromechanical (MEMS) device is presented which comprises a metallized semiconductor. The metallized semiconductor can be used for conductor applications because of its low resistivity, and for transistor applications because of its semiconductor properties. In addition, the metallized semiconductor can be tuned to have optical properties which allow it to be useful for optical MEMS devices. | 10-02-2008 |
20080311690 | ELIMINATE RELEASE ETCH ATTACK BY INTERFACE MODIFICATION IN SACRIFICIAL LAYERS - Methods of making a microelectromechanical system (MEMS) device are described. In some embodiments, the method includes forming a sacrificial layer over a substrate, treating at least a portion of the sacrificial layer to form a treated sacrificial portion, forming an overlying layer over at least a part of the treated sacrificial portion, and at least partially removing the treated sacrificial portion to form a cavity situated between the substrate and the overlying layer, the overlying layer being exposed to the cavity. | 12-18-2008 |
20090002804 | ELECTROMECHANICAL DEVICE TREATMENT WITH WATER VAPOR - Methods, devices, and systems provide MEMS devices exhibiting at least one of reduced stiction, reduced hydrophilicity, or reduced variability of certain electrical characteristics using MEMS devices treated with water vapor. The treatment is believed to form one or more passivated surfaces on the interior and/or exterior of the MEMS devices. Relatively gentle temperature and pressure conditions ensure modification of surface chemistry without excessive water absorption after removal of sacrificial material to release the MEMS devices. | 01-01-2009 |
20090071933 | ETCHING PROCESSES USED IN MEMS PRODUCTION - The efficiency of an etching process may be increased in various ways, and the cost of an etching process may be decreased. Unused etchant may be isolated and recirculated during the etching process. Etching byproducts may be collected and removed from the etching system during the etching process. Components of the etchant may be isolated and used to general additional etchant. Either or both of the etchant or the layers being etched may also be optimized for a particular etching process. | 03-19-2009 |
20090101623 | ETCHING PROCESSES USED IN MEMS PRODUCTION - The efficiency of an etching process may be increased in various ways, and the cost of an etching process may be decreased. Unused etchant may be isolated and recirculated during the etching process. Etching byproducts may be collected and removed from the etching system during the etching process. Components of the etchant may be isolated and used to general additional etchant. Either or both of the etchant or the layers being etched may also be optimized for a particular etching process. | 04-23-2009 |
20090122384 | CAPACITIVE MEMS DEVICE WITH PROGRAMMABLE OFFSET VOLTAGE CONTROL - A capacitive MEMS device is formed having a material between electrodes that traps and retains charges. The material can be realized in several configurations. It can be a multilayer dielectric stack with regions of different band gap energies or band energy levels. The dielectric materials can be trappy itself, i.e. when defects or trap sites are pre-fabricated in the material. Another configuration involves a thin layer of a conductive material with the energy level in the forbidden gap of the dielectric layer. The device may be programmed (i.e. offset and threshold voltages pre-set) by a method making advantageous use of charge storage in the material, wherein the interferometric modulator is pre-charged in such a way that the hysteresis curve shifts, and the actuation voltage threshold of the modulator is significantly lowered. During programming phase, charge transfer between the electrodes and the materials can be performed by applying voltage to the electrodes (i.e. applying electrical field across the material) or by UV-illumination and injection of electrical charges over the energy barrier. The interferometric modulator may then be retained in an actuated state with a significantly lower actuation voltage, thereby saving power. | 05-14-2009 |
20100128339 | INTERFEROMETRIC OPTICAL DISPLAY SYSTEM WITH BROADBAND CHARACTERISTICS - Broad band white color can be achieved in MEMS display devices by incorporating a material having an extinction coefficient (k) below a threshold value for wavelength of light within an operative optical range of the interferometric modulator. One embodiment provides a method of making the MEMS display device comprising depositing said material over at least a portion of a transparent substrate, depositing a dielectric layer over the layer of material, forming a sacrificial layer over the dielectric, depositing an electrically conductive layer on the sacrificial layer, and forming a cavity by removing at least a portion of the sacrificial layer. The suitable material may comprise germanium, germanium alloy of various compositions, doped germanium or doped germanium-containing alloys, and may be deposited over the transparent substrate, incorporated within the transparent substrate or the dielectric layer. | 05-27-2010 |
20100206629 | DISPLAY DEVICE WITH DESICCANT - Systems and methods for providing MEMS devices with integrated desiccant are provided. In one embodiment, a dry composition comprising desiccant is impact sprayed onto the backplate or substrate of a MEMS device, and becomes fused with the substrate. In another embodiment, the desiccant is impact sprayed such that the desiccant adheres to the impact sprayed surface. In yet another embodiment, the impact-sprayed surface is impregnated with the desiccant. In still another embodiment, the desiccant is combined with a suitable inorganic binder, then impact sprayed such that the desiccant adheres to the impact sprayed surface. In yet a further embodiment, the desiccant is micronized or pulverized into a powder of desired particle size, and then impact sprayed onto a surface. Thus, the desiccant particles or powder are fused onto the target surface through the impact spraying process. | 08-19-2010 |
20100219155 | EQUIPMENT AND METHODS FOR ETCHING OF MEMS - Etching equipment and methods are disclosed herein for more efficient etching of sacrificial material from between permanent MEMS structures. An etching head includes an elongate etchant inlet structure, which may be slot-shaped or an elongate distribution of inlet holes. A substrate is supported in proximity to the etching head in a manner that defines a flow path substantially parallel to the substrate face, and permits relative motion for the etching head to scan across the substrate. | 09-02-2010 |
20100238537 | CAPACITIVE MEMS DEVICE WITH PROGRAMMABLE OFFSET VOLTAGE CONTROL - A capacitive MEMS device is formed having a material between electrodes that traps and retains charges. The material can be realized in several configurations. It can be a multilayer dielectric stack with regions of different band gap energies or band energy levels. The dielectric materials can be trappy itself, i.e. when defects or trap sites are pre-fabricated in the material. Another configuration involves a thin layer of a conductive material with the energy level in the forbidden gap of the dielectric layer. The device may be programmed (i.e. offset and threshold voltages pre-set) by a method making advantageous use of charge storage in the material, wherein the interferometric modulator is pre-charged in such a way that the hysteresis curve shifts, and the actuation voltage threshold of the modulator is significantly lowered. During programming phase, charge transfer between the electrodes and the materials can be performed by applying voltage to the electrodes (i.e. applying electrical field across the material) or by UV-illumination and injection of electrical charges over the energy barrier. The interferometric modulator may then be retained in an actuated state with a significantly lower actuation voltage, thereby saving power. | 09-23-2010 |
20100245979 | MEMS CAVITY-COATING LAYERS AND METHODS - Devices, methods, and systems comprising a MEMS device, for example, an interferometric modulator, that comprises a cavity in which a layer coats multiple surfaces. The layer is conformal or non-conformal. In some embodiments, the layer is formed by atomic layer deposition (ALD). Preferably, the layer comprises a dielectric material. In some embodiments, the MEMS device also exhibits improved characteristics, such as improved electrical insulation between moving electrodes, reduced stiction, and/or improved mechanical properties. | 09-30-2010 |
20110128212 | DISPLAY DEVICE HAVING AN INTEGRATED LIGHT SOURCE AND ACCELEROMETER - A display device having an illumination system with integrated accelerometer is disclosed in which a portion of the illumination system is used as the proof mass for the accelerometer. In one embodiment, the display device includes a plurality of display elements, one or more light sources, one or more light redirectors configured to redirect at least a portion of the light generated by the light sources to at least a portion of the plurality of display elements, one or more light detectors each configured to determine a light intensity, and a processor configured to determine one or more accelerations based on the determined light intensity. | 06-02-2011 |
20110149374 | TWO-TERMINAL VARIABLE CAPACITANCE MEMS DEVICE - A two-terminal, variable capacitance device is described that is constructed by connecting multiple MEMS devices having different actuation or “pull in” voltages in parallel. | 06-23-2011 |
20120075313 | INTERFEROMETRIC OPTICAL DISPLAY SYSTEM WITH BROADBAND CHARACTERISTICS - Broad band white color can be achieved in MEMS display devices by incorporating a material having an extinction coefficient (k) below a threshold value for wavelength of light within an operative optical range of the interferometric modulator. One embodiment provides a method of making the MEMS display device comprising depositing said material over at least a portion of a transparent substrate, depositing a dielectric layer over the layer of material, forming a sacrificial layer over the dielectric, depositing an electrically conductive layer on the sacrificial layer, and forming a cavity by removing at least a portion of the sacrificial layer. The suitable material may comprise germanium, germanium alloy of various compositions, doped germanium or doped germanium-containing alloys, and may be deposited over the transparent substrate, incorporated within the transparent substrate or the dielectric layer. | 03-29-2012 |
20120206462 | MEMS CAVITY-COATING LAYERS AND METHODS - Devices, methods, and systems comprising a MEMS device, for example, an interferometric modulator, that comprises a cavity in which a layer coats multiple surfaces. The layer is conformal or non-conformal. In some embodiments, the layer is formed by atomic layer deposition (ALD). Preferably, the layer comprises a dielectric material. In some embodiments, the MEMS device also exhibits improved characteristics, such as improved electrical insulation between moving electrodes, reduced stiction, and/or improved mechanical properties. | 08-16-2012 |
20120274647 | PIEZOELECTRIC RESONATORS AND FABRICATION PROCESSES - This disclosure provides implementations of electromechanical systems resonator structures, devices, apparatus, systems, and related processes. In one aspect, a sacrificial layer is deposited on an insulating substrate. A lower electrode layer is formed proximate the sacrificial layer. A piezoelectric layer is deposited on the lower electrode layer. An upper electrode layer is formed on the piezoelectric layer. At least a portion of the sacrificial layer is removed to define a cavity such that at least a portion of the lower electrode layer is spaced apart from the insulating substrate. | 11-01-2012 |
20130003158 | APPARATUS AND METHOD FOR OPTICAL DECOUPLING - This disclosure provides apparatus, systems and methods for optical decoupling. In one implementation, an optical system includes a substrate transmissive to visible light, a first antireflective structure disposed on a surface of the substrate, a second antireflective structure. The first and second antireflective structures define at least one cavity containing air in between. The optical system further includes a plurality of support posts configured to space the first antireflective structure from the second antireflective structure to define the height of the at least one cavity. A reflective display is disposed on a surface of the second antireflective structure opposite the at least one cavity. | 01-03-2013 |
20140267756 | Microbolometer supported by glass substrate - This disclosure provides systems, methods and apparatus for forming microbolometers on glass substrates. In one aspect, the formation of microbolometers on glass substrates can reduce the size and cost of the resultant array and associated circuitry. In one aspect, a portion of the measurement and control circuitry can be formed by thin-film deposition on the glass substrate, while sensitive measurement and control circuitry can be formed on ancillary CMOS substrates. In one aspect, the microbolometers may be packaged using a variety of techniques, including a wafer-level packaging process or a pixel-level packaging process. | 09-18-2014 |