Abstract: A method for manufacturing a micromechanical structure includes: forming a first insulation layer above a substrate; forming a first micromechanical functional layer on the first insulation layer; forming multiple first trenches in the first micromechanical functional layer, which trenches extend as far as the first insulation layer; forming a second insulation layer on the first micromechanical functional layer, which second insulation layer fills up the first trenches; forming etch accesses in the second insulation layer, which etch accesses locally expose the first micromechanical functional layer; and etching the first micromechanical functional layer through the etch accesses, the filled first trenches and the first insulation layer acting as an etch stop.

Abstract: Organometallic complexes and use thereof in thin film deposition, such as CVD and ALD are provided herein. The organometallic complexes are (alkyl-substituted ?3-allyl)(carbonyl)metal complexes.

Abstract: Memory device and method for fabricating a memory device on two layers of a semiconductor wafer. An example device includes bit lines and word lines fabricated at one layer of a semiconductor wafer and re-writable nonvolatile memory cells that include a two-terminal access device with a bidirectional voltage-current characteristics for positive and negative voltages applied at the terminals. Additionally, a drive circuit electrically coupled to the memory cells and configured to program the memory cells is fabricated at another layer of the semiconductor wafer. Another example embodiment includes a memory device where a plurality of memory arrays are fabricated at one layer of a semiconductor wafer and a plurality of drive circuits electrically coupled to the memory cells and configured to read the memory cells are fabricated at a second layer of the semiconductor wafer.

Abstract: In a method for fabricating a semiconductor device, a conductive layer is formed on a substrate, where the substrate has a bottom layer formed thereon. A magnetic tunnel junction layer is formed on the conductive layer. The magnetic tunnel junction layer is patterned using an etching gas containing oxygen. An insulating layer is formed by oxidizing the conductive layer exposed outside the patterned magnetic tunnel junction layer using the etching gas.

Abstract: Disclosed herein are biochemical actuator heads instrumented with a receptor conductive polymer for reversibly controlling ligand-receptor interactions. Also disclosed are systems and methods for utilizing and fabricating the biochemical actuator head. The biochemical actuator head and related systems and methods may be used in a wide array of applications including, without limitation, micro/nano assembly, examination of cellular signaling mechanisms, image-guided cell nanosurgery or particle processing. Particle processing systems and methods are also provided utilizing a receptor conductive polymer for reversibly controlling ligand-receptor interactions.

Abstract: The spikes in current and voltage that result from the failure of a galvanic dielectric layer are safely contained by a galvanic isolation fuse that pops and forms and open circuit between a high-voltage die and a low-voltage die in response to the failure of the galvanic dielectric layer.

Abstract: According to one embodiment, a magnetic random access memory includes a plurality of magnetoresistance elements. The plurality of magnetoresistance elements each include a recording layer having magnetic anisotropy perpendicular to a film surface, and a variable magnetization direction, a reference layer having magnetic anisotropy perpendicular to a film surface, and an invariable magnetization direction, and a first nonmagnetic layer formed between the recording layer and the reference layer. The recording layer is physically separated for each of the plurality of magnetoresistance elements. The reference layer and the first nonmagnetic layer continuously extend over the plurality of magnetoresistance elements.

Abstract: 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.

Abstract: Disclosed is a novel non-volatile, ferroelectric random access memory (F-RAM) device and a method for fabricating a damascene self-aligned F-RAM device structure on a planar surface using a reduced number of masks and etching steps.

Abstract: In a method for fabricating a magnetic tunnel junction, a fixed layer, a tunnel insulating layer, a free layer, and an anti-etch layer are formed on a substrate. A sacrificial layer having a hole is formed on the anti-etch layer. An upper electrode is buried in the hole. The sacrificial layer is removed. The anti-etch layer, the free layer, the tunnel insulating layer, and the fixed layer are etched using the upper electrode as a mask.

Abstract: A fabricating method of a microelectronic device including the following steps is provided. First, a substrate is provided. Second, a semi-conductor element is formed in a CMOS circuit region of the substrate. Next, a plurality of metallic layer, a plurality of contact plugs and a plurality of oxide layer are formed on the substrate. The metallic layers and the oxide layers are interlaced with each other and the contact plugs are formed in the oxide layers and connected with the metallic layers correspondingly so as to form a micro electromechanical system (MEMS) structure within a MEMS region and an interconnecting structure within the CMOS circuit region. Then, a first protective layer is formed on at least one of the oxide layers and a second protective layer is formed on the interconnecting structure. Predetermined portions of the oxide layers located within the MEMS region are removed and thereby the MEMS structure is partially suspended above the substrate.

Abstract: Disclosed is an integrated circuit comprising a substrate (10) carrying a plurality of circuit elements; a metallization stack (12, 14, 16) interconnecting said circuit elements, said metallization stack comprising a patterned upper metallization layer comprising a first metal portion (20) and a second metal portion (21); a passivation stack (24, 26, 28) covering the metallization stack; a gas sensor including a sensing material portion (32, 74) on the passivation stack; a first conductive portion (38) extending through the passivation stack connecting a first region of the sensing material portion to the first metal portion; and a second conductive portion (40) extending through the passivation stack connecting a second region of the sensing material portion to the second metal portion. A method of manufacturing such an IC is also disclosed.

Abstract: In some examples, a semiconductor package can be configured to electrically couple to a printed circuit board. The semiconductor package can include: (a) a lid having one or more first electrically conductive leads; (b) a base coupled to the lid and having one or more second electrically conductive leads electrically coupled to the one or more first electrically conductive leads; (c) one or more first semiconductor devices mechanically coupled to the lid and electrically coupled to the one or more first electrically conductive leads; and (d) one or more first micro-electrical-mechanical system devices mechanically coupled to the lid and electrically coupled to the one or more first electrically conductive leads. At least one of the lid or the base can have at least one port hole. The one or more first electrically conductive leads can be configured to couple to the printed circuit board. Other embodiments are disclosed.

Abstract: A stereoscopic image display and method is provided. The stereoscopic image display device includes: a thin film transistor array substrate, a color filter substrate facing the thin film transistor array substrate, the color filter substrate including a plurality of black matrices, a plurality of black stripes on the color filter substrate, each of the plurality of black stripes corresponding to the black matrices, and a patterned retarder film on the color filter array substrate over the black stripes, wherein at least one of the plurality of black stripes includes a first black pattern and a second black pattern that are spaced apart from each other, such that gaps are disposed therebetween.

Abstract: Disclosed is an integrated circuit comprising a substrate (10) carrying a plurality of circuit elements; a metallization stack (12, 14, 16) interconnecting said circuit elements, said metallization stack comprising a patterned upper metallization layer comprising a first metal portion (20) and a second metal portion (21); a passivation stack (24, 26, 28) covering the metallization stack; a gas sensor including a sensing material portion (32, 74) on the passivation stack; a first conductive portion (38) extending through the passivation stack connecting a first region of the sensing material portion to the first metal portion; and a second conductive portion (40) extending through the passivation stack connecting a second region of the sensing material portion to the second metal portion. A method of manufacturing such an IC is also disclosed.

Abstract: An integrated circuit die includes conductive connection sites located at least on a surface of the integrated circuit die within a contiguous region thereof. The integrated circuit also includes a core circuit located outside the contiguous region. The core circuit is coupled to at least one of the connection sites.

Abstract: Provided is a method of manufacturing a semiconductor device. In the method, after a thin liner is formed on a substrate on which a lower interconnection is formed, a silicon source is supplied to form a silicide layer under the liner by a reaction between the silicon source and the lower interconnection, and the silicide layer is nitrided and an etch stop layer is formed. Therefore, the lower interconnection is prevented from making contact with the silicon source, variations of the surface resistance of the lower interconnection can be prevented, and thus high-speed devices can be fabricated.

Abstract: A semiconductor device manufacturing method includes the steps of forming a silicate film by performing a first step of forming a metal oxide film on a silicon substrate, and a second step of inducing a solid phase reaction between the metal oxide film and a surface of the silicon substrate by heat treatment, and forming a high dielectric constant insulating film on the silicate film.

Abstract: A light emitting system is disclosed. The system comprises an active region having a stack of bilayer quantum well structures separated from each other by barrier layers. Each bilayer quantum well structure is formed of a first layer made of a first semiconductor alloy for electron confinement and a second layer made of a second semiconductor alloy for hole confinement, wherein a thickness and composition of each layer is such that a characteristic hole confinement energy of the bilayer quantum well structure is at least 200 meV.

Abstract: A TFT array substrate includes a pixel region and a wiring region disposed outside the pixel region. The wiring region has a wiring layer including scan or data wirings. A repair wiring layer including repair wiring is disposed insulatedly below or above the wiring layer. A scan or data wiring has a first intersection and a second intersection with a repair wiring section of the repair wiring. When the scan or data wiring is broken, a repair wiring section is cut off the repair wiring by a first cut-off point and a second cut-off point, and the broken scan or data wiring is electrically connected to the repair wiring section through soldering the first intersection and the second intersection. Thus, products that would otherwise be rejected in the manufacturing process of LCD panels can be repaired, which decreases the reject ratio, increases the yield and saves the production cost.

Abstract: A gallium nitride (GaN) bonded substrate and a method of manufacturing a GaN bonded substrate in which a polycrystalline nitride-based substrate is used. The method includes loading a single crystalline GaN substrate and a polycrystalline nitride substrate into a bonder; raising the temperature in the bonder; bonding the single crystalline GaN substrate and the polycrystalline nitride substrate together by pressing the single crystalline GaN substrate and the polycrystalline nitride substrate against each other after the step of raising the temperature; and cooling the resultant bonded substrate.

Abstract: A cleaning control apparatus capable of performing a cleaning process efficiently regardless of qualities and thicknesses of films formed in a process tube and a gas supply nozzle. The cleaning control apparatus employs cleaning request signal output units configured to output cleaning request signals requesting cleaning processes of a silicon-containing gas supply system and nitriding source gas supply system when accumulated amounts of the molecules of the silicon-containing gas and the nitriding source gas exceeds preset values.

Abstract: Embodiments disclosed herein generally relate to a process of depositing a transparent conductive oxide layer over a substrate. The transparent oxide layer is sometimes deposited onto a substrate for later use in a solar cell device. The transparent conductive oxide layer may be deposited by a “cold” sputtering process. In other words, during the sputtering process, a plasma is ignited in the processing chamber which naturally heats the substrate. No additional heat is provided to the substrate during deposition such as from the susceptor. After the transparent conductive oxide layer is deposited, the substrate may be annealed and etched, in either order, to texture the transparent conductive oxide layer. In order to tailor the shape of the texturing, different wet etch chemistries may be utilized. The different etch chemistries may be used to shape the surface of the transparent conductive oxide and the etch rate.

Abstract: A method and an electronic device structure comprising at least one access lead to adapted to be connected to an electrical circuit; at least one substrate region; at least one semiconductor die positioned on the substrate; the at least one semiconductor die being operatively connected to the at least one access lead; a dielectric region extending below the at least one semiconductor die; the dielectric region being formed by creating a cavity in the at least one substrate region; whereby the dielectric region operates to reduce electric field stresses produced by the at least one semiconductor die to thereby reduce the possibility of material failure and voltage breakdown.

Abstract: A pressure detecting device includes a glass substrate as a substrate, a lower electrode arranged on the glass substrate, an upper electrode spaced apart from the lower electrode and facing the lower electrode, the upper electrode having holes as one or more through-openings, and a source line as a change extracting wiring for detecting a change in electrical state caused by the upper electrode receiving pressure to deflect toward the lower electrode.

Abstract: A chip package structure and a method for forming the chip package structure are disclosed. At least a block is formed on a surface of a cover, the cover is mounted on a substrate having a sensing device formed thereon for covering the sensing device, and the block is disposed between the cover and the sensing device. In the present invention, the block is mounted on the cover, there is no need to etch the cover to form a protruding portion, and thus the method of the present invention is simple and has low cost.

Abstract: A temperature sensing element includes a thermistor composed of Si-base ceramics and a pair of metal electrodes bonded onto the surfaces of the thermistor. The metal electrodes contain Cr and a metal element ? having a Si diffusion coefficient higher than that of Cr. A diffusion layer is formed in a bonding interface between the thermistor and each metal electrode, the diffusion layer including a silicide of the metal element ? in a crystal grain boundary of the Si-base ceramics. A temperature sensor including the diffusion layers is provided. Owing to the diffusion layers, the temperature sensor ensures heat resistance and bonding reliability and enables temperature detection with high accuracy in a temperature range, in particular, of from ?50° C. to 1050° C.

Abstract: A method for manufacturing a sensor device (100; 200; 300; 400) comprising a thermal sensor (23), a battery (33), an antenna (34), an electronic circuitry (22) and a solar cell (43) together integrally in one semiconductor carrier (10), the method comprising the steps of:—providing a silicon wafer (10) with two main surfaces (11, 12); a first functional layer (20) is manufactured in one main surface (11), comprising a thermal sensor portion (21) and comprising electronic circuitry (22) arranged in a non-overlapping relationship with the thermal sensor portion; a second functional layer (30) containing a battery (33) and an antenna (34) is arranged in a non-overlapping relationship with the thermal sensor portion; a third functional layer (40) containing one or more solar cells (43) is arranged in a non-overlapping relationship with the thermal sensor portion; the portion of the wafer underneath the thermal sensor portion (21) is removed.

Abstract: In a method for fabricating a magnetic tunnel junction, a first magnetic layer is formed on a substrate, and a tunnel insulating layer is formed on the first magnetic layer. Subsequently, a second magnetic layer is formed on the tunnel insulating layer. In the method, the first magnetic layer is formed by periodically sputtering a magnetic target while a metal target is continuously sputtered.

Abstract: A memory includes a semiconductor substrate. Cell transistors are on the substrate. Contact plugs each of which is buried between the adjacent cell transistors and electrically connected to a diffusion layer between the adjacent cell transistors. An interlayer dielectric film buries gaps between the contact plugs. A storage element is provided not above the contact plugs but above the interlayer dielectric film. A sidewall film covers a part of a side surface of the storage element, and is provided to overlap with one of the contact plugs as viewed from above a surface of the semiconductor substrate. A lower electrode is provided between a bottom of the storage element and the interlayer dielectric film and between the sidewall film and one of the contact plugs, and electrically connects the storage element to one of the contact plugs.

Abstract: A pressure sensor (1) is provided which has a piezoresistive membrane (2) which can be deformed by the action of the pressure of a medium. The membrane (2) is arranged on a carrier substrate (3) and extends over an opening (32) in the carrier substrate (3). The pressure sensor (1) has a protective layer (4) to protect the membrane (2) from direct contact with a medium. The protective layer (4) covers the membrane (2) both in a first region (28) inside the opening (32) and in a second region (29) outside the opening (32). Furthermore, a process for producing a pressure sensor (1) is provided in which the protective layer (4) forms an etch stop for an etching process.

Abstract: A magnetic tunnel junction includes an amorphous ferromagnetic reference layer having a first reference layer side and an opposing second reference layer side. The first reference layer side has a greater concentration of boron than the second reference layer side. A magnesium oxide tunnel barrier layer is disposed on the second side of the amorphous ferromagnetic reference layer. The magnesium oxide tunnel barrier layer has a crystal structure. An amorphous ferromagnetic free layer is disposed on the magnesium oxide tunnel barrier layer.

Abstract: Provided are a distributed feedback laser diode and a manufacturing method thereof. The distributed feedback laser diode includes a first area having a first grating layer disposed in a longitudinal direction, a second area disposed adjacent to the first area and having a second grating layer disposed in the longitudinal direction, and an active layer disposed over the first and second areas. Coupling coefficients of the first and second grating layers are made different in the first and second areas by a selective area growth method. The distributed feedback laser diode includes grating layers each having an asymmetric coefficient and is implemented within an optimal range capable of obtaining both a high front facet output and stable single mode characteristics. Thus, high manufacturing yield and low manufacturing cost can be achieved.

Abstract: A semiconductor device includes a semiconductor substrate and a semiconductor mass element configured to move in response to an applied acceleration. The mass element is defined by trenches etched into the semiconductor substrate and a cavity below the mass element. The semiconductor device includes a sensing element configured to sense movement of the mass element.

Abstract: A process to form a photodiode (PD) with the waveguide structure is disclosed. The PD processes thereby reduces a scattering of the parasitic resistance thereof. The process includes steps to form a PD mesa stripe, to bury the PD mesa stripe by the waveguide region, to etch the PD mesa stripe and the waveguide region to form the waveguide mesa stripe. In the etching, the lower contact layer plays a role of the etching stopper.

Abstract: A process for manufacturing a MEMS device, wherein a bottom silicon region is formed on a substrate and on an insulating layer; a sacrificial region of dielectric is formed on the bottom region; a membrane region, of semiconductor material, is epitaxially grown on the sacrificial region; the membrane region is dug down to the sacrificial region so as to form through apertures; the side wall and the bottom of the apertures are completely coated in a conformal way with a porous material layer; at least one portion of the sacrificial region is selectively removed through the porous material layer and forms a cavity; and the apertures are filled with filling material so as to form a monolithic membrane suspended above the cavity. Other embodiments are directed to MEMS devices and pressure sensors.

Abstract: A diaphragm of an MEMS electroacoustic transducer including a first axis-symmetrical pattern layer is provided. Because the layout of the first axis-symmetrical pattern layer can match the pattern of the sound wave, the vibration uniformity of the diaphragm can be improved.

Abstract: 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.

Abstract: A conductor having a projecting portion is formed which forms a terminal portion. An uncured prepreg including a reinforcing material is closely attached to the conductor and the prepreg is cured to form an insulating film including the reinforcing material. When the prepreg is closely attached, the prepreg is stretched by the projecting portion, so that a region of the prepreg, which is closely attached to the conductor, can be thinner than the other region of the prepreg. Then, by reducing the thickness of the entire insulating film, an opening can be formed in the portion having a smaller thickness. The step of reducing the thickness can be performed by etching. Further, it is preferable not to remove the reinforcing material in this step. The strength of a terminal and an electronic device can be increased by leaving the reinforcing material at the opening.

Abstract: In order to provide a semiconductor laser element or an integrated optical device with high reliability, a horizontal-cavity semiconductor laser or an optical module includes a deeply dug DBR mirror serving as a cavity mirror, the deeply dug DBR mirror being composed of a material that is lattice-matched to a substrate and that has a band gap energy that does not absorb light emitted from an active layer.

Abstract: A Microelectromechanical systems (MEMS) structure comprises a MEMS wafer. A MEMS wafer includes a handle wafer with cavities bonded to a device wafer through a dielectric layer disposed between the handle and device wafers. The MEMS wafer also includes a moveable portion of the device wafer suspended over a cavity in the handle wafer. Four methods are described to create two or more enclosures having multiple gas pressure or compositions on a single substrate including, each enclosure containing a moveable portion. The methods include: A. Forming a secondary sealed enclosure, B. Creating multiple ambient enclosures during wafer bonding, C. Creating and breaching an internal gas reservoir, and D. Forming and subsequently sealing a controlled leak/breach into the enclosure.

Abstract: An improved method for manufacturing an MEMS microphone with a double fixed electrode is specified which results in a microphone which likewise has improved properties.

Abstract: A method for producing a liquid-discharge-head substrate includes a step of preparing a silicon substrate including, at a front-surface side of the silicon substrate, an energy generating element; a step of forming a first etchant introduction hole on the front-surface side of the silicon substrate; a step of supplying a first etchant into the first etchant introduction hole formed on the front-surface side of the silicon substrate, and supplying a second etchant to a back-surface side of the silicon substrate; a step of stopping the supply of the second etchant; and a step of, after the supply of the second etchant has been stopped, forming a liquid supply port extending through front and back surfaces of the silicon substrate by the supply of the first etchant.

Abstract: A method for forming a semiconductor device includes forming a substrate, forming a moveable member of bulk silicon and forming a first dimple structure on a first surface of the moveable member, where the first surface faces the substrate.

Abstract: A semiconductor device includes a substrate, an insulator layer on the substrate, an inductor on the insulator layer, and a film including a ferromagnetic particle on the inductor.

Abstract: A piezoelectric device and a fabricating method thereof are provided. Variation of output frequency is suppressed by forming an organic resin to protect an IC chip that is mounted in a cavity of a container body, and damage that may occur to the IC chip during the mounting process is prevented. The piezoelectric device includes a container body, a crystal resonator, an IC chip and a cover body. A surface of the IC chip, which is a mounting surface for mounting to the container body, has bumps thereon for connecting to terminal pads of a circuit wiring pattern configured on a bottom surface of a bottom cavity of the container body, and the other surface of the IC chip has an insulating protective sheet adhered and fixed thereon.

Abstract: The present invention relates to a CMOS compatible MEMS microphone, comprising: an SOI substrate, wherein a CMOS circuitry is accommodated on its silicon device layer; a microphone diaphragm formed with a part of the silicon device layer, wherein the microphone diaphragm is doped to become conductive; a microphone backplate including CMOS passivation layers with a metal layer sandwiched and a plurality of through holes, provided above the silicon device layer, wherein the plurality of through holes are formed in the portions thereof opposite to the microphone diaphragm, and the metal layer forms an electrode plate of the backplate; a plurality of dimples protruding from the lower surface of the microphone backplate opposite to the diaphragm; and an air gap, provided between the diaphragm and the microphone backplate, wherein a spacer forming a boundary of the air gap is provided outside of the diaphragm or on the edge of the diaphragm; wherein a back hole is formed to be open in substrate underneath the diaph

Abstract: Embodiments of the invention provide robust electrothermal MEMS with fast thermal response. In one embodiment, an electrothermal bimorph actuator is fabricated using aluminum as one bimorph layer and tungsten as the second bimorph layer. The heating element can be the aluminum or the tungsten, or a combination of aluminum and tungsten, thereby providing a resistive heater and reducing deposition steps. Polyimide can be used for thermal isolation of the bimorph actuator and the substrate. For MEMS micromirror designs, the polyimide can also be used for thermal isolation between the bimorph actuator and the micromirror.

Abstract: The optical semiconductor device includes a spot-size converter formed on a semiconductor substrate. The spot-size converter has a multilayer structure including a light transition region. The multilayer structure includes a lower core layer, and an upper core layer having a refractive index higher than that of the lower core layer. The width of the upper core layer is gradually decreased and the width of the lower core layer is gradually increased in the light transition region. Both sides and an upper side of the multilayer structure are buried by a semi-insulating semiconductor layer in the light transition region. Light incident from one end section of the spot-size converter is propagated to the upper core layer. The light transits from the upper core layer to the lower core layer in the light transition region, is propagated to the lower core layer, and exits from the other end section thereof.

Abstract: The NH3 plasma treatment by remote plasma is firstly proposed to replace the covalent bonding process during surface modification procedure that for amine bond generation.