Abstract: The invention relates to an integrated semiconductor memory with at least one memory cell having at least one transistor which forms an inversion channel in the switched-on state. The transistor comprises a structure element having a first source/drain region, a second source/drain region and a region arranged between the first and the second source/drain region, the structure element is insulated from a semiconductor substrate by an insulation layer, a gate dielectric being arranged on the structure element and a word line being arranged on the gate dielectric.

Abstract: A microelectronic product and a method for fabricating the same each provide a capacitor formed interposed between a first dielectric layer and a second dielectric layer formed over a substrate having a first contact region and a second contact region exposed therein. The capacitor is also connected to a first conductor stud that penetrates the first dielectric layer and contacts the first contact region and a second conductor stud that penetrates the second dielectric layer. A contiguous conductor interconnect and conductor stud layer is formed within a dual damascene aperture through the second dielectric layer and the first dielectric layer and contacting the second contact region. An etch stop layer employed when forming a trench within the dual damascene aperture also passivates a capacitor sidewall.

Abstract: To provide a dielectric thin with a high dielectric constant, a low leakage current, and stable physical properties and electrical properties and to provide a thin film capacitor or other thin film dielectric device with a high capacitance and high reliability and a method of production of the same, a dielectric thin film containing oxides such as barium strontium titanate expressed by the formula (BaxSr(1-x))aTiO3 (0.5<x?1.0, 0.96<a?1.00) and having a thickness of not more than 500 nm and a method of production of a thin film dielectric device including a step of annealing the dielectric thin film in an atmosphere of an oxidizing gas after forming a dielectric thin film on a conductive electrode.

Abstract: Stacked gate structures for a NAND string are created on a substrate. Source implantations are performed at a first implantation angle to areas between the stacked gate structures. Drain implantations are performed at a second implantation angle to areas between the stacked gate structures. The drain implantations create lower doped regions of a first conductivity type in the substrate on drain sides of the stacked gate structures. The source implantations create higher doped regions of the first conductivity type in the substrate on source sides of the stacked gate structures.

Abstract: A nonvolatile memory device includes first and second impurity diffusion regions formed in a semiconductor substrate, and a memory cell formed on a channel region of a semiconductor substrate between the first and second impurity diffusion regions. The memory cell includes a stacked gate structure formed on the channel region, and first and second select gates formed on the channel regions and opposite sidewalls of the stacked gate structure. Since the first and second select gates are spacer-shaped to be self-aligned on opposite sidewalls of the stacked gate structure, a size of a memory cell is reduced to enhance an integration density of a semiconductor device.

Abstract: A semiconductor memory includes memory cell transistors comprising a tunnel insulating film, a floating gate electrode, a first insulating film, a control gate electrode, and a first metal salicide film; low-voltage transistors comprising a first p-type source region and a first p-type drain region, a first gate insulating film, and a first gate electrode of an n conductivity type having the same dose of a first p-type impurity as with the first p-type source region; and high-voltage transistors comprising a second p-type source region and a second p-type drain region, a second gate insulating film thicker than the first gate insulating film, and a second gate electrode of an n conductivity type having the same dose of a second p-type impurity as with the second p-type source region.

Abstract: Disclosed is a power semiconductor device, including a first semiconductor layer of a first conductivity type, a second semiconductor layer of the first conductivity type and a third semiconductor layer of a second conductivity type which are alternately and laterally arranged on the first semiconductor layer and, a fourth semiconductor layer of the second conductivity type selectively formed in the surface regions of the second and third semiconductor layers, a fifth semiconductor layer of the first conductivity type selectively formed in the surface region of the fourth semiconductor layer, and a control electrode formed on the surfaces of the second, fourth and fifth semiconductor layers, in which a layer thickness ratio A is given by the expression: 0<A=t/(t+d)?0.72 where t is the thickness of the first semiconductor layer, and d is the thickness of the second semiconductor layer.

Abstract: A semiconductor device comprises a drain, a body in contact with the drain, the body having a body top surface, a source embedded in the body, extending downward from the body top surface into the body, a trench extending through the source and the body to the drain, and a gate disposed in the trench, having a gate top surface that extends substantially above the body top surface. A method of fabricating a semiconductor device comprises forming a hard mask on a substrate having a top substrate surface, forming a trench in the substrate, through the hard mask, depositing gate material in the trench, where the amount of gate material deposited in the trench extends beyond the top substrate surface, and removing the hard mask to leave a gate structure that extends substantially above the top substrate surface.

Abstract: A high voltage MOS transistor is provided that is compatible with low-voltage, sub-micron CMOS and BiCMOS processes. The high voltage transistor of the present invention has dopants that are implanted into the substrate prior to formation of the epitaxial layer. The implanted dopants diffuse into the epitaxial layer from the substrate during the formation of the epitaxial layer and subsequent heating steps. The implanted dopants increase the doping concentration in a lower portion of the epitaxial layer. The implanted dopants may diffuse father into the epitaxial layer than dopants in the buried layer forming an up-retro well that prevents vertical punch-through at high operating voltages for thin epitaxial layers. In addition, the doping concentration below the gate may be light so that the threshold voltage of the transistor is low.

Abstract: An MOS device includes a semiconductor layer of a first conductivity type and first and second source/drain regions of a second conductivity type formed in the semiconductor layer proximate an upper surface of the semiconductor layer. The first and second source/drain regions are spaced apart relative to one another. A gate is formed above and electrically isolated from the semiconductor layer, at least partially between the first and second source/drain regions. At least a given one of the first and second source/drain regions is configured having an effective width that is substantially greater than a width of a junction between the semiconductor layer and the given source/drain region.

Abstract: A semiconductor device which is compact and thin in size, low in resistance of a current path and parasitic inductance and excellent in reliability is provided. This semiconductor device comprises a semiconductor substrate, a first main electrode which is formed on a front surface of the semiconductor substrate, a second main electrode which is formed on a rear surface of the semiconductor substrate, and a conducting portion which is formed in a direction to pierce through the semiconductor substrate, wherein the second main electrode is extracted to the front surface of the semiconductor substrate via the conducting portion. And, the conducting portion is a through via which has a through hole formed through the semiconductor substrate in its thickness direction and a conductive portion which is formed in the through hole and connected to the second main electrode.

Abstract: A memory element comprises a first number of electrodes and a second number of electrically conducting channels between sub-groups of two of said electrodes, the channels exhibiting an electrical resistance that is reversibly switchable between different states, wherein the first number is larger than two and the second number is larger than the first number divided by two. The electrically conducting channels may be provided in transition metal oxide material, which exhibits a reversibly switchable resistance that is attributed to a switching phenomenon at the interfaces between the electrodes and the transition metal oxide material.

Abstract: A semiconductor device 100 includes an LDMOS transistor which includes: a P-type silicon substrate 102; a gate electrode 120 formed on the P-type silicon substrate 102; a drain (a second N-type diffusion area 109) formed apart from the gate electrode 120 in the horizontal direction; a drain electrode 130 formed on the drain (the second N-type diffusion area 109); an insulating film (a field oxide film 106) which is provided between the gate electrode 120 and the drain electrode 130, and has a film thickness thicker than that of a gate insulating film 112; and an electric field control electrode 118 formed along the drain electrode 130 on the insulating film.

Abstract: A bonded SOI wafer and a method for forming a bonded SOI wafer are provided. According to the disclosed method, a first semiconductor wafer is provided, having a first dielectric layer disposed at an outer surface of the first wafer and a plurality of dielectric filled trenches extending from the outer surface inwardly into the semiconductor. The outer surface of the first wafer is bonded to the outer surface of a second semiconductor wafer to form a bonded wafer having a bulk semiconductor region, a buried dielectric layer overlying the bulk semiconductor region, and a semiconductor-on-insulator layer overlying the buried dielectric layer, with the dielectric filled trenches extending upwardly from the buried dielectric layer into the semiconductor-on-insulator layer. The thickness of the semiconductor-on-insulator layer is then reduced until uppermost surfaces of at least some of the dielectric filled trenches are at least partially exposed.

Abstract: A semiconductor device comprising a semiconductor body having a top surface and a first and second laterally opposite sidewalls as formed on an insulating substrate is claimed. A gate dielectric is formed on the top surface of the semiconductor body and on the first and second laterally opposite sidewalls of the semiconductor body. A gate electrode is then formed on the gate dielectric on the top surface of the semiconductor body and adjacent to the gate dielectric on the first and second laterally opposite sidewalls of the semiconductor body. The gate electrode comprises a metal film formed directly adjacent to the gate dielectric layer. A pair of source and drain regions are then formed in the semiconductor body on opposite sides of the gate electrode.

Abstract: One embodiment of the invention relates to a field effect trench transistor with a multiplicity of transistor cells that are arranged like an array and whose gate electrodes are arranged in active trenches formed in a semiconductor body. Inactive trenches are arranged in the array of the transistor cells, there being no gate electrodes situated in said inactive trenches, and a series of polysilicon diodes are integrated in one or more of the inactive trenches which diodes, for protection against damage to the gate oxide through ESD pulses, are contact-connected to a source metallization at one of their ends and to a gate metallization at their other end, and/or alternatively or additionally one or more polysilicon zener diodes connected in series is or are integrated in the inactive trench or trenches and contact-connected to the gate metallization by one of its or their ends and to drain potential by its or their other end.

Abstract: A breakdown protection circuit for a source follower comprising a field effect transistor (FEI). The protection circuit comprises a plurality of PFET's and NFET's that are controlled to exhibit on and off states for advantageously configuring a gate, source, drain and body of the source follower FET, to avoid breakdown of and forward biasing of certain FET junctions.

Abstract: The semiconductor device comprises a well 58 formed in a semiconductor substrate 10 and having a channel region; a gate electrode 34n formed over the channel region with an insulating film 32 interposed therebetween; source/drain regions 60 formed in the well 58 on both sides of the gate electrode 34n, sandwiching the channel region; and a pocket region 40 formed between the source/drain region and the channel region. The well 58 has a first peak of an impurity concentration at a depth deeper than the pocket region 40 and shallower than the bottom of the source/drain regions 60, and a second peak of the impurity concentration at a depth near the bottom of the source/drain regions 60.

Abstract: A semiconductor device includes a semiconductor substrate that has an oxide film selectively formed on a part thereof; a semiconductor layer that is formed on the oxide film by epitaxial growth; a first gate electrode that is formed on the semiconductor layer; first source/drain layers that are formed on the semiconductor layer so as to be disposed at both sides of the first gate electrode, respectively; a second gate electrode that is formed on the semiconductor substrate; and second source/drain layers that are formed on the semiconductor substrate so as to be disposed at both sides of the second gate electrode, respectively.

Abstract: The invention relates to a semiconductor diode, an electronic component and to a voltage source converter. According to the invention, the semiconductor diode having at least one pn-transition can be switched between a first state and a second state. In comparison to the first state, the second state has a greater on-state resistance and a smaller accumulated charge, and the pn-transition is capable of blocking both in the first state as well as in the second state with at least one predetermined blocking ability. An MOS-controlled diode is hereby obtained in which the transition from the on-state to the blocking state is simplified and is thus not critical with regard to the temporal sequence of the control pulses.

Abstract: A semiconductor structure, fluid ejection device, and methods for manufacturing the same are provided, such that a contact to a substrate is formed from a conductive layer.

Abstract: A structure of a MIS transistor for realizing a CMOS circuit capable of simultaneously achieving the high ON current and the low power consumption is provided. Each of the gate insulators of a n channel MIS transistor and a p channel MIS transistor is composed of a hafnium oxide film. Also, the gate electrode is composed of a Pt silicide film with a ratio of Si atoms to Pt atoms of approximately 1 (PtSix: x=1) in the vicinity of a region in contact with the gate insulator. Also, the gate electrode of the p channel MIS transistor is composed of a Pt silicide film with a ratio of Si atoms to Pt atoms of less than 1 (PtSix: x<1) in the vicinity of a region in contact with the gate insulator. Therefore, the Fermi level pinning of the gate electrode is suppressed.

Abstract: A method of forming an oxide region in a semiconductor device includes the steps of forming a plurality of trenches in a semiconductor layer of the device, the trenches being formed in close relative proximity to one another, and oxidizing the semiconductor layer such that an insulating layer is formed on at least sidewalls and bottom walls of the trenches. The trenches are configured such that the insulating layer formed as a result of the oxidizing step substantially fills the trenches and substantially consumes the semiconductor layer between corresponding pairs of adjacent trenches. In this manner, a substantially continuous oxide region is formed throughout the plurality of trenches.

Abstract: A semiconductor device includes a first insulation film, a second insulation film, a thin film resistor interposed between the insulation films. A predetermined voltage is applied to the thin film resistor so that a current flows through the thin film resistor. When a crack occurs in the insulation films, the thin film resistor is partially destroyed and the resistance of the thin film resistor changes. The crack is detected by measuring the change in resistance of the thin film resistor based on the predetermined voltage and the current flowing through the thin film resistor. Therefore, a crack inspection can be conducted without destruction of the device.

Abstract: In a metal gate replacement process, strain may be selectively induced in the channels of NMOS and PMOS transistors. For example, a material having a higher coefficient of thermal expansion than the substrate may be used to form the gate electrodes of PMOS transistors. A material with a lower coefficient of thermal expansion than that of the substrate may be used to form the gate electrodes of NMOS transistors.

Abstract: A MEMS system, such as a biosensor, includes a micromechanical resonator and a piezoresistive sensing element which includes an organic semiconductor, such as an organic thin film transistor.

Abstract: In a spin valve type element, an interface insertion layer (32, 34) of a material exhibiting large spin-dependent interface scattering is inserted in a location of a magnetically pinned layer (16) or a magnetically free layer (20) closer to a nonmagnetic intermediate layer (18). A nonmagnetic back layer (36) may be additionally inserted as an interface not in contact with the nonmagnetic intermediate layer to increase the output by making use of spin-dependent interface scattering along the interface between the pinned layer and the nonmagnetic back layer or between the free layer and the nonmagnetic back layer.

Abstract: A sensor having a light detector with a small gap between the cathode and anode to enable a high pressure cavity resulting in a long lifetime of the detector due to insignificant sputtering from the cathode and subsequent minimal burying of the noble gas in the cavity. The detector may be made with MEMS technology and its techniques. The sensor may contain an array of light detectors. Some of the detectors may be UV detectors.

Abstract: On a leadframe on which to fix a photodetector element, an element mount frame and a fitting frame are laid with a gap left in between. A shielding frame for electromagnetically shielding the photodetector element is tied, via a tying portion, not to the element mount frame but to the fitting frame. Bending the tying portion brings it into a state in which it covers the photodetector element, but the stress resulting from this bending of the tying portion is shut off by the gap so as not to spread to the element mount frame. On the element mount frame, a circuit element for processing the signal from the photodetector element also is fixed.

Abstract: A photogate structure having increased quantum efficiency, especially for low wavelength light such as blue light. The photogate is formed of a thin conductive layer, such as a layer of doped polysilicon. A nitride insulating cap is formed over the conductive layer. The nitride layer reduces the reflections at the conductor/insulator interface. A pixel cell incorporating the photogate structure also has a buried accumulation region beneath the photogate. A method of fabricating the photogate structure is also disclosed.

Abstract: A semiconductor device includes a semiconductor substrate, and a MOS transistor provided on the semiconductor substrate and having a channel type of a first conductivity, the MOS transistor comprising a semiconductor region of the first conductivity type including first and second channel regions, gate insulating films provided on the first and second channel regions, a gate electrode provided on the gate insulating films, and first and second source/drain regions which are located at a distance from each other so as to sandwich the first and second channel regions, the first and second source/drain regions contacting the semiconductor region of the first conductivity type and forming a Schottky junction.

Abstract: Schottky barrier diodes use a dielectric separation region to bound an active region. The dielectric separation region permits the elimination of a guard ring in at least one dimension. Further, using a dielectric separation region in an active portion of the integrated circuit device may reduce or eliminate parasitic capacitance by eliminating this guard ring.

Abstract: An element isolating region for separating an element region of a semiconductor layer is formed in a peripheral circuit section of a semiconductor memory device, and a first conductive layer is formed with the element region with a first insulating film interposed therebetween. A second conductive layer is formed on the first conductive layer to extend into the element isolating region. A surface of that section of the second conductive layer which is positioned within the element isolating region is exposed, and a third conductive layer is formed on the second conductive layer with a second insulating film interposed therebetween. Further, a contact is electrically connected to an exposed surface of the second conductive layer.

Abstract: A semiconductor device has a channel termination region for using a trench (30) filled with field oxide (32) and a channel stopper ring (18) which extends from the first major surface (8) through p-well (6) along the outer edge (36) of the trench (30), under the trench and extends passed the inner edge (34) of the trench. This asymmetric channel stopper ring provides an effective termination to the channel (10) which can extend as far as the trench (30).

Abstract: A high power FET switch comprises an N? drift layer, in which pairs of trenches are recessed to a predetermined depth; oxide side-walls extend to the trench bottoms, and each trench is filled with a conductive material. N+ and metal layers on opposite sides of the drift layer provide drain and source connections for the FET, and the conductive material in each trench is connected together to provide a gate connection. A shallow P region extends across the bottom and around the corners of each trench's side-walls into the drift layer. The application of a sufficient gate voltage causes holes to be injected from the shallow P regions into the N? drift layer, thereby modulating the drift layer's conductivity and lowering the device's on-resistance, and enabling current to flow between the drain and source connections.

Abstract: An input matching parallel inductor 114 which utilizes a spiral inductor, and an input matching parallel capacitor 115 which utilizes an MIM capacitor, both being constituting elements of an input matching circuit portion 125, form an input matching parallel capacitor 115 inside an input matching circuit via-hole 121 being formed by applying a method of surface via-hole to the front surface of a GaAs substrate 124. A choke inductor 119 which utilizes a spiral inductor, and a bypass capacitor 120 which utilizes an MIM capacitor, both being constituting elements of a drain voltage feeding circuit 107, form a bypass capacitor 120 inside a drain voltage feeding circuit via-hole 123 formed by applying a method of surface via-hole to the front surface of the GaAs substrate 124. A drain voltage terminal 136 is extended by a drawing wire 135 from between the spiral inductor and the drain voltage feeding circuit via-hole 123.

Abstract: Device with integrated capacitance structure The present invention relates to a device with integrated capacitance structure has at least one first and an adjacent second rewiring plane, each of which comprises at least one first partial structure and a second partial structure, which is different from the first partial structure, the second partial structure in each case substantially surrounding the first partial structure, and the first partial structure of the first rewiring plane being electrically connected to the second partial structure of the second rewiring plane and the second partial structure of the first rewiring plane being electrically connected to the first partial structure of the second rewiring plane and forming different poles of the capacitance structure.

Abstract: A memory element may be formed from a polysilicon PN junction. In one state, the junction exhibits the characteristics of a diode. After exposure to a reverse bias breakdown voltage, the junction may exhibit the characteristics of a resistor. Thus, two different states may be detected by determining the characteristics of the diode. In addition, the diode may be erased by exposing the device with the resistor characteristics to still higher reverse bias conditions creating an open circuit. Because of the grain boundary conditions in the polysilicon PN junction, the breakdown of the junction is permanent.

Abstract: An independent access, double-gate transistor and tri-gate transistor fabricated in the same process flow is described. An insulative plug is removed from above the semiconductor body of the I-gate device, but not the tri-gate device. This allows, for instance, metalization to form on three sides of the tri-gate device, and allowing independent gates for the I-gate device.

Abstract: Numerous embodiments of an apparatus and method of a dielectric material having a low dielectric constant and good mechanical strength are described. In one embodiment a dielectric material having multiple porous regions is disposed over a substrate. A caged structure is bridged within the plurality of pores. In one particular embodiment, the caged structure may be carborane or a carborane derivative.

Abstract: A light absorption layer for use in fabricating semiconductor devices is provided with a high Si concentration. For example, a semiconductor device comprises a substrate and an Si-rich dielectric light absorption layer, such as an SiON or SiOX layer having an Si concentration of at least 68%. A second dielectric antireflective coating layer is optionally formed over the Si-rich dielectric light absorption layer.

Abstract: Fluid injection devices and fabrication methods thereof. A first structural layer is disposed on a substrate. A fluid chamber is disposed between the substrate and the first structural layer. At least one bubble generator is disposed on the first structural layer and on the opposite side of the fluid chamber. A first passivation layer is disposed on the first structural layer covering the bubble generator. A second structural layer is disposed on the passivation layer. A second passivation layer is conformably deposited on the second passivation layer. A nozzle adjacent to the bubble generator passes through the second passivation layer, the second structural layer, the first passivation layer, and the first structural layer communicating the fluid chamber, wherein the sidewall of the nozzle is made of the first structural, the first passivation layer and the second passivation layer.

Abstract: Embodiments of the present invention are directed to a film substrate of a semiconductor package. The film substrate of the semiconductor package comprises a thin film insulating substrate and a thin copper circuit pattern. An inter-pattern groove between the thin copper circuit patterns is formed by laser etching. Accordingly, the embodiment improves electrical contact between the film substrate and a semiconductor chip mounted thereon, and improves the manufacturing process for the film substrate by adopting a simple laser machining to form the thin copper circuit pattern in lieu of a traditional wet-etching process that undergoes complex lithography steps.

Abstract: A structure, apparatus and method for a FET prime cell surrounded by a conductor is provided. The surrounding conductor includes a substrate contact arranged proximate a source of the FET. The surrounding conductor may be a ring substrate contact arranged within the substrate of the FET in electrical communication with elongated sources of the FET. No external contacts are needed to the ring substrate contact because no current flows therethrough while the ring substrate contact may act as a collection source for noise such as stray currents.

Abstract: An electrical package structure incorporating a chip with polymer thereon is described, including at least a package, a polymer and a molding compound. The package includes a carrier, at least one chip and multiple wires, wherein the chip is disposed on the carrier and the wires electrically connect the chip and the carrier. The polymer is disposed at the periphery of the chip possibly extending to the sidewalls of the chip and covering a portion of each wire near the chip, and the chip, the wires and the polymer are all enclosed in the molding compound. The polymer is preferably a stress buffer polymer like epoxy resin or polyimide, capable of inhibiting stress concentration at the periphery of the chip when the chip is subjected to repeated heat cycles for a long time. Therefore, the reliability of the electrical package structure can be improved.

Abstract: Active device bases, leadframes utilizing the same, and leadframe fabrication methods. The base includes a plate, a predetermined attachment area for an active device on a surface of the plate, and a recess in the predetermined attachment area, which substantially does not penetrate the plate.

Abstract: A lead frame is produced using a thin metal plate to form a stage for mounting a semiconductor chip, a plurality of leads encompassing the stage, and a frame portion for fixing the stage and leads together. Surfaces of the internal ends of the leads are each expanded in a longitudinal direction and/or a width direction so as to form expanded portions; cutouts are formed in the internal ends of the leads; or the internal ends of the leads are extended outwardly so as to form extended portions. A sealing resin is molded to incorporate the lead frame so as to produce a semiconductor package. Hence, it is possible to increase the overall contact area between the leads and the sealing resin; it is possible to increase the adhesion between the leads and the sealing resin; thus, it is possible to improve the reliability of the semiconductor package in manufacturing.

Abstract: An apparatus of antenna with heat slug and its fabricating process are provided, in which the antenna with heat slug can be realized with a single sheet or double sheets of metal. A dual-band antenna module with a mask cover is taken as an example to realize the apparatus. Each single sheet of metal can be achieved by simply cutting and bending a metal plate. Thereby, it is a simple and low-cost fabricating process. In the known fabricating process of integrated circuit, the heat slug and the antenna can be combined in a module at the same step. Therefore, integrating the antenna with heat slug in a fabricating process needs not to develop a new process.

Abstract: The present invention provides inhibiting an electrical leakage caused by anion migration. A trenched portion 15 is provided as ion migration-preventing zone between a source electrode 4 and a gate electrode 5. The trenched portion 15 is formed so as to surround a periphery of the source electrode 4.

Abstract: Provided are a semiconductor lead frame, a semiconductor package having the semiconductor lead frame, and a method of plating the semiconductor lead frame. The method includes preparing a substrate formed of a Fe—Ni alloy (alloy 42), and a plating layer that contains grains less than 1 micrometer in size and is plated on the substrate. The growth of whiskers when a Sn plated layer is formed on a substrate formed of a Fe—Ni alloy (alloy 42) can be suppressed by minimizing the grain size of the Sn plated layer.