Abstract: A semiconductor structure and method wherein a recess is disposed in a surface portion of a semiconductor structure and a dielectric film is disposed on and in contract with the semiconductor. The dielectric film has an aperture therein. Portions of the dielectric film are disposed adjacent to the aperture and overhang underlying portions of the recess. An electric contact has first portions thereof disposed on said adjacent portions of the dielectric film, second portions disposed on said underlying portions of the recess, with portions of the dielectric film being disposed between said first portion of the electric contact and the second portions of the electric contact, and third portions of the electric contact being disposed on and in contact with a bottom portion of the recess in the semiconductor structure. The electric contact is formed by atomic layer deposition of an electrically conductive material over the dielectric film and through the aperture in such dielectric film.

Abstract: A manufacturing method of a semiconductor device of the present invention includes the steps of forming a stacked body in which a semiconductor film, a gate insulating film, and a first conductive film are sequentially stacked over a substrate; selectively removing the stacked body to form a plurality of island-shaped stacked bodies; forming an insulating film to cover the plurality of island-shaped stacked bodies; removing a part of the insulating film to expose a surface of the first conductive film, such that a surface of the first conductive film almost coextensive with a height of the insulating film; forming a second conductive film over the first conductive film and a left part of the insulating film; forming a resist over the second conductive film; selectively removing the first conductive film and the second conductive film using the resist as a mask.

Abstract: A method of forming a portion (10) of a compound semiconductor MOSFET structure comprises forming a compound semiconductor layer structure (14) and an oxide layer (20) overlying the same. Forming the compound semiconductor structure (14) includes forming at least one channel material (16) and a group-III rich surface termination layer (18) overlying the at least one channel material. Forming the oxide layer (20) includes forming the oxide layer to overlie the group-III rich surface termination layer and comprises one of (a) depositing essentially congruently evaporating oxide of at least one of (a(i)) a ternary oxide and (a(ii)) an oxide more complex than a ternary oxide and (b) depositing oxide molecules, with use of at least one of (b(i)) a ternary oxide and (b(ii)) an oxide more complex than a ternary oxide.

Abstract: Disclosed are a CMOS image sensor and a method for manufacturing the same. The CMOS image sensor includes a photodiode area and a floating diffusion area formed on a semiconductor substrate, a transistor formed on the semiconductor substrate between the photodiode area and the floating diffusion area, an isolation layer formed below the transistor, and a channel area formed between the transistor and the isolation layer.

Abstract: A CMOS image sensor includes a photodiode, and a plurality of transistors for transferring charges accumulated at the photodiode to one column line, wherein at least one transistor among the plurality of transistors has a source region wider than a drain region, for increasing a driving current.

Abstract: A semiconductor device has an electrode pad, a capacitor and a substrate. The substrate has a given area on which the electrode pad and the capacitor are arranged. The electrode pad and the capacitor are arranged on the substrate so that each of at least two sides of the capacitor and each of at least two sides of the electrode pad is adjacent to each other at a given interval. The capacitor has a connecting side that connects the two sides of the capacitor and faces to the electrode pad. Outside angles of the capacitor formed by the connecting side and the two sides of the capacitor are more than 90 degrees.

Abstract: A memory element for a magnetic RAM, having a first magnetic portion in a first recess of a first insulating layer; and a non-magnetic portion and a second magnetic portion in a second recess of a second insulating layer covering the first insulating layer, the second recess exposing the first magnetic portion and a portion of the first insulating layer around the first magnetic portion, the non-magnetic portion being interposed between the first and second magnetic portions.

Abstract: In a magnetic memory 1, a magneto-resistivity effect element 4 is disposed adjacently to a wire 5 for producing a writing magnetic field and further a ferromagnetic body 20 is disposed so as to cover at least part of the wire 5 and consequently orient the state X of magnetization of this ferromagnetic body 20 in one direction. According to this invention, it is made possible to homogenize the magnetic property during the course of writing and implement the writing work efficiently.

Abstract: Disclosed herein is an improved memory device wherein the area occupied by a conventional landing pad is significantly reduced to around 50% to 10% of the area occupied by conventional landing pads. This is accomplished by removing the landing pad from the cell structure, and instead forming a conductive via structure that provides the electrical connection from the memory stack or device in the structure to an under-metal layer. By forming only this via structure, rather than separate vias formed on either side of a landing pad, the overall width occupied by the connective via structure from the memory stack to an under-metal layer is substantially reduced, and thus the via structure and under-metal layer may be formed closer to the memory stack (or conductors associated with the stack) so as to reduce the overall width of the cell structure.

Abstract: A method of fabricating a semiconductor device includes forming a mask pattern over a semiconductor substrate to define a channel region. A portion of the semiconductor substrate is etched using the mask pattern as an etching mask to form a first pillar. A spacer is formed over a sidewall of the mask pattern and the first pillar. A portion of the semiconductor substrate exposed between the first pillars is etched using the spacer and the mask pattern as an etching mask to form a second pillar elongated from the first pillar. A portion of the second pillar is selectively etched to form a third pillar. The spacer and the mask pattern are removed. An impurity is implanted into an upper part of the first pillar and the semiconductor substrate between the third pillars to form a source/drain region. A surrounding gate is formed over an outside of the third pillar.

Abstract: A nonvolatile semiconductor memory device which is superior in writing and charge holding properties, including a semiconductor substrate in which a channel formation region is formed between a pair of impurity regions formed with an interval, and a first insulating layer, a floating gate, a second insulating layer, and a control gate over an upper layer portion of the semiconductor substrate. It is preferable that a band gap of a semiconductor material forming the floating gate be smaller than that of the semiconductor substrate. For example, it is preferable that the band gap of the semiconductor material forming the floating gate be smaller than that of the channel formation region in the semiconductor substrate by 0.1 eV or more. This is because, by decreasing the bottom energy level of a conduction band of the floating gate electrode to be lower than that of the channel formation region in the semiconductor substrate, carrier injecting and charge holding properties are improved.

Abstract: A technology capable of improving a charge retention characteristic of a nonvolatile memory is provided. In a memory cell in which an interlayer insulating film formed of an ONO film obtained by laminating a lower silicon oxide film, a silicon nitride film, and an upper silicon oxide film is formed between a floating gate formed of a polycrystalline silicon film and a control gate formed of a polycrystalline silicon film, the upper silicon oxide film is formed through LPCVD and is then nitrided through a remote plasma process, thereby introducing nitrogen of, for example, 5 to 6 atom % into the upper surface portion of the upper silicon oxide film.

Abstract: A semiconductor device, which ensures device reliability especially in fine regions and enables great capacitance and high-speed operations, has memory cells including, in a first region of a main surface of a semiconductor substrate, a gate insulating film, a floating gate electrode, an interlayer insulating film, a control gate electrode, and source and drain regions of the second conduction type arranged in a matrix, with a shallow isolation structure for isolating the memory cells. When using a shallow structure buried with an insulating film for element isolation, the isolation withstand voltage in fine regions can be prevented from lowering and the variation in threshold level of selective transistors can be reduced. When the memory cells in a memory mat are divided by means of selective transistors, the disturb resistance of the memory cells can be improved.

Abstract: A nonvolatile semiconductor memory device includes a plurality of floating gate electrodes respectively formed above a semiconductor substrate with first insulating films disposed therebetween, and a control gate electrode formed above the plurality of floating gate electrodes with a second insulating film disposed therebetween. In each of the plurality of floating gate electrodes is formed to have a width of an upper portion thereof in a channel width direction which is smaller than a width of a lower portion thereof in the channel width direction and one of contact surfaces thereof on at least opposed sides which contact the second insulating film is formed to have one surface, and the second insulating film has a maximum film thickness in a vertical direction, the maximum film thickness being set smaller than a distance from a lowest surface to a highest surface of the second insulating film in the vertical direction.

Abstract: A multiple dual bit integrated circuit system is provided that includes forming first address lines in a semiconductor substrate and forming a charge-trapping layer over the semiconductor substrate. A semiconductor layer is formed over the charge-trapping layer and second address lines are formed in the semiconductor layer to form a plurality of dual bit locations.

Abstract: Provided is a highly reliable multi-bit memory cell capable of miniaturization including: a semiconductor substrate with a channel formed therein; diffusion layers arranged at two sides of the channel, for serving as source/drain; an insulating film arranged on a part of the channel; a trap film made of an insulating material having an electron trapping characteristic, arranged on the semiconductor substrate, the diffusion layers and the insulating film, and including trap regions each capable of trapping electrons in at least areas in contact with the semiconductor substrate at two sides of the insulating film; and a gate electrode arranged on the trap film. The trap regions are also formed on side surfaces of the insulating film, and the trap film has a structure in which the trap film is bent upward from the surface of the semiconductor substrate in the trap regions due to the insulating film.

Abstract: The present invention is an object to provide a high-performance vertical field effect transistor having a microminiaturized structure in which the distance between the gate and the channel is made short not through a microfabrication process, having a large gate capacitance, and so elaborated that the gate can control the channel current with a low voltage, and a method for simply and efficiently manufacturing such a field effect transistor not through a complex process such as a microfabrication process.

Abstract: A MIS-type semiconductor device has reduced ON-resistance by securing an overlapping area between the gate electrode and the drift region, and has low switching losses by reducing the feedback capacitance. The MIS-type semiconductor device includes a p-type base region, an n-type drift region, a p+-type stopper region in the base region, a gate insulation film on the base region, a gate electrode on the gate insulation film, an oxide film on the drift region, a field plate on the oxide film, and a source electrode. The position (P) of the impurity concentration peak in base region is located more closely to the drift region. The oxide film is thinner on the side of the gate electrode. The field plate is connected electrically to the source electrode, the spacing (dg) between the gate insulation film and the stopper region is 2.5 ?m or narrower, and the minimum spacing (x) between the drain region and the stopper region is 5.6 ?m or narrower.

Abstract: Channel regions and gate electrodes are also disposed continuously with transistor cells below a gate pad electrode. The transistor cells are formed in a stripe pattern and allowed to contact a source electrode. In this way, the channel regions and the gate electrodes, which are positioned below the gate pad electrode, are kept at a predetermined potential. Thus, a predetermined drain-source reverse breakdown voltage can be secured without providing a p+ type impurity region on the entire surface below the gate pad electrode.

Abstract: A semiconductor device includes a semiconductor substrate and a super junction structure on the substrate. The super junction structure is constructed with p-type and n-type column regions that are alternately arranged. A p-type channel layer is formed to a surface of the super junction structure. A trench gate structure is formed to the n-type column region. An n+-type source region is formed to a surface of the channel layer near the trench structure. A p+-type region is formed to the surface of the channel layer between adjacent n+-type source regions. A p-type body region is formed in the channel layer between adjacent trench gate structures and in contact with the p+-type region. Avalanche current is caused to flow from the body region to a source electrode via the p+-type region without passing through the n+-type source region.

Abstract: A low resistance layer is formed on a semiconductor substrate, and a high resistance layer formed on the low resistance layer. A source region of a first conductivity type is formed on a surface region of the high resistance layer. A drain region of the first conductivity type is formed at a distance from the source region. A first resurf region of the first conductivity type is formed in a surface region of the high resistance layer between the source region and the drain region. A channel region of a second conductivity type is formed between the source region and the first resurf region. A gate insulating film is formed on the channel region, and a gate electrode formed on the gate insulating film. An impurity concentration in the channel region under the gate electrode gradually lowers from the source region toward the first resurf region.

Abstract: The present invention aims at offering the semiconductor device which has the structure which are a high speed and a low power, and can be integrated highly. The present invention is a semiconductor device formed in the SOI substrate by which the BOX layer and the SOI layer were laminated on the silicon substrate. And the present invention is provided with the FIN type transistor with which the gate electrode coiled around the body region formed in the SOI layer, and the planar type transistor which was separated using partial isolation and full isolation together to element isolation, and was formed in the SOI layer.

Abstract: An electronically scannable multiplexing device is capable of addressing multiple bits within a volatile or non-volatile memory cell. The multiplexing device generates an electronically scannable conducting channel with two oppositely formed depletion regions. The depletion width of each depletion region is controlled by a voltage applied to a respective control gate at each end of the multiplexing device. The present multi-bit addressing technique allows, for example, 10 to 100 bits of data to be accessed or addressed at a single node. The present invention can also be used to build a programmable nanoscale logic array or for randomly accessing a nanoscale sensor array.

Abstract: In a thin film transistor and a flat panel display device having the same, cross-talk is minimized. The flat panel display device includes a substrate, a first thin film transistor, a second thin film transistor, and a display element. The first thin film transistor includes: a first gate electrode formed on the substrate; a first electrode insulated from the first gate electrode; a second electrode insulated from the first gate electrode and surrounding the first electrode in the same plane; and a first semiconductor layer insulated from the first gate electrode and contacting the first electrode and the second electrode.

Abstract: The present invention provides a FinFET transistor arrangement produced using a method with the steps: providing a substrate (106, 108); forming an active region (1) on the substrate a fin-like channel region (113b?; 113b?). Formation of the fin-like channel region (113b?; 113b?) has the following steps: forming a hard mask (S1-S4) on the active region (1); anisotropic etching of the active region (1) using the hard mask (S1-S4) forming STI trenches (G1-G5) having an STI oxide filling (9); polishing-back of the STI oxide filling (9); etching-back of the polished-back STI oxide filling (9); selective removal of components of the hard mask forming a modified hard mask (S1?-S4?); anisotropic etching of the active region (1) using the modified hard mask (S1?-S4?) forming widened STI trenches (G1?-G5?), the fin-like channel regions (113b?; 113b?) of the active region (1) remaining for each individual FinFET transistor.

Abstract: An integrated receiver with channel selection and image rejection substantially implemented on a single CMOS integrated circuit is described. A receiver front end provides programmable attenuation and a programmable gain low noise amplifier. Frequency conversion circuitry advantageously uses LC filters integrated onto the substrate in conjunction with image reject mixers to provide sufficient image frequency rejection. Filter tuning and inductor Q compensation over temperature are performed on chip. The filters utilize multi track spiral inductors. The filters are tuned using local oscillators to tune a substitute filter, and frequency scaling during filter component values to those of the filter being tuned. In conjunction with filtering, frequency planning provides additional image rejection. The advantageous choice of local oscillator signal generation methods on chip is by PLL out of band local oscillation and by direct synthesis for in band local oscillator.

Abstract: A semiconductor device comprising a substrate having a well region, at least one well pickup region formed on the substrate to surround the well pickup region, a first drain region formed on the substrate to be positioned on one side of the source region, and a first gate electrode formed on the substrate to be positioned between the source region and the first drain region.

Abstract: Carbon nanotubes may be selectively opened and their exposed ends functionalized. Opposite ends of carbon nanotubes may be functionalized in different fashions to facilitate self-assembly and other applications.

Abstract: Methods of forming a semiconductor structure having FinFET's and planar devices, such as MOSFET's, on a common substrate by a damascene approach, and semiconductor structures formed by the methods. A semiconductor fin of the FinFET is formed on a substrate with damascene processing in which the fin growth may be interrupted to implant ions that are subsequently transformed into a region that electrically isolates the fin from the substrate. The isolation region is self-aligned with the fin because the mask used to form the damascene-body fin also serves as an implantation mask for the implanted ions. The fin may be supported by the patterned layer during processing that forms the FinFET and, more specifically, the gate of the FinFET. The electrical isolation surrounding the FinFET may also be supplied by a self-aligned process that recesses the substrate about the FinFET and at least partially fills the recess with a dielectric material.

Abstract: Disclosed herein is a transistor for a semiconductor device and a method of forming the same. According to the present invention, a novel transistor structure combining a plane channel transistor and a fin-type channel transistor formed on the semiconductor substrate is provided to secure a sufficient channel width as compared to that of the plane channel transistor, thereby satisfying drive current regulated for the transistor.

Abstract: A semiconductor integrated circuit device includes a cell well, a memory cell array formed on the cell well and having a memory cell area and cell well contact area, first wiring bodies arranged in the memory cell area, and second wiring bodies arranged in the cell well contact area. The layout pattern of the second wiring bodies is the same as the layout pattern of the first wiring bodies. The cell well contact area comprises cell well contacts that have the same dopant type as the cell well and that function as source/drain regions of dummy transistors formed in the cell well contact area.

Abstract: In the present resistive memory array, included are a substrate, a plurality of source regions in the substrate, and a conductor connecting the plurality of source regions, the conductor being positioned adjacent to the substrate to form, with the plurality of source regions, a common source. In one embodiment, the conductor is an elongated metal body of T-shaped cross-section. In another embodiment, the conductor is a plate-like metal body.

Abstract: Disclosed herein are embodiments of a multiple fin fin-type field effect transistor (i.e., a multiple fin dual-gate or tri-gate field effect transistor) in which the multiple fins are partially or completely merged by a highly conductive material (e.g., a metal silicide). Merging the fins in this manner allow series resistance to be minimized with little, if any, increase in the parasitic capacitance between the gate and source/drain regions. Merging the semiconductor fins in this manner also allows each of the source/drain regions to be contacted by a single contact via as well as more flexible placement of that contact via.

Abstract: Disclosed herein are an electrode layer for capacitors, a method of manufacturing the electrode layer, a unit sensor using the electrode layer, and a tactile sensor using the unit sensor. The electrode layer comprises a polymer substrate, an electrode formed on the polymer substrate, and a signal transmission line formed on the polymer substrate such that the signal transmission line is connected to the electrode. The unit sensor comprises upper and lower electrode layers, which are identical to the above-described electrode, and a spacer layer made of polymer. According to the present invention, the sensor can be easily manufactured while the sensor has high flexibility and easy extensionabilty.

Abstract: A method for manufacturing a wafer scale package including at least one substrate having replicated optical elements. The method uses two substrates, at least one of which is pre-shaped and has at least one recess in its front surface. Optical elements are replicated on a first substrate by causing a replication tool to abut the first substrate. The second substrate is then attached to the first substrate in an abutting relationship in such a way that the optical element is contained in a cavity formed by the recess in one of the substrates in combination with the other substrate. Thereby, a well defined axial distance between the optical elements and the second substrate is achieved. Consequently, a well defined axial distance between the optical elements and any other objects attached to the second substrate, e.g. further optical elements, image capturing devices, light sources, is also established.

Abstract: A semiconductor element, a semiconductor sensor, and a semiconductor memory element are provided, in which an MFMIS structure having a lower electrode and an integrated circuit can be integrated. An epitaxially grown ?-Al2O3 single crystal film (2) is disposed on a semiconductor single crystal substrate (1), and an epitaxial single crystal Pt thin film (3) is disposed on the ?-Al2O3 single crystal film (2).

Abstract: A photosensitive device for enabling high speed detection of electromagnetic radiation. The device includes recessed electrodes for providing a generally homogeneous electric field in an active region. Carriers generated in the active region are detected using the recessed electrodes.

Abstract: A solid-state element device having: a solid-state element having a pad electrode smaller than a contact electrode, the solid-state element being flip-mounted; a power receiving/supplying portion for receiving/supplying a power, the power receiving/supplying portion being bonded to the solid-state element such that an element mounting surface thereof is nearly flush with a mounting surface of the solid-state element; and an inorganic sealing portion for sealing the solid-state element formed of an inorganic sealing material and a thermal expansion coefficient equal to that of the power receiving/supplying portion. The inorganic sealing portion defines an air layer between the solid-state element and the power receiving/supplying portion.

Abstract: A light shielding film, an insulating layer, a planarizing layer, and a color filter are formed consecutively on a semiconductor substrate having plural photodiodes in a matrix arrangement. A transparent conductive film is formed on the color filter, and micro-lenses are formed directly on the conductive film such that they reside above each photodiode. Static charges on a surface of each micro-lens are discharged to the conductive film, and static charge buildup on the micro-lenses is therefore prevented.

Abstract: An optical sensor element includes: an n-type semiconductor region formed on a substrate; an i-type semiconductor region which is formed on the substrate between the p-type semiconductor region and the n-type semiconductor region and which is lower in impurity concentration than the p-type semiconductor region and the n-type semiconductor region; an anode electrode formed on the insulation film and connected to the p-type semiconductor region; and a cathode electrode formed on the insulation film and connected to the n-type semiconductor region. A reverse bias voltage Vb is applied when detecting the photocurrent, the reverse bias voltage Vb satisfying a following relation.

Abstract: A vertical rectifying and protection power diode, formed in a lightly-doped semiconductor layer of a first conductivity type, resting on a heavily-doped substrate of the first conductivity type, having a first ring-shaped region, of the first conductivity type more heavily-doped than the layer and more lightly doped than the substrate, surrounding an area of the layer and extending to the substrate; and a second ring-shaped region, doped of the second conductivity type, extending at the surface of the first region and on either side thereof; a first electrode having a thin layer of a material capable of forming a Schottky diode with the layer, resting on the area of the layer and on at least a portion of the second ring-shaped region with which it forms an ohmic contact.

Abstract: A multiple field plate transistor includes an active region, with a source, a drain, and a gate. A first spacer layer is over the active region between the source and the gate and a second spacer layer over the active region between the drain and the gate. A first field plate on the first spacer layer is connected to the gate. A second field plate on the second spacer layer is connected to the gate. A third spacer layer is on the first spacer layer, the second spacer layer, the first field plate, the gate, and the second field plate, with a third field plate on the third spacer layer and connected to the source. The transistor exhibits a blocking voltage of at least 600 Volts while supporting a current of at least 2 Amps with an on resistance of no more than 5.0 m?-cm2, of at least 600 Volts while supporting a current of at least 3 Amps with an on resistance of no more than 5.3 m?-cm2, of at least 900 Volts while supporting a current of at least 2 Amps with an on resistance of no more than 6.

Abstract: A semiconductor device and a method for manufacturing the same are provided. A gate insulating film is formed under a vacuum condition to prevent deterioration of reliability of the device due to degradation of a gate insulating material and to have stable operating characteristics. The semiconductor device includes an element isolating film formed at element isolating regions of a semiconductor substrate, which is divided into active regions and the element isolating regions; a gate insulating film having openings with a designated width formed at the active regions of the semiconductor substrate; gate electrodes formed on the gate insulating film; and lightly doped drain regions and source/drain impurity regions formed in the surface of the semiconductor substrate at both sides of the gate electrodes.

Abstract: There is provided a semiconductor device excellent in reliability. The semiconductor device is comprised of a semiconductor substrate, an insulating portion having a multilayer insulating film composed of an etch stopper film, an insulating film, an etch stopper film, an insulating film, an etch stopper film and an insulating film provided on an upper portion of the semiconductor, fuses provided on the insulating portion, and a seal ring composed of a copper containing metal film, a barrier metal film, a copper containing metal film and a barrier metal film embedded in the insulating portion so as to surround a region just below the fuses.

Abstract: An integrated circuit and fabrication method are presented. The integrated circuit includes a capacitor containing a base electrode, a covering electrode, and a dielectric between the base and covering electrodes. The dielectric contains an oxide of a material contained in the base electrode, which may be produced by anodic oxidation. A peripheral edge of the dielectric is uncovered by the covering electrode. A base layer on the capacitor includes a cutout adjacent to the dielectric. During fabrication, the base layer protects the material of the base electrode that is to be anodically oxidized from chemicals, and also protects the surrounding regions from anodic oxidation. A precision resistor may be fabricated simultaneously with the capacitor.

Abstract: When a package substrate with a built-in capacitor includes a first thin-film small electrode 41aa and a second thin-film small electrode 42aa that are electrically short-circuited to each other via a pinhole P in a high-dielectric layer 43, a power supply post 61a and a via hole 61b are not formed in the first thin-film small electrode 41aa, and a ground post 62a and a via hole 62b are not formed in the second thin-film small electrode 42aa, either. As a result, the short-circuited small electrodes 41aa and 42aa are electrically connected to neither a power supply line nor a ground line, and become a potential independent from a power supply potential and a ground potential. Therefore, in the thin-film capacitor 40, only the portion where the short-circuited small electrodes 41aa and 42aa sandwich the high dielectric layer 43 loses the capacitor function, and portions where other thin-film small electrodes 41a and 42a sandwich the high dielectric layer 43 maintain the capacitor function.

Abstract: An integrated circuit including a bipolar transistor is disclosed. One embodiment provides an insulation structure used to form a junction insulation, a collector structure formed inside a semiconductor zone having openings dividing the collector structure into collector zones. The collector zones are arranged in such a manner that a shortest lateral distance between an emitter zone and the insulation structure runs at least through one of the collector zones.

Abstract: A vertical organic transistor and a method for fabricating the same are provided, wherein an emitter, a grid with openings and a collector are sequentially arranged above a substrate. Two organic semiconductor layers are interposed respectively between the emitter and the grid with openings and between the grid with openings and the collector. The channel length is simply decided by the thickness of the organic semiconductor layers. The collector current depends on the space-charge-limited current contributed by the potential difference between the emitter and the openings of the grid. And the grid voltage can thus effectively control the collector current. Further, the fabrication process of the vertical organic transistor of the present invention is simple and exempt from using the photolithographic process.

Abstract: A ferroelectric varactor suitable for capacitive shunt switching is disclosed. High resistivity silicon with a SiO2 layer and a patterned metallic layer deposited on top is used as the substrate. A ferroelectric thin-film layer deposited on the substrate is used for the implementation of the varactor. A top metal electrode is deposited on the ferroelectric thin-film layer forming a CPW transmission line. By using the capacitance formed by the large area ground conductors in the top metal electrode and bottom metallic layer, a series connection of the ferroelectric varactor with the large capacitor defined by the ground conductors is created. The large capacitor acts as a short to ground, eliminating the need for vias. The concept of switching ON and OFF state is based on the dielectric tunability of the ferroelectric thin-films. At 0 V, the varactor has the highest capacitance value, resulting in the signal to be shunted to ground, thus isolating the output from the input.

Abstract: Structure and methods for a differential junction varactor. The structure includes: a silicon first region formed in a silicon substrate, the first region of a first dopant type; and a plurality of silicon second regions in physical and electrical contact with the first region, the plurality of second regions spaced apart and not in physical contact with each other, the plurality of second regions of a second dopant type, the first dopant type different from the second dopant type; a cathode terminal electrically connected to the first region; a first anode terminal electrically connected to a first set of second regions of the plurality of second regions; and a second anode terminal electrically connected to a second set of second silicon regions of the plurality of second regions, second regions of the first set of second regions alternating with second regions of the second set of second regions.