Abstract: An object is to reduce the resistance of each member included in a transistor, to improve ON current of the transistor, and to improve performance of an integrated circuit. A semiconductor device including an n-channel FET and a p-channel FET which are provided over a single crystal semiconductor substrate with an insulating layer interposed therebetween and are isolated by an element isolation insulating layer. In the semiconductor device, each FET includes a channel formation region including a semiconductor material, a conductive region which is in contact with the channel formation region and includes the semiconductor material, a metal region in contact with the conductive region, a gate insulating layer in contact with the channel formation region, a gate electrode in contact with the gate insulating layer, and a source or drain electrode partly including the metal region.

Abstract: A method for producing a solid-state semiconducting structure, includes steps in which: (i) a monocrystalline substrate is provided; (ii) a monocrystalline oxide layer is formed, by epitaxial growth, on the substrate; (iii) a bonding layer is formed by steps in which: (a) the impurities are removed from the surface of the monocrystalline oxide layer; (b) a semiconducting bonding layer is deposited by slow epitaxial growth; and (iv) a monocrystalline semiconducting layer is formed, by epitaxial growth, on the bonding layer so formed. The solid-state semiconducting heterostructures so obtained are also described.

Abstract: An electronic device can include a first transistor having a first channel region further including a heterojunction region that, in one aspect, is at most approximately 5 nm thick. In another aspect, the first transistor can include a p-channel transistor including a gate electrode having a work function mismatched with the associated channel region, and the heterojunction region can lie along a surface of a semiconductor layer closer to a substrate than an opposing surface of the substrate. The electronic device can also include an n-channel transistor, and the subthreshold carrier depth of the p-channel and n-channel transistors can have approximately a same value as compared to each other. A process of forming the electronic device can include forming a compound semiconductor layer having an energy band gap greater than approximately 1.2 eV.

Abstract: A semiconductor device and method of manufacturing the device is disclosed. In one aspect, the device includes a semiconductor substrate and a GaN-type layer stack on top of the semiconductor substrate. The GaN-type layer stack has at least one buffer layer, a first active layer and a second active layer. Active device regions are definable at an interface of the first and second active layer. The semiconductor substrate is present on an insulating layer and is patterned to define trenches according to a predefined pattern, which includes at least one trench underlying the active device region. The trenches extend from the insulating layer into at least one buffer layer of the GaN-type layer stack and are overgrown within the at least one buffer layer, so as to obtain that the first and the second active layer are continuous at least within the active device regions.

Abstract: In a thin film transistor, an increase in off current or negative shift of the threshold voltage is prevented. In the thin film transistor, a buffer layer is provided between an oxide semiconductor layer and each of a source electrode layer and a drain electrode layer. The buffer layer includes a metal oxide layer which is an insulator or a semiconductor over a middle portion of the oxide semiconductor layer. The metal oxide layer functions as a protective layer for suppressing incorporation of impurities into the oxide semiconductor layer. Therefore, in the thin film transistor, an increase in off current or negative shift of the threshold voltage can be prevented.

Abstract: The disclosure concerns a method of manufacturing a semiconductor device including forming a plurality of fins made of a semiconductor material on an insulating layer; forming a gate insulating film on side surfaces of the plurality of fins; and forming a gate electrode on the gate insulating film in such a manner that a compressive stress is applied to a side surface of a first fin which is used in an NMOSFET among the plurality of fins in a direction perpendicular to the side surface and a tensile stress is applied to a side surface of a second fin which is used in a PMOSFET among the plurality of fins in a direction perpendicular to the side surface.

Abstract: The present invention efficiently arranges a spare TFT element in a pixel region of a liquid crystal display device. A display device includes a substrate on which TFT elements which are arranged in pixel regions each of which is surrounded by two neighboring scanning signal lines and two neighboring video signal lines are formed. The substrate arranges a first TFT element and a second TFT element in each pixel region in which the first TFT element and the second TFT element independently include a channel layer, a drain electrode and a source electrode respectively, only either one of the first TFT element and the second TFT element in each pixel region is operated when a video signal is applied to the video signal line and a scanning signal is applied to the scanning signal line, and the first TFT element and the second TFT element differ from each other in largeness or a shape of an occupied area or a channel width and a channel length of each TFT element when the substrate is viewed in a plan view.

Abstract: There is provided a method of removing trap levels and defects, which are caused by stress, from a single crystal silicon thin film formed by an SOI technique. First, a single crystal silicon film is formed by using a typical bonding SOI technique such as Smart-Cut or ELTRAN. Next, the single crystal silicon thin film is patterned to form an island-like silicon layer, and then, a thermal oxidation treatment is carried out in an oxidizing atmosphere containing a halogen element, so that an island-like silicon layer in which the trap levels and the defects are removed is obtained.

Abstract: Disclosed is an integrated circuit device having series-connected planar or non-planar field effect transistors (FETs) with integrated voltage equalization and a method of forming the device. The series-connected FETs comprise gates positioned along a semiconductor body to define the channel regions for the series-connected FETs. Source/drain regions are located within the semiconductor body on opposing sides of the channel regions such that each portion of the semiconductor body between adjacent gates comprises one source/drain region for one field effect transistor abutting another source/drain region for another field effect transistor. Integrated voltage equalization is achieved through a conformal conductive layer having a desired resistance and positioned over the series-connected FETs such that it is electrically isolated from the gates, but in contact with the source/drain regions within the semiconductor body.

Abstract: Semiconductor device structures including a semiconductor body that is partially depleted to define a floating charge-neutral region supplying a floating body for charge storage and methods for forming such semiconductor device structures. The width of the semiconductor body is modulated so that different sections of the body have different widths. When electrically biased, the floating charge-neutral region at least partially resides in the wider section of the semiconductor body.

Abstract: A semiconductor device has at least two main carbon-rich regions and two additional carbon-rich regions. The main carbon-rich regions are separately located in a substrate so that a channel region is located between them. The additional carbon-rich regions are respectively located underneath the main carbon-rich regions. The carbon concentrations is higher in the main carbon-rich regions and lower in the additional carbon-rich regions, and optionally, the absolute value of a gradient of the carbon concentration of the bottom portion of the main carbon-rich regions is higher than the absolute value of a gradient of the carbon concentration of the additional carbon-rich regions. Therefore, the leakage current induced by a lattice mismatch effect at the carbon-rich and the carbon-free interface can be minimized.

Abstract: A TFT formed on an insulating substrate source, drain and channel regions, a gate insulating film formed on at least the channel region and a gate electrode formed on the gate insulating film. Between the channel region and the drain region, a region having a higher resistivity is provided in order to reduce an Ioff current. A method for forming this structure comprises the steps of anodizing the gate electrode to form a porous anodic oxide film on the side of the gate electrode; removing a portion of the gate insulating using the porous anodic oxide film as a mask so that the gate insulating film extends beyond the gate electrode but does not completely cover the source and drain regions. Thereafter, an ion doping of one conductivity element is performed. The high resistivity region is defined under the gate insulating film.

Abstract: One or more embodiments relate to a static random access memory cell comprising: a first inverter including a first n-channel pull-down transistor coupled between a first node and a ground voltage; a second inverter including a second n-channel pull-down transistor coupled between a second node and the ground voltage; a first n-channel access transistor coupled between a first bit line and the first node of the first inverter, a fin of the first n-channel access transistor having a lower charge carrier mobility than a fin of the first n-channel pull-down transistor; and a second n-channel access transistor coupled between a second bit line and the second node of the second inverter, a fin of the second n-channel access transistor having a lower charge carrier mobility than a fin of the second n-channel pull-down transistor.

Abstract: A multi-gate transistor and a method of forming a multi-gate transistor, the multi-gate transistor including a fin having an upper portion and a lower portion. The upper portion having a first band gap and the lower portion having a second band gap with the first band gap and the second band gap designed to inhibit current flow from the upper portion to the lower portion. The multi-gate transistor further including a gate structure having sidewalls electrically coupled with said upper portion and said lower portion and a substrate positioned below the fin.

Abstract: A process may include first etching a trench isolation dielectric through a dielectric hard mask that abuts the sidewall of a fin semiconductor. The first etch can be carried out to expose at least a portion of the sidewall, causing the dielectric hard mask to recede to a greater degree in the lateral direction than the vertical direction. The process may include second etching the fin semiconductor to achieve a thinned semiconductor fin, which has receded beneath the shadow of the laterally receded hard mask. The thinned semiconductor fin may have a characteristic dimension that can exceed photolithography limits. Electronic devices may include the thinned semiconductor fin as part of a field effect transistor.

Abstract: A method for fabrication of 3D semiconductor devices utilizing a layer transfer and steps for forming transistors on top of a pre-fabricated semiconductor device comprising transistors formed on crystallized semiconductor base layer and metal layer for the transistors interconnections and insulation layer. The advantage of this approach is reduction of the over all metal length used to interconnect the various transistors.

Abstract: In a high breakdown voltage semiconductor element among elements integrated together on an SOI substrate in which its rated voltage is shared between an embedded oxide layer and a drain region formed by an element active layer, both high integration and high breakdown voltage are realized while also securing suitability for practical implementation and practical use. The high breakdown voltage is realized without hampering size reduction of the element by forming an electrically floating layer of a conductivity type opposite to that of the drain region at the surface of the drain region. Further, the thickness of the embedded oxide layer is reduced to a level suitable for the practical implementation and practical use by setting the thickness of the element active layer of the SOI substrate at 30 ?m or more.

Abstract: Multi-gate metal oxide silicon transistors and methods of making multi-gate metal oxide silicon transistors are provided. The multi-gate metal oxide silicon transistor contains a bulk silicon substrate containing one or more convex portions between shallow trench regions; one or more dielectric portions over the convex portions; one or more silicon fins over the dielectric portions; a shallow trench isolation layer in the shallow trench isolation regions; and a gate electrode. The upper surface of the shallow trench isolation layer can be located below the upper surface of the convex portion, or the upper surface of the shallow trench isolation layer can be located between the lower surface and the upper surface of first dielectric layer. The multi-gate metal oxide silicon transistor can contain second spacers adjacent to side surfaces of the convex portions in a source/drain region.

Abstract: An object of the present invention is to provide a method for manufacturing a thin film transistor which enables heat treatment aimed at improving characteristics of a gate insulating film such as lowering of an interface level or reduction in a fixed charge without causing a problem of misalignment in patterning due to expansion or shrinkage of glass. A method for manufacturing a thin film transistor of the present invention comprises the steps of heat-treating in a state where at least a gate insulating film is formed over a semiconductor film on which element isolation is not performed, simultaneously isolating the gate insulating film and the semiconductor film into an element structure, forming an insulating film covering a side face of an exposed semiconductor film, thereby preventing a short-circuit between the semiconductor film and a gate electrode.

Abstract: A semiconductor structure includes a semiconductor substrate; a planar transistor on a first portion of the semiconductor substrate, wherein the first portion of the semiconductor substrate has a first top surface; and a multiple-gate transistor on a second portion of the semiconductor substrate. The second portion of the semiconductor substrate is recessed from the first top surface to form a fin of the multiple-gate transistor. The fin is electrically isolated from the semiconductor substrate by an insulator.

Abstract: A process is provided for fabricating rounded three-dimensional germanium active channels for transistors and sensors. For forming sensors, the process comprises providing a crystalline silicon substrate; depositing an oxide mask on the crystalline silicon substrate; patterning the oxide mask with trenches to expose linear regions of the silicon substrate; epitaxially grow germanium selectively in the trenches, seeded from the silicon wafer; optionally etching the SiO2 mask partially, so that the cross section resembles a trapezoid on a stem; and annealing at an elevated temperature. The annealing process forms the rounded channel. For forming transistors, the process further comprises depositing and patterning a gate oxide and gate electrode onto this structure to form the gate stack of a MOSFET device; and after patterning the gate, implanting dopants into the source and drain located on the parts of the germanium cylinder on either side of the gate line.

Abstract: According to the present invention, a circuit and methods for enhancing the operation of SOI fabricated devices are disclosed. In a preferred embodiment of the present invention, a pulse discharge circuit is provided. Here, a circuit is designed to provide a pulse that will discharge the accumulated electrical charge on the body of the SOI devices in the memory subarray just prior to the first access cycle. As explained above, once the accumulated charge has been dissipated, the speed penalty for successive accesses to the memory subarray is eliminated or greatly reduced. With a proper control signal, timing and sizing, this can be a very effective method to solve the problem associated with the SOI loading effect. Alternatively, instead of connecting the bodies of all SOI devices in a memory circuit to ground, the bodies of the N-channel FET pull-down devices of the local word line drivers can be selectively connected to a reference ground.

Abstract: A FinFET and nanowire transistor with strain direction optimized in accordance with the sideface orientation and carrier polarity and an SMT-introduced manufacturing method for achieving the same are provided. A semiconductor device includes a pMISFET having a semiconductor substrate, a rectangular solid-shaped semiconductor layer formed at upper part of the substrate to have a top surface parallel to a principal plane of the substrate and a sideface with a (100) plane perpendicular to the substrate's principal plane, a channel region formed in the rectangular semiconductor layer, a gate insulating film formed at least on the sideface of the rectangular layer, a gate electrode on the gate insulator film, and source/drain regions formed in the rectangular semiconductor layer to interpose the channel region therebetween. The channel region is applied a compressive strain in the perpendicular direction to the substrate principal plane. A manufacturing method of the device is also disclosed.

Abstract: A method for manufacturing a semiconductor device with high response speed and high reliability. In the method for manufacturing a semiconductor device of the invention, a bonding layer is formed over a substrate, an insulating film and a storage capacitor portion lower electrode are formed over the bonding layer, a single crystal silicon layer is formed over the insulating film, a storage capacitor portion insulating film is formed over the storage capacitor portion lower electrode, a wiring is formed over the storage capacitor portion insulating film, a channel forming region and a low concentration impurity region are formed over the single crystal silicon layer, and a gate insulating film and a gate electrode are formed over the single crystal silicon layer. The storage capacitor portion insulating film is formed by depositing a YSZ film with a single crystal silicon layer used as a base film, whereby the permittivity increases and thus the leakage current from the storage capacitor portion is suppressed.

Abstract: This disclosure concerns a memory comprising a semiconductor layer extending in a first direction; a source; a drain; a body between the source and the drain; a bit-line extending in the first direction; a first gate-dielectric on a first side-surface of the body; a first gate-electrode on the first side-surface of the body via the first gate dielectric film; a first gate line extending in the first direction, connected to a bottom of the first gate-electrode, and formed integratedly with the first gate-electrode using same material; a second gate dielectric on a second side-surface of the body; a second gate-electrode on the second side surface of the body via the second gate dielectric film; and a second gate line extending in a second direction crossing the first direction, connected to an upper portion of the second gate-electrode, and formed integratedly with the second gate-electrode using same material.

Abstract: The present invention provides a technology that makes it possible to enhance the gain and the efficiency of an RF bipolar transistor. Device isolation is given between a p+ type isolation region and an n+ type collector embedded region and between a p+ type isolation region and an n type collector region (an n+ type collector extraction region) with an isolation section that surrounds the collector extraction region in a plan view and is formed by embedding a dielectric film in a groove penetrating an isolation section, a collector region, and a collector embedded region and reaching a substrate. Further, a current route is formed between an emitter wiring (a wiring) and the substrate with an electrically conductive layer formed by embedding the electrically conductive layer in a groove penetrating a dielectric film, silicon oxide films, a semiconductor region, and the isolation regions and reaching the substrate, and thereby the impedance between the emitter wiring and the substrate is reduced.

Abstract: TFT structures optimal for driving conditions of a pixel portion and driving circuits are obtained using a small number of photo masks. First through third semiconductor films are formed on a first insulating film. First shape first, second, and third electrodes are formed on the first through third semiconductor films. The first shape first, second, third electrodes are used as masks in first doping treatment to form first concentration impurity regions of one conductivity type in the first through third semiconductor films. Second shape first, second, and third electrodes are formed from the first shape first, second, and third electrodes. A second concentration impurity region of the one conductivity type which overlaps the second shape second electrode is formed in the second semiconductor film in second doping treatment. Also formed in the second doping treatment are third concentration impurity regions of the one conductivity type which are placed in the first and second semiconductor films.

Abstract: A thin-film transistor includes an insulating substrate, a source electrode, and a drain electrode, disposed over the top of the insulating substrate, a semiconductor layer electrically continuous with the source electrode, and the drain electrode, respectively, a gate dielectric film formed over the top of at least the semiconductor layer; and a gate electrode disposed over the top of the gate dielectric film so as to overlap the semiconductor layer. Further, a first bank insulator is formed so as to overlie the source electrode, a second bank insulator is formed so as to overlie the drain electrode, and the semiconductor layer, the gate dielectric film, and the gate electrode are embedded in a region between the first bank insulator, and the second bank insulator.

Abstract: A method of fabricating a semiconductor device is provided in which the channel of the device is present in an extremely thin semiconductor-on-insulator (ETSOI) layer, i.e., a semiconductor layer having a thickness of less than 20 nm. In one embodiment, the method begins with forming a first semiconductor layer and epitaxially growing a second semiconductor layer on a handling substrate. A first gate structure is formed on a first surface of the second semiconductor layer and source regions and drain regions are formed adjacent to the gate structure. The handling substrate and the first semiconductor layer are removed to expose a second surface of the second semiconductor layer that is opposite the first surface of the semiconductor layer. A second gate structure or a dielectric region is formed in contact with the second surface of the second semiconductor layer.

Abstract: An integrated circuit includes a bulk technology integrated circuit (bulk IC) including a bulk silicon layer and complementary MOSFET (CMOS) transistors fabricated thereon. The integrated circuit also includes a single transistor dynamic random access memory (1T DRAM) cell arranged adjacent to and integrated with the bulk IC.

Abstract: A field-effect transistor comprising a movable gate electrode that suppresses a leakage current from the gate electrode, and has a large current drivability and a low leakage current between a source and a drain. The field-effect transistor comprises: an insulating substrate; a semiconductor layer of triangle cross-sectional shape formed on the insulating substrate, having a gate insulation film on a surface, and forming a channel in a lateral direction; fixed electrodes that are arranged adjacent to both sides of the semiconductor layer and in parallel to the semiconductor layer, each of the electrodes having an insulation film on a surface; a source/drain formed at the end part of the semiconductor layer; and the movable gate electrode formed above the semiconductor layer and the fixed electrodes with a gap.

Abstract: A vertical transistor of a semiconductor device and a method for forming the same are disclosed. The vertical transistor comprises a silicon fin disposed on a semiconductor substrate, a source region disposed in the semiconductor substrate below a lower portion of the silicon fin, a drain region disposed in an upper portion of the silicon fin, a channel region disposed in a sidewall of the silicon fin between the source region and the drain region, a gate oxide film disposed in a surface of the semiconductor substrate and the sidewall of the silicon fin, and a pair of gate electrodes disposed on the gate oxide films.

Abstract: A double-structure silicon on insulator (SOI) substrate with a silicon layer, an insulation film (silicon oxide film), a silicon layer, and an insulation film in this order from the side of the surface. The upper-layer insulation film is formed so as to have a uniform distribution of depth while the lower-layer insulation film is formed so as to have a non-uniform distribution of depth so that a thick portion may be formed in the silicon layer along a predetermined path. The refractive index of Si is 3.5 and the refractive index of SiO2 is 1.5. The thick portion of the silicon layer provides a core and the insulation films corresponding to this thick portion provide clads, thereby forming an optical waveguide along the predetermined path. The silicon layer at the side of the surface has a uniform thickness, thereby enabling characteristics of MOS devices fabricated on various portions of the silicon layer to be met with each other easily and facilitating a design of the electrical device as a whole.

Abstract: A method for fabrication of 3D semiconductor devices utilizing a layer transfer and steps for forming transistors on top of a pre-fabricated semiconductor device comprising transistors formed on crystallized semiconductor base layer and metal layer for the transistors interconnections and insulation layer. The advantage of this approach is reduction of the over all metal length used to interconnect the various transistors.

Abstract: A semiconductor substrate comprising: a semiconductor base; dielectric layers of mutually different film thicknesses formed on the semiconductor base; and semiconductor layers of mutually different film thicknesses formed on the dielectric layers.

Abstract: Disclosed herein is a TFT substrate which exhibits good characteristic properties despite the omission of the barrier metal layer to be normally interposed between the source-drain electrodes and the semiconductor layer in the TFT. The TFT substrate permits sure and direct connection with the semiconductor layer of the TFT. The thin film transistor substrate has a substrate, a semiconductor layer and source-drain electrodes. The source-drain electrodes are composed of oxygen-containing layers and thin films of pure copper or a copper alloy. The oxygen-containing layer contains oxygen such that part or all of oxygen combines with silicon in the semiconductor layer. And, the thin films of pure copper or a copper alloy connect with the semiconductor layer of the thin film transistor through the oxygen-containing layers.

Abstract: Structures and methods for integrating a thick oxide high-voltage metal-oxide-semiconductor (MOS) device into a thin oxide silicon-on-insulator (SOI). A method of forming a semiconductor structure includes forming first source and drain regions of a first device below a buried oxide layer of a silicon-on-insulator (SOI) wafer, forming a gate of the first device in a layer of semiconductor material above the buried oxide layer; and forming second source and drain regions of a second device in the layer of semiconductor material above the buried oxide layer.

Abstract: A power source and methods thereof includes a structure comprising one or more p type layers, one or more n type layers, and one or more intrinsic layers and at least one source of radiation is disposed on at least a portion of the structure. Each of the p type layers is separated from each of the n type layers by one of the intrinsic layers.

Abstract: A device includes a first transistor including a fin and a second transistor including a fin, the fin of the first transistor having a lower charge carrier mobility than the fin of the second transistor. In a method, the fin of the first transistor is treated to have a lower charge carrier mobility than the fin of the second transistor.

Abstract: To provide a structure and a manufacturing method for efficiently forming a transistor to which tensile strain is preferably applied and a transistor to which compressive strain is preferably applied over the same substrate when stress is applied to a semiconductor layer in order to improve mobility of the transistors in a semiconductor device. Plural kinds of transistors which are separated from a single-crystal semiconductor substrate and include single-crystal semiconductor layers bonded to a substrate having an insulating surface with a bonding layer interposed therebetween are provided over the same substrate. One of the transistors uses a single-crystal semiconductor layer as an active layer, to which tensile strain is applied. The other transistors use single-crystal semiconductor layers as active layers, to which compressive strain using part of heat shrink generated by heat treatment of the base substrate after bonding is applied.

Abstract: Provided is a fin field effect transistor (FinFET) having low leakage current and a method of manufacturing the same. The FinFET includes: a bulk silicon substrate; a fence-shaped body formed by patterning the substrate; an insulating layer formed on a surface of the substrate to a first height of the fence-shaped body; a gate insulating layer formed at side walls and an upper surface of the fence-shaped body at which the insulating layer is not formed; a gate electrode formed on the gate insulating layer; source/drain formed at regions of the fence-shaped body where the gate electrode is not formed. The gate electrode includes first and second gate electrodes which are in contact with each other and have different work functions. Particularly, the second gate electrode having a low work function is disposed to be close to the drain.

Abstract: The present invention relates to high performance three-dimensional (3D) field effect transistors (FETs). Specifically, a 3D semiconductor structure having a bottom surface oriented along one of a first set of equivalent crystal planes and multiple additional surfaces oriented along a second, different set of equivalent crystal planes can be used to form a high performance 3D FET with carrier channels oriented along the second, different set of equivalent crystal planes. More importantly, such a 3D semiconductor structure can be readily formed over the same substrate with an additional 3D semiconductor structure having a bottom surface and multiple additional surfaces all oriented along the first set of equivalent crystal planes. The additional 3D semiconductor structure can be used to form an additional 3D FET, which is complementary to the above-described 3D FET and has carrier channels oriented along the first set of equivalent crystal planes.

Abstract: A process may include first etching a trench isolation dielectric through a dielectric hard mask that abuts the sidewall of a fin semiconductor. The first etch can be carried out to expose at least a portion of the sidewall, causing the dielectric hard mask to recede to a greater degree in the lateral direction than the vertical direction. The process may include second etching the fin semiconductor to achieve a thinned semiconductor fin, which has receded beneath the shadow of the laterally receded hard mask. The thinned semiconductor fin may have a characteristic dimension that can exceed photolithography limits. Electronic devices may include the thinned semiconductor fin as part of a field effect transistor.

Abstract: Embodiments relate to a method for fabricating a transistor by using a SOI wafer. A gate insulation layer and a first gate conductive layer on a silicon-on-insulator substrate of a substrate to form a first gate conductive pattern, a gate insulation layer pattern, and a silicon layer pattern. A device isolation insulation layer exposing the top surface of the first gate conductive layer pattern may be formed. A second gate conductive layer may be formed. A mask pattern may be formed. Then, a gate may be formed by etching. After forming a source and drain conductive layer on the silicon layer pattern, the mask pattern may be removed. A salicide layer may be selectively contacting the gate and the source and drain conductive layer may be formed.

Abstract: An integrated circuit structure includes a semiconductor substrate; a metallization layer over the semiconductor substrate; a first dielectric layer between the semiconductor substrate and the metallization layer; a second dielectric layer between the semiconductor substrate and the metallization layer, wherein the second dielectric layer is over the first dielectric layer; and a contact plug with an upper portion substantially in the second dielectric layer and a lower portion substantially in the first dielectric layer. The contact plug is electrically connected to a metal line in the metallization layer. The contact plug is discontinuous at an interface between the upper portion and the lower portion.

Abstract: In one aspect, the present invention teaches a multiple-gate transistor 130 that includes a semiconductor fin 134 formed in a portion of a bulk semiconductor substrate 132. A gate dielectric 144 overlies a portion of the semiconductor fin 134 and a gate electrode 146 overlies the gate dielectric 144. A source region 138 and a drain region 140 are formed in the semiconductor fin 134 oppositely adjacent the gate electrode 144. In the preferred embodiment, the bottom surface 150 of the gate electrode 146 is lower than either the source-substrate junction 154 or the drain-substrate junction 152.

Abstract: A method for making floating body memory cells from a bulk substrate. A thin silicon germanium and overlying silicon layers are formed on the bulk substrate. Anchors and a bridge are formed to support the silicon layer when the silicon germanium layer is etched so that it can be replaced with an oxide.

Abstract: A TFT formed on an insulating substrate source, drain and channel regions, a gate insulating film formed on at least the channel region and a gate electrode formed on the gate insulating film. Between the channel region and the drain region, a region having a higher resistivity is provided in order to reduce an Ioff current. A method for forming this structure comprises the steps of anodizing the gate electrode to form a porous anodic oxide film on the side of the gate electrode; removing a portion of the gate insulating using the porous anodic oxide film as a mask so that the gate insulating film extends beyond the gate electrode but does not completely cover the source and drain regions. Thereafter, an ion doping of one conductivity element is performed. The high resistivity region is defined under the gate insulating film.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed, in which an insulating layer may be formed in a strained silicon layer under source/drain regions to substantially overcome conventional problems resulting from a channel decrease in the semiconductor device.

Abstract: There is provided a method of removing trap levels and defects, which are caused by stress, from a single crystal silicon thin film formed by an SOI technique. First, a single crystal silicon film is formed by using a typical bonding SOI technique such as Smart-Cut or ELTRAN. Next, the single crystal silicon thin film is patterned to form an island-like silicon layer, and then, a thermal oxidation treatment is carried out in an oxidizing atmosphere containing a halogen element, so that an island-like silicon layer in which the trap levels and the defects are removed is obtained.